NZ627116B2 - Novel antibiotic preparation method and platform system based on same - Google Patents
Novel antibiotic preparation method and platform system based on same Download PDFInfo
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- NZ627116B2 NZ627116B2 NZ627116A NZ62711612A NZ627116B2 NZ 627116 B2 NZ627116 B2 NZ 627116B2 NZ 627116 A NZ627116 A NZ 627116A NZ 62711612 A NZ62711612 A NZ 62711612A NZ 627116 B2 NZ627116 B2 NZ 627116B2
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Classifications
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- C07K14/195—Peptides having more than 20 amino acids; Gastrins; Somatostatins; Melanotropins; Derivatives thereof from bacteria
- C07K14/24—Peptides having more than 20 amino acids; Gastrins; Somatostatins; Melanotropins; Derivatives thereof from bacteria from Enterobacteriaceae (F), e.g. Citrobacter, Serratia, Proteus, Providencia, Morganella, Yersinia
- C07K14/245—Escherichia (G)
-
- C—CHEMISTRY; METALLURGY
- C07—ORGANIC CHEMISTRY
- C07K—PEPTIDES
- C07K16/00—Immunoglobulins [IGs], e.g. monoclonal or polyclonal antibodies
-
- C—CHEMISTRY; METALLURGY
- C07—ORGANIC CHEMISTRY
- C07K—PEPTIDES
- C07K16/00—Immunoglobulins [IGs], e.g. monoclonal or polyclonal antibodies
- C07K16/08—Immunoglobulins [IGs], e.g. monoclonal or polyclonal antibodies against material from viruses
- C07K16/081—Immunoglobulins [IGs], e.g. monoclonal or polyclonal antibodies against material from viruses from DNA viruses
- C07K16/085—Herpetoviridae, e.g. pseudorabies virus, Epstein-Barr virus
-
- C—CHEMISTRY; METALLURGY
- C07—ORGANIC CHEMISTRY
- C07K—PEPTIDES
- C07K16/00—Immunoglobulins [IGs], e.g. monoclonal or polyclonal antibodies
- C07K16/12—Immunoglobulins [IGs], e.g. monoclonal or polyclonal antibodies against material from bacteria
- C07K16/1203—Immunoglobulins [IGs], e.g. monoclonal or polyclonal antibodies against material from bacteria from Gram-negative bacteria
-
- C—CHEMISTRY; METALLURGY
- C07—ORGANIC CHEMISTRY
- C07K—PEPTIDES
- C07K19/00—Hybrid peptides, i.e. peptides covalently bound to nucleic acids, or non-covalently bound protein-protein complexes
-
- C—CHEMISTRY; METALLURGY
- C07—ORGANIC CHEMISTRY
- C07K—PEPTIDES
- C07K2317/00—Immunoglobulins specific features
- C07K2317/70—Immunoglobulins specific features characterized by effect upon binding to a cell or to an antigen
- C07K2317/73—Inducing cell death, e.g. apoptosis, necrosis or inhibition of cell proliferation
-
- C—CHEMISTRY; METALLURGY
- C07—ORGANIC CHEMISTRY
- C07K—PEPTIDES
- C07K2319/00—Fusion polypeptide
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- C12—BIOCHEMISTRY; BEER; SPIRITS; WINE; VINEGAR; MICROBIOLOGY; ENZYMOLOGY; MUTATION OR GENETIC ENGINEERING
- C12N—MICROORGANISMS OR ENZYMES; COMPOSITIONS THEREOF; PROPAGATING, PRESERVING, OR MAINTAINING MICROORGANISMS; MUTATION OR GENETIC ENGINEERING; CULTURE MEDIA
- C12N15/00—Mutation or genetic engineering; DNA or RNA concerning genetic engineering, vectors, e.g. plasmids, or their isolation, preparation or purification; Use of hosts therefor
- C12N15/09—Recombinant DNA-technology
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- C12N15/00—Mutation or genetic engineering; DNA or RNA concerning genetic engineering, vectors, e.g. plasmids, or their isolation, preparation or purification; Use of hosts therefor
- C12N15/09—Recombinant DNA-technology
- C12N15/11—DNA or RNA fragments; Modified forms thereof; Non-coding nucleic acids having a biological activity
- C12N15/62—DNA sequences coding for fusion proteins
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- C12—BIOCHEMISTRY; BEER; SPIRITS; WINE; VINEGAR; MICROBIOLOGY; ENZYMOLOGY; MUTATION OR GENETIC ENGINEERING
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- C12N15/00—Mutation or genetic engineering; DNA or RNA concerning genetic engineering, vectors, e.g. plasmids, or their isolation, preparation or purification; Use of hosts therefor
- C12N15/09—Recombinant DNA-technology
- C12N15/63—Introduction of foreign genetic material using vectors; Vectors; Use of hosts therefor; Regulation of expression
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N2500/00—Screening for compounds of potential therapeutic value
- G01N2500/04—Screening involving studying the effect of compounds C directly on molecule A (e.g. C are potential ligands for a receptor A, or potential substrates for an enzyme A)
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N33/00—Investigating or analysing materials by specific methods not covered by groups G01N1/00 - G01N31/00
- G01N33/48—Biological material, e.g. blood, urine; Haemocytometers
- G01N33/50—Chemical analysis of biological material, e.g. blood, urine; Testing involving biospecific ligand binding methods; Immunological testing
- G01N33/53—Immunoassay; Biospecific binding assay; Materials therefor
- G01N33/569—Immunoassay; Biospecific binding assay; Materials therefor for microorganisms, e.g. protozoa, bacteria, viruses
Abstract
Disclosed is an antibiotic preparation method, comprising steps as follows: (1) determining targets selected from prokaryotic cells, eukaryotic cells, viruses or products thereof which said antibiotic will react against directly; (2) designing a molecular structure of said antibiotic according to the formula F-R: wherein, R is a recognition region, which specifically recognizes or combines said targets; F is an effect region, which generates pharmaceutical effects in said targets, and said pharmaceutical effects are effects selected from regulating, repairing, labelling and causing death of said targets; specifically comprising ; making a recognition region molecular structure library; making an effect region molecular structure library; designing a recombinant molecular structure library using said recognition region molecular structure library and said effect region molecular structure library according to said general formula by structural readjustment, structural recombination and/or structural confirmation of the molecular structures for the recognition region; (3) using said recombinant molecular structure library to prepare and verify recombinants to obtain candidate antibiotics; (4) screening the candidates from (3) for fulfilment of requirements as a medicine to obtain antibiotics; said making a recognition region molecular structure library refers to artificially preparing artificial substances which specifically recognize and/or combine said targets as well as obtaining a molecular structure thereof; wherein said artificial substances are antibody mimetics designed according to the amino acid sequence of an immunoglobulin which can specifically recognize a unique substance on said targets. the formula F-R: wherein, R is a recognition region, which specifically recognizes or combines said targets; F is an effect region, which generates pharmaceutical effects in said targets, and said pharmaceutical effects are effects selected from regulating, repairing, labelling and causing death of said targets; specifically comprising ; making a recognition region molecular structure library; making an effect region molecular structure library; designing a recombinant molecular structure library using said recognition region molecular structure library and said effect region molecular structure library according to said general formula by structural readjustment, structural recombination and/or structural confirmation of the molecular structures for the recognition region; (3) using said recombinant molecular structure library to prepare and verify recombinants to obtain candidate antibiotics; (4) screening the candidates from (3) for fulfilment of requirements as a medicine to obtain antibiotics; said making a recognition region molecular structure library refers to artificially preparing artificial substances which specifically recognize and/or combine said targets as well as obtaining a molecular structure thereof; wherein said artificial substances are antibody mimetics designed according to the amino acid sequence of an immunoglobulin which can specifically recognize a unique substance on said targets.
Description
Description
Novel Antibiotic Preparation Method and Platform System Based on Same
Technical Field
? This invention relates to biological ne developing technology, especially to a novel
antibiotic ation method and platform system based on same.
Background
Currently, the research and development of pharmaceutical ry, particularly antibiotic, is
facing difficulties: 1. There are more and more drug-resistant pathogenic bacteria. Current
antibiotics don't pose a threat to drug-resistant pathogenic bacteria. Mortality rate caused by these
drug-resistant pathogenic ia is increasing. 2. The speed of novel medicine developing is far
behind the occurring pace of drug-resistant pathogenic bacteria. It needs long time and costs much
to screen antibiotics with traditional methods as well as obtain the achievement from the research
and development. 3. The novel antibiotics developed by gene engineering or biotechnology are
? still easy to result in drug-resistance of pathogenic bacteria.
It was shown by statistics data of WHO that, in millions of people infected with drug-resistant
staphylococcus aureus every year, around 30% of said people die finally---which is higher than
the mortality rate of AIDS. In order to cure ion of drug-resistant staphylococcus aureus, the
cost of whole world s 20 n USD every year. After drug-resistant staphylococcus
aureus occurred, vancomycin became the main role to cure staphylococcus aureus ion.
However, there has been vancomycin-resistant staphylococcus aureus occurred in hospital since
2002. gh the spreading area of vancomycin-resistant staphylococcus aureus is small at
present, there is little ne that can t them effectively, so the mortality rate caused by
infection of vancomycin-resistant staphylococcus aureus is very high. In the latest 10 years,
another drug-resistant bacteria—multi-drug-resistant Gram-negative bacteria occurred, and they
have stronger drug-resistance. Almost none of antibiotics used in t clinical medicine can
threaten said drug-resistant bacteria.
Currently most of antibiotics are produced by bacteria and fungi, or derived from natural
antibiotics by chemical modification. The traditional screening method for antibiotics comprises
isolating microorganisms from soil samples, extracting secretions from medium for growing said
rganisms, detecting substance with antibacterial or izing effects in said secretions and
separating individual medicine ingredients with potential medicinal value. The method was very
effective in golden age of developing antibiotics (1940-1950). But it comes to the end now, as
? said screening method depends on secretions of bacteria and fungi in nature, namely the novel
antibiotics are obtained by screening and modifying secretions of discovered microorganisms.
