Two-dimensional gel systems for rapid histone analysis for use in minislab polyacrylamide gel electrophoresis

Two two-dimensional polyacrylamide minislab gel systems were devised for the rapid analysis of histone modified species and variants. The first system consisted of an acetic acid-urea or acetic acid-urea-Triton X-100 minislab gel for the first-dimension electrophoresis followed by a polyacrylamide-sodium dodecyl sulfate minislab gel for the second-dimension electrophoresis. The second system consisted of a polyacrylamide-sodium dodecyl sulfate minislab gel for the first-dimension electrophoresis followed by either an acetic acid-urea or an acetic acid-urea-Triton X-100 minislab gel for second-dimension electrophoresis. Both systems offer distinct advantages for rapid high-resolution analysis of modified histone species and variants.     

Observations on the reaction of 2-hydroxy-5-nitrobenzyl bromide with a peptide-bound tryptophanyl residue

Previous studies on the isolation of peptides containing tryptophanyl residues modified with 2-hydroxy-5-nitrobenzyl bromide demonstrated multiple products of reaction at the same residue as well as technical difficulties in the primary structure analysis of peptides containing the modified tryptophanyl residue. The present study was undertaken to explore the reaction of 2-hydroxy-5-nitrobenzyl bromide with the single tryptophanyl residue in a synthetic peptide, experimental allergenic encephalitogenic peptide. The modification of this peptide was accomplished in sodium acetate, pH 4.75, and reagent removed by gel filtration. Amino acid analysis of the modified peptide suggested that only the tryptophanyl residue had been modified under these experimental conditions. The modified peptide could be separated into multiple derivatives by high-performance liquid chromatography. Although it is clear that some of the observed heterogeneity reflects a difference in the degree of substitution at the single tryptophanyl residue, several of the derivatives appear to have the same extent of substitution. It is suggested that the heterogeneity observed is a reflection of the establishment of a new diastereoisomeric center in the peptide. These results are consistent with previous observations from other laboratories and provide a basis for the explanation of apparent heterogeneity of peptides obtained from modified proteins.     

Western blotting and immunochemical detection of histones electrophoretically resolved on acid-urea-Triton- and sodium dodecyl sulfate-polyacrylamide gels

We have developed a method for the efficient transfer of histones from acetic acid-urea-Triton X-100 (AUT)-polyacrylamide minislab gels to nitrocellulose. The AUT gel was equilibrated with 50 mM acetic acid and 0.5% sodium dodecyl sulfate and then with 62.5 mM Tris-HCl, pH 6.8, and 2.3% sodium dodecyl sulfate. An alkaline transfer buffer [25 mM 3-(cyclohexylamino)-1-propanesulfonic acid, pH 10, with 20% methanol] was used to electrophoretically transfer the strongly basic proteins from AUT or sodium dodecyl sulfate gels to nitrocellulose. The applicability of this approach in the immunochemical detection of ubiquitinated histone species is demonstrated.     

Phosphorylation of the chromodomain changes the binding specificity of Cbx2 for methylated histone H3

The chromatin organizer modifier domain (chromodomain) is present in proteins that contribute to chromatin organization and mediates their binding to methylated histone H3. Despite a high level of sequence conservation, individual chromodomains manifest substantial differences in binding preference for methylated forms of histone H3, suggesting that posttranslational modification of the chromodomain might be an important determinant of binding specificity. We now show that mouse Cbx2 (also known as M33), a homolog of Drosophila Polycomb protein, is highly phosphorylated in some cell lines. A low-mobility band of Cbx2 observed on SDS-polyacrylamide gel electrophoresis was thus converted to a higher-mobility band by treatment with alkaline phosphatase. Mass spectrometric analysis revealed serine-42, a conserved amino acid in the chromodomain, as a phosphorylation site of Cbx2. Phosphorylation of the chromodomain of Cbx2 on this residue in vitro resulted in a reduced level of binding to an H3 peptide containing trimethylated lysine-9 as well as an increase in the extent of binding to an H3 peptide containing trimethylated lysine-27, suggesting that such phosphorylation changes the binding specificity of Cbx2 for modified histone H3. Phosphorylation of the chromodomain of Cbx2 may therefore serve as a molecular switch that affects the reading of the histone modification code and thereby controls epigenetic cellular memory.     

