Identification of new homologs of PD-(D/E)XK nucleases by support vector machines trained on data derived from profile-profile alignments

PD-(D/E)XK nucleases, initially represented by only Type II restriction enzymes, now comprise a large and extremely diverse superfamily of proteins. They participate in many different nucleic acids transactions including DNA degradation, recombination, repair and RNA processing. Different PD-(D/E)XK families, although sharing a structurally conserved core, typically display little or no detectable sequence similarity except for the active site motifs. This makes the identification of new superfamily members using standard homology search techniques challenging. To tackle this problem, we developed a method for the detection of PD-(D/E)XK families based on the binary classification of profile-profile alignments using support vector machines (SVMs). Using a number of both superfamily-specific and general features, SVMs were trained to identify true positive alignments of PD-(D/E)XK representatives. With this method we identified several PFAM families of uncharacterized proteins as putative new members of the PD-(D/E)XK superfamily. In addition, we assigned several unclassified restriction enzymes to the PD-(D/E)XK type. Results show that the new method is able to make confident assignments even for alignments that have statistically insignificant scores. We also implemented the method as a freely accessible web server at http://www.ibt.lt/bioinformatics/software/pdexk/.     

Interferon‐inducible protein,P56, inhibits HPV DNA replication by binding to the viral protein E1

Type I interferon (IFN) inhibits, by an unknown mechanism, the replication of human papillomaviruses (HPV), which are major human pathogens, Here, we present evidence that P56 (a protein), the expression of which is strongly induced by IFN, double‐stranded RNA and viruses, mediates the anti‐HPV effect of IFN. Ectopic expression of P56 inhibited HPV DNA replication and its ablation in IFN‐treated cells alleviated the inhibitory effect of IFN on HPV DNA replication. Protein–protein interaction and mutational analyses established that the antiviral effect of P56 was mediated by its direct interaction with the DNA replication origin‐binding protein E1 of several strains of HPV, through the tetratricopeptide repeat 2 in the N‐terminal region of P56 and the C‐terminal region of E1. In vivo, the interaction with P56, a cytoplasmic protein, caused translocation of E1 from the nucleus to the cytoplasm. In vitro, recombinant P56, or a small fragment derived from it, inhibited the DNA helicase activity of E1 and E1‐mediated HPV DNA replication. These observations delineate the molecular mechanism of IFN's antiviral action against HPV.     

Deinococcus radiodurans DR1088 is a novel RecF‐interacting protein that stimulates single‐stranded DNA annealing

RecF, together with the recombination mediators RecO and RecR, is required in the RecFOR homologous recombination repair pathway in bacteria. In this study, a recF‐dr1088 operon, which is highly conserved in the Deinococcus‐Thermus phylum, was identified in Deinococcus radiodurans. Interaction between DRRecF and DR1088 was confirmed by yeast two‐hybrid and pull‐down assays. DR1088 exhibited some RecO‐like biochemical properties including single/double‐stranded DNA binding activity, ssDNA binding protein (SSB) replacement ability and ssDNA (with or without SSB) annealing activity. However, unlike other recombination proteins, dr1088 is essential for cell viability. These results indicate that DR1088 might play a role in DNA replication and DNA repair processes.     

The role of recombination in evolutionary adaptation of Escherichia coli to a novel nutrient

The benefits and detriments of recombination for adaptive evolution have been studied both theoretically and experimentally, with conflicting predictions and observations. Most pertinent experiments examine recombination's effects in an unchanging environment and do not study its genomewide effects. Here, we evolved six replicate populations of either highly recombining R⁺ or lowly recombining R^? E. coli strains in a changing environment, by introducing the novel nutrients L‐arabinose or indole into the environment. The experiment's ancestral strains are not viable on these nutrients, but 130 generations of adaptive evolution were sufficient to render them viable. Recombination conferred a more pronounced advantage to populations adapting to indole. To study the genomic changes associated with this advantage, we sequenced the genomes of 384 clones isolated from selected replicates at the end of the experiment. These genomes harbour complex changes that range from point mutations to large‐scale DNA amplifications. Among several candidate adaptive mutations, those in the tryptophanase regulator tnaC stand out, because the tna operon in which it resides has a known role in indole metabolism. One of the highly recombining populations also shows a significant excess of large‐scale segmental DNA amplifications that include the tna operon. This lineage also shows a unique and potentially adaptive combination of point mutations and DNA amplifications that may have originated independently from one another, to be joined later by recombination. Our data illustrate that the advantages of recombination for adaptive evolution strongly depend on the environment and that they can be associated with complex genomic changes.     

