Complementary addressed modification of single-stranded DNA using a [Fe-EDTA] derivative of oligonucleotide

A one-tube synthesis scheme for coupling EDTA residue to the 5'-terminus of unprotected oligonucleotides via propylenediamine linker is described. The EDTA derivative of oligonucleotide d(pTGACCCTCTTCCC)A forms a kinetically stable complex with Fe2+ ion. In the presence of ascorbic acid with O2 limiting, this complex modifies single-stranded DNA (a 302-mer) in a site-specific way near the target complementary nucleotide sequence. The DNA fragment can be then cleaved predominantly at modified pyrimidine nucleotides (hidden breaks) by hot piperidine treatment, whereas few direct breaks (i.e. without piperidine) occurs at this site. No autocleavage of the [Fe.EDTA]-oligonucleotide derivative is observed under the experiment's conditions.     

Low molecular weight peptides from the venom of the giant hornet Vespa orientalis. Structure and function

Three 14-member linear peptides (HR-1, HR-2 and HR-3) capable of degranulating mast cells and thus initiating histamine release were isolated from the venom of the giant hornet Vespa orientalis, using reverse phase high performance liquid chromatography. The complete amino acid sequence of the peptides HR-1 and HR-2 molecules and partial structure of peptide HR-3 were determined, using automatic degradation by the Edman method. It was shown that peptide HR-1 at relatively low concentrations (2-20 micrograms/ml) selectively liberated histamine from rat mast cells and, when taken at higher doses (50-100 micrograms/ml), exerted a non-selective cytotoxic action. Besides, this peptide caused erythrocyte hemolysis, inhibited Ca2+-ATPase with concomitant uncoupling of Ca2+ transport and ATP hydrolysis as well as induced the conductance of lipid bilayer membranes, predominantly for monovalent cations due to the formation of nonspecific single permeability channels.     

Hepatitis C Virus RNA Replication Depends on Specific Cis- and Trans-Acting Activities of Viral Nonstructural Proteins

Many positive-strand RNA viruses encode genes that can function in trans, whereas other genes are required in cis for genome replication. The mechanisms underlying trans- and cis-preferences are not fully understood. Here, we evaluate this concept for hepatitis C virus (HCV), an important cause of chronic liver disease and member of the Flaviviridae family. HCV encodes five nonstructural (NS) genes that are required for RNA replication. To date, only two of these genes, NS4B and NS5A, have been trans-complemented, leading to suggestions that other replicase genes work only in cis. We describe a new quantitative system to measure the cis- and trans-requirements for HCV NS gene function in RNA replication and identify several lethal mutations in the NS3, NS4A, NS4B, NS5A, and NS5B genes that can be complemented in trans, alone or in combination, by expressing the NS3–5B polyprotein from a synthetic mRNA. Although NS5B RNA binding and polymerase activities can be supplied in trans, NS5B protein expression was required in cis, indicating that NS5B has a cis-acting role in replicase assembly distinct from its known enzymatic activity. Furthermore, the RNA binding and NTPase activities of the NS3 helicase domain were required in cis, suggesting that these activities play an essential role in RNA template selection. A comprehensive complementation group analysis revealed functional linkages between NS3-4A and NS4B and between NS5B and the upstream NS3–5A genes. Finally, NS5B polymerase activity segregated with a daclatasvir-sensitive NS5A activity, which could explain the synergy of this antiviral compound with nucleoside analogs in patients. Together, these studies define several new aspects of HCV replicase structure-function, help to explain the potency of HCV-specific combination therapies, and provide an experimental framework for the study of cis- and trans-acting activities in positive-strand RNA virus replication more generally.     

Microelectrode analysis of neuronal organization of the parietal association cortex

Responses of 304 neurons in the anterior part of the middle suprasylvian gyrus in cats to acoustic, photic, and somatosensory stimulation and also to simultaneous presentation of 2 or 3 stimuli of these modalities. Three groups of neurons were distinguished: those responding by an increased firing rate (187) or by inhibition (22) and those not responding (95). The first group comprised mono- (64) and polysensory (105) and well as neurons responding only to a combination (18). On the basis of the convergent properties of the polysensory neurons in this region it is postulated that the parietal cortex performs principally integrative processes based on iteraction of visual-cutaneous and cutaneo-auditory afferent information.State Medical Institute, Kemerovo. Translated from Neirofiziologiya, Vol. 4 No. 1, pp. 54–60, January–February, 1972.     