Said traditional method for developing antibiotics requires long time unavoidably, and has
uncertain e. Thus, in the past 50 years, ceutical companies never stopped screening
antibiotics, but novel antibiotics screened are less and less. It's demonstrated by statistics data of
Infectious Diseases Society of America (IDSA) that, in recent new medicine applications of FDA
in US, there are only 16 novel antibiotics applications, and there is no one patent application
about otic against highly-drug-resistant Gram-negative bacteria. The famous popular
e magazine "Scientific American" had warned continuously from 2009 to 2012 that, super
? are threatening human life safety. CDC in US forecast that, the current used antibiotics would
become invalid y 10-20 years later. The New York Times reports that, due to abusing
antibiotics in agriculture, human would go back to the times without any available antibiotics 5
years later, and NDM-1 super ium mutant genes has lead to panic in the world. The problem
of antibiotics and esistant bacteria in stockbreeding is also a serious problem, and has
? influenced agricultural product safety. The recent 40 years is a vacuum period of antibiotics
development. In a word, the speed of developing and researching novel medicine is far behind the
pace of drug-resistant bacteria mutation.
At t, there are two methods for developing novel antibiotics: (1) modifying current
antibiotics or synthesizing new type of antibiotics, (2) conducting gene modification on bacteria
synthesizing antibiotics. However, both of said two methods have not overstepped such a keynote
that : antibacterial mechanism of said antibiotics is not novel to bacteria. Therefore, without
ion, the bacteria will generate drug-resistance to said "novel" antibiotics soon.
In order to resist pathogenic microorganisms with strong variability, strong viability, strong
pathogenicity and various species, the problems urgent to be solved tly are as follows:
1. providing antibiotics with stronger antibacterial or sterilizing effects to pathogenic bacteria,
especially to drug-resistant pathogenic bacteria;
2. providing methods for preparing said antibiotics in clause 1, ably methods which can
? response to variability of pathogenic bacteria, i.e. developing and researching methods of
antibiotics with short development cycle, which can sensitively resist new or variant pathogenic
microorganisms;
3. said antibiotics developed by said method will not lead to esistance of pathogenic
microorganisms in a short time.
However, the above-mentioned problems are just "conundrums" which have not been solved by
current several generations of antibiotics and ional antibiotics developing methods.
Summary of Invention
In view of technical difficulties of obtaining novel antibiotics existing in
? above-mentioned fields, provided is a method and platform different from traditional strategies
for developing antibiotics. Through said method and platform, novel otics with specific
recognition and
killing capacity against any pathogenic rganism, target cell or target tissue can be offered
in a short term; Said methods can sensitively solve drug-resistance raised due to continuous
? mutation of pathogenic microorganism, i.e., promptly provides corresponding novel antibiotics
against newly-raised variant strains. And said novel antibiotics prepared by said method rarely
lead to variance of enic microorganism as well as drug-resistance, due to their novel
sterilization mechanism. Technical solution of this ion is as follows:
? A novel antibiotic preparation method, wherein steps are as follows:
(1) determining targets: said s refer to yotic cells, eukaryotic cells, viruses or products
thereof which said novel antibiotic will react against directly;
(2) designing molecular structure of said novel antibiotic:
said lar structure of said novel otic is designed according to the following general
formula:
?)? C R? )
n, R is recognition region, which specifically recognizes or combines said targets; F is
effect region, which generates ceutical effects to targets, and said pharmaceutical effects
are effects of regulating, repairing, labeling, causing death and/or collapsing against said targets
specifically;
establishing recognition region molecular structure library;
establishing effect region molecular structure y;
? according to said general formula, designing recombinant molecular structure library on the basis
of said recognition region molecular structure library and effect region molecular structure
library;
said designing refers to the process of structural readjustment, structural recombination and/or
structural confirmation carried out on the basis of molecular structures of ted, selected or
? ed substances used as effect region or recognition region;
(3) based on said recombinant molecular structure library, preparing and verifying recombinant so
as to obtain candidate novel antibiotics;
(4) ing novel antibiotics which meet medicine ement from candidate novel
? antibiotics.
Said establishing recognition region molecular ure y refers to ting
currently-known natural nces which specifically recognize and/or combine said targets by
searching and analyzing; or/and artificially preparing artificial substances which specifically
recognize and/or combine said targets.
? Said natural substances refer to natural bioactive molecular, or recognition region of
bacteriophage, which can be recognized by acceptor of said targets;
said artificial substances refer to antibody mimetic, said antibody mimetic is designed according
to amino acid sequence of immunoglobulin which can specifically ize unique substance on
said targets.
Said antibody mimetic is short peptide with a structure of VHCDR1-VHFR2-VLCDR3 from
N-terminal to inal, which is tuted by the regions of VHCDR1, VHFR2, V LCDR3 on
Fab short arm of said immunoglobulin; or
is r of said short peptide; said mutamer refers to product obtained by artificial
site-mutation to 5 amino acid residues of VHCDR1 and 9 amino acid residues of VLCDR3 on
? short e, which preserves recognition capability to unique substance on said targets.
Said immunoglobulin can be multiple. E.g., VHCDR1 of V HCDR1-VHFR2-VLCDR3 is from one
immunoglobulin, and V CDR3 is from another immunoglobulin.
Said immunoglobulin is prepared by taking unique substance on target as immunogen to
immunize animal.
Said immunoglobulin is prepared by taking common unique substances on multiple targets as
immunogens to immunize animal.
Said immunoglobulin is prepared by taking multiple unique substances on target as
immunogens respectively to immunize animal.
When said target refers to virus, prokaryotic cell or eukaryotic cell with phospholipid bilayer
membranes as the basic structure of its cell ne or pe, said pharmaceutical effect
? refers to causing death and/or collapsing;
said effect region refers to bioactive substance which can form ion channel or pore path on
phospholipid bilayer membranes.
Said effect region refers to pseudomonas aeruginosa barteriocin .
Said effect region refers to colicins El, Ia, Ib, A, B or N; or
domains of colicin les El, Ia, lb, A, B and/or N which can form ion ls; or molecules
obtained by allosterism from colicin molecules El, Ia, Ib, A, B or N,
or from domains of n molecules El, Ia, Ib, A, B or N which can form ion channels, having
function of forming ion channels in said phospholipid bilayer membranes.
? Said recombinant is recombinant polypeptide, said ing recombinant refers to that gene
coding said recombinant polypeptide is transformed into biological expression system to express
fusion protein, and candidate novel antibiotic is obtained by separating and ing fusion
protein.
Said ical expression system refers to Escherichia coli pET system engineering bacteria
E, coli B834 (DE3).
Said pharmaceutical effect refers to labeling, said effect region refers to label, said preparing
recombinant refers to linking effect region and recognition region operably.
Novel antibiotic preparation platform system comprises 3 interoperable systems: (1) goal
? proposing system, (2) designing , (3) laboratory system;
said platform prepares novel antibiotic according to said method of any one of claims 1-14; said
goal proposing system ines development goal, and delivers task instruction to said
designing system;
said designing system establishes recognition region molecular ure library as well as effect
? region molecular structure y, designs molecular structure library for said recombinant, and
es said molecular structure library to said laboratory system,
said laboratory system offers experimental results to said designing system; said designing system
reports the finally-selected candidate products as development results to marketing system;
said designing refers to the procedure of structural adjustment, structural recombination and/or
? structural confirmation based on molecular structure of the collected, selected or prepared
substance used as effect region or recognition region.
Said tory system comprises at least one 3r d party partner institution which undertakes said
ments.
? By the method for preparing novel antibiotics of this invention, it's available to prepare a batch of
candidate novel otics against most targets, and select novel antibiotics specifically against
said targets with recognition region and effect region from candidates. In the method of this
invention, said targets may be prokaryotic cells (e.g., staphylococcus aureus with drug-resistance
in e 5, environmental ant-cyanobacteria in example 6, bacillus anthracis in e
3), eukaryotic cells (e.g., agricultural fungus against by antifungal polypeptide in example 4, EB
virus-induced tumor cells in example 1), virus (e.g., unique envelope glycoprotein in EB virus in
example 1), products of said yotic or eukaryotic cells.
During preparation, in accordance with general formula
( it ? )
, establishing recognition region molecular structure
? library as well as effect region molecular structure library, and designing molecular structure
library for recombinants.
Because there exist substances with specific recognition for specific species of cells in nature,
such as, pheromone, ligand of acceptor on ition cells, immunoglobulin produced in human
or animal. er, globulin against xenobiotic is produced naturally by immune
system of animals. On the basis of globulin prepared through artificially immunizing
animals or existing naturally, it's basically ble to obtain recognition substances against any
said target, which makes said method of this invention has a wide applicability.
? Additionally, there also exist substances in nature, which can form lethal change on specific cells.
For example, both of colicin and monas aeruginosa bacteriocins can be ted as effect
, but their disadvantage is that the species of target cells they react against are limited.
Taking advantages of above-mentioned two kinds of substances and adopting their strong points
while overcoming own deficiencies, as to novel antibiotics prepared by the method of this
? invention, ition region leads whole recombinant molecular to recognize target substances,
and effect region completes pharmaceutical effects.
The principle of the method of this invention is preparing novel otics based on a general
formula, collecting and/or designing a batch of molecular structures of recognition region and
effect region against target substance proposed to establish molecular structure library, then
? designing molecular structure of novel antibiotics according to established molecular structure
library, and obtaining a batch of molecular structure libraries of recombinants; afterwards,
preparing a batch of candidate novel antibiotics in line with molecular structural information of
molecular structure libraries of recombinants, finally ing said ate novel antibiotics
one by one to select novel antibiotic which meets pharmaceutical standards. The advantages of
? the preparation method of this invention are as follows:
(1) The method of this invention only aims against prokaryotic cells, eukaryotic cells, virus or
products thereof to prepare novel antibiotics, and these above-mentioned substances either have
natural recognition substances or have unique surface substances or their own can be conducted
as immunogen for immunizing animal to obtain immunoglobulin which recognize themselves,
which s that, it's available to always obtain recognition region by preparation method of
this invention, and effectively breaks a bottleneck existing in current otic development, i.e.,
the y that proteins as targets of drug effect (i.e., drug targets) have been exhausted gradually,
and the left s are undruggable (i.e., do not react with drugs).