Bacterial transformation: ComFA is a DNA‐dependent ATPase that forms complexes with ComFC and DprA

Pneumococcal natural transformation contributes to genomic plasticity, antibiotic resistance development and vaccine escape. Streptococcus pneumoniae, like many other naturally transformable species, has evolved sophisticated protein machinery for the binding and uptake of DNA. Two proteins encoded by the comF operon, ComFA and ComFC, are involved in transformation but their exact molecular roles remain unknown. In this study, we provide experimental evidence that ComFA binds to single stranded DNA (ssDNA) and has ssDNA‐dependent ATPase activity. We show that both ComFA and ComFC are essential for the transformation process in pneumococci. Moreover, we show that these proteins interact with each other and with other proteins involved in homologous recombination, such as DprA, thus placing the ComFA‐ComFC duo at the interface between DNA uptake and DNA recombination during transformation.     

Characterization of RNA primers synthesized by the human breast cancer cell DNA synthesome

We previously reported on the purification and characterization of a functional multi‐protein DNA replication complex (the DNA synthesome) from human cells and tissues. The synthesome is fully competent to carry‐out all phases of the DNA replication process in vitro. In this study, DNA primase, a component of the synthesome, is examined to determine its activity and processivity in the in vitro synthesis and extension of RNA primers. Our results show that primase activity in the P4 fraction of the synthesome is 30‐fold higher than that of crude cell extracts. The synthesome synthesizes RNA primers that are 7–10 ribonucleotides long and DNA primers that are 20–40 deoxyribonucleotides long using a poly(dT) template of exogenous single‐stranded DNA. The synthesome‐catalyzed RNA primers can be elongated by E. coli DNA polymerase I to form the complementary DNA strands on the poly(dT) template. In addition, the synthesome also supports the synthesis of native RNA primers in vitro using an endogenous supercoiled double‐stranded DNA template. Gel analysis demonstrates that native RNA primers are oligoribonucleotides of 10–20 nt in length and the primers are covalently link to DNA to form RNA‐primed nascent DNA of 100–200 nt. Our study reveals that the synthesome model is capable of priming and continuing DNA replication. The ability of the synthesome to synthesize and extend RNA primers in vitro elucidates the organizational and functional properties of the synthesome as a potentially useful replication apparatus to study the function of primase and the interaction of primase with other replication proteins. J. Cell. Biochem. 106: 798–811, 2009. © 2009 Wiley‐Liss, Inc.     

Mutational analysis of active‐site residues in the Mycobacterium leprae RecA intein,a LAGLIDADG homing endonuclease: Asp122 and Asp193 are crucial to the double‐stranded DNA cleavage activity whereas Asp218 is not

