DE2263289C3 - Process for the preparation of carrier-bound polypeptides - Google Patents

Description

The use of carrier-bound protein bodies is gaining more and more importance in science and technology Meaning as they allow it in the simplest and most secure way. Active ingredients and substrates according to their Implementation again / u separate. For this reason, numerous development laboratories have established themselves The aim is to develop carriers for proleinar active ingredients, the proteins from aqueous Solution as quickly and completely as possible while preserving its biological effectiveness as much as possible and do not release the active ingredient again during use. After the rudimentary exposure The carrier-bound active substance is to be removed from the substrate quickly and completely by filtration The substrate solution should be separable, and a layer of the material should result in a high flow rate Allow in continuous operation. Having first preparations sent to synthetic or pretreated active ingredients bound to natural macromolecules, e.g. B. enzymes contained, still to be regarded as quite imperfect As a result of years of development work, there are now products with a high content of active ingredients and good fillability. ίο Certain disadvantages of these products have been identified so far viewed as fundamentally unavoidable. The carriers contain groups that act against polypeptides, in particular their terminal and pendant amino groups are reactive and thus under formation able to react with an amide group. These groups, such as carboxylic acid anhydrides, carboxylic acid chloride or phenyl ester moieties, are hydrolytic and become a sizeable one Partly hydrolyzed before reacting with the protein body. Formed by hydrolysis Carboxyl groups whose negative charges in the later reaction with those which are also negatively charged Substrate molecules can be a hindrance and also the matrix properties of the carrier can be significant change. Other functional groups at whose Hydrolysis no carboxyl groups, but amino or hydroxyl groups are formed, react so sluggishly that it is extremely difficult to bind proteins long reaction times or activity-damaging reaction conditions. Furthermore, t.H the Production of the basic, which are often functionally important Amino groups of a protein body in non-basic amide groups the biological effectiveness in many Cases lost, so that only that portion of the active ingredient remains active in the bound state which the bond took place more or less by chance at a non-essential amino group has.

The invention is based on the object. Poly peptides bind under gentle conditions to such carriers / u that are easy to manufacture and do not contain any groups that create new polar or even ionic groups through hydrolysis or side reactions form. The binding of the polypeptides should be possible at temperatures and pH values which the biological activity of the polypeptides is not impaired, and should be as extensive as possible Maintain the biological activity of the bound protein. The Reaklionprodiikl should be water-soluble or water-swellable depending on the intended use and in the latter Case can be easily filtered and washed out. It was found that the photochemical bond of the polypeptides to inert substances fulfills these / many requirements.

By working from I). F 1 ad and its co-workers (e.g. I). F 1 ad and .1. Sperling, Journ. Anicr. Chem. Soc. ^l > 3, pp. 967 to 971: 1971) at the Weizmann Institute (Rehovoih. Israel) it is known to add toluene or lower olefins such as 1-butene to glycine or glycine-containing polypeptides by photochemical reaction. The glycine units change into those of phenylalanine or norleucine. In a typical implementation of this type (J. S per Ii im. G 65 J. Amcr. Chem. Soc, 1969, Vol. 91, pp. 5389 and 5390), a polypeptide composed of 90% di-alanine and 10% glycine is used with a molecular weight of 4800 in a solution in water, tert-butyl alcohol and acetone

ills sensitizer) rail i-butene or toluene under the action of UV light for hours at room temperature ". This resulted in polypeptides which were partly soluble, partly insoluble. 2 to 3% phenylalanine units. This corresponds to a conversion of the glycine units present of 5 to 10% in the case of butene and from 20 to 30% in the case of toluene . 75 to 78) was continued to a serious impairment of the biological activity by photochemical reactions by reaction with toluene or butene lysozyme completely. RNase was inactivated to 90%. _ppen numerous works by various researchers is a plurality of further photochemical reactions are known, of which collectively it can be said that they proceed in an unspecific manner and with low yields Binding of polypeptides to carrier substances should be used, because it is a general experience that reactions between macromolecules proceed less easily than reactions between macromolecules and low molecular weight compounds.Therefore, only those reactions have so far been used to bind polypeptides to carrier substances that take place quantitatively in the low molecular weight range. But even with this one could only achieve the binding of small amounts of polypeptides. For this reason, the photochemical addition to the binding between polypeptides and carrier substances initially appeared to be hopeless. In addition, with each binding / between polypeptides and carrier substances, only a slight preservation of the biological activity was to be expected. For example, the effectiveness of trypsin is reduced _{to a fraction of the original value by acylation with} polyacrylic acid derivatives, whereas acetylation only negatively affects the activity of trypsin. The same observation can be made for insulin and many other biologically active pro-

^tel etwar ^ therefore completely surprising that polypeptides can be bound by photochemical means to carriers of various types under the gentlest conditions quantitatively while largely preserving their biloeischen activity. The fact that the photochemical reaction is not fundamentally bound to certain reactive organic groups even though, as will be discussed later, some certain groups are quite beneficial, allows the carrier materials to be selected largely according to the application requirements. Water-soluble carriers can be used as well as water-insoluble swellable ones Gels or bead polymers or even inorganic carriers modified with organic compounds.

