Adsorption of non-membrane proteins on the surface of model phospholipid membranes.

1. Two new methods are proposed for enhancement of the binding of hydrophilic proteins by liposomes. 2. An alkylating derivative of phosphatidic acid has been obtained by its reaction with N,N,N'-tris(2-chloroethyl)-N'-(p-formylphenyl)propylene-1,3-diamine. The alkylating activity of this derivative is very low due to the electron-acceptor effect of the formyl residue. Phosphatidylcholine liposomes which contain this alkylating derivative in the lipid bilayer may be obtained. The compound residing in the outer monolayer may be reduced by NaBH4. Upon reduction, the formyl residue is transformed into a hydroxymethyl residue. Therefore, the alkylating group of the compound is activated, and proteins may be attached covalently to the outer monolayer by alkylation with such chemically reactive liposomes. 3. Reaction of alkylating liposomes with myoglobin results in covalent binding of this hydrophilic protein. Complement-mediated leakage of such myoglobin-carrying liposomes may be induced by antibodies against myoglobin. 4. Modification of hydrophilic proteins with dansyl chloride results, even at small extents of modification, in a dramatic increase of the affinity of such proteins to phosphatidylcholine liposomes.

Highly selective affinity labeling of the primer-binding site of E. coli DNA polymerase I.

Highly selective affinity labeling of the primer site of E. coli DNA polymerase I was performed with the 5'-reactive derivatives of oligothymidylate in the presence of poly(dA) template. Subtilysine cleavage proved that the site of affinity modification belonged to the 'Klenow' part of DNA polymerase I. If taken separately, Klenow fragment was not labeled by these oligonucleotide derivatives. The site of affinity labeling were tested in the structure of DNA polymerase I by hydroxylamine cleavage. At least two sites of labeling were revealed. The main one was localized between Gly-833 and His-928.

Localisation of the binding site for the initiating substrate on the RNA polymerase from Sulfolobus acidocaldarius.

RNA polymerase from the archaebacterium Sulfolobus acidocaldarius was chemically modified with AMP o-formylphenyl ester followed by reduction with borohydride. The modified protein catalyzes the labeling of its own largest subunit when incubated with [alpha-33P]UTP in the presence of poly[d(A-T)]. On cleaving of the labeled protein using cyanogen bromide, hydroxylamine or amino acid-specific endoproteinases for a very brief period, the pattern and size of the radioactive fragments formed are best explained by attachment of the label between Gly843 and Met895 of the largest subunit. In this region there exists a highly conserved sequence which is also found in other archaebacterial, eukaryotic and prokaryotic RNA polymerase. This suggests that the binding site for the initiating substrate of RNA polymerases has been conserved during evolution.

Highly selective affinity labelling of RNA polymerase B (II) from wheat germ.

DNA-dependent RNA polymerase B (II) from wheat germ was modified by incubation with 4-[N-(beta-hydroxyethyl)-N-methyl]benzaldehyde esters of AMP, ADP or ATP, followed by reduction with NaBH4. Reaction of the modified enzyme with [alpha-32P]UTP in the presence of various DNA templates led to a highly selective affinity labelling of the subunit with Mr 140 000 by covalently linked ApU. Labelling was inhibited by 1 microgram/ml alpha-amanitin.

Mapping of the region of the tick-borne encephalitis virus replicase adjacent to initiating substrate binding center.

Affinity labelling with aldehyde-containing analogs of initiation substrates of nuclear fraction of tick-borne encephalitis virus (TBEV) infected cells results in a labelling of a single polypeptide with a molecular mass of 68 kDa which was immunologically identified as TBEV NS3 protein. A single-hit hydroxylamine hydrolysis, using limited and long-term CNBr cleavages allowed one to identify Lys1800 and/or Lys1803 as the label attachment sites. These amino acid residues are situated in the proximity of the 'B'-site of NTP-binding motif of viral RNA replicase.

Highly selective affinity labeling of DNA polymerase alpha-primase from human placenta by reactive analogs of ATP.

Highly selective affinity labeling of a DNA-polymerase alpha-primase complex from human placenta by o-formylphenyl esters of ATP, ADP and AMP was performed in a two-step procedure in which a substrate analog attached to the active center was elongated by radioactive ATP. If the covalent attachment is performed in the presence of poly(dT) template, the ATP esters modify selectively the delta subunit of the complex. If poly(dT) is added after the covalent binding of the reagent, both delta and gamma subunits become labeled. With the o-formylphenyl ester of AMP the delta-subunit is modified. The ADP ester modifies both the delta and gamma subunit in the presence and absence of template. It is shown that formylphenyl ester of ATP is not the substrate in the reaction of elongation catalyzed by primase. The data obtained suggest the binding site of initiating substrate to be located in the region of contact of the two subunits of primase. The role of the template in the formation of the active site is discussed.

