[KE peptide regulates SIRT1, PARP1, PARP2 gene expression and protein synthesis in human mesenchymal stem cells aging.]

It was shown that KE peptide (Lys-Glu, vilon) has immunomodulatory, oncostatic and geroprotective effects. The aim of this work is to evaluate the effect of the KE peptide on gene expression and protein synthesis of SIRT1, PARP1, PARP2 during aging of human mesenchymal stem cells (MSC). The KE peptide increased gene expression and synthesis of the SIRT1 protein in «young¼ MSCs by 6 and 8,2 times, respectively. The KE peptide reduced gene expression and PARP1 protein synthesis during MSC aging by 2,1 and 5,3 times, respectively; and also reduced gene expression and PARP2 protein synthesis by 2,1 and 4,7 times, respectively. According to molecular modeling data, the KE peptide can interact with the GCGG sequence of double-stranded DNA (dsDNA) in the classical B-form and with the GGGC sequence of the curved dsDNA nucleosome. The indicated dsDNA sequences were found in the promoters of the human SIRT1, PARP1, PARP2 genes. Thus, the KE peptide regulates gene expression and synthesis of SIRT1, PARP1, PARP2 proteins in human mesenchymal stem cells during replicative ageing, which underlies the biological activity and geroprotective effect of this peptide.

Design of Stable α-Helical Peptides and Thermostable Proteins in Biotechnology and Biomedicine.

α-Helices are the most frequently occurring elements of the secondary structure in water-soluble globular proteins. Their increased conformational stability is among the main reasons for the high thermal stability of proteins in thermophilic bacteria. In addition, α-helices are often involved in protein interactions with other proteins, nucleic acids, and the lipids of cell membranes. That is why the highly stable α-helical peptides used as highly active and specific inhibitors of protein-protein and other interactions have recently found more applications in medicine. Several different approaches have been developed in recent years to improve the conformational stability of α-helical peptides and thermostable proteins, which will be discussed in this review. We also discuss the methods for improving the permeability of peptides and proteins across cellular membranes and their resistance to intracellular protease activity. Special attention is given to the SEQOPT method (http://mml.spbstu.ru/services/seqopt/), which is used to design conformationally stable short α-helices.

[DYNAMICS AND MECHANISMS OF INTERACTION OF HETERO-HEXAMERIC TIP49a/b COMPLEXES WITH DS-DNA].

Evolutionary conserved TIP49a and TIP49b ATPases belong to the AAA+ superfamily of DNA-dependent ATPases that are involved in many cellular processes such as chromatin remodeling, regulation of transcription and cell division during mitosis, the maintenance of genome stability, snoRNP biogenesis, and participate in the formation of active form of telomerase. These proteins are involved in the complex networks of protein-protein interactions and, in spite of high structural similarity, in some cases, can perform opposite functions. Despite of the variety of their different activities, the exact mechanisms of action of TIP49a and TIP49b are still poorly understood. In this paper, by means of molecular docking approaches we first modeled the structures of hetero-hexameric TIP49 complexes with short ds-DNA fragments (20 base pairs with different GC content) within the central channel of hexameric ring. Using molecular dynamics simulations in the periodic water box (MD) we investigated conformational dynamics and mechanisms of DNA unwinding activity of these proteins. We shown that: a) the interaction between the positively charged protein loops and DNA within the central channel of protein ring leads to the partial unwinding of the DNA helix; b) DNA unwinding occurs only in the region within the protein ring, while the terminal parts of DNA outside the protein complex remain in its initial b-form conformation; c) the presence of ATP in the active sites of protein complex affects both the dynamics and the structure of DNA, leading to the breakage of some complementary bonds in AT-rich DNA sequences.

[Introduction of additional thiol groups into glucoamylase in Aspergillus awamori and their effect on the thermal stability and catalytic activity of the enzyme].

Five mutant forms of glucoamylase (GA) from the filamentous fungus Aspergillus awamori with artificial disulfide bonds (4D-G137A\A14C, 6D-A14C\Y419C\G137A, 10D-V13C\G396C, 11D-V13C\G396C\A14C\Y419C\G137A, and 20D-G137A\A246C\A14C) were constructed using computer simulation and experimentally tested for thermostability. The introduction of two additional disulfide bonds between its first and thirteenth alpha-helices and that of the loop located close to a catalytic residue--E400--made it possible to assess the effects of disulfide bridges on protein thermostability. The mutant proteins with combined amino acid substitutions G137A\A14C, V13C\G396C\A14C\Y419C\G137A, and G137A\A246C\A14C showed higher thermal stability as compared to the wild-type protein. At the same time, new disulfide bridges in the mutant A14C\Y419C\G137A and V13C\G396C proteins led to the destabilization of their structure and the loss of thermal stability.

