AT409801B - METHOD FOR SCREENING AND ISOLATING MICROORGANISMS, IN PARTICULAR PROKARYONTIC AND EUKARYONTIC CELLS THAT PRESENT AN ANTIQUE - Google Patents

Description

       

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   The invention relates to a method for screening and isolating microorganisms, in particular prokaryotic and eukaryotic cells, which present an antigen.



   Screening methods for cell or phage display libraries represent a speed-determining bottleneck in the field of genomes. Efficient methods for sorting cells are either expensive or associated with the risk of the cells that are to be screened and isolated being to damage.



   On the other hand, cheaper methods are often associated with high background signals, which lead to problems in the detection of microorganisms (cells, phages, etc.) in which there is an interest. At least, such methods with high background signals result in a lot of work when analyzing positive signals at a high rate of false positive results.



   The identification of organisms in which there is interest with antibodies is a general method in such screening systems and in the identification, separation, cultivation and manipulation of such microorganisms.



   For example, it is known that the labeling of a target entity with fluorescent monoclonal antibodies (MABs) or antibodies which are linked to staining reagents is a selection means for identifying target cells. However, if such identification is done manually or mechanically, numerous activities involving incubations and washing steps have to be carried out. Instead of such direct labeling with monoclonal antibodies, indirect analysis is customary, in which the biological target microorganisms are first labeled with a specific MAB which is not labeled.



  After extensive washing to remove unbound specific MAB, a second antibody is added which is labeled and recognizes the first antibody. However, although such indirect methods are more specific, they require significant amounts of reagents and numerous activities that are used in such identification processes.



   It has been proposed to use magnetic particles that have an antibody bound to their surface that can bind to specific proteins or antigens (US 5,466,574 and US 6,013,532). It has also been suggested that this method be used to separate cells, cell components or viruses with a characteristic determinant from a test sample, e.g. B. for the removal of rare cells, for the depletion of natural killer cells, for the determination of reticulocytes, for phagocytosis tests, for obsonization tests, for the detection of specific tumor cells or for the immunospecific isolation of monocytes, granulocytes or other cell types.

   It has not yet been proposed to use such a system specifically for screening and isolating viable prokaryotic and eukaryotic cells, for example from a library of cells that have a library of antigens within a membrane protein. In fact, in the methods of the prior art, the viability of the cells is often greatly reduced during the screening and isolation processes according to such a prior art. As a result, a large number of target microorganisms are lost or killed during such procedures.



   C1q is a plasma protein that is constantly present in relatively high concentrations (70 to 80 mg / l) and is part of the classic way of activating complement. The C1q protein molecule has 6 spherical "heads", each of which contains an A, B and C polypeptide chain and carries an 81 residue extension that forms part of a central, collagen-like triple helix swan - zes ist (Eggleton et al., Trends in CELL BIOL. 8 (1998), pp. 428-431). C1q is known to bind first to an antigen, followed by the binding of C1s and C1r to C1q (thereby forming the C1 component complex), followed by serial binding of the other complement components C2- C9). C1q binds to a number of different cell types, triggering a number of different immune responses and inflammatory responses.

   The interactions of C1q with human neutrophils, eosinophils, platelets, endothelial cells and B-lymphocytes have been described to influence inflammatory reactions and adaptive immune responses. C1q is also described to modulate a number of different functions in fibroblasts.



   One of the more important biological roles of C1q is the detection of antigen / antibody complexes. C1q binds to such complexes when an antigen on the outer surface membrane of a pathogenic bacterium is recognized by an antibody. If C1q to such

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 Binding immune complexes, the activation of the other component factors through this binding process leads to an enzyme complex on the bacterial membrane, which leads to an attack and perforation of the bacterial cell wall (membrane) and to the lysis of the bacterium.

