Regulation of Staphylococcus xylosus xylose utilization genes at the molecular level

D-Xylose Blocks the Broad Negative Regulation of XylR on Lipid Metabolism and Affects Multiple Physiological Characteristics in Mycobacteria

D-xylose is the most abundant fermentable pentose, which usually represents an architectural component of the bacterial cell wall. However, its regulatory function and the involved signaling pathway in bacteria remain largely unclear. Here, we show that D-xylose can act as a signaling molecule to regulate the lipid metabolism and affect multiple physiological characteristics in mycobacteria. D-xylose directly interacts with XylR and inhibits its DNA-binding ability, thus blocking XylR-mediated repression. The xylose inhibitor, XylR, plays a global regulatory role and affects the expression of 166 mycobacterial genes that are involved in lipid synthesis and metabolism. Furthermore, we show that the xylose-dependent gene regulation of XylR affects the multiple physiological characteristics of Mycobacterium smegmatis, including bacterial size, colony phenotype, biofilm formation, cell aggregation, and antibiotic resistance. Finally, we found that XylR inhibited the survival of Mycobacterium bovis BCG in the host. Our findings provide novel insights into the molecular mechanism of lipid metabolism regulation and its correlation with bacterial physiological phenotypes.

Farming Practice Influences Antimicrobial Resistance Burden of Non-Aureus Staphylococci in Pig Husbandries

Non-aureus staphylococci (NAS) are ubiquitous bacteria in livestock-associated environments where they may act as reservoirs of antimicrobial resistance (AMR) genes for pathogens such as Staphylococcus aureus. Here, we tested whether housing conditions in pig farms could influence the overall AMR-NAS burden. Two hundred and forty porcine commensal and environmental NAS isolates from three different farm types (conventional, alternative, and organic) were tested for phenotypic antimicrobial susceptibility and subjected to whole genome sequencing. Genomic data were analysed regarding species identity and AMR gene carriage. Seventeen different NAS species were identified across all farm types. In contrast to conventional farms, no AMR genes were detectable towards methicillin, aminoglycosides, and phenicols in organic farms. Additionally, AMR genes to macrolides and tetracycline were rare among NAS in organic farms, while such genes were common in conventional husbandries. No differences in AMR detection existed between farm types regarding fosfomycin, lincosamides, fusidic acid, and heavy metal resistance gene presence. The combined data show that husbandry conditions influence the occurrence of resistant and multidrug-resistant bacteria in livestock, suggesting that changing husbandry practices may be an appropriate means of limiting the spread of AMR bacteria on farms.

D-Xylose Sensing in Saccharomyces cerevisiae: Insights from D-Glucose Signaling and Native D-Xylose Utilizers

Extension of the substrate range is among one of the metabolic engineering goals for microorganisms used in biotechnological processes because it enables the use of a wide range of raw materials as substrates. One of the most prominent examples is the engineering of baker's yeast Saccharomyces cerevisiae for the utilization of d-xylose, a five-carbon sugar found in high abundance in lignocellulosic biomass and a key substrate to achieve good process economy in chemical production from renewable and non-edible plant feedstocks. Despite many excellent engineering strategies that have allowed recombinant S. cerevisiae to ferment d-xylose to ethanol at high yields, the consumption rate of d-xylose is still significantly lower than that of its preferred sugar d-glucose. In mixed d-glucose/d-xylose cultivations, d-xylose is only utilized after d-glucose depletion, which leads to prolonged process times and added costs. Due to this limitation, the response on d-xylose in the native sugar signaling pathways has emerged as a promising next-level engineering target. Here we review the current status of the knowledge of the response of S. cerevisiae signaling pathways to d-xylose. To do this, we first summarize the response of the native sensing and signaling pathways in S. cerevisiae to d-glucose (the preferred sugar of the yeast). Using the d-glucose case as a point of reference, we then proceed to discuss the known signaling response to d-xylose in S. cerevisiae and current attempts of improving the response by signaling engineering using native targets and synthetic (non-native) regulatory circuits.

Genome-scale exploration of transcriptional regulation in the nisin Z producer Lactococcus lactis subsp. lactis IO-1

Transcription is of the most crucial steps of gene expression in bacteria, whose regulation guarantees the bacteria's ability to adapt to varying environmental conditions. Discovering the molecular basis and genomic principles of the transcriptional regulation is thus one of the most important tasks in cellular and molecular biology. Here, a comprehensive phylogenetic footprinting framework was implemented to predict maximal regulons of Lactococcus lactis subsp. lactis IO-1, a lactic acid bacterium known for its high potentials in nisin Z production as well as efficient xylose consumption which have made it a promising biotechnological strain. A total set of 321 regulons covering more than 90% of all the bacterium's operons have been elucidated and validated according to available data. Multiple novel biologically-relevant members were introduced amongst which arsC, mtlA and mtl operon for BusR, MtlR and XylR regulons can be named, respectively. Moreover, the effect of riboflavin on nisin biosynthesis was assessed in vitro and a negative correlation was observed. It is believed that understandings from such networks not only can be useful for studying transcriptional regulatory potentials of the target organism but also can be implemented in biotechnology to rationally design favorable production conditions.