[Current insights into chromatin structure organization].

This review summarizes current insights into organization of chromatin structure at different levels of DNA compaction. Analysis of available experimental data allowed concluding that only nucleosomal level of structural organization was sufficiently investigated, whereas structure of a 30-nm chromatin fiber remains an open issue. The data on the chromatin structure obtained at the level of the nucleus speak in favor of a biphasic fractal organization of chromatin.

[The effect of point amino acid substitutions in an internal alpha-helix on thermostability of Aspergillus awamori X100 glucoamylase].

Conformational flexibility of alpha-helices in glucoamylase of the fungus Aspergillus awamori was studied by molecular dynamics methods. Several amino acid substitutions (G127A, P128A, I136L, G137A, and G139A) optimizing intrinsic interactions in one of the alpha-helices (D) within the hydrophobic core of this protein were constructed and studied. It was found that these point mutations had different effects on the glucoamylase thermal inactivation constant. Unlike amino acid substitution P128A and substitutions G137A and A246C, I136L and G139A displayed a pronounced additive thermostabilizing effect.

[L29M] substitution in the interface of subunit-subunit interactions enhances Escherichia coli RecA protein properties important for its recombinogenic activity.

Genetic analysis of RecA protein chimeras and their ancestors, RecAEc (from Escherichia coli) and RecAPa (Pseudomonas aeruginosa) had allowed us to place these proteins with respect to their recombinogenic activities in the following order: RecAPa>RecAX21>RecAX20=RecAEc. While RecAX20 differs from RecAEc in five amino acid residues with two substitutions ([S25A] and [I26V]) at the interface of subunit interactions in the RecA polymer, RecAX20 and RecAX21 differ only by a single substitution [L29M] present at the interface. Here, we present an analysis of the biochemical properties considered important for the recombinogenic activity of all four RecA proteins. While RecAX20 was very similar to RecAEc by all activities analysed, RecAX21 differed from RecAEc in several respects. These differences included an increased affinity for double-stranded DNA, a more active displacement of SSB protein from single-stranded DNA (ssDNA), a decreased end-dependent RecAX21 protein dissociation from a presynaptic complex, and a greater accumulation of intermediate products relative to the final product in the strand-exchange reaction. RecAPa was more tolerant than RecAX21 only to the end-dependent RecA protein dissociation. In addition, RecAPa was more resistant to temperature and salt concentrations in its ability to form a presynaptic RecAPa::ATP::ssDNA filament. Calculations of conformational energy revealed that the [L29M] substitution in RecAX21 polymer caused an increase in its flexibility. This led us to conclude that even a small change in the flexibility of the RecA presynaptic complex could profoundly affect its recombinogenic properties.

Local water bridges and protein conformational stability.

Recent studies have pointed out the important role of local water structures in protein conformational stability. Here, we present an accurate and computationally effective way to estimate the free energy contribution of the simplest water structure motif--the water bridge. Based on the combination of empirical parameters for accessible protein surface area and the explicit consideration of all possible water bridges with the protein, we introduce an improved protein solvation model. We find that accounting for water bridge formation in our model is essential to understand the conformational behavior of polypeptides in water. The model formulation, in fact, does not depend on the polypeptide nature of the solute and is therefore applicable to other flexible biomolecules (i.e., DNAs, RNAs, polysaccharides, etc.).

Position dependence of amino acid intrinsic helical propensities II: non-charged polar residues: Ser, Thr, Asn, and Gln.

The assumption that the intrinsic alpha-helical propensities of the amino acids are position independent was critical in several helix/coil transition theories. In the first paper of these series, we reported that this is not the case for Gly and nonpolar aliphatic amino acids (Val, Leu, Met, and Ile). Here we have analyzed the helical intrinsic propensities of noncharged polar residues (Ser, Thr, Asn, and Gln) at different positions of a model polyalanine-based peptide. We found that Thr is more favorable (by approximately 0.3 kcal/mol) at positions N1 and N2 than in the helix center, although for Ser, Asn, and Gln the differences are smaller (+/-0.2 kcal/mol), and in many cases within the experimental error. There is a reasonable agreement (+/-0.2 kcal/mol) between the calculated free energies, using the ECEPP/2 force field equipped with a hydration potential, and the experimental data, except at position N1.