The conversion of polypeptides with macromolecular carrier substances should in any case allow come that a covalent bond is already made by the reaction of a single reactive Grouping of the polypeptide and the carrier molecule comes about. A quantitative response of all reactive groups of both components is therefore not required. If anyway in most of them In some cases, a poorer yield is achieved in the reaction of pnnentiden with macromolecules. than in analogous reactions with low molecular weight compounds, it can be seen in which considerable degree of reactions between macromolecules versus low molecular weight reactions be-S are involved. It was therefore not foreseeable that precisely in the photochemical reaction the Implementation of macromolecular partners is more complete than the implementation of polypeptides with low molecular weight compounds. This surprising effect can - without thereby the invention to want to commit to a certain theory to be interpreted as meaning that with the photochemical Reactions, as far as their mechanism is known so far, predominantly hydrophobic parts of the molecule react with each other, e.g. the methylene group of the glycine residue with butene or toluene. As the polypeptides as a whole rather hydrophilic and chemical reactions only strong in aqueous or otherwise polar reaction media are accessible, the photochemically reactive non-polar groups should through the strongly vutated polar groups of the polypeptide are strongly shielded and hydrophobic for small ones Molecules are difficult to access. The carriers used in the method of the invention are, however, usually hydrophilic, so that there is an interaction and agglomeration with comes from the hydrophilic groups of the polypeptide. This inevitably also reduces the hydrophobic, Photochemically activatable groups of both macromolecules brought into spatial proximity and their implementation facilitated.

The invention relates to a method for producing carrier-bound PoK peptides in which one the aqueous solution of a Pol> peptide in the presence a non-peptide macromolecular carrier compound and a photosensitizer known per se in the absence of oxygen with ultraviolet light or with additional presence of an organic peroxide irradiated with visible light.

The term "polypeptide" can be interpreted broadly. It is not just water-soluble natural protein bodies that fall including such as enzymes, antibodies, hormones with protein structure, inhibitors, but also from a few Natural or synthetic polypeptides made up of amino acid units, such as dipeptides, or compounds, which are only partially constructed in the manner of peptides, such as penicillins. Furthermore, one can also use substances which have no peptide structure, react with oligomeric peptides and transfer them to carrier molecules via this group tie.

The term "carrier" has been used more comprehensively here than in the other biochemical literature common. It does not only include insoluble solids. 55 but also water-soluble compounds that are known as Act as vehicles for the bound polypeptide and e.g. B. its transport to certain points of a biological system, its permeability through boundary layers or membranes, its distribution 60 to influence different phases and the like.

As a macromolecular carrier compound comes thanks to the low specificity of the photochemical Reaction takes a wide variety of non-peptide-like compounds into account. It is in the The vast majority of cases involve natural or synthetic organic polymers, however Inorganic carriers can also be used, provided they are sufficient for the activating radiation

are permeable, a sufficient internal surface and trust photochemically activatable organic groups on this surface. As examples of Inorganic carriers of this type are porous glass, swellable silicates, in particular clay minerals, or called highly disperse silica, which are modified with such siloxanes as alkenyl, toluyl or contain other groups accessible to photochemical addition,

The organic ones used in the majority of cases Carrier compounds have a molecular weight above 1,000 and preferably above 10,000. They can be water-soluble, but for most applications they become water-insoluble carriers used, preferably those that are composed predominantly of hydrophilic monomer units and their insolubility in water are due solely to their cross-linked structure, these are the carrier substances It is well known that no molecular

containing polymer endneC H bond in "-Stelluii! cleaved to the carbonamide group with the formation of a C radical {cf. I. Rosenthal in "The Chemistry of Amides" by S. Patai and J. Zabrick \ Intercience, New York 1970. p. 303). Homopolymers and copolymers of methacrylamide, which have wedge n-C ' hydrogen atoms, are therefore less reactive and less preferred than homopolymers and mixed polymers of acrylamide or vinylpyrrolidone not critical, although hydrophilic comonomers are generally preferred, such as. B. methacrylamide. Acrylic and methacrylic acid and their water-soluble salts, vinyl pyrrolidone. Hydroxyulkylester of acrylic or methacrylic acid, such as. B. hydroxyethyl acrylate, 2-hydroxypropyl acrylate. Butanediol-1,2-acrylal. Butanediol-1,4-acrylate or the

indicate weights. The crosslinking is preferably so 20 corresponding methacrylates, furthermore aminoalkyl

esters or aminoalkylamides of acrylic or methacrylic acid and their salts or quaternization products. like Dimethylaminoäthylmethacnlat or its hydrochloride or hydroacetate, methacrylic

oxyäthyltrimethylammoniumchlorid.