[Reaction between rabbit skeletal muscle creatine kinase and ATP gamma-amides]. / Vzaimodeistvie kreatinkinazy iz skeletnykh myshts krolika s gamma-amidami ATP.

The interaction of creatine kinase from skeletal muscles of rabbit with ADP, ATP and gamma-amides of ATP: gamma-anilide ATP (1), gamma-benzylamide ATP (2), N-2-hydroxyethyl-N-methyl-gamma-amide ATP (3) and 4-(N-2-hydroxyethyl-N-methylamino)-benzyl-gamma-amide ATP (4) was investigated. The values of dissociation constants of nucleotides were determined by fluorescence quenching method. All analogs preserve their affinity to the enzyme, analogs 1 and 2 being the strongest in affinity. The values of dissociation constants of these analogs are equal to those for ATP and ADP. The influence of Mg2+ and creatine on gamma-amides ATP enzyme binding was investigated. The affinity of gamma-amides of ATP in the presence of Mg2+ and creatine was shown to decrease. It is concluded that gamma-amides of ATP (1,2) have the suitable structure for the preparation of affinity reagents for creatine kinase.

[Highly selective affinity labeling of a promoter in a complex with E. coli RNA-polymerase by alkylating derivatives of initiating substrates]. / Vysokoselektivnoe affinnoe mechenie promotora v komplekse s RNK-polimerazoi E. coli alkiliruiushchimi proizvodnymi initsiruiushchikh substratov.

The complex [promoter A2 X E. coli RNA polymerase] was treated with phosphoamides, derivatives of 4-[N-methyl, N-(2-chloroethyl)]-aminobenzylamine and guanosine-5'-mono-, di-, and triphosphates with the alkylating group attached to the terminal phosphates. After this, [alpha-32P]CTP was added. Residues of the affinity reagents bound covalently at the first stage were elongated by radioactive -pC residues due to the catalytic action of the active centre of RNA polymerase. Affinity labelled were beta-and sigma-subunits of the enzyme, and the promoter. The affinity label was localized on -pGpC residues. A guanine residue was alkylated in the promoter as suggested by radioactivity elimination kinetics. As the data obtained and the previously known length of the reagent (maximum distance between the alpha-phosphorus atom of the reagent and the point of alkylation is less than 0.6 nm) indicate, there is a direct rather than protein-mediated contact between the template and the substrate within the complex [promoter X RNA polymerase].

[Localization of a histidine residue in the binding site for the initiating substrate of E. coli RNA-polymerase]. / Lokalizatsiia ostatka gistidina v oblasti sviazyvaniia initsiiruiushchego substrata RNK-polimerazy E. coli.

E. coli RNA polymerase was selectively labelled in the presence of promoters at a histidine residue of the beta-subunit by treatment with GDP beta-imidazolide and then with [alpha-32P]UTP (or [alpha-33P]UTP). Partial cyanogen bromide cleavage of the labelled polypeptide afforded a series of "single-hit" labelled peptides, the electrophoretic pattern of which suggested that the labelling site was His1237. This conclusion was confirmed by a similar pattern obtained with products of the cyanogen bromide cleavage of a radioactive peptide obtained by the limited trypsinolysis (C-terminal peptide consisting of 423 amino acid residues). Interpretation of our earlier results in favour of His1116 as the labelling point (Dokl. Acad. nauk SSSR, 1985, v. 281, p. 723) was incorrect due to the electrophoretic "compression" of three labelled peptide bands.

[Localization of lysine residues in the site of initiating substrate binding of E. coli RNA-polymerase]. / Lokalizatsiia ostatkov lizina v oblasti sviazyvaniia initsiiruiushchego substrata RNK-polimerazy E. coli.

Superselective affinity labelling of E. coli RNA polymerase in a complex with the promoter-containing fragment of T7 DNA by treatment with orto-formylphenyl ester of GMP followed by addition of [alpha-33P]UTP resulted in covalent binding of the residue--pGpU (p-radioactive phosphate) with one of lysine residues of the beta-subunit, Lys1048, Lys1051, Lys1057, Lys1065. The amino acid sequence of this region of the beta-subunit of E. coli RNA polymerase has a high extent of homology with that deduced for a region of tobacco chloroplast RNA polymerase on the basis of the nucleotide sequence of the chloroplast rpoB-like gene.

