A Novel Glucosyltransferase Involved in O-Antigen Modification of Shigella flexneri Serotype 1c

The O antigen of serotype 1c differs from the unmodified O antigen of serotype Y by the addition of a disaccharide (two glucosyl groups) to the tetrasaccharide repeating unit. It was shown here that addition of the first glucosyl group is mediated by the previously characterized gtrI cluster, which is found within a cryptic prophage at the proA locus in the bacterial chromosome. Transposon mutagenesis was performed to disrupt the gene responsible for addition of the second glucosyl group, causing reversion to serotype 1a. Colony immunoblotting was used to identify the desired revertants, and subsequent sequencing, cloning, and functional expression successfully identified the gene encoding serotype 1c-specific O-antigen modification. This gene (designated gtrIC) was present as part of a three-gene cluster, similar to other S. flexneri glucosyltransferase genes. Relative to the other S. flexneri gtr clusters, the gtrIC cluster is more distantly related and appears to have arrived in S. flexneri from outside the species. Analysis of surrounding sequence suggests that the gtrIC cluster arrived via a novel bacteriophage that was subsequently rendered nonfunctional by a series of insertion events.Shigella flexneri is a pathovar of Escherichia coli that is the main causative agent of endemic bacillary dysentery (shigellosis). It is estimated that S. flexneri is responsible for approximately 100 million shigellosis cases annually, resulting in hundreds of thousands of deaths, predominantly in young children (11). Currently no vaccine is available, although there is evidence to suggest that serotype-specific immunity occurs following infection and that induction of immunity can be replicated with vaccines (9). Shigella serotype diversity arises due to differences in the chemical structure of the O-antigen repeating unit in the lipopolysaccharide, which is the main target of the adaptive host immune response following infection.Because immunity to S. flexneri can be conferred by the induction of antibodies directed against the O antigen, an understanding of the prevalence of different serotypes and the underlying basis of serotype diversity can inform appropriate vaccine design. All S. flexneri serotypes (with the exception of serotype 6) share a common O-antigen backbone, consisting of a repeating tetrasaccharide unit that is comprised of one N-acetylglucosamine residue (GlcNAc) and three rhamnose residues (RhaI, RhaII, and RhaIII) (14). The 12 traditionally recognized S. flexneri serotypes differ by the presence or absence of just six different chemical modifications (glucosylations or O acetylations) of the O antigen. The genes responsible for these O-antigen modifications are introduced into the bacterial genome via bacteriophages (3). Glucosylation of the S. flexneri O antigen is mediated by three genes [gtrA, gtrB, and gtr(type)] that are arranged in a single operon known as a gtr cluster. gtrA and gtrB are highly conserved between different gtr clusters and encode proteins involved in transferring the glucosyl group from the cytoplasm into the periplasm, where O-antigen modification is thought to take place. gtr(type) is unique to each gtr cluster and encodes a glucosyltransferase that is responsible for attaching the glucosyl group to a specific sugar unit of the O antigen via a specific linkage (3).Investigations of S. flexneri have typically focused on serotypes for which commercially available typing sera are available. More recently, it has become clear that other serotypes are also epidemiologically important. In Bangladesh in the late 1980s, two novel S. flexneri strains that did not agglutinate with antibodies specific for the traditionally recognized serotypes were isolated (4). Chemical analysis of the O antigen revealed that these strains belonged to a new serotype, which was named serotype 1c due to the similarity its O antigen shares with the O antigens of serotype 1a and 1b strains (19). Serotype 1c has since been isolated in Egypt, Indonesia, Pakistan, and Vietnam (6, 15, 18). Serotype 1c was shown to be the most prevalent S. flexneri serotype in a northern province of Vietnam, accounting for more than a third of all S. flexneri strains isolated from 1998 to 1999 (15). Identification of serotype 1c currently relies on agglutination testing using monoclonal antibody MASF Ic (19).The O antigen of serotype 1c is distinguished by the presence of a disaccharide (two glucosyl groups) linked to the GlcNAc in the tetrasaccharide repeating unit of the O antigen. The first glucosyl group is joined to GlcNAc via an α1→4 linkage, as occurs in the O antigen of serotype 1a and serotype 1b strains (type I modification). The O antigen of serotype 1c is distinguished by the presence of a second glucosyl group that is linked to the first via an α1→2 linkage (Fig. ​(Fig.1).1). Type Ia modification is prerequisite to type Ic modification.Open in a separate windowFIG. 1.Chemical structure of the tetrasaccharide repeat units in the O antigens of S. flexneri serotypes 1a and 1c. Note that the O antigen of serotype 1b (not shown) differs from that of serotype 1a by the O acetylation of l-RhaIII.In this study, the genetic basis of O-antigen modification in serotype 1c was elucidated. Serotype 1c strains isolated from different locations and times were compared to gain insight into the evolution of this serotype. This is the first report of the identification of a glucosyltransferase gene that is responsible for addition of the second glucosyl group, causing serotype conversion from serotype 1a to serotype 1c.     