The polymers can be polymerized with two or more comonomers due to small proportions of comonomers Double bonds, such as divinylbenzene, glycol diacnlate or dimethacrylate or triallylcyaniiral vernel / i being.

In addition to the hydrophilic or water-soluble monomers mentioned, the structure of the carrier molecules even if they are to be water-soluble or highly swellable, non-water-soluble monomers

be involved. The Triigerstoffc are then water-soluble or good swell bar if they consist of a vinyl polymer, optionally in addition to a crosslinking Monomers

little that the substances are swellable in water. Through a swellability to at least twice the dry volume already becomes a great inner one Surface «released for binding of polypeptides. However, in order to also penetrate very large Protein molecules and, after their photochemical binding, also the diffusion of large ones in and out Allowing substrate molecules is a stronger swellability in water, for example by a factor of preferably 10 to 200 times the dry volume is advantageous.

If carriers are used, they are in the solution of the polypeptides do not swell, so they must. to bind a sufficient amount of polypeptides to be able to, in the form of extremely fine particles, e.g. B. latex particles are present. To a large number of known ones polypeptides can be attached photochemically to natural or synthetic polymeric complexes will. Such loaded latex particles can then be used, similar to blood cells, as carriers for biological serving active substances.

Among the water-soluble or water-swellable carrier substances which are fundamentally suitable for the process of the invention, those are distinguished by a high photochemical reactivity. which are wholly or partly built up from monomer units which are as hydrophilic as possible and tend to form free radicals. This applies to macromolecular compounds with carboxamide, carboxylic acid ester, laelon. Hemiacetal and cyclic ether groups. Homopolymers and copolymers of acrylamide or vinyl pyramidone and polysaccharides have proven to be very reactive. I ^! In addition to the polysaccharides, the carrier materials, such as Sepharose and polydextran gels, which are already widely used in biochemistry, are used. Agarose gels. Cellulose in the form of powder, fibers. Fleece (filter paper) or regenerated film, etc., preferred. The hydroxyl groups of the polysaccharides can be partially etherified or esterified, for example in order to reduce the biodegradability. In the case of the polysaccharides, the radical reaction probably attacks the C — Η bond adjacent to the ring oxygen atom, whereby a hydrogen atom is split off and a carbon radical is formed (cf. I. R osen 1ha I and D. El ad. Tetrahedron Letters 1967. Vol . 23. pp. 3193-3204).

In an analogous manner, in carboxamide groups

a) at least 80 mol percent from a hydroxyl alkyl ester acrylic or methacrylic acid or

b) at least 60 mol% of acrylic or methacrylamide or of vinylpyrrolidone or

c) at least 40 mol percent from acrylic or methacrylic acid or from their dialkylaminoalkyl esters or

d) at least 20 mole percent of water-soluble Salts of acrylic or methacrylic acid or from salts or quaternization products of dialkylaminoalkyl groups Jer acrylic or methacrylic acid

and the remaining part is composed of water-insoluble monomers.

Water-soluble carriers that are easily unrecognizable functional groups, such as hydroxyl or carboxyl groups, can also be included if desired subsequently by reaction with functional crosslinking agents such as diisocyanates, bis-epoxides. Urea-formaldehyde condensates etc. to any desired degree of shortening or swelling to adjust.

A particularly advantageous method for producing water-insoluble Triigerstoffc is described in the German Offcnlegiingsschrift 20 09 218. This process gives swellable crosslinked carrier polymers in the form of beads of, for. B. 0.1 to

63

I mm in diameter by polymerizing an aqueous solution of a vinyl monomer and a crosslinking agent in an organic phase. A very high degree of swelling is achieved with these polymers because the polymer is polymerized from the outset in the presence of a large amount of water, ie in the swollen state.

Although the macromolecular substances described above contain groups that have a photochemical Linkage with polypeptides are accessible ίο, it can happen that only after a long time and strong irradiation, a sufficient number of bonds between a polypeptide and a Carrier arises. To avoid damage to the polypeptide due to long exposure to radiation and a great deal of effort To avoid radiation energy, it has proven useful in such cases to incorporate such into the carrier material bring in organic groups that form a pholochemical Reaction are particularly easily accessible. Such groups are rope-attached alkyl groups. especially those with a terminal double bond, or alkylphynyl groups. including above all the toluyl residue. These groups can be divided into many Cases by reaction of the carrier with toluene carboxylic acid chloride. Toloyl sulfochloride. Introduce allyl chloride, acrylic acid chloride, etc. In this way one can determine the photochemical reactivity of all carrier materials containing OH groups or amino groups. be they photochemically inert or reactive per se, improve. This is preferably true for carriers mil Polysaccharide structure. so Agarosc. Polydcxtran and cellulose, as well as for hydroxyalkyl-substituted polyvinyl compounds. such as homopolymers or copolymers of hydroxyalkylamides or N-hydroxyalkylamides acrylic or methacrylic acid. When using vinyl polymers as a carrier, it is more advantageous monomers with corresponding side groups must be used even in their construction. z. B. vinyl toluene or allyl acrylate or methacrylate. The proportion of these monomers can be fractions of a Percentages up to 50% or more based on the total weight of the monomers.