   Although C1q is known to be highly specific for antibody / antigen-immune complexes and has also been used in substance-conjugated form to determine or detect a specific antigen in a body fluid or other biological fluid, C1q has never been suggested use a method for isolating viable prokaryotic and eukaryotic cells. At the cell detection level, C1q or C1q reagents were used to bind to fixed and immobilized cells in order to chemically measure surface antigen or intracellular substances of microorganisms (cf. US 4,882,423).



   It is therefore an object of the present invention to provide a method for the selection and isolation of viable microorganisms, in particular viable prokaryotic and eukaryotic cells which present an antigen, which is inexpensive, easy to handle and highly selective, has little background and has no negative effects on the microorganisms, preferably cells to be selected, and can therefore be used for screening large libraries which have only one or a few targets of interest.



   In addition, it is an aim to provide such a screening and isolation system, in particular for cell libraries that have a library of antigens in an outer membrane display connection, and wherein the detection of the antigen is possible even when it is inserted as such Outer membrane protein is presented.



   These tasks are solved by a method for screening and isolating microorganisms, in particular prokaryotic and eukaryotic cells, which have an antigen, which is characterized by the following steps: the provision of a suspension of a large number of viable microorganisms which comprise one or more Contain microorganisms, in particular prokaryotic and eukaryotic cells, which present at least one type of antigen on their surface, - bringing this suspension of microorganisms into contact with a solution which
Contains antibodies which bind to the at least one type of antigen, - incubating this suspension with these antibodies in order to enable the antibodies to bind to the antigen (s),

     bringing this suspension of microorganisms into contact with antibody / antigen
Complexes on their surface with C1q molecules to enable the C1q molecules to bind to the antibody / antigen complexes on the surface, and isolating viable microorganisms, in particular prokaryotic and eukaryotic cells, which have C1q molecules which are bound to an antibody / antigen complex on their surface.



   It was surprising that with the use of C1q molecules a quick one. and a simple and inexpensive method for screening, selecting and isolating viable microorganisms, in particular fragile prokaryotic and eukaryotic cells, could be provided. Although the complement is known to damage cells that present an antigen / antibody complex on their surface, it has therefore only been used in connection with necrochemistry (e.g.

   No. 4,882,423), it was found in the course of the present invention that the use of the C1q molecules and reagents for screening and isolating viable cells can be carried out without risking rare or fragile cells as a result of problems related to viability to lose with the screening process.



   In addition, C1q molecules have another advantage compared to a secondary anti
 EMI2.1
 bind greater affinity to lgG2 and lgG4. It is therefore possible to specifically isolate epitopes that could result in complement-mediated lysis.



   According to preferred embodiments of the present invention, the suspension of the large number of viable microorganisms has a library of microorganisms, in which each individual microorganism presents at least one unique antigen which is not common for the majority of the large number of microorganisms. This antigen or library of antigens can preferably be derived from pathogenic organisms, e.g. B. from a genomic library of such a microorganism. According to another preferred embodiment, a

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 such antigen can be a randomized peptide, for example generated from randomized DNA sequences (Grabowska et al., Virology 269 (2000), 47-53; Rowley et al., J. Immunol. 164 (2000), 3413-3419).

   Another preferred alternative is to present expressed sequence tags (ESTs), preferably ESTs derived from specific EST libraries with known specificity, e.g. of specific organisms or specific cell types.



   Such microorganisms, in which heterologous antigens are presented, are even more endangered by normal screening methods because of their increased fragility, in particular with regard to their membrane stability. It is therefore even more surprising that in the present C1q system, the number of viable cells is high enough even for screening for single or rare cells / antigens.



   Preferred cells used for the presentation of antigens according to the present invention are prokaryotic and eukaryotic cells, which are easy to handle in the laboratory under conventional conditions. Cells with established techniques for gene manipulation are particularly preferred.



    As stated above, it is preferred that the antibody to be presented (s) to be presented is heterologous to the microorganisms, i. that is, the antigen is not present in the wild type of such microorganisms (e.g., such microorganisms genetically modified).