Mycobacterium leprae recA harbors an in‐frame insertion sequence that encodes an intein homing endonuclease (PI‐MleI). Most inteins (intein endonucleases) possess two conserved LAGLIDADG (DOD) motifs at their active center. A common feature of LAGLIDADG‐type homing endonucleases is that they recognize and cleave the same or very similar DNA sequences. However, PI‐MleI is distinctive from other members of the family of LAGLIDADG‐type HEases for its modular structure with functionally separable domains for DNA‐binding and cleavage, each with distinct sequence preferences. Sequence alignment analyses of PI‐MleI revealed three putative LAGLIDADG motifs; however, there is conflicting bioinformatics data in regard to their identity and specific location within the intein polypeptide. To resolve this conflict and to determine the active‐site residues essential for DNA target site recognition and double‐stranded DNA cleavage, we performed site‐directed mutagenesis of presumptive catalytic residues in the LAGLIDADG motifs. Analysis of target DNA recognition and kinetic parameters of the wild‐type PI‐MleI and its variants disclosed that the two amino acid residues, Asp¹²² (in Block C) and Asp¹⁹³ (in functional Block E), are crucial to the double‐stranded DNA endonuclease activity, whereas Asp²¹⁸ (in pseudo‐Block E) is not. However, despite the reduced catalytic activity, the PI‐MleI variants, like the wild‐type PI‐MleI, generated a footprint of the same length around the insertion site. The D122T variant showed significantly reduced catalytic activity, and D122A and D193A mutations although failed to affect their DNA‐binding affinities, but abolished the double‐stranded DNA cleavage activity. On the other hand, D122C variant showed approximately twofold higher double‐stranded DNA cleavage activity, compared with the wild‐type PI‐MleI. These results provide compelling evidence that Asp¹²² and Asp¹⁹³ in DOD motif I and II, respectively, are bona fide active‐site residues essential for DNA cleavage activity. The implications of these results are discussed in this report.     

The role of the CroR response regulator in resistance of Enterococcus faecalis to D‐cycloserine is defined using an inducible receiver domain

Enterococcus faecalis is an opportunistic multidrug‐resistant human pathogen causing severe nosocomial infections. Previous investigations revealed that the CroRS two‐component regulatory pathway likely displays a pleiotropic role in E. faecalis, involved in virulence, macrophage survival, oxidative stress response as well as antibiotic resistance. Therefore, CroRS represents an attractive potential new target for antibiotherapy. In this report, we further explored CroRS cellular functions by characterizing the CroR regulon: the ‘domain swapping’ method was applied and a CroR chimera protein was generated by fusing the receiver domain from NisR to the output domain from CroR. After demonstrating that the chimera CroR complements a croR gene deletion in E. faecalis (stress response, virulence), we conducted a global gene expression analysis using RNA‐Seq and identified 50 potential CroR targets involved in multiple cellular functions such as cell envelope homeostasis, substrate transport, cell metabolism, gene expression regulation, stress response, virulence and antibiotic resistance. For validation, CroR direct binding to several candidate targets was demonstrated by EMSA. Further, this work identified alr, the gene encoding the alanine racemase enzyme involved in E. faecalis resistance to D‐cycloserine, a promising antimicrobial drug to treat enterococcal infections, as a member of the CroR regulon.     

Characterization of a myrosinase cDNA from Brassica parachinensis and its defense role against Plutella xylostella after suppression

Abstract In Brassicaceae, myrosinase catalyzes the hydrolysis of glucosinolate and plays an important role in anti‐herbivore defense. We have cloned and characterized the full‐length complementary DNA of myrosinase gene from Brassica parachinensis that exhibits high sequence identity with myrosinase genes from other Brassica species. To investigate the role of this myrosinase in defense against the diamondback moth (Plutella xylostella), we constructed an RNA‐interference (RNAi) cassette expressing a double‐stranded RNA that targeted myrosinase and transfected it into B. parachinensis. Myrosinase was suppressed in the resulting transgenic plants. Diamondback moth larvae feeding on transgenic plants had lower larval and pupal weights, longer pupal duration, and lower fecundity than those feeding on non‐transgenic plants, suggesting that the diamondback moth has adapted to the glucosinolate‐myrosinase defensive system. Therefore, the suppression of myrosinase is a potential approach for controlling the diamondback moth.     

NapM,a new nucleoid‐associated protein,broadly regulates gene expression and affects mycobacterial resistance to anti‐tuberculosis drugs

Nucleoid‐associated proteins (NAPs) play important roles in the global organization of bacterial chromosomes. However, potential NAPs and their functions are barely characterized in mycobacteria. In this study, NapM, an alkaline protein, functions as a new NAP. NapM is conserved in all of the sequenced mycobacterial genomes, and can recognize DNA in a length‐dependent but sequence‐independent manner. It prefers AT‐rich DNA and binds to the major groove. NapM possesses a clear DNA‐bridging function, and can protect DNA from DNase I digestion. NapM globally regulates the expression of more than 150 genes and the resistance of Mycobacterium smegmatis to two anti‐tuberculosis drugs, namely, rifampicin and ethambutol. An ABC transporter operon was found to be specifically responsible for the napM‐dependent ethambutol resistance of M. smegmatis. NapM also presents a similar regulation of anti‐tuberculosis drug resistance in M. tuberculosis. These results suggest that NapM is a new member of the mycobacterial NAP family. Our findings expand the range of identified NAPs and improve the understanding on the relationship between NAPs with antibiotic resistance in mycobacteria.     