Position dependence of non-polar amino acid intrinsic helical propensities.

Until now and based on the success of the helix/coil transition theory it has been assumed that the alpha-helical propensities of the amino acids are position independent. This has been critical to derive the set of theoretical parameters for the 20 natural amino acids. Here, we have analyzed the behavior of several non-polar residues, Val, Ile, Leu, Met and Gly at the N-cap, at each position of the first helical turn and at a central helical position of a 16-residue peptide model system that starts with eight consecutive alanine residues. We have interpreted the results from these experiments with the model of the helix/coil transition (AGADIR), that indicates that the intrinsic helical propensity is position dependent. Gly, Val and Ile are more favorable at the first turn than in the middle of the alpha-helix, while for Leu and Met we observe the opposite behavior. The differences between the observed helical propensities are as large as 1.0 kcal/mol in some cases. Molecular modeling calculations using the ECEPP/2 force-field equipped with a hydration potential show that this effect can be explained by the combination of three factors: (a) the side-chains in the first helix turn are more solvent-exposed; (b) they have fewer intramolecular van der Waals' contacts; and (c) they posses higher configurational entropy than that in the central position of an alpha-helix. The position-dependent results of the calculations are in reasonable agreement with the experimental estimates and with the intrinsic propensities of the amino acids derived from the statistical analysis of the protein structure database.

Insights into thermal resistance of proteins from the intrinsic stability of their alpha-helices.

To investigate the role of alpha helices in protein thermostability, we compared energy characteristics of alpha helices from thermophilic and mesophilic proteins belonging to four protein families of known three-dimensional structure, for at least one member of each family. The changes in intrinsic free energy of alpha-helix formation were estimated using the statistical mechanical theory for describing helix/coil transitions in peptide helices [Munoz, V., Serrano, L. Nature Struc. Biol. 1:399-409, 1994; Munoz, V., Serrano, L. J. Mol. Biol. 245:275-296, 1995; Munoz, V., Serrano, L. J. Mol. Biol. 245:297-308, 1995]. Based on known sequences of mesophilic and thermophilic RecA proteins we found that (1) a high stability of alpha helices is necessary but is not a sufficient condition for thermostability of RecA proteins, (2) the total helix stability, rather than that of individual helices, is the factor determining protein thermostability, and (3) two facets of intrahelical interactions, the intrinsic helical propensities of amino acids and the side chain-side chain interactions, are the main contributors to protein thermostability. Similar analysis applied to families of L-lactate dehydrogenases, seryl-tRNA synthetases, and aspartate amino transferases led us to conclude that an enhanced total stability of alpha helices is a general feature of many thermophilic proteins. The magnitude of the observed decrease in intrinsic free energy on alpha-helix formation of several thermoresistant proteins was found to be sufficient to explain the experimentally determined increase of their thermostability. Free energies of intrahelical interactions of different RecA proteins calculated at three temperatures that are thought to be close to its normal environmental conditions were found to be approximately equal. This indicates that certain flexibility of RecA protein structure is an essential factor for protein function. All RecA proteins analyzed fell into three temperature-dependent classes of similar alpha-helix stability (delta G(int) = 45.0 +/- 2.0 kcal/mol). These classes were consistent with the natural origin of the proteins. Based on the sequences of protein alpha helices with optimized arrangement of stabilizing interactions, a natural reserve of RecA protein thermoresistance was estimated to be sufficient for conformational stability of the protein at nearly 200 degrees C.

Factors that affect the stabilization of alpha-helices in short peptides by a capping box.

It was reported recently that the capping box sequences of four N-terminal residues are very important for the stabilization of alpha-helices in proteins and peptides. To elucidate factors that affect the stabilization of alpha-helices in short peptides by this motif, we analyzed conformational properties of side chains of five N-terminal residues in several analogs of neuropeptide Y (NPY). The analysis revealed three previously unreported factors that appear to be important for stabilization of an alpha-helix: (a) a second capping box hydrogen bond for the side chains of Ser, Thr, and Cys; (b) long-range electrostatic interactions between the first (N-cap) and fifth (N4) residues; and (c) capping interactions of alpha-amino groups with the N4 residue. These factors were incorporated into the parameter set of a recently published, statistical mechanics approach that showed excellent accuracy in the prediction of the helical propensities of short peptides in water [Muñoz, V., & Serrano, L. (1995) J. Mol. Biol. 245, 275-296, 297-308]. A significant improvement in the agreement between theoretical predictions and experimental data was achieved. The present results also clarify the nature of capping box stabilization of alpha-helices in peptides and proteins, indicating that the total influence of hydrogen bonding, local interactions between side chains, helix macrodipole--charge/dipole interactions, and solvation possibilities must all be taken into account. All these factors are associated with approximately the same energy, but with different residues at the N-cap position, they may have opposite effects on the helix stability of peptides. Thus, a delicate balance of interactions of different types controls the stabilization properties of N-cap residues in alpha-helices.