   According to another preferred embodiment, the antibody-containing solution has more than a single antibody species. The method according to the invention is suitable for screening a mixed antibody solution which, for example, originates from human or animal serum, which was intentionally drawn in relation to a specific antigen or an entire antigen library or was caused in some other way (for example by specific plasma selec- tion). As a result, the present system is perfectly suitable for a cloning system, as described in WO 99/30151.



   Preferred antibody solutions are therefore antibody preparations (in particular IgG preparations) which originate from human blood, in particular from patients with antibodies against the pathogen of the antigen library to be screened for. Hyperimmunoglobulin preparations of, for example, HAV, HBV, HCV, HIV patients or of patients who have infections with, for example, Staphylococcus aureus, Mycobacterium tuberculosum, Staphylococcus epidermidis, Streptococcus pneumoniae, paeruginosa or Chlamydia pneumoniae, or other clinically, are particularly suitable have survived relevant infections with viral, prokaryotic or eukaryotic pathogens.



   If an antigen library in or adjacent to a surface protein of a microorganism, e.g. B. a bacterium such as E. coli, it can often be difficult to form a complex from an antigen, an antibody and a C1q molecule, especially when the antigen is presented in a rather unnatural environment. On the other hand, if such an immune complex or the detection of such an immune complex would cause the immune complex to damage or tear the cell wall, the viability of the microorganisms would be seriously endangered.

   In fact, it was surprising that screening, detection and isolation with C1q molecules was possible even with antigens presented as an integral part of the surface protein of the microorganisms, especially in those cases where this antigen is presented as an integral part of the outer membrane protein (as described for example in WO 99/30151).



   According to a preferred embodiment, the C1q molecule used in the present invention is selected from the group consisting of C1q, substance-conjugated C1q, synthetic C1q peptide, surface-bound C1q or mixtures of such components.



  In particular, C1q, which is conjugated to specific marker substances, is preferred. Such marker substances can be signal-emitting substances, such as enzyme substrates, dyes or pigments, magnetizable substances, donors or acceptors for electron transmission, radioactive materials, metal compounds and metal compositions which emit signals which can be detected by the sensor organs or an external instrument, Enzymes or coenzymes that can be modified to emit detectable signals, biotinylation, agglutinating substances that come together to be easily detected thereby, cell function regulating substances, for example certain enzymes that respond to the counter

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 stamps conjugated with C1q to give the latter any functions, and substances

   such as highly polymeric materials that capture or reversibly fix the C1q-conjugated antigens. C1q can be isolated from various animals, including sheep, rabbits, guinea pigs, cattle, horses, dogs, mice and humans, and can be prepared using conventional purification procedures. It is also possible to use synthetic C1q peptides that contain the essential part for immune complex recognition and binding. Examples of such C1q molecules, in particular substance- or surface-bound C1qs, are known in principle to the person skilled in the art and are described, for example, in US Pat. Nos. 4,882,423 and 4,143,124.



   According to preferred embodiments, the C1q molecule is immobilized on a solid matrix, in particular on magnetic particles, and the microorganisms in which there is interest are purified by affinity purification using such magnetic particles. It was surprising that this method is suitable for isolating viable microorganisms, in particular prokaryotic and eukaryotic cells, which may have been genetically manipulated with regard to their surface proteins. Although the magnetic immobilization and manipulation of cells is known in principle (see, for example, US Pat. No. 6,013,532), it is known, however, that a large number of target microorganisms are normally lost or killed in such activities.

   In addition, such magnetic methods have only been applied to normal, non-manipulated, or fragile cells, and never in conjunction with the complement system, which is known to have a strong impact on the integrity of the surface of such microorganisms and their viability.



   According to a further aspect, the present invention relates to a method for producing a culture of microorganisms which present an antigen, which is characterized in that the microorganisms isolated according to the invention, which are identified by the present method, are optionally separated from the antibodies and the C1q molecules are cloned and, if necessary, grown in a suitable growth medium, for example to identify the antigen or immune complex.