The type of interaction of histone H5 wo ith DNA changes significantly at various stages of chromatin condensation

Histones were covalently bound to DNA by dimethylsulfate-induced crosslinking and DNA-contacting peptides of histone H5, thus modified, were mapped by a combination of peptide cleavage reactions and peptide gel electrophoresis. In the nucleosome, the only strong crosslinking point is His-25 which resides near the ends of nucleosomal DNA. This contact point persists throughout different steps of chromatin condensation--decondensation. In decondensed chromatin, it is supplemented by the contact with DNA of the N-terminus of the histone H5 molecule. The high level of chromatin condensation existing in the nuclei or induced by bivalent cations results in a new and considerably stronger crosslinking point His-62, which is also characteristic for cooperative H5-DNA complexes. This structural change is observed only on oligonucleosomal chains containing no less than 3 contiguous nucleosomes, and is absent in isolated mono- or dinucleosomes. We propose that the formation of the 30-nm chromatin fibre, typical for the nuclei, is accomplished in part by the histone H5-linker DNA cooperative interactions, manifested by strong His-62--linker DNA contact.     

An RNA aptamer that selectively recognizes symmetric dimethylation of arginine 8 in the histone H3 N-terminal peptide

Epigenetic modifications of N-terminal histone tails, especially histone H3, are important for the regulation of the target genes in chromatin. Specific methods for detection of these modifications in histone H3?N-terminal peptides are valuable tools for diagnostic and therapeutic purposes. As an alternative to antibodies, RNA aptamers display compatible binding affinities and selectivites against various biologically relevant targets. Systematic evolution of ligands by exponential enrichment (SELEX) was performed against histone H3R8Me2sym. A 14-amino acid peptide that mimics this modified histone tail was prepared in a biotinylated form and 10 selection cycles of SELEX were carried out. This produced 4 aptamers, one of which (clone 1) was observed to have low nanomolar binding affinity (K(d)=12 nM) against the cognate peptide. The affinity of this aptamer is comparable to 2 commercially available antibodies against differently modified histone H3 peptides and it displays a greater selectivity than the antibodies.     

Structural basis of HP1/PXVXL motif peptide interactions and HP1 localisation to heterochromatin

HP1 family proteins are adaptor molecules, containing two related chromo domains that are required for chromatin packaging and gene silencing. Here we present the structure of the chromo shadow domain from mouse HP1beta bound to a peptide containing a consensus PXVXL motif found in many HP1 binding partners. The shadow domain exhibits a novel mode of peptide recognition, where the peptide binds across the dimer interface, sandwiched in a beta-sheet between strands from each monomer. The structure allows us to predict which other shadow domains bind similar PXVXL motif-containing peptides and provides a framework for predicting the sequence specificity of the others. We show that targeting of HP1beta to heterochromatin requires shadow domain interactions with PXVXL-containing proteins in addition to chromo domain recognition of Lys-9-methylated histone H3. Interestingly, it also appears to require the simultaneous recognition of two Lys-9-methylated histone H3 molecules. This finding implies a further complexity to the histone code for regulation of chromatin structure and suggests how binding of HP1 family proteins may lead to its condensation.     

DNA and histone H1 interact with different domains of HMG 1 and 2 proteins.

High mobility group (HMG) proteins 1 and 2 from calf thymus have been digested under structuring conditions (0.35 M NaCl, pH 7.1) with two proteases of different specificities, trypsin and V8. The two proteases give a different but restricted pattern of peptides in a time course digestion study. However, when the interactions of the peptides with DNA are studied by blotting, a closely related peptide from HMG-1 and -2 does not show any apparent binding. This peptide, from the V8 protease digestion, has been isolated by DNA-cellulose chromatography and has the amino acid composition predicted for a fragment containing the two C-terminal domains of the protein, i.e., approximately residues 74-243 for HMG-1. The same peptide shows the only interaction detectable with labelled histone H1. A separate function for the different domains of HMG proteins 1 and 2 is proposed.     

Antimicrobial activity of histones from hemocytes of the Pacific white shrimp.