Although polypeptides can also be photochemically linked or crosslinked, Polypeptides play no role as carriers in the present process and therefore do not belong to the Scope of the invention.

The photochemical reaction between the polypeptide and the carrier takes place in an aqueous solution of the polypeptide. This also includes solutions of polypeptides in mixtures of water with lower alcohols, such as. B. methanol, ethanol, propanol or Bulanol, or with acetone and the like. The concentration of the polypeptide in the solution used should expediently be in the range from 100 μg / ml to 10 mg / ml. The carrier material is generally used in such an amount that the polypeptide, when fully bound to the carrier, forms a proportion of 1 to 50 percent by weight, preferably 10 percent by weight, but these amounts can also be deviated from.

The actual photochemical reaction is triggered by photosensitization. Photosensitizers have long been known. The basics in this area were developed by G. O. S c h e η c k and co-workers and are e.g. in »Organic Photochemistry «. R. O. K a η. New York: Mac Graw-HiIl 1966. pp. 14-17.

Pliolosensitization is understood as the energetic excitation of an acceptor molecule (A) by a donor molecule (D), which primarily absorbs the radiation energy (hi). In the present case, sensitizers function as donor molecules, that is, they are first brought into their lowest excited singlet state (S ₁ ) by ultraviolet light, after which they are converted into the lowest triplicate region by intersystem crossing. This state is relatively long-lived and therefore capable of stimulating other molecules to triplet states through diffusion-controlled energy transfer, from which these molecules can react radically. This reaction sequence can be represented as follows:

D (S ₁ ) -

D (T ₁ ) + A -

D (S ₁ )

D (T ₁ )

D + A (T ₁ )

The acceptor molecule A can, for. Be the polypeptide or the carrier molecule.

According to Hammond and co-workers (.1. Am. Soc. 86. 4537 [1964]), good photosensitizers (donors) should have a high absorption of the irradiated energy, with the UV spectrum of the sensitizer (donor) not overlapping that of the acceptor as far as possible and should lie in a longitudinal area. They must also have a higher triplet energy than the acceptor and also have the most efficient possible intersystem crossing. Finally, the photosensitizer itself should not enter into any photochemical reactions, ie should be as photochemically inert as possible. According to data from H amm ο η d et al and E 1 mο 1 ae ν et al, C a 1 ν ert and Pitts have compiled a number of compounds which are effective as photosensitizers and are suitable for the process of the invention (JG CaI -vc rt and JN Pitts Jr. "Photochemistry." John Wiley et Sons. Inc. New York, London, Sidney 1966, p. 298). These include, ordered according to decreasing energy of the excited triplts state. Propiophenone, xanthone. Acetophenone. Triacetyl benzene. Isobutyrophenone, diphenylpropanone. Benzaldehyde. Triphenyl methyl ketone. Carbazole. Diphenylene oxide. Triphenylamine. Dibenzothiophene. o-dibenzoyibenzene. Benzophenone. Dichlorobenzophenone. Diacetylbenzene. Fluorene and many others. Ketones have been shown to be quite effective. In addition to the ketones already mentioned, acetone, methyl ethyl ketone and methyl isobutyl ketone should be mentioned. Acetophenone and propiophenone are particularly preferred because, due to their absorption spectrum, they absorb a large part of the energy emitted by a high-pressure mercury lamp, namely in the range of the 366 nm and 313 nm emission lines of mercury.

The excited photosensitizer generates a carbon radical through interaction with the polypeptide or the carrier molecule. Typical reactions of this type are shown below for the glycine group (I) of a polypeptide. for a glucose unit {II) of a polysaccharide. for an acrylamide unit (IH) of a vinyl polymer and for a carrier polymer containing toluyl groups (IV) formula

609 629,241

(ο

ίο

Maßii! (shown in C * indicates a carbon polymer by addition and subsequent radical
radical). "transmission with any transmitter (AH)

-NH- CO

- CONH

CH,

-NH-CO

-CONH

(D

-NHCO

CONH

+ -CH ₁ CH-

CO-O-CH, -CH = CH,

CHO- CHO- IS -CH ₁ - CH- / \ HIGH O HIGH O CO- HIGH CH-CH ₁ OH
\ / V. !
HIGH C-CH ₁ OH
\ χ 10 \ /
CHO- \ - ·
CHO-

(H)

CO -O- CH, - CH - CH ₁ - CH

+ AH

CON Η

Ν H CO-

(III)

-CH ₁ -CH- CONH

CO-O-CH ₁ -CH ₁ -CH ₁ -CH

NHCO

CH ₃

CH ₁

CH ₂

¹ I.