DNA intercalation without flipping in the specific ThaI–DNA complex

The PD-(D/E)XK type II restriction endonuclease ThaI cuts the target sequence CG/CG with blunt ends. Here, we report the 1.3 Å resolution structure of the enzyme in complex with substrate DNA and a sodium or calcium ion taking the place of a catalytic magnesium ion. The structure identifies Glu54, Asp82 and Lys93 as the active site residues. This agrees with earlier bioinformatic predictions and implies that the PD and (D/E)XK motifs in the sequence are incidental. DNA recognition is very unusual: the two Met47 residues of the ThaI dimer intercalate symmetrically into the CG steps of the target sequence. They approach the DNA from the minor groove side and penetrate the base stack entirely. The DNA accommodates the intercalating residues without nucleotide flipping by a doubling of the CG step rise to twice its usual value, which is accompanied by drastic unwinding. Displacement of the Met47 side chains from the base pair midlines toward the downstream CG steps leads to large and compensating tilts of the first and second CG steps. DNA intercalation by ThaI is unlike intercalation by HincII, HinP1I or proteins that bend or repair DNA.     

Localization of sequences coding for histone messenger RNA in the chromosomes of Drosophila melanogaster

In situ hybridization of sea urchin (Psammechinus miliaris, Lytechinus pictus and Strongylocentrotus purpuratus) histone messenger RNA has been used to map complementary sequences on polytene chromosomes from Drosophila melanogaster. The sea urchin RNA hybridizes to the polytene regions from 39D3 through 39E1-2, including both of these bands (39D2 may also be included). This region is identical to the one which hybridizes most heavily with non-polyadenylated cytoplasmic RNA from D. melanogaster tissues. Sea urchin mRNAs coding for several individual histones each hybridize across the entire region from 39D3 (or D2) through 39E1-2, as would be expected if the individual mRNA sequences are interspersed. In view of the apparently even distribution of sequences complementary to histone mRNA within the 39D3-39E1-2 region, the significance of the several polytene bands in this region remains an open question. Biochemical characterization of the hybrids between sea urchin histone mRNA and D. melanogaster DNA suggests that sea urchin mRNAs for several of the histone classes have some portions which retain enough sequence homology with the D. melanogaster sequences to form hybrids, although the hybrids have base pair mismatches. In situ hybridization of chromosomes in which region 39D-E is ectopically paired show no evidence of sequence homology in the chromosome region with which 39D-E is associated.     

Mutability of an HNH nuclease imidazole general base and exchange of a deprotonation mechanism

Several unique protein folds that catalyze the hydrolysis of phosphodiester bonds have arisen independently in nature, including the PD(D/E)XK superfamily (typified by type II restriction endonucleases and many recombination and repair enzymes) and the HNH superfamily (found in an equally wide array of enzymes, including bacterial colicins and homing endonucleases). Whereas the identity and position of catalytic residues within the PD(D/E)XK superfamily are highly variable, the active sites of HNH nucleases are much more strongly conserved. In this study, the ability of an HNH nuclease to tolerate a mutation of its most conserved catalytic residue (its histidine general base), and the mechanism of the most active enzyme variant, were characterized. Conversion of this residue into several altered chemistries, glutamine, lysine, or glutamate, resulted in measurable activity. The histidine to glutamine mutant displays the highest residual activity and a pH profile similar to that of the wild-type enzyme. This activity is dependent on the presence of a neighboring imidazole ring, which has taken over as a less efficient general base for the reaction. This result implies that mutational pathways to alternative HNH-derived catalytic sites do exist but are not as extensively or successfully diverged or reoptimized in nature as variants of the PD(D/E)XK nuclease superfamily. This is possibly due to multiple steric constraints placed on the compact HNH motif, which is simultaneously involved in protein folding, DNA binding, and catalysis, as well as the use of a planar, aromatic imidazole group as a general base.     