? Moreover, there also exist substances as effect region in nature, but said nces have
selectivity in connection with different pharmaceutical effects. For example, if the goal is to
prepare a novel antibiotic to cause death of target cells, nces such as colicins are
competent to achieve said goal; if the goal is to regulate, interfere or label, it's sufficient to
select substance molecules with such effects as effect . On the basis of general formula
the method of this ion premised on, it's ensured that novel antibiotics can be prepared
? against most target substances, i.e., the method of this invention has high success rate and wide
ability.
(2) The best advantage of the method of this invention is that, against one target substance,
several novel antibiotics can be prepared once time and they are well prepared to r
drug-resistance of pathogenic microorganism, because in this invention, novel antibiotics are
prepared against some target substance based on a general formula; recombinants library is
obtained by ishing effect region library and recognition region library respectively, and
ble inants with well effects are selected as novel antibiotics from inants
library. This solves a problem existing in current new drug development that, the speed to occur
? drug-resistance in pathogenic rganism is high, and there is no other alternative antibiotic
when drug-resistance occurs.
In the method of this invention, when establishing recognition region library, specific monoclonal
antibodies are preferably selected as the designed recognition region, i.e., they are designed as the
commonly-designed single-chain antibodies, small molecular antibodies in prior art or antibody
mimetic with structure shown in Table 1 which was disclosed by inventor of this invention
previously. That is, molecular structure of the established recognition region may be antibody
mimetic in Table 1 or point mutation products of said antibody mimetic; point mutation refers to
short peptides obtained by conducting artificial point mutation on amino acid residue of two
recognition regions composing antibody mimetic, which have recognition capacity against said
? target.
This makes members of the established recognition region molecular ure library expanded
unlimitedly, so as to counter mutation of pathogen better, which amplifies the above second
advantage of the method of this invention. For e, if target (pathogenic cell) is not
recognized due to drug-resistance occurring on one recognition region, there can be many similar
? recognition region molecular ures as candidates.
Antibody mimetic has more advantages compared with antibody, and is easier to be ed as
well as operated artificially. Owing to different directed targets, substances conducted as
recognition regions may be pheromone, phage recognition region or specific monoclonal
antibodies which are collected from current se, but they are limited after all. In bioactive
? substances found in plants, animals or microorganisms, the most effective ive nce to
recognize single molecule is antibody. In order to avoid the disadvantage of nature antibody with
huge size, people always design and prepare antibody mutamer with smaller size. However, these
mutamers consist of hundreds of amino acid residues, and still have huge size compared with
recognition regions we seek. Fab short arm of each natural antibody has 6 antigen binding regions,
and they as well as their backbone form complicated l structure. Said spatial structure has
function of recognizing and binding specific antigen, while in novel antibiotics developed by the
platform of this invention, it's sufficient that ition region only has recognition function, and
recognition region does not need to bind the corresponding antigen. According to Qiu et al
(Small antibody mimetic comprising two complementarity-determining regions and a framework
? region for tumor ing, Nature Biotechnology 25(8):921-929(2007)) Qiu et al selected 2
n binding regions and one backbone region on Fab short arm of natural antibody to form a
short peptide antibody mimetic ing to structure of natural dy; although its size was
50-300 times smaller than natural antibody, it preserves basic biological activity of natural
antibody, i.e., it can recognize some antigen specifically. Because immune system in human or
animals will respond to produce immunoglobulin specifically against said immunogen when
irritated by immunogen, this invention preferably prepares monoclonal antibodies recognizing
targets and es recognition region based on the monoclonal antibodies and the antibody
mimetic designing idea disclosed in article of Qiu et al, 2007. Thus, aiming at any pathogenic
microorganism cell or pending-treated cell, specific monoclonal antibodies can be prepared
? theoretically, and suitable recognition region substances — dy mimetic can be ed
pondingly. This makes that the success rate to prepare novel antibiotics against some targets
by the method of this ion has qualitative leap comparing with traditional method for
preparing antibiotics, and the time to obtain products is shortened a lot. Theoretically, the time to
prepare a novel antibiotic even a batch of novel antibiotics against one target equals to the time to
obtain specific monoclonal antibody and the time to prepare recombinant protein by
bioengineering method.
Said s are multiple targets with common e antigen, and said antibody mimetic is
prepared by immunizing animal with said common surface antigen as antigen composition. Novel
antibiotics prepared by taking said antibody mimetic as recognition region can recognize several
? said targets, i.e., they have effects of broad-spectrum antibiotics.
With regard to recognition region molecular structure library established by the method of this
invention, if ic substance on the selected target surface is common for various
microorganism surfaces, the corresponding antibody mimetic becomes a broad-spectrum
recognition region, that is, only if its surface has similar substances, the rganism cell can
be recognized, and the prepared novel antibiotic t it is spectrum antibiotic. If the
selected ic substance is unique for one microorganism cell, the corresponding antibody
mimetic becomes a narrow-spectrum recognition region, and only the microorganism cell with
similar substance can be recognized.
Taking various surface substances on the selected targets as immunogens, generating
corresponding monoclonal antibodies by taking said surface substances separately to immunize
animal to obtain many kinds of antibody mimetic and mutamer thereof which can recognize said
rganism cell specifically, is another approach to expand recognition region library. It's
available to y select any one of these antibody mimetic as the first recognition region of
novel antibiotic developed by the method of this invention. After being used practically for a
? period of time, if said microorganism has occurred drug-resistance against said recognition region
(e.g., structure of the corresponding surface substance (antigen) is modified to keep said
recognition region from being ized), it's available to select another from these antibody
mimetic as the second recognition region, the third recognition region, the fourth ition
region ? of novel antibiotic developed by the method of this invention, accordingly to offer
? various optional novel antibiotics, which effectively overcomes the ulty of failing to
immediately provide alternative drug for ent after drug-resistance occurring against
antibiotics in prior art. The method of this invention is capable to extend the effective ation
lifetime of one novel antibiotic.
When said target refers to virus, prokaryotic cell or eukaryotic cell with phospholipid bilayer
? membranes as the basic structure of its cell membrane or envelope, said pharmaceutical effect
refers to causing death and/or collapsing,
said effect region refers to bioactive substance which can form ion channel or pore path on
phospholipid bilayer membranes, such as the tly known colicin and pseudomonas
aeruginosa barteriocin Pyosin.
? Said effect region refers to colicins El, Ia, Ib, A, B or N; or refers to s of colicin molecules
El, Ia, Ib, A, B and/or N which can form ion ls;
or refers to molecules obtained by allosterism from colicin les El, Ia, Ib, A, B or N,
or from domains of colicin molecules El, Ia, Ib, A, B or N which can form ion channels, having
function of forming ion channels in said phospholipid bilayer nes. It's illustrated
according to description of background art that, main pathogenic microorganisms confronted by
human currently and in future have a common characteristic that their cell membranes have a
ure of phospholipid bilayer membranes. In nature, there exist many bacteriocins which kill
bacteria by directly forming ion channel through cell membranes of bacteria. The typical
representation is a bacteriocin secreted by Escherichia olicin, and its function is to kill
? Escherichia coli of the same species but different strains, rather than hurt other species of bacteria
and host of Escherichia coli-human as well as animals. As a model sample of colicins which
forms ion channel, after colicin Ia was found by Jacob in 1952, transmembrane spatial ure of
ion channel formed by colicin Ia in artificial lipid bilayer membranes in the state of opening or
closing was finally demonstrated in 1996 (Qiu et al, Major transmembrane movement associated
? with colicin Ia channel gating. J. Gen. Physiology, 107:313-328 (1996)), which laid a theoretical
basis for designing and preparing novel antibiotics on molecular level. However, wild-type n
only reacts on ichia coli of the same species but different strains, and it's necessary to alter
its ing to make colicin attack other pathogenic bacteria. Therefore, colicin is an ideal
candidate of effect region of novel antibiotic developed by the platform of this invention.
When said recombinant is recombinant polypeptide, above-mentioned linking effect region and
recognition region refers to that gene coding said recombinant polypeptide is transformed into
biological expression system to express fusion protein, and novel antibiotic is ed by
separating and purifying fusion protein.
Said ceutical effect refers to labeling, said effect region refers to label, said preparing
? recombinant refers to linking effect region and recognition region operatively. For example, the
molecule of recognition region can be ed with radioactive marker.
Concerning the method of this invention, after recognition region molecule is confirmed t
, effect region molecule is selected, and selection of effect region molecule is relative to the
goal of establishing said antibiotic. For example, if the goal is to regulate against target, it's
? available to select molecule with repairing function; if the goal is to cause target dead or limit its
growth and development, it's available to select biological polypeptide molecule which can form
lethal ion channel through target's cell membrane, like colicin; if the goal is to label or image
target, it's available to link label or imaging agent to recognition region to obtain novel antibiotic
for labeling, and label is bound to target through recognition region, in order to t
? continuous therapy or research against labeling cells.
In the method of this invention for developing novel antibiotics, the important work is to establish
recognition region library, because most targets have phospholipid bilayer as the basic structure of
their cell membrane or envelop. In the method of this invention, colicin, pseudomonas aeruginosa
? barteriocin Pyosin are preferably selected as effect region. Colicin is an effective regulation
motivation for al competition and maintaining biodiversity among Escherichia coli, and
Escherichia coli varies continuously in order to avoid the sterilization from colicin; colicin has
been existing for billions of years, and it's still playing a aceable physiological role in
alimentary canal of each individual multicellular organism. Since the attacking target of novel
? antibiotics prepared by the method of this invention is microorganism or cell of other species, and
these microorganisms or cells have never been attacked by n, it will cost much time for
these bacteria to e immune proteins r with bacteria; accordingly, it's forecasted that
novel antibiotics obtained by the method of this invention will have longer ation lifetime
than traditional antibiotics. By means of g ion channel through target's membrane, colicin
has strong sterilization , which is appropriately hundreds of even tens of nds of times
as that of traditional otics, like llin, cynnematin, vancomycin, streptomycin,
carbapenem, tigecycline, etc. Effect region selected preferably by the method of this invention
will give much stronger sterilization effect to novel antibiotics prepared by the method of this
invention, compared with traditional antibiotics.