Leakage and slow allostery limit performance of single drug-sensing aptazyme molecules based on the hammerhead ribozyme

Engineered “aptazymes” fuse in vitro selected aptamers with ribozymes to create allosteric enzymes as biosensing components and artificial gene regulatory switches through ligand-induced conformational rearrangement and activation. By contrast, activating ligand is employed as an enzymatic cofactor in the only known natural aptazyme, the glmS ribozyme, which is devoid of any detectable conformational rearrangements. To better understand this difference in biosensing strategy, we monitored by single molecule fluorescence resonance energy transfer (FRET) and 2-aminopurine (AP) fluorescence the global conformational dynamics and local base (un)stacking, respectively, of a prototypical drug-sensing aptazyme, built from a theophylline aptamer and the hammerhead ribozyme. Single molecule FRET reveals that a catalytically active state with distal Stems I and III of the hammerhead ribozyme is accessed both in the theophylline-bound and, if less frequently, in the ligand-free state. The resultant residual activity (leakage) in the absence of theophylline contributes to a limited dynamic range of the aptazyme. In addition, site-specific AP labeling shows that rapid local theophylline binding to the aptamer domain leads to only slow allosteric signal transduction into the ribozyme core. Our findings allow us to rationalize the suboptimal biosensing performance of the engineered compared to the natural aptazyme and to suggest improvement strategies. Our single molecule FRET approach also monitors in real time the previously elusive equilibrium docking dynamics of the hammerhead ribozyme between several inactive conformations and the active, long-lived, Y-shaped conformer.     

The influence of footwear on foot motion during walking and running

There are evidences to suggest that wearing footwear constrains the natural barefoot motion during locomotion. Unlike prior studies that deduced foot motions from shoe sole displacement parameters, the aim of this study was to examine the effect of footwear motion on forefoot to rearfoot relative motion during walking and running. The use of a multi-segment foot model allowed accurate both shoe sole and foot motions (barefoot and shod) to be quantified. Two pairs of identical sandals with different midsole hardness were used. Ten healthy male subjects walked and ran in each of the shod condition.The results showed that for barefoot locomotion there was more eversion of the forefoot and it occurred faster than for shod locomotion. In this later condition, the range of eversion was reduced by 20% and the rate of eversion in late stance by 60% in comparison to the barefoot condition. The sole constrained both the torsional (eversion/inversion) and adduction range of motion of the foot. Interestingly, during the push-off phase of barefoot locomotion the rate and direction of forefoot torsion varied between individuals. However, most subjects displayed a forefoot inversion direction of motion while shod. Therefore, this experiment showed that the shoes not only restricted the natural motion of the barefoot but also appeared to impose a specific foot motion pattern on individuals during the push-off phase. These findings have implications for the matching of footwear design characteristics to individual natural foot function.     

Evolution of new gene functions: simulation and analysis of the amplification model

Creation of new genes and functions is a central feature of evolution. Duplication of existing genes has long been assumed to be the source of new genes, but the precise mechanism has remained unclear. One suggestion is that new genes are created via temporary amplifications, which simultaneously increase both the selective advantage of weak, pre-existing secondary functions and the target for optimizing mutations. This paper examines the amplification model by formalizing it into a mathematical framework. This framework is used to perform stochastic (Monte Carlo) simulations. In addition, experimental data from Salmonella typhimurium LT2 are used to support the modelling, by providing estimates for parameter values. The results show that amplification of tandem repeats is likely to contribute to creation of new genes in nature.     