The role of vertebrate histone proteins or histone derived peptides as innate immune effectors has only recently been appreciated. In this study, high levels of core histone proteins H2A, H2B, H3 and H4 were found in hemocytes from the Pacific white shrimp, Litopenaeus vannamei. The proteins were identified by in-gel digestion, mass spectrometry analysis, and homology searching. The L. vannamei histone proteins were found to be highly homologous to histones of other species. Based on this homology, histone H2A was cloned and its N-terminus was found to resemble the known antimicrobial histone peptides buforin I, parasin, and hipposin. Consequently, a 38 amino acid synthetic peptide identical to the N-terminus of shrimp H2A was synthesized and assayed, along with endogenous histones H2A, H2B, and H4, for growth inhibition against Micrococcus luteus. Histone H2A, purified to homogeneity, completely inhibited growth of the Gram-positive bacterium at 4.5 microm while a mixture of histones H2B and H4 was active at 3 microm. In addition, a fraction containing a fragment of histone H1 was also found to be active. The synthetic peptide similar to buforin was active at submicromolar concentrations. These data indicate, for the first time, that shrimp hemocyte histone proteins possess antimicrobial activity and represent a defense mechanism previously unreported in an invertebrate. Histones may be a component of innate immunity more widely conserved, and of earlier origin, than previously thought.     

Radioiodination of chicken erythrocyte histones H4 and H5 in chromatin.

The conformational state of histones in isolated chicken erythrocyte chromatin was studied using procedures developed for probing surface proteins on membranes. Under controlled conditions, only exposed tyrosyl residues react with iodide radicals, generated either by the oxidant, chloramine-T (paratoluenesulfonyl chloramide), or the enzyme lactoperoxidase, giving monoidotyrosine. Using 125-iodine, this study compared the reactive tyrosines in free and bound histones H4, and H5. The relative extent of iodination of these histones within (H4) and outside (H5) of the nucleosomes was measured after extraction and gel electrophoresis. Each of the histones was further analyzed for the extent of specific tyrosine iodination by separating the tryptic peptides by high voltage electrophoresis. The identity of the labeled peptide was determined by dansylation of the amino acids present in each hydrolyzed peptide. The results show that there is a difference in the conformational arrangement of these histones on chromatin and in the free forms, since in chromatin not all tyrosine residues are as accessible for iodination as in the denatured state. Residue 53 of histone H5 for instance is more reactive than residues 28 and 58, indicating that the segments containing the latter residues are involved in either protein-DNA or protein-protein interactions. In histone H4, preferential labeling of 2 of the 4 tyrosines present was also observed.     

Influence of combinatorial histone modifications on antibody and effector protein recognition

Increasing evidence suggests that histone posttranslational modifications (PTMs) function in a combinatorial fashion to regulate the diverse activities associated with chromatin. Yet how these patterns of histone PTMs influence the adapter proteins known to bind them is poorly understood. In addition, how histone-specific antibodies are influenced by these same patterns of PTMs is largely unknown. Here we examine the binding properties of histone-specific antibodies and histone-interacting proteins using peptide arrays containing a library of combinatorially modified histone peptides. We find that modification-specific antibodies are more promiscuous in their PTM recognition than expected and are highly influenced by neighboring PTMs. Furthermore, we find that the binding of histone-interaction domains from BPTF, CHD1, and RAG2 to H3 lysine 4 trimethylation is also influenced by combinatorial PTMs. These results provide further support for the histone code hypothesis and raise specific concerns with the quality of the currently available modification-specific histone antibodies.     

An enzyme-coupled assay measuring acetate production for profiling histone deacetylase specificity

Histone deacetylases catalyze the hydrolysis of an acetyl group from post-translationally modified acetyl-lysine residues in a wide variety of essential cellular proteins, including histones. Because these lysine modifications can alter the activity and properties of affected proteins, aberrant acetylation/deacetylation may contribute to disease states. Many fundamental questions regarding the substrate specificity and regulation of these enzymes have yet to be answered. Here, we optimize an enzyme-coupled assay to measure low micromolar concentrations of acetate, coupling acetate production to the formation of NADH (nicotinamide adenine dinucleotide, reduced form) that is measured by changes in either absorbance or fluorescence. Using this assay, we measured the steady-state kinetics of peptides representing the H4 histone tail and demonstrate that a C-terminally conjugated methylcoumarin enhances the catalytic efficiency of deacetylation catalyzed by cobalt(II)-bound histone deacetylase 8 [Co(II)–HDAC8] compared with peptide substrates containing a C-terminal carboxylate, amide, and tryptophan by 50-, 2.8-, and 2.3-fold, respectively. This assay can be adapted for a high-throughput screening format to identify HDAC substrates and inhibitors.     