? In the case that both recognition region and effect region are recombinants of polypeptide
molecule, the method of binding recognition region to effect region is preferably to size the
nucleotide sequence coding said recombinant, then to build recombinant expression vector
loading said nucleotide sequence, finally to transform said recombinant expression vector into
biological expression system, e.g., said recombinant is expressed in engineered strain of
? Escherichia coli and separated. Furthermore, engineered strain of Escherichia coli pET system,
i.e., E.coli B834 (DE3) is selected preferably as biological expression system in the method of
this invention, and the expression rate of said recombinant protein in this system is higher h
verification.
About novel antibiotics prepared by the method of this invention, a batch of recombinants are
? gained in steps of ing recombinant, and the recombinants having recognition and
pharmacological effects at least against targets, i.e., novel antibiotics are finally selected through
conventional function verification, i.e., verification of recognition and pharmacological s of
inants by using their targets and non-targets. For some recombinants without effect on
targets but with effects on non-targets, it's available to confirm their effect spectrum by further
? verification.
This ion also provides rm system of operating the above-mentioned method to
develop novel antibiotics, which makes ion of the method to develop novel antibiotics
standardized and modeled to enhance the efficiency of developing novel antibiotic. Said platform
comprises 3 coordinated system groups: (1) goal proposing system, (2) designing system and (3)
? laboratory system;
Said goal ing system determines development goal and give task instruction to designing
system; the task of said goal proposing system is confirming which targets should be aimed at for
developing novel otics, what pharmacological effects the novel antibiotics carry out against
? said targets; for example, through search, demands of medicine field, drug-resistance status of
antibiotics are analyzed, and new ens as well as information thereof and experimental data
or outsourced contracting projects are ted as well as counted to confirm development goal.
In this invention, said pharmaceutical effects are effects of regulating, ing, marking, causing
death and/or collapsing. Said goal proposing system may e core members of R&D team,
marketing team; the fixed goal may be outsourced contracting projects, which designates to
develop novel antibiotics against some enic microorganisms;
Designing system designs recognition region, effect region and molecular structure of said
recombinants and proposes the desired experimental task to laboratory system according to task
? instruction from goal proposing system and said general formula; it's required for designing
system of novel otics to establish recognition region library and effect region library in
accordance with task instructions from goal ing system. Based on instructions from goal
proposing , nces specifically recognizing said targets are collected, selected and
prepared as recognition region; said preparing substances specifically recognizing said targets
refers to preparing and screening to obtain monoclonal antibody specifically recognizing said
targets through immunizing s by using unique substances separated from said targets or
said targets as immunogen;
Said laboratory system offers experimental results to novel antibiotic designing system, and novel
antibiotic designing system reports candidate products of finally-selected development
achievements to goal proposing system;
said designing refers to the ure of structural adjustment, structural recombination and/or
ural confirmation based on molecular structure of the collected, selected or prepared
substance.
In rm system of this invention, said laboratory system completes experimental work
? according to instruction from novel antibiotic designing system, for example, preparing
monoclonal antibody of candidates as recognition region, preparing polypeptide as effect region
and preparing said recombinants as well as carrying out a series of verification work. Basically,
the work of said laboratory system includes preparing monoclonal antibody against target,
obtaining amino acid sequence of monoclonal antibody by sequencing, synthesizing the gene of
the designed antibody c, synthesizing the gene coding recombinant, preparing as well as
ing inant or preparing recombinant, verifying recombinant, ting mental
report and giving feedback to ing system.
In development platform of this invention, designing system is the core of technology, and all
works in laboratory system can be completed by prior art, thus, it's available to build a own
? completed laboratory work team, and it's also available to only arrange administrator for
laboratory work team, and outsource laboratory work by tory system administrator to the
3rd partner institutes who focus on experiment works of the corresponding stages. Through the
above-mentioned process, development work can be completed with uality efficiently;
research and development resources are integrated cost-effectively. Development platform
? established by this invention equals to a R & D factory of novel antibiotics.
Each system of said platform system of this invention performs its own function, coordinates to
make the whole platform system work efficiently, which makes available that it only costs around
half a year to generate a target novel antibiotic. In fact, a batch of novel antibiotics t one
target was produced during this half a year, and antibiotic preparation efficiency is far higher than
? traditional preparation. In addition, the work of each system is carried out pointedly, accordingly
fund of corporation or research institution is assigned with definite object, rather than ed
blindly in projects t practically applicable significance or market demand. In particular, in
platform of this invention, some works of system can be rced to a 3 rd partner specialized in
corresponding field. Consequently, not only can the high-efficient ation and utilization of
R&D equipments and resources be realized, but also the R&D cost is lowered and the consumed
time is shortened.
Workflow chart of said platform system of this invention is shown as Figure 5, and it avoids
wasting and repeating in development work at a maximum extent.
In summary, the method and platform system of this invention provide a new method for
preparing medicine, and the advantages superior to traditional antibiotic preparation methods are
as s:
(1) non-subjecting to limitation of traditional method for screening antibiotics: novel antibiotics
? prepared by the method of this invention have common structural constitution, i.e., consist of
effect region and recognition region. In development projects t targets with phospholipid
bilayer cell membranes, it's available to select the t colicin as effect region; under
introduction of recognition , colicin of novel antibiotics can form lethal ion channel through
almost all cell membranes with phospholipid bilayer cell ne structure.
As there exists genus-unique or species-unique or strain-unique surface substances on surfaces of
cell membranes in most microorganisms, preparing monoclonal antibody specifically recognizing
the target by using said surface nces or cells containing said surface substances as
immunogen is a very mature technology at present, and after obtaining said monoclonal antibody,
? dy mimetic will be obtained as recognition region in light of the idea of designing antibody
mimetic in previous ions by inventor. Thereby, the development method of this invention
will not be subjected to limitation that proteins as targets of drug effect (i.e., drug targets)
discovered at present have been ted gradually, and the left s are pharmacological
significance (undruggable i.e., do not react with drugs), and it is capable to develop novel
? antibiotics specifically against most enic microorganisms.
(2) capacity of sensitively countering drug-resistance of pathogenic microorganism: because there
is not only one surface antigen substance in pathogenic microorganism, it's available to select
various surface substances on the surface of target microorganism for immunizing animal to
generate corresponding monoclonal antibody, accordingly many kinds of antibody mimetic and
mutamer thereof which can recognize said microorganism cell specifically are gained. As shown
in Figure 3, it's available to firstly select any of these antibody mimetics as the first recognition
region of novel antibiotic developed by the method of this invention. After being used practically
for a period of time, if said microorganism has occurred esistance against said recognition
region (e.g , structure of the corresponding surface nce (antigen) is modified to keep said
recognition region from being recognized), it's ble to select another from these antibody
mimetics as the second recognition region, the third recognition region, the fourth recognition
region of novel antibiotic developed by the method of this invention, accordingly to offer
various optional novel antibiotics, which effectively overcomes the difficulty of failing to
? ately provide alternative drug for ent after drug-resistance occurring against
otics in prior art. The method of this invention is capable to extend the effective application
lifetime of one novel antibiotic.
(3) the recognition region nces provided in said platform or method of this ion
se, preferably comprise antibody mimetic, and mutamer by point mutation on short peptide
of said antibody mimetic. Therefore, when mutation occurs on surface antigen of target
pathogenic microorganism, there has existed not only one candidate dy mimetic waiting for
recognizing with said surface antigen, which makes the capacity of development method of this
ion to counter drug-resistance further improved, as shown in Figure 4.
(4) it's difficult for target to occur drug-resistance. In the method of this invention, it's preferable
to select colicins as substances of effect region of novel antibiotics; bactericidal mechanism of
colicin is different from that of most current antibiotics, and is not known well by pathogenic
microorganisms; it will cost much time to occur esistance in enic microorganisms,
? which provides plenty of time to develop the next-generation antibiotics.
(5) By means of forming ion channel through target's ne, colicin has strong sterilization
effect, which is appropriately hundreds of even tens of thousands of times as that of traditional
antibiotics, like penicillin, cynnematin, vancomycin, streptomycin, carbapenem, tigecycline, etc.
As a preferred effect region of the method of this ion, it will give much stronger
? sterilization effect to novel antibiotics prepared by the method of this invention, compared with
traditional antibiotics.
(6) Different from ional method of screening otics with long-time consuming, it's only
required to cost 4-6 months to produce a batch of novel antibiotics against s pathogenic
microorganisms through the method of this invention. The procedure is that, animal (mouse) is
immunized using different antigens; the corresponding monoclonal antibody will be ed by
haemospasia after 2 to 3 weeks of antibody production period; the nucleotide sequences coding
variable region and backbone of heavy chain and light chain on Fab segment of monoclonal antibody
are obtained by using protein sequencing and gene translation technology; according to the obtained
? nucleotide sequences, gene coding recognition region — antibody mimetic is designed,
and it is bound to effect region —gene coding n to construct the recombinant plasmid; the
ered bacteria are transfected by said inant plasmid to express a novel antibiotic by
proliferation. Afterwards, specificity and sensitivity of antibiosis and cytocidal effect of the
separated and ed novel antibiotic are verified. It's only required about half a year to screen a
batch of novel antibiotics by the whole procedure. Such high efficiency of construction and
production will bring the revolutionary changes to traditional construction and production of
otics.