[Highly selective affinity labeling of DNA-dependent RNA-polymerase of bacteriophage T7]. / Vysokoselektivnoe affinnoe mechenie DNK-zavisimoi RNK-polimerazy bakteriofaga T7.

T7 phage RNA polymerase was affinity labelled in the presence of its promoter by treatment with an ATP gamma-derivative (a phosphoamide obtained from 4-(N-chloroethyl, N-methyl)aminobenzylamine, or one of esters obtained from 2-methoxy-4-formylphenol, 4-formylphenol, and 2[N-(4-formylphenyl), N-methyl]-aminoethanol) followed by addition of [alpha-32P]GTP. The most efficient labelling took place with the alkylating phosphoamide reagent.

[Highly selective affinity labeling of DNA-dependent RNA-polymerase II from human placenta]. / Vysokoselektivnoe affinnoe mechenie DNK-zavisimoi RNK-polimerazy II iz platsenty cheloveka.

RNA polymerase II from human placenta was affinity labelled in crude preparation using two-step technique, which includes treatment of the enzyme with an aldehyde-containing reactive analogue of ATP, ADP or AMP in the presence of poly[d(A-T)] followed (after borohydride reduction) by the elongation of the attached label with [alpha-32P]UTP. A polypeptide of the molecular mass ca. 140 kDa proved to be the labelling target. No labelling was observed in the absence of poly[d(A-T)] or the reagent or in the presence of alpha-amanitin. All the results suggest the attachment of the affinity reagents to the second-largest subunit of the human RNA polymerase II, which therefore takes part in the initiation substrate's binding.

[Localization of a lysine residue near the site of initiating substrate binding of T7 bacteriophage RNA polymerase]. / Lokaliatsiia ostatka lizina v oblasti sviazyvaniia initsiruiushchego substrata RNK-polimerazy bakteriofaga T7.

A highly selective affinity label was introduced into the T7 phage RNA polymerase by means of GMP ortho-formylphenyl ester and [alpha-32P]UTP nearby the enzyme's active site, which was located using limited cleavage technique. Hydroxylamine, bromine, N-chlorosuccinimide, and cyanogen bromide were employed as the reagents. Analysis of gel-electrophoretic patterns of the cleavage products led to a conclusion that Lys631 is the target of labelling. The region nearby this residue has a high degree of sequence homology with regions of RNA polymerases from T3 and SP6 phages and yeast mitochondria.

[Replication complex of tick-borne encephalitis complex. I. Identification of a nuclear fraction protein responsible for the initiation of RNA synthesis using affinity labeling]. / Replikativnyi kompleks virusa kleshchevogo éntsefalita. I. Vyiavleniebelka iadernoi fraktsii infitsirovannykh kletok, otvetstvennykh za initsiatsiiu sinteza RNK, s pomoshch'iu affinnogo mecheniia.

The pig embryo kidney cells infected by tick-borne encephalitis virus were fractionated into nuclear-associated, cytoplasmic and membrane fractions. The main part of the virus replicase activity was associated with the nuclei. The replication complex is able to synthesize full-length viral RNAs in vitro. To identify proteins involved in the initiation of the replication at the late stages of the infection, the highly specific affinity labelling technique was used. It was shown that with aldehyde-containing derivatives of ATP, ADP and AMP and [alpha-32P]GTP the target of labelling is a polypeptide having molecular weight about 69 kDa. The same protein is immunostained with TBE virus specific antibodies after blotting onto nitrocellulose. The conclusion is made that nonstructural protein NS3 takes part in virus replication at the late stage of the infection.

[Covalent labelling of the Klenow fragment of DNA-polymerase I from E. coli]. / Kovalentnoe mechenie fragmenta Klenova DNK-polimerazy I E. coli.

Incubation of the Klenow fragment of E. coli DNA polymerase I with [alpha-32P] dNTP (or NTP) results in the covalent radiolabelling of the enzyme, the bond being stable in acid (pH 2) and alkaline (pH 12) conditions and nucleophiles, such as beta-mercaptoethylamine, efficiently inhibiting the labelling. It is suggested that radiolabelling of the enzyme is the result of formation of chemically active products of the radiolysis of [alpha-32P]NTP (which are likely to be radicals). Non-radioactive NTP hinder the labelling, whereas Mg2+ and polynucleotide do not affect it. Cleavage of the enzyme by hydroxylamine and cyanogen bromide and analysis of gel-electrophoretic patterns of the cleavage products led to conclusion that 32P-label is located between Gly-544 and Met-647.