EpiProfile Quantifies Histone Peptides With Modifications by Extracting Retention Time and Intensity in High-resolution Mass Spectra

Histone post-translational modifications contribute to chromatin function through their chemical properties which influence chromatin structure and their ability to recruit chromatin interacting proteins. Nanoflow liquid chromatography coupled with high resolution tandem mass spectrometry (nanoLC-MS/MS) has emerged as the most suitable technology for global histone modification analysis because of the high sensitivity and the high mass accuracy of this approach that provides confident identification. However, analysis of histones with this method is even more challenging because of the large number and variety of isobaric histone peptides and the high dynamic range of histone peptide abundances. Here, we introduce EpiProfile, a software tool that discriminates isobaric histone peptides using the distinguishing fragment ions in their tandem mass spectra and extracts the chromatographic area under the curve using previous knowledge about peptide retention time. The accuracy of EpiProfile was evaluated by analysis of mixtures containing different ratios of synthetic histone peptides. In addition to label-free quantification of histone peptides, EpiProfile is flexible and can quantify different types of isotopically labeled histone peptides. EpiProfile is unique in generating layouts (i.e. relative retention time) of histone peptides when compared with manual quantification of the data and other programs (such as Skyline), filling the need of an automatic and freely available tool to quantify labeled and non-labeled modified histone peptides. In summary, EpiProfile is a valuable nanoflow liquid chromatography coupled with high resolution tandem mass spectrometry-based quantification tool for histone peptides, which can also be adapted to analyze nonhistone protein samples.The nucleosome, the basic unit of chromatin, consists of 147 base pairs of DNA wrapped around histone proteins (H2A, H2B, H3, and H4). Histones play vital roles in chromatin, interacting with many signaling proteins and chromatin-structural proteins through various post-translational modifications (PTMs)¹ (1–3). There are numerous PTMs on histones, including methylation (mono - me1, di - me2, tri - me3), acetylation (ac), phosphorylation (ph), ubiquitination, and SUMOylation (4). Histone PTMs can affect chromatin function, and therefore influence processes such as gene accessibility, DNA repair and chromosome condensation. Moreover, histone PTMs cross-talk in a synergistic manner to fine-tune gene expression (5). Therefore, quantification of histone PTMs has become a high priority to investigate cell regulation and epigenetics (6).Traditionally, antibody-based methods (e.g. Western blot) have been used to analyze histone modifications (7), which have multiple disadvantages. First, antibodies are not available for every new PTM discovered. Second, PTMs on neighboring amino acids (e.g. H3K9me1–3 and H3S10ph) may prevent antibody binding, a phenomenon called epitope occlusion. Third, the quantification of PTMs via antibody-based methods is not sensitive to small differences (e.g. <twofold). Mass spectrometry (MS) has emerged as a sensitive and efficient technique to detect known and novel PTMs (8). The high mass accuracy and the high speed of modern mass spectrometers allow for sensitive, confident, and accurate peptide quantification when coupled with nanoflow liquid chromatography (nanoLC).NanoLC-MS/MS analysis of protein digests (i.e. bottom-up MS) is nowadays a mature and widely applied technology. Data-dependent acquisition is the most commonly adopted MS acquisition method to identify peptides via bottom-up MS (9–12), generating MS1 and MS2 spectra. Nevertheless, histone proteins are particularly challenging to analyze by using the generalized bottom-up workflow. As histones are rich with lysines and arginines, tryptic digest of histones generates short peptides that are difficult to be retained on C18 columns. To improve histone peptide retention, the unmodified and mono-methylated lysines and peptide N terminus can be selectively chemically propionylated (13–16), preventing tryptic digest after lysine to generate longer peptides. Moreover, peptide identification through traditional database searches leads to a large number of false positives, as allowing several dynamic modifications (e.g. me1/me2/me3, ac, ph) dramatically increases the number of molecular candidates and thus the possibility to achieve a false hit (12). Therefore, software tools that quantify histone peptides require additional data to correctly map a given peptide, such as previous knowledge of peptide retention