Phylogenetic characterization of the purple sulfur bacterium Thiocapsa sp. BBS by analysis of the 16S rRNA, cbbL, and nifH genes and its description as Thiocapsa bogorovii sp. nov., a new species

Strain BBS, the purple sulfur bacterium assigned initially to the species Thiocapsa roseopersicina, is the best studied representative of this species. However, no molecular phylogenetic analysis has been performed to confirm its systematic position. Based on the results of analysis of the sequences of 16S rRNA, cbbL, and nifH genes, DNA-DNA hybridization with the T. roseopersicina type strain, and comparative analysis of the phenotypic characteristics of various species belonging to the genus Thiocapsa, we suggest that strain BBS should be assigned to a new species of the genus Thiocapsa, Thiocapsa bogorovii sp. nov. Original Russian Text ? T.P. Tourova, O.I. Keppen, O.L. Kovaleva, N.V. Slobodova, I.A. Berg, R.N. Ivanovsky, 2009, published in Mikrobiologiya, 2009, Vol. 78, No. 3, pp. 381–392.     

Enzymes of the citramalate cycle in <Emphasis Type="Italic">Rhodospirillum rubrum</Emphasis>

Rhodospirillum rubrum is among the bacteria that can assimilate acetate in the absence of isocitrate lyase, the key enzyme of glyoxylate shunt. Previously we have suggested the functioning of a new anaplerotic cycle of acetate assimilation in this bacterium: citramalate cycle, where acetyl-CoA is oxidized to glyoxylate. This work has demonstrated the presence of all the key enzymes of this cycle in R. rubrum extracts: citramalate synthase catalyzing condensation of acetyl-CoA and pyruvate with the formation of citramalate, mesaconase forming mesaconate from L-citramalate, and the enzymes catalyzing transformation of propionyl-CoA + glyoxylate 3-methylmalyl-CoA ? mesaconyl-CoA. At the same time, R. rubrum synthesizes crotonyl-CoA carboxylase/reductase, which is the key enzyme of ethylmalonyl-CoA pathway discovered recently in Rhodobacter sphaeroides. Physiological differences between the citramalate cycle and the ethylmalonyl-CoA pathway are discussed.     

Molecular characterization of a fungal gene paralogue of the penicillin penDE gene of Penicillium chrysogenum

Background  

Penicillium chrysogenum converts isopenicillin N (IPN) into hydrophobic penicillins by means of the peroxisomal IPN acyltransferase (IAT), which is encoded by the penDE gene. In silico analysis of the P. chrysogenum genome revealed the presence of a gene, Pc13g09140, initially described as paralogue of the IAT-encoding penDE gene. We have termed this gene ial because it encodes a protein with high similarity to IAT (IAL for IAT-Like). We have conducted an investigation to characterize the ial gene and to determine the role of the IAL protein in the penicillin biosynthetic pathway.     

Polymorphisms in the neural nicotinic acetylcholine receptor α4 subunit (CHRNA4) are associated with ADHD in a genetic isolate

The neural nicotinic acetylcholine receptor α4 subunit (CHRNA4), at 20q13.2-q13.3, is an important candidate gene for conferring susceptibility to attention deficit/hyperactivity disorder (ADHD). Several studies have already looked for association/linkage between ADHD and CHRNA4 in different populations. We used the Pedigree Disequilibrium Test to search for evidence of association between ADHD and six SNP marker loci in families from the isolated Paisa population. We found that the T allele of SNP rs6090384 exhibits a deficit of transmission in unaffected individuals (OR = 5.43, IC 1.54-19.13) (global P value = 0.014). We also found significant association and linkage to extended haplotypes rs2273502-rs6090384 (combination of variants C-T, respectively) (P = 0.02) and rs6090384-rs6090387 (P = 0.04) (combination of variants T-G, respectively). SNP rs6090384, variant T, has also been reported to be associated with inattention in a previous study. This makes ours the ninth study to examine the association of CHRNA4 with ADHD and the seventh one to find evidence for association in a population with a different ethnicity.