Acylation of the alpha-amino group in neuropeptide Y(12-36) increases binding affinity for the Y2 receptor.

Competition assays using three series of analogs of neuropeptide Y (NPY) ([Xaa11]NPY(11-36), [Xaa12]NPY(12-36), and [Xaa13]NPY(13-36) revealed that the binding affinity for the Y2 receptor was considerably lowered by truncation of residue 11. Upon acetylation or succinylation of the alpha-amino group, the binding affinity of [Xaa12]NPY(12-36) recovered to a level similar to that of [Xaa11]NPY(11-36). No significant difference was observed between the increases caused by acetylation and those caused by succinylation, suggesting that the increase in binding affinity cannot be explained by the change in the net charge at the N-terminus as a consequence of the modification. The scattered data points on a plot of the alpha-helix content vs. IC50 of all these analogs revealed the absence of any apparent relationship, an indication that prior formation of the alpha-helix is not necessary for binding to the Y2 receptor. It has been widely accepted that fewer than 12 residues from the C-terminus are directly involved in binding of NPY to the Y2 receptor, while the remaining part of NPY only assists in the adoption of a favorable conformation by the C-terminal hexapeptide for recognition by the receptor. However, the present results suggest that the region around residue 12 does not project from the Y2 receptor.

Investigation of the conformational properties of a beta-(1-->3) branched beta-(1-->6) heptasaccharide elicitor and its analogues by internal coordinate stochastic dynamics.

A series of beta-(1-->3) branched beta-(1-->6) oligosaccharides that are known to take part in switching immune reactions in plants was studied by a molecular dynamics approach. A novel technique was applied which recently proved to be very efficient in polypeptide simulations. Molecular dynamics is simulated in internal rather than Cartesian coordinates with dramatically reduced numbers of degrees of freedom and a time step ten-fold larger than usual values. Comparison and classification of most populated conformational states revealed a few conformational motifs that are frequently adopted by highly active oligosaccharides and are not populated in an inactive analogue. As a result a putative biologically active conformation of the oligosaccharides is proposed.

[Global optimization of the conformational energy of oligopeptides using a tunnel algorithm]. / Global'naia optimizatsiia konformatsionnoi énergii oligopeptidov s pomoshch'iu tunnel'nogo algoritma.

The tunneling algorithm has been suggested as a method for the searching of the low energy conformations of the oligopeptides. The efficiency of the method has been compared with other global energy minimization methods such as grid search and molecular dynamics. It has been shown that tunneling algorithm reached global minimum of potential energy of the molecule of 3-4 residues more effectively than other methods. Experiments with oligopeptides of more than 4 residues showed that although during reasonable time tunneling algorithm does not reach the global minimum it can very effectively find the low energy minimum.

[The pharmacokinetics of fluorescein, hematoporphyrin and its derivative during the development of granuloma]. / Farmakokinetika fliuorestseina, gematoporfirina i ego proizvodnogo pri razvitii granulemy.

In experiments on rats with granuloma reproduced by subcutaneous implantation of foreign material there was shown a slowing of excretion from the organism as well as a considerable redistribution between the organs of fluorescein, hematoporphyrin and its derivative as compared with intact animals. The noted changes practically did not depend on the time of granuloma development.

[The pharmacokinetics of hematoporphyrin, its derivative and fluorescein during the development of carcinosarcoma]. / Farmakokinetika gematoporfirina, ego proizvodnogo i fliuorestseina pri razvitii kartsinosarkomy.

The pharmacokinetics of fluorescein, hematoporphyrin and a derivative of hematoporphyrin was studied microspectrofluorometrically on rats with transplanted carcinosarcoma. It was shown that in the rats in contrast to intact animals the tissue concentration of fluorescein exhibits a general tendency towards an increase, that of hematoporphyrin towards a decrease and that of hematoporphyrin derivative towards an increase in all parenchymatous organs and a decrease in the skin and mucosae of the hollow organs. At the equally short period of the maximal accumulation of luminophores, the tumour tissue differs from the normal one by a pronounced delay of excretion only of hematoporphyrin derivative.