time.Quantification of histone peptides is particularly challenging because of presence of isobaric peptides, near isobaric PTMs such as tri-methylation (42.047 Da) and acetylation (42.011 Da), and low abundant species. Previous knowledge about relative peptide retention time (RT) enables differentiation between species close in mass and therefore selection of the correct peak for integration of the area of the chromatographic peak (i.e. area under curve or AUC). However, determination of peptide RT might be difficult because of their low abundance though acid extraction was performed to purify histones. This problem can be solved by using isotopically labeled synthetic histone peptides (17), or data independent approaches (18). When using relative retention time information to assign peak identities, reproducible nanoLC is crucial, especially because some isobaric peptides co-elute. In this case, the MS acquisition method must perform targeted MS2 for the co-eluting isobaric peptides at the specific time that they elute. These species can be discriminated and quantified based on the intensity of fragment ions unique to each species. For instance, the peptides KacSTGGKAPR (H3K9ac) and KSTGGKacAPR (H3K14ac) have the same mass and overlap at the nanoLC elution (the full protein sequence of human canonical histone H3 and H4 are shown in Fig. 1A). Thus, the co-eluting isobaric peptides could not be quantified separately based on the MS1 signal, but the unique fragment ions present in MS2 spectra allow them to be quantified individually.Open in a separate windowFig. 1.Histones are a challenge for quantitative mass spectrometry analyses. A, Human histone H3.1 and H4 protein sequences. B, Spline fitting to calculate AUC: blue lines are the original peaks and pink lines are the fitted peaks. C, An example of isobaric PTM modified peptides. The above MS2 is matched with H3K18ac, and the same MS2 is also matched with H3K23ac below. D, The workflow of EpiProfile: inputting precursor m/z and charge state, extracting elution profiles, selecting the correct chromatographic peak, calculating AUC, and outputting quantification tables and figures.There have been few computational investigations attempting to solve the problem of quantifying co-eluting isobaric peptides. DiMaggio et al. used a mixed integer linear optimization (MILP) framework to quantify partially co-eluting isobaric histone peptides from electron transfer dissociation (ETD) spectra (19). The framework is comprised of two MILP models: (1) enumerating the entire space of the modified forms that satisfy a given peptide mass and (2) determining the relative composition of the modified forms in the spectrum. Another study by Guan et al. identified isobaric peptides by searching ETD MS/MS spectra for ions representing all possible configurations of modified peptides using a visual assistance program. The relative abundances of these species were estimated by using a nonnegative least squares procedure (20). Other quantification programs can also perform accurate peak picking, but are commonly not as suitable for heavily modified and isobaric histone peptides (e.g. Skyline) (21). These software programs are unable to provide the layouts of histone peptides (i.e. relative RTs) or discriminate all isobaric modified peptides, two tasks that are vital for full characterization of a histone sample.In this study, we developed a new quantification program named EpiProfile. EpiProfile extracts ion chromatography for known histone peptides by using previous knowledge about their elution profiles. Moreover, it discriminates and quantifies the isobaric histone peptides by resolving the linear equations listed with the peak heights of unique fragment ions between the two modification sites in the MS2 spectra (e.g. ions between H3K9ac and H3K14ac). We evaluated the accuracy of EpiProfile by mixing different ratios of synthetic histone peptides, and then tested EpiProfile by analyzing nanoLC-MS/MS data sets of the following samples: purified histones from HeLa cells, a synthetic histone peptide library, and histone peptides labeled during cell growth with ¹³C-labeled glucose media or stable isotope labeling by amino acids in cell culture (SILAC) (22). We compared EpiProfile to manual quantification of the data, and also with the openly available program Skyline. We found that manual quantification is obviously time-consuming and that Skyline cannot generate the layouts of histone peptides and cannot discriminate four or six-component isobaric peptides, a common occurrence in histone data. Moreover, EpiProfile is highly flexible, and thus it can be used to analyze various protein samples, including isotopically labeled peptides and nonhistone data sets.     