The preferred responsiveness of the Ghcinresies over other amino acid residues is advantageous for the method of the invention. da GIveinrste occur in almost all natural egg white bodies, but are often not functional. The photochemical The reaction at the glycine residue therefore often has little or no influence on the biological Effectiveness of the bound polypeptide.

Basically, the triggering is photochromic Reactions do not depend on the presence of a pholosensitizer. It is quite possible the polypeptide or the carrier molecule directly through a sufficiently high-energy radiation

₄ <i to suggest transferring a radical. As is known from the work of K. Dose and co-workers (Photochemistry and Phoiobiologv 1068. Vol. 7. pp. 671 to 673) . skin-like inactivation occurs with the immediate excitation of the pohncpiids

i.e. the molecular structure is irreversibly destroyed The method of the invention is therefore preferably carried out with radiation whose energy for the immediate activation of the PoIv peptide * flour sufficient, but the photosensitizer to / u rain is capable. Fine for the method of the invention Well suited radiation is one of ultraviolet light Wavelength of more than 2W. In addition to radiation in the specified range, the usual high-pressure silver lamps also emit harder ones Radiations in the range from -40 to 20 nm This steel diameter is expediently filtered out through PVC glass. The duration of the irradiation is determined according to the strength of the radiation source and the effectiveness dc> Photosensitizers and can im

65 ranges from 10 minutes to 50 hours Use of the common high pressure mercury immersion lamps. d. H. lamps with one power or with olefinic side groups of the carrier- \, m 12S up to 500 watts, cherish the radiation

(IV)

A variety of other analogous reactions on other groups of the polypeptide. ?. B. on the healing of the Cv stone. Cystine. Metnionine or Trvptophans or the carrier molecule can occur. Radicals of this kind react with one another through recombination :

-NHCO

-CONH

+ - CH ₂ - C -

- CONH CONH

\ / CH

> -CH ₂ -C-

CONH,

generally / between 1 and 30 hours. N; ieh If the radiation source is switched off, the reaction is ended immediately; unreacted carrier material, protein and the protein-carrier compounds are stable. and it is in contrast to other methods of attachment there is no risk of hydrolytic cleavage of the bonds created by the chemical process.

The photochemical reaction can also be triggered with light radiation in the visible range, when next to a visible light stimulant phosensitizer. like Biacetsl. a perovd, how /. B. di-tert-butyl peroxide. \ is used.

One of the main advantages of the chemical bonding process over the purely chemical one Binding is the free choice of temperature and pH value. You can go at any depth and - as far as the temperature resistance of the polypeptide allows any high temperatures, for example between -5 and 70 "C, as well as in a neutral, acidic or alkaline environment the method can be optimally adapted to the stability conditions of the polypeptide. Also extremely sensitive to temperature Proteins can be processed under the most gentle of conditions.

An important requirement for binding of the polypeptide to the carrier is the absence of Oxygen. It is known that oxygen is very easily stimulated photochemically in the presence of sensitizers and triggers a large number of undesirable side reactions. It is therefore necessary to carry out the reaction in an oxygen-free protective gas atmosphere, for example in nitrogen or argon. Around to completely remove oxygen contained in the peptide solution, one leaves before the action of the Radiation bubbling an oxygen-free inert gas through the solution.

After the completion of the irradiation and binding of the polypeptide to the carrier, the reaction solution can may be used as such for the intended purpose. To dissolved carriers bound biologically active proteins can be used, for example, as pharmaceutical preparations of reduced degradability or absorbable wedge can be used in the body. One can use those bound to soluble carriers Polypeptides can also be obtained in substance by using precipitants. like inorganic salts or alcohols. The precipitated product can then be filtered off and mixed with salt solutions or alcohol-water mixtures be washed out. Products in solid form can be filtered off immediately and washed with water.

In the preferred embodiment of a polypeptide bound to a swellable bead polymer, the product can be distributed directly in a substrate solution, the substrate interacting with the bound polypeptide, for example an enzyme . After the substrate has reacted, the carrier-bound enzyme can be completely separated off by simple filtration. You can also use the bead polymer in a dense bed as a column filling and allow the substrate solution to flow through the column. When using a bead polymer of uniform particle size, a high flow rate can be achieved in such a reaction column.

The method of the invention can be practiced in a wide variety of embodiments, which cannot be presented exhaustively here. Of course, it is also possible one after the other or to bind different proteins to the same carrier at the same time. Further embodiments of the The invention and its results can be found in the following examples.

In some cases, e.g. B. in affinity chromatography of high molecular weight compounds on carrier-bound affine proteins, the protein must be at a sufficient distance from the main chain of the carrier polymer be bound. In such cases, carrier compounds are used which are particularly photochemical active groups on longer, e.g. B. wear rope chains containing 6 to 12 carbon atoms. Examples for such carriers are vinyl polymers with

is curing of acrylic or methacrylic acid esters of higher unsaturated alcohols. Polysaccharides can be modified with correspondingly long-chain unsaturated compounds.