A Xylose-Inducible Expression System and a CRISPR Interference Plasmid for Targeted Knockdown of Gene Expression in Clostridioides difficile

Here we introduce plasmids for xylose-regulated expression and repression of genes in Clostridioides difficile The xylose-inducible expression vector allows for ∼100-fold induction of an mCherryOpt reporter gene. Induction is titratable and uniform from cell to cell. The gene repression plasmid is a CRISPR interference (CRISPRi) system based on a nuclease-defective, codon-optimized allele of the Streptococcus pyogenes Cas9 protein (dCas9) that is targeted to a gene of interest by a constitutively expressed single guide RNA (sgRNA). Expression of dCas9 is induced by xylose, allowing investigators to control the timing and extent of gene silencing, as demonstrated here by dose-dependent repression of a chromosomal gene for a red fluorescent protein (maximum repression, ∼100-fold). To validate the utility of CRISPRi for deciphering gene function in C. difficile, we knocked down the expression of three genes involved in the biogenesis of the cell envelope: the cell division gene ftsZ, the S-layer protein gene slpA, and the peptidoglycan synthase gene pbp-0712 CRISPRi confirmed known or expected phenotypes associated with the loss of FtsZ and SlpA and revealed that the previously uncharacterized peptidoglycan synthase PBP-0712 is needed for proper elongation, cell division, and protection against lysis.IMPORTANCE Clostridioides difficile has become the leading cause of hospital-acquired diarrhea in developed countries. A better understanding of the basic biology of this devastating pathogen might lead to novel approaches for preventing or treating C. difficile infections. Here we introduce new plasmid vectors that allow for titratable induction (P _xyl ) or knockdown (CRISPRi) of gene expression. The CRISPRi plasmid allows for easy depletion of target proteins in C. difficile Besides bypassing the lengthy process of mutant construction, CRISPRi can be used to study the function of essential genes, which are particularly important targets for antibiotic development.

Complex synergistic amino acid-nucleotide interactions contribute to the specificity of NagC operator recognition and induction

NagC is a transcription factor that represses genes involved in N-acetylglucosamine catabolism in Escherichia coli. Repression by NagC is relieved by interaction with GlcNAc6P, the product of transport of GlcNAc into the cell. The DNA-binding domain of NagC contains a classic helix-turn-helix (HTH) motif, but specific operator recognition requires, in addition, an adjacent linker sequence, which is thought to form an extended wing. Sequences in the linker region are required to distinguish NagC-binding sites from those of its paralogue, Mlc. In investigating the contribution of the HTH to operator recognition, we have identified mutations in the first two positions of the recognition helix of the DNA-binding motif of NagC, which change NagC from being a repressor, which binds in the absence of the inducing signal (GlcNAc6P), to one whose binding is enhanced by GlcNAc6P. In this case GlcNAc6P behaves as a co-repressor rather than an inducer for NagC. The NagC mutants exhibiting this paradoxical behaviour have basic amino acids, arginine or lysine, at two critical positions of the recognition helix. Introducing a third amino acid change converts NagC back to a protein, which represses in the absence of GlcNAc6P. The triple mutant also effectively represses a modified NagC operator that is not repressed by wild-type NagC, showing that this form of NagC is a more promiscuous DNA binder. Specific recognition of the NagC operator thus involves a modulation of basic amino acid-DNA interactions, which affects the ability to discriminate against other permissive sites.

Complementation Plasmids, Inducible Gene-Expression Systems, and Reporters for Staphylococci

A cornucopia of methods and molecular tools is available for genetic modification of staphylococci, as shown for at least ten different species to date (Prax et al. Microbiology 159:421-435, 2013). This chapter reviews a number of frequently used vectors for complementation purposes that usually replicate in E. coli and staphylococci and differ in parameters including copy number, mode of replication, and sequence length. Systems for the artificial control of gene expression are described that are modulated by low-molecular-weight effectors such as metal cations, carbohydrates, and antibiotics. Finally, the usefulness of reporter proteins that exhibit enzymatic or autofluorescent characteristics in staphylococci is highlighted.

