The electrostatic role of the Zn-Cys2His2 complex in binding of operator DNA with transcription factors: mouse EGR-1 from the Cys2His2 family.

The mouse factor Zif268, known also as early growth response protein EGR-1, is a classical representative for the Cys2His2 transcription factor family. It is required for binding the RNA polymerase with operator dsDNA to initialize the transcription process. We have shown that only in this family of total six Zn-finger protein families the Zn complex plays a significant role in the protein-DNA binding. Electrostatic feature of this complex in the binding of factor Zif268 from Mus musculus with operator DNA has been considered. The factor consists of three similar Zn-finger units which bind with triplets of coding DNA. Essential contacts of the factor with the DNA phosphates are formed by three conservative His residues, one in each finger. We describe here the results of calculations of the electrostatic potentials for the Zn-Cys2His2 complex, Zn-finger unit 1, and the whole transcription factor. The potential of Zif268 has a positive area on the factor surface, and it corresponds exactly to the binding sites of each of Zn-finger units. The main part of these areas is determined by conservative His residues, which form contacts with the DNA phosphate groups. Our result shows that the electrostatic positive potential of this histidine residue is enhanced due to the Zn complex. The other contacts of the Zn-finger with DNA are related to nucleotide bases, and they are responsible for the sequence-specific binding with DNA. This result may be extended to all other members of the Cys2His2 transcription factor family.

Recognition rules for binding of Zn-Cys2His2 transcription factors to operator DNA.

The molecules of Zn-finger transcription factors consist of several similar small protein units. We analyzed the crystal structures 46 basic units of 22 complexes of Zn-Cys2His2 family with the fragments of operator DNA. We showed that the recognition of DNA occurs via five protein contacts. The canonical binding positions of the recognizing α-helix were -1, 3, 6, and 7, which make contacts with the tetra-nucleotide sequence ZXYZ of the coding DNA strand; here the canonical binding triplet is underlined. The non-coding DNA strand forms only one contact at α-helix position 2. We have discovered that there is a single highly conservative contact His7α with the phosphate group of nucleotide Z, which precedes each triplet XYZ of the coding DNA chain. This particular contact is invariant for the all Zn-Cys2His2 family with high frequency of occurrence 83%, which we considered as an invariant recognition rule. We have also selected a previously unreported Zn-Cys2His2-Arg subfamily of 21 Zn-finger units bound with DNA triplets, which make two invariant contacts with residues Arg6α and His7α with the coding DNA chain. These contacts show frequency of occurrence 100 and 90%, and are invariant recognition rule. Three other variable protein-DNA contacts are formed mainly with the bases and specify the recognition patterns of individual factor units. The revealed recognition rules are inherent for the Zn-Cys2His2 family and Zn-Cys2His2-Arg subfamily of different taxonomic groups and can distinguish members of these families from any other family of transcription factors.

[Ultrasonic cleavage of DNA in complexes with Ag(I), Cu(II), Hg(II)].

We investigated a phenomenon of ultrasonic cleavage of DNA complexed with transition metal cations Ag(I), Cu(II) and Hg(II). We found the statistically significant dependence of relative intensity of cleavage on cation type and concentration. Each cation may cause two different types of distortion in the DNA double-helix depending on whether it binds to major or minor DNA groove. The intensity of ultrasonic cleavage decreases if cation binds to the major DNA groove; the intensity of cleavage increases if cation binds to the minor DNA groove and disturbs the hydrogen bonds of complementary base pairs or it intercalates between bases. Both types of DNA distortion can affect the intensity of N-S interconversion of deoxyribose.

Recognition rules for binding of homeodomains to operator DNA.