Production of the carrier substances

A. Production of a swellable bead polymer from

Acrylamide and allyl methacrylate

In a round bottom flask (500ml) provided with a thermometer. Stirrer. 87 g of n-heptane and 55 g of perchlorethylene are placed in the reflux condenser and CO _{2 discharge pipe.} 0.25 g of benzoylproxide and 0.01 g of a stabilizer are dissolved therein. After removing oxygen with about 2 g of dry ice, a monomer solution is added at 25 C, consisting of?

12 g of acrylamide.
3 grams of allyl methacrylate.
0.375 g glycol dimethacrylate.
^ ⁵ 17.5 g formamide.

0.044 g of poly (methacrylic) choline chloride. solved in

Formamide as a thickener.
0.1 g emulsifier (statistical copolymer n-butyl methyl acrylate / methacryioylcholine chloride = 90/10).

The monomer phase is distributed in the organic phase by constant stirring. The polymerization is triggered by adding 0.25 g of dimethylaniline. The polymerization lasts 8 hours for one Temperature below 30 C and continuous passage of CO. The obtained fine pearls are through Decanting and suction freed of the organic phase, washed in acetone and in vacuo dried.

A content of 3.5 percent by weight of allyl methacrylate was determined by bromine titration.

B. Production of a swellable bead polymer from acrylamide and glycol monoacrylate

In a 500 ml round bottom flask equipped as in A, will

70 g n-heptane.

70 g perchlorethylene

submitted. After removing the oxygen by means of 2 g dry ice, a monomer solution is obtained with stirring added consisting of

9 g acrylamide,

9 g of 2-hydroxyethyl methacrylate,
0.2 g NN -Methylene bis (methacrylamide).

0.9 g emulsifier (as in A),
10g water,

Ig 0.1% aqueous solution of ammonium peroxydisulfate,

1 g of 0.1% aqueous solution of Fe '"sulfate.

The monomer phase is lent by constant stirring in the organic phase. The reaction takes place by adding 0.4% strength aqueous sulfuric acid. With a reaction time of 8 hours, the temperature is kept at 30.degree. _{CO 2 is passed in} during the entire duration of the reaction. The fine beads obtained are freed from the organic phase by decanting and brief suction, washed in acetone and dried in vacuo.

C. Production of a swellable acrylamide bead polymer

15 g of acrylamide are given in the in A. Way polymerized in suspension.

D. Production of a swellable bead polymer from acrylamide and glycol monomethacrylate

A mixture of 14.25 g of acrylamide and 0.75 g of 2-hydroxyethyl methacrylate is given in H; r in A. Way polymerized in suspension.

E. Preparation of a water-soluble copolymer of acrylamide and vinyl toluene

4.68 g of vinyl toluene and 17.06 g of acrylamide were dissolved in 216 ml of absolute tetrahydrofuran and 0.216 g of azoisobutyric acid dinitrile were added. The air was displaced from the reaction vessel with nitrogen. After 2 hours at 65 ^° C., the polymerization was complete. The precipitation polymer was filtered off, washed several times with tetrahydrofuran and dried.

Yield: 9.58 g.

Toluyl group content (determined by UV spectrometry) 9 percent by weight.

The product was dissolved in water and crosslinked by gel filtration on an epichlorohydrin Dextran gel with a water absorption of 100 g per 10 g of dry matter in different fractions Separated by molecular weight. The fraction eluted with the exclusion volume (MW greater than 100,000) was lyophilized to give 2.8 g.

Combined gel chromatography of the fraction with a molecular weight below 100,000 was able to 530 mg of the polymer with a molecular weight of 5000 to 10,000 are obtained by initially by gel filtration on a dextran gel crosslinked with epichlorohydrin with a water absorption of 50 g per 10 g of dry matter the portion with a molecular weight below 10,000 and by gel filtration this part of a dextran gel (water absorption 25 g per 10 g dry substance), the part with a molecular weight above 5000 was obtained.

Production of carrier-bound polypeptides
example 1

Binding of trypsin to agarose photosensitized by acetone

Agarose beads were repeatedly suspended in water, washed and centrifuged. 10g of the moist gel obtained (equivalent to 100 mg agarose) were in water-acetone mixture (90/10) containing 50 mg of dissolved trypsin, suspended and in a Comfortable watch-out apparatus. consisting of a Tauclischaehl, cooling shaft and the reaction vessel with oxygen-free nitrogen, which by 10% aq. Acetone was passed I hour long fumigated and then with a high pressure mercury lamp (125 watts) for 18 hours

ίο good stirring and exposed with water cooling. at the exposure university! the apparatus was wrapped in aluminum foil.

After exposure, the material was obtained by centrifugation, several times with water and 1 N NaCl solution and centrifuged.

Protein determination

The Feuchlgcl was still further Sinai with Washed with water and lyophilized. The nitrogen content was determined according to K j c 1 d a h 1 and from this the ProtCHi content was calculated. Protein content: 21V Bound protein yield: 63%.