(7) The rm of this invention provides teamwork approach and resource utilization method to
? efficiently develop novel antibiotics. Since the developed antibiotics have common structural
characteristics, through said platform of this invention, ch and development resources are
integrated effectively, and development work can be performed as flow-line production, which
equals to a R & D y of novel antibiotics.
In summary, method and platform system to develop novel antibiotics of this invention can offer
novel antibiotics with specific recognition region and effect region against most pathogenic
microorganisms and targets. For most targets, the tly-known iocins are competent as
the role of effect region, so development cycle of a novel antibiotic depends on the time to design
molecular structure and the time to prepare as well as verify recombinants. Because recognition
region depends not only on the selected nature substances but mainly depends on
artificial-prepared antibody mimetic as recognition region, while obtaining monoclonal antibody
through immunizing animals by using an immunogen and then getting amino acid sequence of
said onal antibody is a current mature technology, based on the t biotechnological
level, the time to develop a novel antibiotic can be controlled in a short period basically. Platform
for operating said development method of this invention fully optimizes, utilizes and integrates
human ces and technology resources, to ensure efficient conduct of development process
and make novel antibiotic development operating as flow-line production.
Description of figures
Figure 1 shows general formula of novel antibiotic developed by the method of this invention:
n F is effect region; R is recognition .
Figure 2 shows structure of antibody mimetic.
Figure 3 shows strategy 1 to construct recognition .
Figure 4 shows strategy 2 to uct recognition region.
Figure 5 shows platform work flow chart, wherein M represents goal proposing system; D
represents designing ; L ents laboratory system; double-headed arrow represents
information exchange ways during preparation of novel antibiotics.
Figure 6 shows comparison of in vitro killing effect of novel antibiotics t EB virus-induced
Burkitt's lymphoma.
? (A) Control group, (B) group treated by novel antibiotics group 1
Figure 7 shows comparison of survival curves about inhibition of novel antibiotics prepared by
this invention, wild-type colicin and anti-staphylococcus aureus polypeptide (ZL 01128836.1) on
methicillin-resistant staphylococcus aureus (ATCC BAA-42), vancomycin-resistant enterococci
(ATCC ), multi-drug ant pseudomonas aeruginosa (clinical isolated strain 13578 in
? West China al);
Ordinate represents the minimum inhibitory concentration (nMol);
wherein A is vancomycin-resistant enterococci, (1) anti-staphylococcus aureus polypeptide, MIC
= 0.91 nMol, (2) wild-type colicin Ia, MIC = 0.91 nMol, (3) PMC-AM1, MIC = 0.23 nMol; B is
methicillin-resistant staphylococcus aureus, (1) anti-staphylococcus aureus polypeptide, MIC
0.06 nMol, (2) wild-type colicin Ia, MIC = 0.23 nMol, (3) PMC-AM1, MIC = 0.06 nMol; C is
multi-drug resistant pseudomonas nosa, (1) anti-staphylococcus aureus polypeptide, MIC
0.91 nMol, (2) wild-type colicin Ia, MIC = 0.91 nMol, (3) PMC-AM1, MIC = 0.23 nMol.
Figure 8A shows test results of tion of anti-cyanobacteria polypeptide against
? microcystis aeruginosa growing in liquid medium; the left flask is control, and the right
flask is anti-cyanobacteria polypeptide of 351.1g/ml.
Figure 8B shows test results of inhibition of anti-cyanobacteria polypeptide against
anabaena growing in liquid medium; the left flask is control, and the right flask is
anti-cyanobacteria polypeptide of 3514/m1.
? Figure 8C shows test s of inhibition of anti-cyanobacteria polypeptide against lla
growing in liquid ; the left flask is control, and the right flask is anti-cyanobacteria
polypeptide of 35µg/ml.
Figure 8D shows test s of inhibition of anti-cyanobacteria polypeptide against scenedesmus
growing in liquid medium; the left flask is control, and the right flask is anti-cyanobacteria
polypeptide of 35ug/m1.
EMBODIMENTS
The method and platform of this invention will be described by the following currently-completed
development examples.
Example 1 preparation of novel antibiotics t virus -induced tumor
(1) determining targets: to ine lethal novel antibiotics against EB induced tumor
cells.
(2) designing molecular structure of novel antibiotics:
the following designing work was med according to general formula
F R ? )
, wherein F is effect region; R is recognition region.
ishing recognition region molecular structure library: monoclonal antibodies
specifically-recognizing EB virus - anti-EB virus envelope glycoprotein antibodies gp320, i.e.,
monoclonal antibodies secreted by ATCC HB-168 hybridoma cells and amino acid ces
information thereof which had existed in prior art were found by searching in database.
Based on said monoclonal antibody, inventors designed a series of antibody c structures as
shown in Table 1, and obtained a series of mutamers through random point mutation on the first 5
and the last 9 amino acids of antibody mimetics with structures listed in Table 1,
Table 1 the designed an
VHCDR1-VHFR2-VHCDR3
VLCDR1-VHFR2-VLCDR3
VHCDR1-VHFR2-VLCDR3
-VHFR2-VLCDR3
V LCDR1-VHFR2-VHCDR3
VLCDR2-VHFR2-VHCDR3
? Establishing effect region molecular structure library: because the preparation goal was lethal
novel antibiotics against EB-virus induced tumor cells, colicin could form lethal ion channel
through cell membrane of Escherichia coli of the same species but different strains by itself to
cause death of Escherichia coli of the same species but different strains, and it was a competent
candidate substance for effect region. Thus, colicins Ia, Ib, A, B and N or mutant sequence were
ed as substances of effect region library and offered to laboratory system.
Preliminarily obtaining the designed molecular structure library of recombinants: from amino
terminal to carboxyl al: colicin or rs thereof + 28 peptides mimetic recognizing EB
virus envelop 1 co rotein, and molecular structures of some recombinants are shown in Table 2:
No. Recognition region effect region Recombinant molecule (amino
molecule molecule terminal - carboxyl terminal)
1 -VHFR2-VHCDR3 Ia Ia-VHCDRI-VHFR2-VHCDR3
2 VLCDRI-VHFR2-VLCDR3 Ia DR1-VHFR2-VLCDR3
3 VHCDR1-VHFR2-VLCDR3 Ia Ia-VHCDR1-VHFR2-VLCDR3
4 VHCDR2-VHFR2-VLCDR3 Ia Ia-VHCDR2-VHFR2-VLCDR3
VLCDR1-VHFR2-VHCDR3 Ia Ia-VLCDR1-VHFR2-VHCDR3
6 VLCDR2-VHFR2-VHCDR3 Ia Ia-VLCDR2-VHFR2-VHCDR3
7 -VHFR2-VHCDR3 mla (Seq ID mla-VHCDR1-VHFR2-VHCDR3
No.1)
8 -VHFR2-VLCDR3 mla mla-VLCDR1-VHFR2-VLCDR3
9 VHCDR1-VHFR2-VLCDR3 mla mla-VHCDRI-VHFR2-VLCDR3
VHCDR2-VHFR2-VLCDR3 mla m1a-VHCDR2-VHFR2-VLCDR3
11 VLCDR1-VHFR2-VHCDR3 mla mla-VLCDR1-VHFR2-VHCDR3
12 VLCDR2-VHFR2-VHCDR3 mla mIa-VLCDR2-VHFR2-VHCDR3
Note* monoclonal dies secreted by ATCC HB-168 hybridoma cells, V LCDRI, VLCDR2, VHCDR1, VHCDR2
VHFR2, VLCDR3, VHCDR3, colicin Ia and amino acid sequence thereof as well as nucleotide sequence thereof are
known, accordingly amino acid sequence and nucleotide sequence of recombinants can be deduced, and they will
? take too much space. Thereby, such sequence information will not be listed in this description.
(3) Laboratory system: recombinant y was obtained by binding the provided effect region
and recognition region; gene coding said inant was ed into expression vector to
obtain recombinant expression vector; a batch of recombinant polypeptides were obtained by
transforming said recombinant expression vector into ered bacteria.
? Anti-target verification experiment was conducted on the obtained recombinants (verification
method and experimental design were the same as recorded in ZL200410081446.8). Recombinant
3 and 9 in Table 2 had the best killing effect against us induced tumor cells, and their
s of in vitro killing ment on EB-virus induced Burkitt's lymphoma are shown in
Figure 6; other 9 kinds of inants had different killing effects against EB virus-induced
tumor, which are weaker than inant 3 and 9; all recombinants had no toxic and side effects
on normal cells. The experimental process of verification is the same as recorded in example 2-5
of ZL200410081446.8.
Recombinants prepared by taking the mutants of antibody mimetics in recombinants 3 and 9 as
recognition region were verified that, in Table 3, recombinants with Seq ID No.2-6 as recognition
? region has basically lent killing effects against EB virus induced tumor cells as that of
inant 3 or 9.
Table 3 amino acid sequences of 28 anti-EB virus induced tumor e mimetic
VHCDR1-VHFR2-VLCDR3 and mutamers thereof
NO. VHCDR1-VHFR2-VLCDR3 and point mutants thereof
Seq ID No.2 SFGMHWVRQAPEKGLEWVAGQGYSYPYT
Seq ID No.3 SYGMHWVRQAPEKGLEWVAGQGYSYPYT
Seq ID No.4 SFGMHWVRQAPEKGLEWVAQQWSSNPYT
Seq ID No.5 SF GMHWVRQAPEKGLEWVALQ GTHQPYT
Seq ID No.6 SF GMHWVRQAPEKGLEWVAQ Q LHFYPHT
Seq ID No.7 RQGMHWVRQAPEKGLEWVAGQGYSYPYT
It took less than 6 months for this preparation, and a batch of candidate novel antibiotics with
specific killing effect against targets were obtained successfully.
Experimental methods and materials adopted to obtain each recombinant in this example
were exactly the same as recorded in Patent No. ZL200410081446.8, except for the inserted gene
? sequences when ucting vectors, so they are not repeated here.,
Example 2 preparation of novel antibiotics against diplococcus intracellularis
(1) determining targets: diplococcus intracellularis.