The spatial arrangement of interfaces between homeodomain transcription factors and operator DNA has been considered. We analyzed the binding contacts for a representative set of 22 complexes of homeodomain transcription factors with a double-stranded operator DNA in the region of the major groove. It was shown that the recognition of DNA by the recognizing _-helix of protein is governed by two contact groups. Invariant protein-DNA group of contacts includes six contacts, formed by atomic groups of coding and non-coding DNA chains with the groups of amino acids. The recognizing _-helix forms contacts by polar groups of residues Trp2 (NE1), Asn5, and Lys9 with the canonical sequence T(1)A(2)A(3)T(4) of the coding DNA chain, and contacts by residues Lys0, Arg7 and Lys11 with the sequence A(4)X(5)X(6)X(7) of a non-coding DNA chain, where X is any nucleotide. Variable protein-DNA group of contacts comprises two groups bound with the sequence T(3)A(4)X(5)X(6) of the non- coding DNA-chain. These contacts are mainly with the bases and specify the binding pattern of individual homeodomains. The invariant contact group represents a recognition pattern for transcription factors of the homeodomain family: multiple adenine-asparagine contact and six position-specific phosphate contacts mainly with lysine or arginine. Within this group, we have found three most significant invariant contacts which allow deducing the recognition rules for homeodomains. These rules are inherent for different taxonomic groups of the homeodomain family and can distinguishing members of this family from any other family of transcription factors.

Binding regularities in complexes of transcription factors with operator DNA: homeodomain family.

In order to disclose general regularities of binding in homeodomain-DNA complexes we considered five of them and extended the observed regularities over the entire homeodomain family. The five complexes have been selected by similarity of protein structures and patterns of contacting residues. Their long range interactions and interfaces were compared. The long-range stage of the recognition process was characterized by electrostatic potentials about 5 Angstrom away from molecular surfaces of protein or DNA. For proteins, clear positive potential is displayed only at the side contacting the DNA. The double-chained DNA molecule displays a rather strong negative potential, especially in their grooves. Thus, a functional role of electrostatics is a guiding of the protein into the DNA major groove, so the protein and DNA could form a loose non-specific complex. At the close-range stage, neutralization of the phosphate charges by positively charged residues is necessary for decreasing the strong electrostatic potential of DNA, allowing nucleotide bases to participate in the formation of protein-DNA atomic contacts in the interface. The recognizing alpha-helix of protein was shown to form both invariant and variable groups of contacts with DNA by means of certain specific side groups. The invariant contacts included highly specific protein-DNA hydrogen bonds between asparagine and adenine, nonpolar contacts of hydrophobic amino acids serving as a stereochemical barrier for fixing the protein factor on DNA, and an interface cluster of water molecules providing local conformational mobility necessary for the dissociation process. There is a unique water molecule within the interface that is conservative and located at the interface center. Invariant contacts of the proteins are mostly formed with the TAAT motif of the promoter DNA forward strand. While the invariant contacts specify the family of homeodomains, the variable contacts that are formed with the reverse strand of DNA provide specificity of individual complexes within the homeodomain family.

[Heterogeneity of double-stranded DNA local structure and dynamics: ultrasound studies].

A method for studying the local inhomogeneities of DNA and its dynamics is proposed. The method is based on the combination of two procedures, splitting the DNA molecules by ultrasound and analysis of DNA fragments obtained by gel electrophoresis. The frequency of cleavage of internucleotide bonds was found to depend on the type of nucleotides forming the bond and on their nearest neighbors. Estimates of cleavage frequencies in each of 16 dinucleotides showed that, in the 5'-d(CpG)-3', 5'-d(CpA)-3', and 5'-d(CpT)-3' dimers, the cleavage occurs considerably more frequently than in the rest, and the frequency of cleavage depends on the nearest neighbors. It was shown that the double-helix cleavage can occur with shifts by several nucleotides. Physical prerequisites were considered that can lead to this pattern of sequence - specific cleavage.

[Thermodynamic characteristics of collagen fibrils reconstructed in vitro at different temperatures and concentrations].