Synthetic Microcin C Analogs Targeting Different Aminoacyl-tRNA Synthetases

Microcin C (McC) is a potent antibacterial agent produced by some strains of Escherichia coli. McC consists of a ribosomally synthesized heptapeptide with a modified AMP attached through a phosphoramidate linkage to the α-carboxyl group of the terminal aspartate. McC is a Trojan horse inhibitor: it is actively taken inside sensitive cells and processed there, and the product of processing, a nonhydrolyzable aspartyl-adenylate, inhibits translation by preventing aminoacylation of tRNA^Asp by aspartyl-tRNA synthetase (AspRS). Changing the last residue of the McC peptide should result in antibacterial compounds with targets other than AspRS. However, mutations that introduce amino acid substitutions in the last position of the McC peptide abolish McC production. Here, we report total chemical synthesis of three McC-like compounds containing a terminal aspartate, glutamate, or leucine attached to adenosine through a nonhydrolyzable sulfamoyl bond. We show that all three compounds function in a manner similar to that of McC, but the first compound inhibits bacterial growth by targeting AspRS while the latter two inhibit, respectively, GluRS and LeuRS. Our approach opens a way for creation of new antibacterial Trojan horse agents that target any 1 of the 20 tRNA synthetases in the cell.Microcins are small (<10-kDa) ribosomally synthesized peptide antibiotics produced by Enterobacteriaceae (17). Three microcins, B, C, and J, form a subgroup of posttranslationally modified microcins. Members of this subgroup have highly unusual structures and inhibit cellular enzymes that are validated targets for antibacterial drug development (25). Posttranslationally modified microcins are attractive as drug candidates because of their strong antibacterial action and because virtually limitless numbers of their derivatives can be generated by means of mutation, chemical synthesis, or both. Microcin B (McB), a 43-residue peptide with thiazole and indole rings (13), inhibits DNA gyrase (21). Microcin J, a 21-amino-acid peptide, assumes an unusual threaded lasso structure (2, 23, 27) and inhibits bacterial RNA polymerase (1, 18). The structure of the subject of this study, McC (compound 1) is shown in Fig. ​Fig.1a.1a. McC is a heptapeptide with a formylated N-terminal methionine and a C-terminal aspartate whose α-carboxyl group is covalently linked to adenosine through an N-acyl phosphoramide bond (10, 14). The phosphoramidate of McC is additionally modified by an O-propylamine group (9).Open in a separate windowFIG. 1.Structures and synthesis of McC analogs. (a) Structures of microcin C (compound 1) and its processing product (compound 2). (b) Structures of synthetic McC analogs 7 to 9 and their expected processing products, compounds 4 to 6, which are established inhibitors of AspRS, GluRS, and LeuRS, respectively. (c) Structure of Asp-AMP (compound 3), the natural reaction intermediate of AspRS. Compounds 2 and 4 are nonhydrolyzable analogs of this compound. (d) Synthesis of compounds 7 to 9, which starts from compounds 4 to 6. Hereto the hexapeptide was coupled to the sulfamoyl precursors 4-6 via the coupling agent DIC, followed by removal of the Fmoc protecting group: (i) Fmoc-MRTGNA-OH, HOBt, DIC, DIPEA; (ii) Et₃N/DMF (1:1 [vol/vol]).The passage of McC through the inner layer of the Escherichia coli cell wall is carried out by the YejABEF transporter (19). Once inside the cell, McC is specifically processed by one of the several broad-specificity E. coli cytoplasmic aminopeptidases (12). The product of processing, modified aspartyl-adenylate (compound 2) (15), closely resembles Asp-AMP (compound 3) (Fig. ​(Fig.1c),1c), the natural reaction intermediate of the tRNA^Asp aminoacylation reaction catalyzed by AspRS. However, because the bond between the α-carboxyl of C-terminal aspartate and the phosphoramidate nitrogen is nonhydrolyzable, compound 2 inhibits AspRS. Unprocessed McC has no effect on tRNA^Asp aminoacylation, while processed McC has no effect on McC-sensitive cells at concentrations at which intact McC strongly inhibits cell growth. Thus, McC is a Trojan horse inhibitor (22): the peptide part allows McC to enter sensitive cells, where it gets processed, liberating the inhibitory part of the drug.Aminoacyl-tRNA synthetases (aaRSs) carry out the condensation of genetically encoded amino acids with cognate tRNAs. When 1 of the 20 aaRSs present in the cell is inhibited, the corresponding tRNA is not charged. This leads to protein synthesis inhibition and cell growth arrest. In principle, variation of the last amino acid of the McC peptide, the product of the mccA gene, should allow investigators to obtain McC derivatives targeting aaRSs other than AspRS. Unfortunately, the results of systematic structure-activity analyses of the McC peptide revealed that substitutions in the seventh codon of mccA invariably prevented McC production, presumably by interfering with posttranslational modifications of the MccA peptide by the McC maturation enzymes (11). Indeed, in vitro analysis showed that the C-terminal asparagine of MccA is required for the addition of the adenosine moiety by the MccB protein (24).Aminoacyl-sulfamoyl adenosines are well-known nanomolar inhibitors of their corresponding aaRSs (5, 20, 26). However, these compounds show low in vivo activities due to limited membrane permeability and the absence of a transporter for these compounds. Here, we show that through chemical attachment of aminoacyl-sulfamoyl adenosines to the first 6 amino acids of the MccA peptide, potent antibacterial agents can be generated. The new compounds share the Trojan horse mechanism of action with McC but target aaRSs specified by the last amino acid of the peptide moiety.     