Enzymatic activity

5 g Feuchlgcl was repeatedly with 0.05-M phosphate buffer. pH 7.5. washed and the Feuchtgcl obtained by centrifugation with 20 ml of cascine substrate solution (4% casein according to H a m m a r s t e η in dilute sodium hydroxide solution: pH 8.0) with thorough stirring incubated at 37 C, the pH by titration with a controlled by a glass electrode automatic burette was kept constant. After 3 to 4 re-use of the en / ynipreparation in the manner indicated, an enzymatic activity of 270 U per 100 mg of dry product is obtained or 12.9 U per milligram bound Protein determined. As 1 unit (Fj that amount of enzyme is designated which within 6 () minutes i μ eq. Pcptide bonds cleave.

Repeated use as a criterion for covalent bonding

No decrease in activity is observed after 5 re-uses. This represents an important one Criterion for the presence of a covalent bond between trypsin and agarose. Only if the activity after any number of uses with a hydrophilic, high molecular substrate (here: casein at pH 8) does not decrease, can be from covalent Binding are spoken, since such substrates are very suitable, unspecific to the carrier Wash out adsorbed protein.

Example 2

Binding photosensitized by acetone
from trypsin to cellulose

1 g of cellulose (microcrystalline 20 to 100 μm) was washed several times with water and in a total volume of 50 ml of water-acetone mixture (90/10), containing 100 mg of trypsin, in the example I exposed manner. Exposure time: 40 hours.

G ₅ work-up

Washing with water and 1 N NaCl solution, the product being filtered off with suction through a glass fritle.
Protein content: 4.8%.

Bound protein bound: 53%. based on inserted protein.

Enzymatic activity per 100 mg dry product: 27.8 U or 5.8 U per milligram of bound protein.

No decrease in activity is observed after 5 times of repeated use.

Example 3

Binding photosensitized by acetone
from trypsin to cellulose containing toluyl groups

Cellulose (as in Example 2) was made with 4-methylbenzoyl chloride esterified to give a product containing 3.5 percent by weight of toluyl groups.

1 g of this product was washed several times with water and described in Example 2 door Way implemented with trypsin.

Exposure time: 15 hours.

Protein content: 7.2%.

Bound protein yield: 83%.

Enzyme. Activity per 100 mg dry product: 49 units or 6.9 units per milligram of bound protein.

Example 4

Binding phospholosensitized by acetone
of trypsin on polyacrylamide beads

1 g of polyacrylamide beads. produced according to C, were swollen in water, washed several times with water and sucked off through a glass frit: 9.4g wet gel.

The entire wet gel was reacted with 100 mg of trypsin in the manner described for Example 2 and washed.

Exposure time: 35 hours.

Protein content: 6.5% (UV spectrometry according to alkaline hydrolysis).

Yield of bound protein: 73%.

Enzymat. Activity per 100mg dry product: 52.8 E.

Enzyme. Activity per milligram bound protein: 8.1 E.

Example 5

Binding photosensitized by acetone

from trypsin to a bead polymer made of acrylamide

and allyl methacrylate

1 g of the bead polymer according to A was swollen in water and washed several times with water and sucked off (9.8 g moist product).

The entire moist product was reacted with 100 mg of trypsin in the same way as in Example 4.

Exposure time: 12 hours.

Yield of bound protein: 91%.

Protein content (UV spectrometry after alkaline hydrolysis): 7.9%.

Enzymai. Activity per 100mg dry product: E.

Enzymat. Activity per milligram of bound protein: 11 E.

Example 6

Binding of trypsin to a bead polymer, photosensitized by acetophenone

made of acrylamide and allyl methacrylate

The procedure of Example 5 is repeated with the difference that in 50 ml of aqueous saturated ίο Acetophenone solution (content by UV spectrometry: 0.003 mol / l) was only exposed for 2 hours. Yield of bound protein: 87%. Protein content: 7.5%.

Enzymat. Activity 103 U / 100 mg dry product; 13.4 U / mg bound protein.

Example 7

Binding of trypsin to a bead polymer, photosensitized by propiophenone made of acrylamide and allyl methacrylate

Example 6 is repeated with the difference that the aqueous phase contains 5% methanol and 0.005 mol / l Contained propionphenone.

Bound protein yield: 96%.

Protein content: 8.1%.

Enzymat. Activity 98 U / 100mg dry product; 12.1 U / mg bound protein.

Example 8

Binding of trypsin to a photosensitized by acetophenone with p-toluene sulfochloride

modified copolymer of acrylamide and

2-hydroxyethyl methacrylate (1: 1)

The bead polymer from A was tosylated to a product containing 3.5 percent by weight of toluyl groups and reacted with trypsin in the presence of acetophenone as in Example 6 and then worked up.
Exposure time: 2 hours.

Bound protein yield: 78%.

Protein content in the product: 6.8%.

Enzymat. Activity per 100mg dry product: E.

Enzymat. Activity per milligram bound

Protein: 12.3 E.