The results of a calorimetric study of type I collagen fibrillogenesis were analyzed. The dependence of the half-width of the temperature transition of a collagen solution on the concentration and temperature of collagen formation was studied. It was demonstrated that, by varying temperature and collagen concentration, one can regulate the density of packing and dimensions of cooperative fibril blocks. At temperatures below the physiological level (25 degrees C and 30 degrees C), and a relatively low concentration of collagen (0.3 mg/ml), fibrils with the lowest density of packing are formed. The degree of order does not change as the collagen concentration increases twofold but grows as the concentration increases fourfold. It was shown that, at the physiological temperature (35 degrees C), fibrils with a dense packing of molecules are formed at all collagen concentrations studied. The value of fibril formation enthalpy is minimal at a temperature of 35 degrees C, pH 7.2, an ionic strength of 0.17 M and a concentration of 1.2 mg/ml. Based on the results obtained, a conclusion was made that the packing density of fibrils formed at physiological temperature does not depend on collagen concentration over the concentration range of 0.3 - 1.2 mg/ml.

[Formation of collagen type I fibrils in vitro]. / Issledovanie obrazovaniia fibrill kollagena tipa I in vitro.

The assembly of collagen fibrils as a function of temperature and collagen concentration was studied. It was shown that temperature increases from 25 to 35 degrees C, the degree of ordering of collagen fibrils increases 1.5-fold at collagen concentration above 1 mg/ml and 2-fold at low collagen concentration. A maximum ordering of fibril structure occurs under conditions close to physiological (T approximately 35 degrees C and collagen concentration 1.2 mg/ml). As temperature is elevated from 30 to 35 degrees C, the packing of collagen molecules in fibrils becomes more ordered: the values of enthalpy and entropy of the transition of fibrils from the native to a disordered state decrease at all collagen concentrations used. At high collagen concentration, the dimensions of cooperative blocks in fibrils formed at 25 and 30 degrees C coincide with those of cooperative blocks of monomeric collagen in solution. Upon increasing the temperature to 35 degrees C, the dimensions of cooperative blocks increase.

[Characteristics of electrostatic interaction of Escherichia coli RNA polymerase with promoters of T4 phage DNA]. / Osobennosti élektrostaticheskogo vzaimodeistviia RNA-polymerasy Escherichia coli s promotorami DNK faga T4.

A comparative analysis of electrostatic potential distribution for "early" T4 phage promoters was undertaken. The data obtained indicate that there are some particular elements in the patterns of electrostatic potential distribution of promoter DNA specific for promoter groups differing by their functional response to ADP-ribosylation of the alpha-subunit as well as to rpoB403- or rpoB409 mutationals of the beta-subunit of RNA-polymerase.

RNA polymerase--promoter recognition. Specific features of electrostatic potential of "early" T4 phage DNA promoters.

Comparative analysis of electrostatic potential distribution for "early" T4 phage promoters was undertaken, along with calculation of topography of electrostatic potential around the native and ADP-ribosylated C-terminal domain of RNA polymerase alpha-subunit. The data obtained indicate that there is specific difference in the patterns of electrostatic potential distribution in far upstream regions of T4 promoters differing by their response to ADP-ribosylation of RNA polymerase. A specific change in profiles of electrostatic potential distribution for the native and ADP-ribosylated forms of RNA polymerase alpha-subunit was observed suggesting that this factor may be responsible for modulating T4 promoter activities in response to the enzyme modification.

Electrostatic potentials of DNA. Comparative analysis of promoter and nonpromoter nucleotide sequences.

Distribution of electrostatic potential of DNA fragments was evaluated. A method for calculation of electrostatic potential distribution based on Coulomb's law is proposed for long DNA fragments (approximately 1000 nucleotide pairs). For short DNA sequences, this technique provides a good correlation with the results obtained using Poisson-Boltzmann equation thus justifying its application in comparative studies for long DNA fragments. Calculation was performed for several DNA fragments from E. coli and bacteriophage T7 genomes containing promoter and nonpromoter regions. The results obtained indicate that coding regions are characterized by more homogeneous distribution of electrostatic potential whereas local inhomogeneity of DNA electrostatic profile is typical for promoter regions. The possible role of electrostatic interactions in RNA polymerase-promoter recognition is discussed.

[Periodicity in contacts of RNA-polymerase with promotors]. / Periodichnosti v kontaktakh RNK-polimerazy s promotorami.