   In another aspect, the present invention relates to a set for carrying out the method according to the invention, comprising - a suspension of a plurality of viable microorganisms which contain one or more microorganisms, in particular prokaryotic or eukaryotic cells which have at least one type of antigen on their surface , - a suspension of antibodies that bind to the at least one antigen type, and - at least one C1q molecule type.



   The three minimum components of the set according to the present invention can be adapted to the specific embodiments described above and optionally in lyophilized form and / or together with suitable auxiliaries. Preferably, further reagents or devices for isolating the cells are included in the set, e.g. B. Devices for magnetic separation of microorganisms, in particular prokaryotic and eukaryotic cells.



   Another aspect of the present invention relates to the use of the method according to the present invention for the identification and isolation of antigens, in particular antigens derived from pathogenic organisms, in order to provide vaccines.



   The method is further described in the example and in the drawing figures, without being restricted to these.



   1 and 2 show the C1q-mediated whole cell affinity purification.



   example
C1q can specifically isolate bacteria that present a specific epitope (T7 epitope):
Test procedure:
Individual colonies of DH5a cells containing the plasmid pEH1-LamBT7 or the plasmid pEH3 (only the vector), which were suspended in 5 ml LBKan or LBchl, were grown for about 4 hours

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 incubated for long at 37 C. At an OD600 of 0.2, the cells were induced with 0.1mM IPTG at 37C for 1.5 hours. A mixture of cells expressing T7 epitope-labeled LamB and non-epitope-expressing cells (ratio = 102: 106) was incubated with 10 ng T7-specific antibody either with or without 10 µg human IgGs (previously on E coli DH5Ó pre-adsorbed) incubated.



  The reaction volume was 100 ul (buffer: 25mM HEPES-CI, pH 7.4.2.5mM CaCl2, 10mM MgCl2, 0.1% BSA), the incubation temperature was 4C, the tubes were placed on a shaker ( Rotator Drive STR4, Stuart Scientific).



   After incubation with 5 µg of biotinylated C1q, 1 ml of HEPES buffer was added, and the Eppendorf tubes were centrifuged at 4 C (8,000 rpm, Biofuge, Heraeus) for 15 min, the cell pellet was again rinsed with 1 ml fresh buffer washed. The cells were then resuspended in 100 ul of buffer and 10 ul of streptavidin-coupled MicroBeads (Miltenyi) were added.



   After 50 min the incubation mixture was diluted with 1.5 ml of HEPES and loaded onto MS columns (Miltenyi). After washing (3 x 1 ml buffer) the column was removed from the magnet and the bound cells were eluted with 1.5 ml buffer. The elution fraction was then loaded again onto an MS column for a second round of separation (the washing and elution volumes were 3 × 1 ml and 1.5 ml, respectively).



   Incubation time: t7 monoclonal antibody: 1 h, biotinylated C1q: overnight (16 h), 50 min with MicroBeads conjugated with streptavidin.



   Fractions 1 + 2,3 + 4 and 5 + 6 were pooled and half the volume was plated on LB plates containing either kanamycin or chloramphenicol.



   Result: Number of cells used in the experiment (E. coli strain DH5a)
LamB T7 (kanamycin resistance): 67 pEH3 (vector only) (chloramphenicol resistance): 1.5 x 105
 EMI5.1
 
<tb> ciq <SEP> (ug <SEP> 5 <SEP> 5 <SEP> 5 <SEP> 5
<Tb>
<Tb>
<tb> Human IgGs <SEP> (ug) <SEP> 10 <SEP> 10 <SEP> 10 <SEP> 10
<Tb>
<Tb>
<tb> T7-Ab <SEP> (ng) 10 <SEP> 10
<Tb>
<Tb>
<Tb>
<tb> washing <SEP> (Ms) <SEP> specific <SEP> 4 <SEP> 7 <SEP> 51 <SEP> 44
<Tb>
<Tb>
<Tb>
<tb> washing <SEP> (MS) <SEP> specific <SEP> 9 <SEP> 2 <SEP> 0 <SEP> 0
<Tb>
<Tb>
<Tb>
<tb> Elution <SEP> specific <SEP> 36 <SEP> 0
<Tb>
<Tb>
<tb> ¯¯¯¯¯¯¯¯¯¯nonspecific <SEP> <10 <SEP> <10
<Tb>
 