(2) designing lar structure of novel antibiotics:
the following designing work was performed according to general formula
, wherein F is effect region; R is recognition .
ishing recognition region molecular structure library:
porin is one outer membrane protein which is common in gram-positive bacteria, like
staphylococcus, streptococcus, enterococcus, gram-negative bacteria, like escherichia coli,
klebsiella nia, pseudomonas aeruginosa, bowman acinetobacter, enterobacter cloacae,
bacillus breslaviensis, serratia marcescens, aeromonas, vibrio, myxococcus, and mycobacterium
tuberculosis; it is an ideal antigen protein, and PorA is one kind of porin.
Monoclonal antibody specifically-recognizing porin PorA which had existed in prior art was
found by searching in database; PUBMED ID of its heavy chain peptide is 2MPA_I-1, and
PUBMED ID of its light chain peptide is 2MPA_L. Based on said monoclonal dy, inventors
designed a series of antibody mimetic molecular structures as shown in Table 1 of example 1.
Establishing effect region lar structure library: because the preparation goal was lethal
novel antibiotics against occus intracellularis, colicin was a competent candidate substance
for effect region. Thus, colicins Ia, Ib, A, B and N were selected as substances of effect region
? library, and colicins Ia, Ib, A, B and N, ion channel domain molecules thereof and mutant
molecules thereof tute effect region molecular ure library.
The preliminarily ed molecular structure of recombinant library was: from amino al
to yl terminal: colicin or ion channel domain thereof or mutamers thereof + anti-PorA
antibody mimetic and molecular structures of some recombinants are shown in Table 4:
NO. Recognition region effect Recombinant molecule (amino
molecule region terminal to carboxyl terminal)
1 VHCDR1 -VHFR2-VHCDR3 Ia Ia-VHCDR1-VHFR2-VHCDR3
2 VLCDR 1 -VHFR2-VLCDR3 Ia Ia-VLCDR1 -VHFR2-VLCDR3
3 VHCDR1 -VHFR2-VLCDR3 Ia Ia-VHCDR1-VHFR2-VLCDR3
4 VHCDR2-VHFR2-VLCDR3 Ia Ia-VHCDR2-VHFR2-VLCDR3
VLCDR1 -VHFR2-VHCDR3 Ia Ia-VLCDR1 -VHFR2-VHCDR3
6 VLCDR2-VHFR2-VHCDR3 Ia Ia-VLCDR2-VHFR2-VHCDR3
Note* monoclonal antibodies specifically-recognizing porin PorA, and PUBMED ID of its heavy chain peptide is
2MPA_H; PUBMED ID of its light chain peptide is , which are all-known. Thus, V LCDR1, VLCDR2,
VHCDR1, VHCDR2 VHFR2, VLCDR3, VHCDR3 are known, accordingly amino acid sequence and nucleotide
sequence of recombinant molecules can be deduced exactly. Thereby, such sequence information will not be listed in
this description.
(3) Laboratory system: gene coding said recombinant was inserted into expression vector to
obtain inant expression vector; a batch of inant polypeptides were obtained by
transforming said recombinant expression vector into engineered ia.
Anti-target cation experiment of the obtained recombinants was carried out. Verification
? experiment was ted on the killing effects of the obtained recombinants against multi-drug
resistant pseudomonas aeruginosa, vancomycin-resistant enterococci, methicillin-resistant
staphylococcus aureus, bowman acinetobacter, klebsiella pneumoniae and mycobacterium
tuberculosis (verification method and experimental design were the same as recorded in
ZL200910092128.4). Recombinant 3 in Table 4 had the best g effect against said pathogenic
? ia; comparison of survival curves about inhibition of novel antibiotics prepared by this
invention on methicillin-resistant staphylococcus aureus (ATCC BAA-42), vancomycin-resistant
enterococci (ATCC 700802), multi-drug resistant pseudomonas aeruginosa cal isolated strain
13578 in West China Hospital) is shown in Figure 7; other 5 kinds of recombinants had different
killing effects against said drug-resistant bacteria, which are weaker than recombinant 3; all
recombinants had no toxic and side effects on normal cells. The experimental process of
verification is the same as recorded in example 2-6 of ZL200910092128.4.
Recombinants prepared by taking the s of dy mimetics in recombinant 3 as
recognition region and taking n la as effect region were verified that, in Table 5,
recombinants with Seq ID 3 as recognition region has basically equivalent killing effects
against the above-mentioned enic bacteria as that of recombinant 3.
Table 5 amino acid sequences of anti-diplococcus intracellularis antibody mimetic
VHCDR1-VHFR2-VLCDR3 and mutamers thereof
No. VHCDR1-VHFR2-VLCDR3 and point mutants thereof
Seq ID No.8 SYWLHWIKQRPGQGLWIGSQSTHVPRT
Seq ID No.9 SYGMHWIKQRPGQGLWIGSQSTHVPRT
Seq ID No.10 SYWIEWIKQRPGQGLWIGSQSTHVPRT
Seq ID No.11 NYWMHWIKQRPGQGLWIGSQSTHVPRT
Seq ID No.12 SYWLHWIKQRPGQGLWIGMQNIGLPWT
Seq ID No.13 SYWLHWIKQRPGQGLWIGQQFTSSPYT
It took less than 6 months for this preparation, and a batch of candidate novel antibiotics with
broad-spectrum antibacterial effect were obtained successfully.
Experimental s and materials adopted to obtain each recombinant in this example were
? exactly the same as recorded in Patent No. ZL200910092128.4, except for the inserted gene
sequences when constructing vectors, so they are not repeated here.
e 3 preparation of novel antibiotics against bacillus anthracis
(1) Goal proposing system determined x toxin or bacillus anthracis as targets; lethal
? infection es caused by x toxin or bacillus anthracis have been posing a huge threat
t human health; in terrorist attacks, anthrax toxin is also the most horrible pathogen or toxin
as weapon.
The goal of this preparation is to provide a novel antibiotic to destroy the toxicity of bacillus
anthracis or anthrax toxin, i.e., to inhibit or interfere anthrax toxin PA antigen from forming active
PA er.
(2) Designing novel antibiotics:
The following designing work was performed according to general formula
, wherein F is effect region; R is recognition region.
The general characteristic of anthrax toxin is that, anthrax toxin is a binary toxin with high
harmfulness to organisms, and consists of protein antigen PA, necrosin and edema factor (LF/EF);
protein antigen PA is a transport structure and can recognize target cells, and it transports in
and edema factor ) into target cells. It's illustrated by animal ments that, a
combination of protein antigen and necrosin can immediately lead to cell death, while no reaction
will be caused as applying said two components separately. The novel antibiotic was designed
preliminarily that recognition region of said novel antibiotic can recognize anthrax PA antigen,
and effect region of said novel antibiotic can inhibit or interfere anthrax toxin PA antigen from
forming active PA heptamer.
Establishing recognition region molecular structure library: anti-bacillus anthracis protein antigen
- lethal factor complex antibody (NCBI 71) generated in cynomolgus and anti-bacillus
cis protein antibody (NCBIABF69350) generated in house mouse were found by searching
database, and they are competent to specifically recognize protein antigen PA of anthrax toxin.
According to amino acid information of said antibodies, a series of dy mimetic ures
and mutants thereof with a structure of V HCDR1-VHFR2-VLCDR3 which can recognize wild-type
? x toxin were designed to build recognition region molecular ure library, and provided
to laboratory .
Establishing effect region molecular structure library: because preparation goal is to inhibit
anthrax toxin PA antigen from forming PA heptamer, in accordance with infection mechanism of
anthrax toxin, in this experiment, some mutant anthrax toxin PA ns (see Seq ID No.10
recorded in ZL200810045212.6) obtained by artificial mutation on anthrax toxin PA antigen were
conducted as member of effect region molecular structure library, and PA lost recognition
capacity to corresponding receptor on target cells; said mutant x toxin PA antigen and
ype anthrax toxin PA antigen constituted heterozygous PA heptamer, which lost
transmembrane activity completely or lly, accordingly interfered with infection ability of
? x toxin.
(3) Laboratory system: inant library was obtained by binding the provided effect region
and recognition region; gene coding said recombinant was inserted into expression vector to
obtain inant expression vector; a batch of recombinant polypeptides were obtained by
transforming said recombinant expression vector into engineered bacteria.
A batch of recombinants with amino acid sequence listed in Table 6 as recognition region and
mutant anthrax toxin PA antigens (see Seq ID No.10 recorded in ZL200810045212.6) as effect
region were obtained through verification, and they could t mice infected by bacillus
anthracis. Verification experiment and results thereof were similar to the effects of pCHCA-PA1
? recorded in ZL200810045212.6.
Table 6 amino acid sequences of antibody mimetics and mutamers thereof recognizing
wild-type an
NO. VHCDR1-VHFR2-VLCDR3 and its point mutants
Seq ID No.14 STALHWRQAPGKGLEWVPRYDEFPYT
Seq ID No.15 SFGMHWRQAPGKGLEWVPRYDEFPYT
Seq ID No.16 NYWMHWRQAPGKGLEWVPRYDEFPYT
Seq ID No.17 STALHWRQAPGKGLEWVFQGSHVPFT
Seq ID No.18 STALHWRQAPGKGLEWVYCHQWSMYT
Seq ID No.19 STALHWRQAP VQ Q WS SNPYT
Seq ID No.20 STALHWRQAPGKGLEWVQQFTSSPYT
It took less than 6 months for this preparation, and a batch of novel antibiotics which have
? protection effects against bacillus anthracis infection were obtained sfully.
Experimental methods (e.g., vector construction, transformation, verification experiment, etc.)
and als adopted to obtain each recombinant in this example were exactly the same as
examples ed in Patent No.ZL200810045212.6, except for the inserted gene of novel
antibiotics, so they are not repeated here.
Example 4 preparation of novel antibiotics against fungi
(1) Goal proposing system determined candida albicans as targets,
and the goal was determined to prepare novel antibiotics killing agricultural fungus - candida
albicans.