Periodicities in the position of E.coli RNA polymerase promoter contacts on several promoters (lacUV5, T7 A3, tetR, lambda cin, lambda c17, RNA1, and trp S.t.) were found by means of Fourier analysis. The comparison of the Fourier spectrum of core RNA polymerase contacts on the lacUV5 promoter and that of holoenzyme revealed a more prominent 7-periodicity in the Fourier spectrum of holoenzyme contacts. 6-, 7-, and 8-periodicities were found in the primary structure of the majority of E.coli promoters. It is shown that RNA polymerase recognizes specific periodic patterns in the promoter structure.

[Integral equations of the theory of liquid in the study of hydration of macromolecules]. / Integral'nye uravneniia teorii zhidkostei v issledovanii gidratatsii makromolekul.

An efficient numerical algorithm for solving integral equations of the theory of liquid in the RISM approximation for infinitely diluted solution of macromolecules with a large number of atoms is proposed. The algorithm is based on applying the non-stationary interactive methods for solving systems of linear algebraic equations. Using this technique we have calculated the solvent-solute atom-atom correlation functions for short fragment of DNA duplex of varying length in aqueous solution.

[Hydration of a fragment of the B-form of DNA duplex: d(GGGGG). A method of integral equations of the theory of liquid]. / Gidratatsiia fragmenta dupleksa B-formy DNK: d(GGGGG). Metod integral'nykh uravnenii teorii zhidkosti.

Based on the numerical algorithm proposed by us in [1] for solving integral equations of the theory of liquids in the RISM approximation we calculate all of the solvent-solute atom-atom correlation functions for a fragment of the DNA duplex d(GGGGG) in infinitely diluted aqueous solution. The obtained results are compared with available experimental data and results from computer simulations.

[Fourier analysis of nucleotide sequences. Periodicity in E. coli promoter sequences]. / Fur'e-analiz nukleotidnykh posledovatel'nostei. Periodichnosti v promoternykh posledovatel'nostiakh E. coli.

Fourier spectra of E. coli promoter DNA sequences have been obtained. The periodical structure of individual promoter sequences is characterized. E. coli promoter sequences are classified according to their Fourier spectra using three feature sets: 1--the number of peaks in Fourier spectra; 2--values of power spectra for promoter primary structures and their similarity with physical periodicities in the backbone of polynucleotide; 3--the presence of blocks made of equal nucleotides. The comparison of Fourier spectra of promoter sequences and corresponding genes is provided. The conclusion that different ways of stabilization of promoter secondary structure in the case of different primary structure periodicities is drawn. The intermittence of AT- and GC-blocks, and variety of Fourier spectra mean DNA hydrate shell in DNA promoters is non-contiguous and non-stable at junction points. Characteristic features of prokaryotic promoters Fourier spectra differ from human promoters.

Non-planar structure of nitrous bases and non-coplanarity of Watson-Crick pairs.

We discuss the non-planar structural stability of the NH2-group in formamide, cytosine, adenine, guanine and aniline molecules. Based on the microwave data available on small amino derivatives and on the results of PCILO conformation study it is shown that the slope of the amino group HNH plane to the molecular plane in nitrous bases should be close to 40 degrees. One of the main consequences of the non-planar structure of bases is a comparatively large (approximately equal to 15 degrees) propeller twisting of purine and pyrimidine planes in the complementary adenine-thymine and guanine-cytosine pairs. It is concluded that the non-coplanarity of single Watson-Crick base pairs is their intrinsic property. The specificity of hydrogen bonding in pairs along with stacking is believed to be the original cause of their peculiar packing in crystals and in DNA and RNA structures.

[The study of actin in denervated skeletal muscles by microcalorimetry]. / Issledovanie aktina denervirovannykh skeletnykh myshts metodom mikrokalorimetrii.

Method of scanning calorimetry of intact and denervated F-actin shows a change in thermostability of protein after denervation.

Nonlinear waves in DNA and regulation of transcription.

The transmission of conformational changes along the DNA double helix is interpreted as a propagation of nonlinear solitary waves. Experimental and theoretical data in favour of this approach are presented. The possible role of nonlinear waves in regulation of transcription is discussed.