Analysis of the peptide carrier in the scutellum of barley embryos by photoaffinity labelling

The preparation of a phenylalanine analogue containing an azido group and its incorporation into dipeptides is described. Peptides modified in this way are taken up into barley (Hordeum vulgare L.) scutella via the previously characterized peptide-transport system. Photoactivation of modified peptides in the presence of isolated scutella resulted in irreversible inhibition of peptide uptake in a concentration-dependent manner. Transport of other solutes which share a common mechanism of energy coupling, but which are transported via distinct carriers, was not inhibited after photo-derivatization of scutella with the modified peptides. Derivatization of isolated scutellar tissue with a ¹⁴C-labelled peptide analogue, resulted in incorporation of label into two proteins of M_r = 54000 and 41000. Scutellar tissue from early-germinating seeds, which do not show active peptide uptake, did not incorporate label into these polypeptides. It is concluded that these proteins are components of the barley peptide-transport system.Abbreviations Ala alanine - Gly glycine - PAGE polyacrylamide gel electrophoresis - Phe phenylalanine - Pro proline - SDS sodium dodecyl sulphate This work was supported by a grant from the Agricultural and Food Research Council.     

Peptide mapping by polyacrylamide gel electrophoresis after cleavage at aspartyl-prolyl peptide bonds in sodium dodecyl sulfate-containing buffers

Protein samples prepared for sodium dodecyl sulfate-polyacrylamide gel electrophoresis are preferentially cleaved at aspartyl-prolyl peptide bonds upon heating at 110 degrees C. The presence of aspartyl-prolyl peptide bonds in a protein can therefore be detected by gel electrophoresis of heated samples and the resulting peptides mapped. The method of heat cleavage also works well with proteins in bands cut from electrophoresed gels using modified stacking conditions in the second electrophoresis. An immunoblotting procedure for peptide mapping of nanogram quantities of specific proteins in complex mixtures is demonstrated. Peptide maps produced by aspartyl-prolyl peptide bond cleavage of fructose-1,6-bisphosphatases from different sources show the effectiveness of the above techniques and suggest a conservation of aspartyl-prolyl peptide bonds in pig kidney and mouse and rat liver fructose-1,6-bisphosphatases.     

An optimized procedure for sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of hydrophobic peptides from an integral membrane protein

A procedure for successful analysis of the hydrophobic tryptic peptides of the Neurospora crassa plasma membrane H+-ATPase by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) is described. The features of this procedure that are essential for the best results include (i) treatment of the hydrophobic peptide samples with neat trifluoroacetic acid, (ii) dissolution and disaggregation of the hydrophobic peptide samples with SDS at 0 degrees C, (iii) SDS-PAGE of the hydrophobic peptide samples in gels containing a 200:1 ratio of acrylamide to bisacrylamide and a 5-20% convex acrylamide gradient, and (iv) silver-staining of the gels after electrophoresis. This method results in the reproducible resolution and visualization of the H+-ATPase hydrophobic tryptic peptides, which range in size from ca. 5 to 21 kDa, as well as other peptides and proteins ranging in size from ca. 2.5 to 150 kDa. The methods described should also prove useful in other studies where resolution and visualization of hydrophobic peptides of integral membrane proteins are required.     

Structural basis for molecular recognition and presentation of histone H3 by WDR5

Histone methylation at specific lysine residues brings about various downstream events that are mediated by different effector proteins. The WD40 domain of WDR5 represents a new class of histone methyl-lysine recognition domains that is important for recruiting H3K4 methyltransferases to K4-dimethylated histone H3 tail as well as for global and gene-specific K4 trimethylation. Here we report the crystal structures of full-length WDR5, WDR5Delta23 and its complexes with unmodified, mono-, di- and trimethylated histone H3K4 peptides. The structures reveal that WDR5 is able to bind all of these histone H3 peptides, but only H3K4me2 peptide forms extra interactions with WDR5 by use of both water-mediated hydrogen bonding and the altered hydrophilicity of the modified lysine 4. We propose a mechanism for the involvement of WDR5 in binding and presenting histone H3K4 for further methylation as a component of MLL complexes.     

Peptide mapping of protein bands from polyacrylamide gel electrophoresis by chemical cleavage in gel pleces and re-electrophoresis

A simple method has been developed for peptide mapping of protein bands obtained by polyacrylamide gel electrophoresis. The procedure is based on selective acid hydrolysis of aspartyl-prolyl bonds which occur in proteins with an average frequency of 1 per 400 amino acid residues. A gel piece containing the protein to be analyzed is soaked with 75% formie acid. For the subsequent incubation at 37°C for 24 h the gel piece is immersed in liquid paraffin. After removal of formic acid by lyophilization the gel piece is rehydrated in buffer and placed into the sample well of a second polyacrylamide gel on which the generated peptides are electrophoretically separated.     

Localization of lysine residue in histone H3 forming the thymine-lysine cross-link after UV-irradiation of deoxyribonucleoprotein

A thymine-modified derivative of histone H3 formed as a result of thermal treatment of UV-irradiated (lambda = 254 nm) solution of deoxyribonucleoprotein from calf thymus at low ionic strength was isolated. The peptides obtained by tryptic hydrolysis of modified histone H3 were separated by high pressure liquid chromatography. The amino acid sequence of the peptide containing a lysine residue with covalently linked thymine was determined by the Edman method. It was found that Lys localized at the N-terminus of the histone H3 molecule interacts with DNA within the composition of the deoxyribonucleoprotein.