Table 1
These results show that C1q bacteria that present a specific epitope (T7 epitope) on the surface are made up of a variety of bacteria,

   that cannot present, isolate this epitope. After a single round of separation, more than 50% positive bacteria with a background of only 10-20 cells (from 1.5 x 105 cells!) Were obtained. In a direct comparison, the secondary antibody used in place of C1q resulted in a much higher background of 300-500 cells that did not present an epitope.



   As can be seen from the present example, C1q currently works best with LamB outer membrane protein or similar proteins that form a homotrimer on the surface. Therefore, if you insert a heterologous peptide into one of the loops, this epitope is presented three times very close to each other. This is of course preferred for efficient C1q binding, since strong binding only occurs when C1q binds to at least two antigen-bound IgGs at the same time.

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Claims (13)

 PATENT CLAIMS: 1. A method for screening and isolating microorganisms, in particular prokaryotic and eukaryotic cells, which present an antigen, characterized by the following steps:  <Desc / Clms Page number 6>  the provision of a suspension of a large number of viable microorganisms which contain one or more microorganisms, in particular prokaryotic and eukaryotic cells, which present at least one type of antigen on their surface, the contacting of this suspension of microorganisms with one Solution containing antibodies that bind to the at least one type of antigen, - incubating this suspension with these antibodies to allow binding of the antibodies to the antigen (s),  bringing this suspension of microorganisms with antibody / antigen complexes on their surface into contact with C1q molecules in order to enable the C1q molecules to bind to the antibody / antigen complexes on the surface. and the isolation of viable microorganisms, in particular prokaryotic and eukaryotic cells, which have C1q molecules which are bound to an antibody / antigen complex on their surface. 2. The method according to claim 1, characterized in that the suspension of a plurality of viable microorganisms has a library of microorganisms, wherein each individual microorganism presents at least one unique antigen that the majority of Variety of microorganisms does not have. 3. The method according to claim 1 or 2, characterized in that the microorganisms are genetically modified and the at least one type of antigen that binds to these antibodies is not present in the wild type of the microorganisms. 4. The method according to any one of claims 1 to 3, characterized in that the antibody-containing solution has more than one antibody species. 5. The method according to any one of claims 1 to 4, characterized in that the antigen is presented as an integral part of a surface protein of this microorganism. 6. The method according to any one of claims 1 to 5, characterized in that the microorganisms are bacteria and the antigen is presented as an integral part of an outer membrane protein. 7. The method according to any one of claims 1 to 6, characterized in that the antibody solution is an IgG solution that comes from blood plasma. 8. The method according to any one of claims 1 to 7, characterized in that the antigen is a randomized peptide. 9. The method according to any one of claims 1 to 8, characterized in that the antigen is a peptide which is derived from a pathogenic microorganism. 10. The method according to any one of claims 1 to 9, characterized in that the C1q molecule is selected from the group consisting of C1q, substance-conjugated C1q, synthetic C1q peptide, surface-bound C1q or mixtures thereof. 11. A method for producing a culture of microorganisms which present an antigen, characterized in that the microorganisms isolated according to a method according to one of claims 1 to 10 are optionally separated from the antibodies and the C1q molecules, cloned and, if appropriate, in be grown in a suitable growth medium. 12. Set for carrying out the method according to the invention, comprising a suspension of a plurality of viable microorganisms which contain one or more microorganisms, in particular prokaryotic and eukaryotic cells which have at least one type of antigen on their surface, a suspension of antibodies which are sensitive to the at least bind an antigen species and at least one Ciq molecule species 13. Use of a method according to claims 1 to 11 for the identification and isolation of antigens.  THEREFORE 2 SHEET OF DRAWINGS