[Highly selective labeling of the E. coli RNA-polymerase promoter complex with reactive derivatives of oligonucleotide primers of various specificity]. / Vysokoselektivnoe mechenie kompleksa RNK-polimerazy E. coli s promotorom reaktsionnosposobnymi proizvodnymi oligonukleotidov- zatravok razlichnoi spetsifichnosti.

A technique of highly selective affinity labelling, which includes covalent modification of the enzyme-T7A2 promoter complex with reactive oligonucleotide derivatives and subsequent elongation of the attached oligonucleotide residue with a radioactive substrate was used to study the product-binding site of E. coli RNA polymerase. Different oligonucleotides complementary to the T7A2 promoter (with lengths ranging from 2 to 8 residues) containing 5'-terminal phosphorylating, alkylating or aldehyde groups were used for the labelling. The procedure resulted in labelling DNA and beta-, beta'- or sigma-subunits of the enzyme, which are therefore believed to contact with growing RNA in the course of initiation. Consideration of the labelling patterns as a functions of the oligonucleotide's length as well as of the structure and chemical specificity of the reactive groups led to a tentative topographic scheme of the RNA polymerase product-binding region.

Studies of the functional topography of the catalytic center of Escherichia coli primase.

The catalytic center of E. coli primase (581 amino acids) was identified by using, in the G4oric single-strand binding protein (SSB) primer RNA (pRNA) synthesis system, ATP and AMP derivatives, which were modified on the 5' side with reactive groups that can be cross-linked to the ATP binding site plus [alpha-32P]GTP. The position of the covalently attached 32P-labeled dinucleotide was mapped by chemical and enzymatic cleavage of labeled wild type and deletion mutants of primase. The catalytic center involves one of the Lys residues Lys-211, Lys-229, and Lys-241. The ATP binding site is preformed in primase, and the cross-linked ATP residue can be elongated to a 5-nucleotide limit, which implies significant stretching of the catalytic center during pRNA synthesis. His-43 close to the N terminus in a proposed zinc finger and Lys-528 near the C terminus were also cross-linked to ATP residues in the primase ATP binding site, suggesting that these regions are topographically close to the catalytic center during pRNA synthesis. When cross-linking was performed on the preformed primase/SSB/G4oric complex with long arm reagents (12-15 A), SSB was also labeled, indicating a close proximity to the site of pRNA synthesis.

A route to RNA with an alkylating group at the 5'-triphosphate residue.

Reaction of ATP with N,N,N'-tris(2-chloroethyl), N' (p-formyl-phenyl)propylenediamine-1,3 (abbreviation C13R) afforded a gamma-ester of ATP (abbreviation C1RpppA) - the product of alkylation by an aliphatic nitrogen mustard residue of C13R. The alkylating activity of the aromatic nitrogen mustard residue of C1RpppA is suppressed by the electron-acceptor effect of the p-formyl group. C1RpppA is a substrate of RNA-polymerase, and affords RNA with C1RpppA-residues at the 5'-termini.

ATP cross-linked to Escherichia coli single-strand DNA-binding protein can be utilized by the catalytic center of primase as initiating nucleotide for primer RNA synthesis on phage G4oric template.

We report a new observation of the role of Escherichia coli single-strand DNA binding protein (SSB) in synthesis of primer RNA (pRNA) catalyzed by.E.coli primase on the SSB-coated phage G4oric template. Using a set of ATP priming substrates with reactive groups attached to the 5' gamma-phosphate on different length "arms", we have demonstrated that, in the primase/SSB/G4oric pRNA synthesis complex, ATP cross-linked to both primase and SSB could be equally utilized as initiating nucleotide for pRNA synthesis. The distance between SSB surface and alpha-phosphorus of the priming substrate was estimated to be less than 7 A. ATP cross-linked to primase and SSB can be further elongated in the presence of other NTPs, giving almost identical patterns of covalently attached pRNAs of up to 12 nucleotides in length. The regions of primase and SSB with cross-linked ATP that can be used for pRNA synthesis are, therefore, arranged in a similar way relative to the active center of pRNA synthesis. The pRNA covalently linked to SSB was localized, mapping between Met48 and Trp88. This observation raises the possibility that SSB may play an active role in the initiation of pRNA synthesis in this system.