Phage T4‐induced DNA breaks activate a tRNA repair‐defying anticodon nuclease

The natural role of the conserved bacterial anticodon nuclease (ACNase) RloC is not known, but traits that set it apart from the homologous phage T4‐excluding ACNase PrrC could provide relevant clues. PrrC is silenced by a genetically linked DNA restriction‐modification (RM) protein and turned on by a phage‐encoded DNA restriction inhibitor. In contrast, RloC is rarely linked to an RM protein, and its ACNase is regulated by an internal switch responsive to double‐stranded DNA breaks. Moreover, PrrC nicks the tRNA substrate, whereas RloC excises the wobble nucleotide. These distinctions suggested that (i) T4 and related phage that degrade their host DNA will activate RloC and (ii) the tRNA species consequently disrupted will not be restored by phage tRNA repair enzymes that counteract PrrC. Consistent with these predictions we show that Acinetobacter baylyi RloC expressed in Escherichia coli is activated by wild‐type phage T4 but not by a mutant impaired in host DNA degradation. Moreover, host and T4 tRNA species disrupted by the activated ACNase were not restored by T4's tRNA repair system. Nonetheless, T4's plating efficiency was inefficiently impaired by AbaRloC, presumably due to a decoy function of the phage encoded tRNA target, the absence of which exacerbated the restriction.     

Binding kinetics and activity of human poly(ADP‐ribose) polymerase‐1 on oligo‐deoxyribonucleotide substrates

Poly(ADP‐ribose) polymerase‐1 (PARP‐1) is a mammalian enzyme that attaches long branching chains of ADP‐ribose to specific nuclear proteins, including itself. Because its activity in vitro is dependent upon interaction with broken DNA, it has been postulated that PARP‐1 plays an important role in DNA strand‐break repair in vivo. The exact mechanism of binding to DNA and the structural determinants of binding remain to be defined, but regions of transition from single‐stranded to double‐strandedness may be important recognition sites. Here we employ surface plasmon resonance (SPR) to investigate this hypothesis. Oligodeoxynucleotide (ODN) substrates that mimic DNA with different degrees of single‐strandedness were used for measurements of both PARP‐1/DNA binding kinetics and PARP‐1's enzyme activities. We found that binding correlated with activity, but was unrelated to single‐strandedness of the ODN. Instead, PARP‐1 binding and activity were highest on ODNs that modeled a DNA double‐strand break (DSB). These results provide support for PARP‐1 recognizing and binding DSBs in a manner that is independent of single‐stranded features, and demonstrate the usefulness of SPR for simultaneously investigating both PARP‐1 binding and PARP‐1 auto‐poly(ADP‐ribosyl)ation activities within the same in vitro system. Copyright © 2009 John Wiley & Sons, Ltd.     

Interactive effects of food quality,temperature and rearing time on condition of juvenile black bream Acanthopagrus butcheri

A laboratory experiment was conducted to determine the interactive effects of temperature and diet on condition indices of juvenile black bream Acanthopagrus butcheri, reared for time periods ranging from 2 to 42 days. After fish were reared for varying periods, growth, morphometric (Fulton's K) and biochemical [RNA:DNA (R:D) ratios] indices were measured. Fulton's K responded primarily to temperature, with progressive decrease in condition over time for fish reared at high temperatures. In contrast, R:D ratios were primarily affected by diet composition, with the highest values observed for fish reared on fish‐based diets as opposed to vegetable‐based diets. Significant effects of rearing time were also observed for Fulton's K and R:D ratios, as were some interactive treatment effects. In addition, Fulton's K and R:D ratios were not significantly correlated, perhaps due to the different periods of time integrated by each index or their relative sensitivity to lipid and protein deposition. These results highlight the complex responses of these condition indices to environmental variables and nutritional status.