Thermally induced structural changes of intrinsically disordered small heat shock protein Hsp22

We applied different methods (differential scanning calorimetry, circular dichroism, Fourier transform infrared spectroscopy, and intrinsic fluorescence) to investigate the thermal-induced changes in the structure of small heat shock protein Hsp22. It has been shown that this protein undergoes thermal-induced unfolding that occurs within a very broad temperature range (from 27 °C to 80 °C and above), and this is accompanied by complete disappearance of α-helices, significant decrease in β-sheets content, and by pronounced changes in the intrinsic fluorescence. The results confirm predictions that Hsp22 belongs to the family of intrinsically disordered proteins (IDP) with certain parts of its molecule (presumably, in the α-crystallin domain) retaining folded structure and undergoing reversible thermal unfolding. The results are also discussed in terms of downhill folding scenario.     

Transcriptional regulation of central carbon and energy metabolism in bacteria by redox-responsive repressor Rex

Redox-sensing repressor Rex was previously implicated in the control of anaerobic respiration in response to the cellular NADH/NAD(+) levels in gram-positive bacteria. We utilized the comparative genomics approach to infer candidate Rex-binding DNA motifs and assess the Rex regulon content in 119 genomes from 11 taxonomic groups. Both DNA-binding and NAD-sensing domains are broadly conserved in Rex orthologs identified in the phyla Firmicutes, Thermotogales, Actinobacteria, Chloroflexi, Deinococcus-Thermus, and Proteobacteria. The identified DNA-binding motifs showed significant conservation in these species, with the only exception detected in Clostridia, where the Rex motif deviates in two positions from the generalized consensus, TTGTGAANNNNTTCACAA. Comparative analysis of candidate Rex sites revealed remarkable variations in functional repertoires of candidate Rex-regulated genes in various microorganisms. Most of the reconstructed regulatory interactions are lineage specific, suggesting frequent events of gain and loss of regulator binding sites in the evolution of Rex regulons. We identified more than 50 novel Rex-regulated operons encoding functions that are essential for resumption of the NADH:NAD(+) balance. The novel functional role of Rex in the control of the central carbon metabolism and hydrogen production genes was validated by in vitro DNA binding assays using the TM0169 protein in the hydrogen-producing bacterium Thermotoga maritima.