? (2) Designing novel antibiotics:
The following designing work was performed according to general formula
F , wherein F is effect ; R is recognition region.
Establishing recognition region molecular structure library: the great progress in fungus basic
ch had been achieved in recent years; amino acid sequence (Seq ID No.21) of candida
ns pheromone consists of 14 amino acid residues. It can move around freely in biological
media, and has biological activity of automatically searching the corresponding receptor on cell
membranes of the same species of fungi cells. Thus, based on such automatically searching
activity, it's available to utilize fungus pheromone as recognition region to induce effect region
? like bacterial exotoxin such as colicin to kill these fungi by forming ion channel through cell
membranes, and a batch of novel biological biocides were constructed accordingly.
Therefore, candida albicans pheromone represented by Seq ID No.21 was selected as recognition
region.
Establishing effect region molecular structure library: because the preparation goal was lethal
novel antibiotics against target of agricultural fungus-candida albicans, colicin was a competent
candidate substance for effect region owing to its characteristics. Thus, colicins Ia, Ib, A, B and N,
and ion channel domains thereof were selected as members of effect region molecular structure
y, and were provided to laboratory system.
The preliminarily designed molecular structure of novel otic was: from amino terminal to
? carboxyl al: colicin or ion l domain thereof or mutamers thereof + candida albicans
one.
(3) Laboratory system: recombinant library was obtained by g the effect region and
recognition region; gene coding said inant was inserted into sion vector to obtain
recombinant expression vector; recombinant polypeptides were expressed by orming said
? recombinant sion vector into engineered bacteria, which realized operable binding between
effect region and recognition region.
The obtained inants were verified that, they all have protection effects on rice (Oryza
sativa) infected by fungi like pyricularia oryzae, illus flavus, and their protection effect on
rice blast infection is thousands of times higher than that of current agricultural antifungal.
? ments and data (e.g., vector construction, transformation) related to obtaining each
recombinant in this preparation was recorded in examples of Patent No. ZL200710050926.1 or
based on the record in prior art, person d in the art can obtain the experimental methods
required for the preparation of this invention by a limited number of experiments, so they are not
repeated here.
? It took 6 months for this preparation, and cost only 1.5-2 years including field experiments,
whose efficiency and success rate are far higher than that of current preparation for a new drug.
Example 5 preparation of novel antibiotics against esistant staphylococcus aureus
(1) goal proposing system determined staphylococcus aureus as targets: since antibiotics like
? penicillin was applied in 1944, bacteria, especially enic bacteria threatening human life,
like lococcus aureus, streptococcus pneumonia, pseudomonas aeruginosa, mycobacterium
tuberculosis, etc., have generated drug-resistance, and human are urgent to develop novel
antibiotics against drug-resistant bacteria.
? (2) Designing novel antibiotics:
The following designing work was performed according to general
formula , wherein F is effect region; R is recognition
region.
Establishing recognition region molecular structure library: many cells e signal transduction
? polypeptides to the outside of cells; these polypeptides can automatically search for the
corresponding receptors on cell membranes of the same species of bacteria, and bind to said
receptors to transport ation into said bacteria; staphylococcus secretes signal transduction
polypeptides to the outside of cells; these polypeptides can automatically search for the
corresponding receptors on cell membranes of the same species of bacteria, and bind to said
? receptors to transport information into said bacteria. These signal transduction polypeptides
consist of several to more than 10 amino acids, and are ideal recognition regions against
staphylococcus. Pheromone ces as Seq ID No.22-26 were collected as the members of
recognition region y h searching.
? Providing effect region: because the preparation goal was lethal novel antibiotics against target of
drug-resistant staphylococcus aureus - candida albicans, colicin was a ent candidate
nce for effect region owing to its characteristics. Thus, colicins Ia, Ib, A, B and N, and ion
channel domains thereof were selected as effect regions, and were provided to tory .
The preliminarily designed molecular structure of novel antibiotic was: from amino terminal to
carboxyl terminal:
colicin or ion channel domain thereof or mutamers thereof + pheromone, and pheromone +
colicin or ion channel domain thereof or mutamers thereof.
(3) Laboratory system: recombinant library was obtained by binding the effect region and
? recognition region; synthetic gene coding said inant was inserted into expression vector to
obtain recombinant expression vector; recombinant polypeptides were expressed by transforming
said recombinant expression vector into engineered ia, which realized operable binding
between effect region and recognition region.
A batch of recombinants were obtained, such as recombinant polypeptide expressed by
recombinant plasmids pBHC-SA1, A2, pBHC-SA3 A4, pBHC-SE and
pBHC-PA (as recorded in Patent No. ZL200910157564.5). They all have icant killing
effects against methicillin-resistant staphylococcus , penicillin-resistant staphylococcus
aureus, vancomycin-resistant enterococci, pseudomonas aeruginosa and multi-drug resistant
pseudomonas aeruginosa.
? Experiments and data (e.g., vector construction, transformation) d to obtaining each
inant in this preparation was recorded in examples of Patent No. ZL200910157564.5 or
based on the record in prior art, person skilled in the art can obtain the mental methods
required for the preparation of this invention by a limited number of ments, so they are not
repeated here.
It took 5 months to prepare a batch of novel antibiotics against drug-resistant bacteria, whose
efficiency and success rate are far higher than that of current ation for a new drug.
Example 6 preparation of novel antibiotics against cyanobacteria
? (1) Goal proposing system determined cyanobacteria as targets: cyanobacteria proliferation
caused by water eutrophication, water pollution are the severest harm threatening water
environment in the world, and they result in huge economic loss to human as well as cause
unrepaired harm to earth's biosphere. As the accelerated industrialization and urbanization
caused by Chinese economic pment, ecological environment pollution and degeneration
aggravate gradually, and water environment ecological control has been major problem we must
face and solve. The current antimicrobial drugs almost have little effects against cyanobacteria;
cyanobacteria is prokaryotic cell belonging to cyanobacteria phylum of bacteria kingdom, and
only chemicals of heavy metals can l acteria at present, e.g., cupric sulfate.
However, in practical application, owing to limited s, it's required to use chemical with
overdose repeatedly, and other beneficial algae, aquatic plants and aquatic organisms are
destroyed when killing cyanobacteria, which s in irreversible permanent damage to
environment.
The purpose is preparing novel antibiotics killing or inhibiting cyanobacteria.
(2) Designing novel antibiotics:
The following ing work was performed according to general formula
? R
F ) , wherein F is effect region; R is recognition region.
Establishing recognition region molecular structure library: a batch of hybridoma cells secreting
anti-cyanobacteria monoclonal antibodies were obtained by immunizing mice with
acteria as antigen, and the deposit No. of one strain of said hybridoma cells is CGMCC
? No.4783.
Based on amino acid sequences of said monoclonal antibodies obtained by sequencing, a batch
of antibody cs were designed, which are shown in Table 1, and mutamers of antibody
mimetics were obtained through random point mutation on the first 5 and the last 9 amino acids
of antibody mimetics; recognition region molecular structure y was built by taking said
antibody mimetic molecules and rs thereof as members. Wherein, the amino acid
ce of antibody mimetic with a structure of V HCDR1-VHFR2-VLCDR3 of monoclonal
antibody secreted by hybridoma CGMCC No.4783) is shown as Seq ID No.27.
Establishing effect region molecular structure library: because the preparation goal was
novel antibiotics killing or inhibiting cyanobacteria, colicin could form lethal ion channel through
? cell membrane of Escherichia coli of the same s but ent strains by itself to cause death
of ichia coli of the same species but different strains, and it was a competent candidate
substance for effect region. Thus, colicins Ia, Ib, A, B and N or mutant sequences thereof were
ed as members of effect region molecular structure library.
Preliminarily obtaining the designed molecular structure of novel antibiotics: from amino terminal
to carboxyl terminal: colicin or mutamers thereof + anti-cyanobacteria antibody
mimetic/mutamers:
(3) Laboratory system: molecular structure of recombinants was obtained by binding the effect
region and recognition region; gene coding said recombinant was inserted into expression vector
to obtain recombinant expression vector; the recombinants were expressed by transforming said
recombinant expression vector into ered bacteria and isolated.
It's revealed by verification on the inhibition effect of obtained recombinants against
cyanobacteria (the design and operation of verification experiments was the same as recorded in
? examples 3-5 of ZL201110155221.2) that, said inants had significant inhibition effects on
microcystis aeruginosa, na but no tion on other beneficial algae like chlorella, diatom
and scenedesmus. Some experimental results are shown as Figure 8A-8D. The molecular
structures of some ed recombinants are listed in Table 7.
Table 7 amino acid ces of antibody mimetics and mutamers t surface ns of
? microcystis aeruginosa
NO. VHCDR1-VHFR2-VLCDR3 and point mutants f
Seq ID No.27 SYWMQWVKQRPGQGLEWIGQQYWSTPPWT
Seq ID No.28 SYGMHWVKQRPGQGLEWIGQQYWSTPPWT
Seq ID No.29 DHYMHWVKQRPGQGLEWIGQQYWSTPPWT
Seq ID No.30 SYWIEWVKQRPGQGLEWIGQQYWSTPPWT
Seq ID No.31 SYWMQWVKQRPGQGLEWIGQQQFTSSPWT
Seq ID No.32 SYWMQWVKQRPGQGLEWIGQQQSREYPYT
Seq ID No.33 SYWMQWVKQRPGQGLEWIGQLQGTHQPYT
It took less than 11 months for this preparation, and a batch of ed novel antibiotics which
had killing effects against targets were obtained successfully.
Experimental methods and materials adopted to obtain recombinants in this preparation were
? exactly the same as recorded in Patent No.ZL201110155221.2, except for the inserted gene of
novel antibiotics in vector construction, so they are not repeated here.
Example 7. Experiments of screening suitable biological expression systems for the methods
of this invention.
Recombinant plasmids were ed during novel otics preparation recorded in
examples 5-6: pBHC-SA1, pBHC-SA2, pBHC-SA3, A4, pBHC-SE, pBHC-PA and
orA 1.