Example 9

Binding of trypsin to a copolymer of acrylamide photosensitized by acetophenone with 2-Hydroxyüthylmethacrylamid after its chemical modification with 4-methylphenyl-

acetic acid chloride 6o

The Perlpolyinerisat from D was by reaction with 4-methylphenylacetic acid chloride to one Modified product containing 1.2% toluyl groups.

1 g of the modified product was in the manner described in Example 6 with trypsin in the presence implemented by acetophenone. Exposure time: 4 hours.

609 629/241

Bound protein yield: 85%.

Protein content in the product: 7.4%.

Enzymat. Activity per ICOmg dry product: 81.5 E.

Enzymat. Activity per milligram of bound trypsin: 11 E.

Example 10

Binding photosensitized by acetophenone

of ribonuelease to a copolymer of

Acrylamide and vinyl toluene of MW over 10,000

500 mg of the soluble polymer according to E and 40 mg of ribonuelease A (chromatographically uniform, 50 U / mg) were dissolved in 50 ml of water saturated with acetophenone and exposed as in Example 6 for 2 hours. The product was lyophilized and washed with ether to remove traces of acetophenone. An aliquot was dissolved in 0.05 M phosphate buffer (pH 7.5) and separated on dextran gel (100 g H ₂ O uptake / 10 g dry matter). The fractions eluted with the exclusion volume were combined, dialyzed against water and lyophilized.

The unbound portion (free RNase) were also combined, lyophilized and dissolved in 10 ml of water and the absorbance measured at 280 nm, it corresponded to a total of 8.5 mg unbound RNase. From this, 79% of the enzyme used was bound to the soluble carrier calculated.

The enzymatic activity was determined alkalimetrically in an autotitrator at pH 7.5 and 37 ^C C with yeast nucleic acid as substrate. It was 35% based on unbound c: RNase and the RNase content of the carrier.

In a comparative experiment without exposure, no binding of RNase to the carrier could be found will.

Example 11
Binding photosensitized by acetophenone

of insulin to a Mi ^ P «£ 5 ^ lÄ
_and vinyl toluene from MW 5000 to IUlHR)

50 ml of water was saturated with acetophenone n insulin and 400 mg of that obtained in E.

^I0 SSztud ^L wr ^^ ie.m2hoursb,
Non-bound insulin was separated from carrier-bound insulin by chromatography on dextran gel (50 g H _{2 O-Sn / 10% dry substance)}

, 5 became 380 mg of a product with a molecular vision Obtained over 10,000 with a protein content of five percent by weight. Gel filtration this £ 33 eextranle! (100g H ^ Aufa / JO, Jrokken substance) resulted in a MW> 100,000 for the largest

^{T <} In a comparison test without exposure, no binding of insulin to the carrier was found.

Example 12

Binding photosensitized by acetophenone
from insulin to dextran

1000 mg of dextran 150 (MW 150,000) and 100 mg of insulin were saturated in 50 ml with acetophenone Dissolved water and brought the solution to pH 4.0 with 0.5 ml of 0.1 N hydrochloric acid.

Exposure as in Example 11.

By gel filtration on dextran gel (100 g H ₂ O-

Aufn / 10 g dry substance) were a product with

an insulin content of 5.8%, which is about

a yield of 55%, based on the amount used

Insulin.

Claims (9)

Γχ Patent claims: 1. A method for producing carrier-bound ^ polypeptides, characterized in that ^. that the aqueous solution of a polypeptide in the presence of a non-peptide macromolecular one Carrier compound and a photosensitizer known per se in the absence Hop. Oxygen with ultraviolet light or - at ^ additional presence of an organic peroxide - irradiated with visible light. 2. The method according to claim 1, characterized in that one is a light radiation with a Wavelength over 290 nm can act. 3. The method according to claims 1 and 2, characterized characterized in that the macromolecular carrier bond has a molecular weight above 1000. preferably over 10,000. 4. Verlahren according to claims 1 to 3, characterized in that the macromolecular Carrier compound is water-soluble or water-swellable. 5. Process according to claims 1 to 4, characterized in that the macromolecular Carrier compound is a water-insoluble, crosslinked compound. 6. The method according to claims 1 to 5, characterized in that the macromolecular Carrier compound contains pendant alkenyl and / or alkylphenyl groups. 7. The method according to claims 1 to 6, characterized in that the macromolecular Inert compound a polysaccharide or homo- or copolymer of acrylic amide or vinylpyrrolidone. 8. The method according to claims I to 7, characterized in that the macromolecular Carrier compound is a cross-linked bead polymer made from a predominant proportion of acrylamide and vinylpyrrolidone or hydroxyalkyl acrylate or methacrylate and optionally a smaller proportion Vinyl toluene, allyl acrylate or methacrylate or a polyallyl ester of a polybasic one Acid is. 9. The method according to claims 1 to 8, characterized in that the dissolved protein an enzyme. Is enzyme inhibitor, antibody, or hormone.