Stepl. Transforming competent cells
40401_11 various engineered bacteria of pET system like BL-21(DE3), B834(DE3), Nova
Blue(DE3) and 618 (Novagen) were transfected by 10Ong inant mutant plasmids
respectively; ice incubate for 5 s, thermal shock at 42°C for 30 seconds, ice bathing for 2
s, adding 160u1 SOC , 220 rpm, incubated at 37°C by shaking for 1 hour, and then
spread on plate (LB medium with 1% agar and 5014/m1 ampicillin) to incubate at 37°C overnight.
Monoclonal colony was selected for proliferation to get strain, and the strain was preserved at low
temperature.
? Step2. Strain recovery
1. Strain recovery
Said preserved strain was unfrozen at 4°C; 1.5m1 strain was added in 10m1 LB medium
(containing AMP 50µg/ml), 220rpm, and incubated at 37°C for 5-8 hours.
2. Inoculation of monoclonal strain
? The recovered strain culturing liquid was diluted at 10 4 or 105 times; 10).d diluted strain culturing
liquid was placed onto the ed LB solid medium (AMP 501.1g/m1) plate and spread. The
plates were placed in moist box for incubation at 37°C for 10-12 hours till round single colonies
were raised on the surface of plate.
Step3. Selection and proliferation of strain
? (1) Regular round single colony with smooth edge was selected by the sterilized toothpick or
inoculation loop from the incubated plate, and placed into 1.5m1 LB medium for culture by
shaking at 220rpm and 37°C for 5-8 hours.
(2) 1.5ml LB medium was added into 100m1 LB medium for culture by shaking at 220rpm and
37°C for 5-8 hours.
? (3) 1 s grade amplification culture: 100m1 strain culturing liquid obtained from the last step was
added into 700m1 improved FB-M9 complex medium for culture by shaking at 220rpm and 37°C
for 5-8 hours.
(4) 2nd grade ication culture: 700m1 strain culturing liquid obtained from the last step was
added into 6x700m1 improved FB-M9 complex medium for culture by shaking at 220rpm and
? 37°C for 5-8 hours.
(5) 3 rd grade amplification e: 6x700m1 strain culturing liquid obtained from the last step was
added into 20L improved FB-M9 complex medium for culture in fermenter with shaking speed at
220rpm and maximum oxygen content, at 37°C for 3-5 hours,
(6) Engineered bacteria fermentation and induction of protein expression: 20L strain culturing
liquid ed from the last step was added into 200L ed FB-M9 complex medium for
culture and protein expression in fermenter, with shaking speed at 220rpm and maximum oxygen
content, at 30°C for 2-4 hours; then at 42°C for 0.5 hours; finally at 37°C for 1-2 hours. Note:
IPTG with final concentration of 0.5mM was added when reaching 42°C.
Step4. Strain collection by fugation
? Strain culturing liquid was centrifuged at 6000g, 4°C for 20min. The precipitate was collected
after centrifugation, and resuspended in 50mM borate buffer ). Note: 2mM PMSF (benzyl
sulfuryl de serine proteases tor) was added into borate buffer, and the operation after
thalli resuspending must be conducted at 4°C.
Step5. Thalli fragmentation
? After thalli were suspended in pH9.0 borate buffer totally, thalli were fragmentated by high
pressure homogenizer at 500-600bar; fragmentation was repeated for 7 times, and there was 3-5
minutes interval between two fragmentations.
Step6. Precipitation of thalli DNA
ntated strain culturing liquid was centrifuged at , 4°C for 40min. The supernatant
? was isolated, added with streptomycin sulfate (16 bottles of streptomycin sulfate with 1 million
units were added into every 200m1 liquid), and stirred on magnetic stirrer for lh.
Step7. Dialysis
Strain culturing liquid obtained by the last step was centrifuged at 55000g, 4°C for 20min. The
supernatant was isolated, placed into dialysis bag, placed in borate buffer for dialysis for 8-12
hours, and the dialysate was changed once every 4 hours.
Step8. Antibacterial engineered polypeptide ne obtained by protein purification
Strain culturing liquid after dialysis was centrifuged at 55000g, 4°C for 20min. The supernatant
was placed into beaker to conduct protein purification by ion exchange method. The supernatant
was loaded in CM ion exchange column, and protein concentration was detected to count protein
content per unit volume; the ratio of loading volume and CM ion gel particles was fixed
according to ion . After g thoroughly, novel antibacterial engineered
polypeptide was obtained through elution by 50mM borate buffer containing 0.2M NaCl.
It's described by s shown in Table 8 that, the expression rate of PMC-SA in E.coli B834
(DE3) was the highest.
? Table 8 comparison of expression rates in different strains (the e yield per unit=total
production of extracted PMC-SAl/the volume of strain culturing liquid)
Engineered strains TG1 BL-21 618 NavaBlue B834
the average yield per unit (mg/L) 0.8 10 5.8 8.1 24.4
The same operation and comparison were conducted on other 6 kinds of recombinant mutant
plasmids, and the results all show the same tendency as shown in Table, that is, ed with
other engineered bacteria, the expression rates of 7 kinds of recombinant mutant plasmids in
? E. coli B834(DE3) are all the highest.
On the basis of this screening experiment, it's preferable but not limited to select E.coli
B834(DE3) as expression system in the method of this invention, in order to efficiently express
and prepare to obtain novel antibiotics.
In y, novel antibiotic preparation method and rm system of this ion are
? capable of providing novel antibiotics with recognition region and effect region specifically
against most pathogenic microorganisms and targets. For most targets, the currently-known
colicin is competent to playing the role of effect region, so the cycle time of preparing a novel
antibiotic depends on the time to design molecular structure, the time to e recognition
region molecular information, as well as the time to prepare and verify recombinants. Because
recognition region depends not only on the selected nature substances but mainly depends on
artificial-prepared antibody mimetic as recognition region, in view of the t biotechnological
level, the time to prepare a novel antibiotic can be basically controlled in a very short period.
Platform for operating said preparation method of this invention fully optimizes, utilizes and
integrates human resources and technology resources, to ensure efficient conduct of development
process and make novel otic development operating as flow-line production.
Claims (10)
1. An antibiotic ation method, comprising steps as follows: (1) determining targets selected from prokaryotic cells, eukaryotic cells, viruses or products thereof which said antibiotic will react against directly; (2) designing a molecular structure of said antibiotic according to the following general formula: n, R is a recognition region, which ically recognizes or combines said targets; F is an effect region, which generates pharmaceutical effects in said targets, and said pharmaceutical effects are effects selected from regulating, repairing, labeling and causing death of said s; ically comprising ; making a recognition region molecular structure library; making an effect region molecular structure library; designing a recombinant molecular structure library using said recognition region molecular structure library and said effect region molecular structure y according to said general formula by structural readjustment, ural recombination and/or structural confirmation of the molecular structures for the recognition region; (3) using said recombinant molecular ure library to prepare and verify recombinants to obtain candidate otics; (4) ing the candidates from (3) for fulfilment of requirements as a ne to obtain antibiotics; said making a recognition region molecular structure library refers to artificially preparing artificial substances which specifically recognize and/or combine said targets as well as obtaining a lar structure thereof; wherein said artificial substances are antibody mimetics designed according to the amino acid sequence of an immunoglobulin which can specifically recognize a unique substance on said targets.
2. The method ing to claim 1, wherein said antibody mimetic is a peptide with a structure of VHCDR1-VHFR2-VLCDR3 from N-terminal to C-terminal, which is constituted by the regions of VHCDR1, VHFR2, VLCDR3 on Fab short arm of said immunoglobulin; or is a mutamer of said short peptide; said mutamer refers to product obtained by cial site-mutation to 5 amino acid residues of VHCDR1 or 9 amino acid residues of VLCDR3 on said short e, which holds recognition capability to unique substance on said s.
3. The method according to any one of claims 1 or 2, wherein said immunoglobulin is prepared by taking common unique substances on multiple targets as immunogens to immunize an animal.
4. The method according to any one of claims 1-3, wherein said target is a virus, prokaryotic cell or eukaryotic cell with phospholipid bilayer membranes as the basic structure of its cell membrane or envelope; said pharmaceutical effect is causing death; and said effect region refers to a bioactive substance which can form an ion channel or pore path in said phospholipid bilayer membranes.
5. The method according to claim 4, n said effect region refers to barteriocin Pyosin of Pseudomonas aeruginosa.
6. The method according to claim 4, wherein said effect region refers to colicins E1, Ia, Ib, A, B or N; or domains of colicin molecules E1, Ia, Ib, A, B and/or N which can form ion channels; or molecules obtained by allosterism from colicin molecules E1, Ia, Ib, A, B, N, domains of colicin molecules E1, Ia, Ib, A, B or N which can form ion channels, having the function of forming ion channels in said phospholipid bilayer membranes.
7. The method according to claim 4, wherein said recombinant is a recombinant polypeptide, said preparing recombinants refers to wherein the gene coding for said inant polypeptide is transformed into a biological expression system to express a fusion n, and the antibiotic is obtained by separating and purifying the fusion protein.
8. The method according to claim 7, n said expression system refers to E.coli B834 (DE3).
9. The method according to claim 1, wherein said ceutical effect is labeling, said effect region is a label, and said preparing recombinant is operably linking said effect region and said recognition region.
10. An antibiotic ation method of any one of claims 1 to 9 substantially as described herein with reference to the Examples.
Applications Claiming Priority (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201110405775.3 | 2011-12-08 | ||
CN201110405775 | 2011-12-08 | ||
PCT/CN2012/086296 WO2013083095A1 (en) | 2011-12-08 | 2012-12-10 | Novel antibiotic preparation method and platform system based on same |
Publications (2)
Publication Number | Publication Date |
---|---|
NZ627116A NZ627116A (en) | 2016-07-29 |
NZ627116B2 true NZ627116B2 (en) | 2016-11-01 |
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