BadR (BB0693) controls growth phase-dependent induction of rpoS and bosR in Borrelia burgdorferi via recognizing TAAAATAT motifs

In Borrelia burgdorferi (Bb), the alternative sigma factor RpoS plays a central role during Bb's adaptation to ticks and mammals. Previous studies have demonstrated that RpoS is not expressed during the early stages of spirochetal growth or when Bb resides in ticks during the intermolt phase, but the molecular details of these events remain unknown. In the current study, biomagnetic bead separation of rpoS promoter-binding proteins, coupled with genetic inactivation, was employed to identify BadR (BB0693) as a negative regulator that controls growth phase-dependent induction of rpoS and bosR in Bb. When badR was inactivated, the expression of rpoS and bosR was induced only during the early stages of bacterial growth, but not during the stationary growth phase. Recombinant BadR bound to the promoter DNA of rpoS and the regulatory region upstream of bosR via AT-rich TAAAATAT motifs. Mutations in this motif markedly inhibited or abolished rBadR binding. These results suggest that BadR directly influences the expression of both rpoS and bosR in Bb. This newly recognized role for BadR to fine-tune the activation of the RpoN-RpoS pathway at strategic times in Bb's life cycle potentially represents another layer of gene control over σ(54)-dependent gene regulation.

Operator recognition by the ROK transcription factor family members, NagC and Mlc

NagC and Mlc, paralogous members of the ROK family of proteins with almost identical helix-turn-helix DNA binding motifs, specifically regulate genes for transport and utilization of N-acetylglucosamine and glucose. We previously showed that two amino acids in a linker region outside the canonical helix-turn-helix motif are responsible for Mlc site specificity. In this work we identify four amino acids in the linker, which are required for recognition of NagC targets. These amino acids allow Mlc and NagC to distinguish between a C/G and an A/T bp at positions ±11 of the operators. One linker position, glycine in NagC and arginine in Mlc, corresponds to the major specificity determinant for the two proteins. In certain contexts it is possible to switch repression from Mlc-style to NagC-style, by interchanging this glycine and arginine. Secondary determinants are supplied by other linker positions or the helix-turn-helix motif. A wide genomic survey of unique ROK proteins shows that glycine- and arginine-rich sequences are present in the linkers of nearly all ROK family repressors. Conserved short sequence motifs, within the branches of the ROK evolutionary tree, suggest that these sequences could also be involved in operator recognition in other ROK family members.

An update on the molecular genetics toolbox for staphylococci

Staphylococci are Gram-positive spherical bacteria of enormous clinical and biotechnological relevance. Staphylococcus aureus has been extensively studied as a model pathogen. A plethora of methods and molecular tools has been developed for genetic modification of at least ten different staphylococcal species to date. Here we review recent developments of various genetic tools and molecular methods for staphylococcal research, which include reporter systems and vectors for controllable gene expression, gene inactivation, gene essentiality testing, chromosomal integration and transposon delivery. It is furthermore illustrated how mutant strain construction by homologous or site-specific recombination benefits from sophisticated counterselection methods. The underlying genetic components have been shown to operate in wild-type staphylococci or modified chassis strains. Finally, possible future developments in the field of applied Staphylococcus genetics are highlighted.

Sphingobacterium lactis sp. nov. and Sphingobacterium alimentarium sp. nov., isolated from raw milk and a dairy environment

Four non-fermenting, rod-shaped, Gram-staining-negative bacterial strains, designated WCC 4512T, WS 4555, WCC 4521T and WS 4556, were isolated from raw milk and the dairy environment. Phylogenetic analyses based on 16S rRNA and groEL gene sequences demonstrated the affiliation of the four strains to two distinct clusters within the class Sphingobacteriia , phylum ‘ Bacteroidetes ’. Strains WCC 4512T and WS 4555 showed the highest 16S rRNA gene sequence similarity to the type strain of S. daejeonense (97.3 and 97.2 %, respectively), whereas strains WCC 4521T and WS 4556 were most closely related to S. composti LMG 23401T (97.6 % 16S rRNA gene sequence similarity). The DNA G+C contents of strains WCC 4512T and WCC 4521T were 44.2 and 39.3 mol%, respectively. The major cellular fatty acids and the presence of menaquinone MK-7 as the predominant quinone for both strains WCC 4512T and WCC 4521T supported their affiliation to the genus Sphingobacterium . DNA–DNA hybridization experiments between strain WCC 4512T and S. daejeonense LMG 23402T and between strain WCC 4521T and S. composti LMG 23401T revealed DNA relatedness values of 2 % (repetition, 3 %) and 8 % (repetition, 17 %), respectively. On the basis of phenotypic and genetic properties, as well as phylogenetic distinctiveness, it is suggested that the four strains represent two novel Sphingobacterium species with strain WCC 4512T ( = DSM 22361T = LMG 25272T) as the type strain of Sphingobacterium lactis sp. nov. (WS 4555 is a reference strain of S. lactis) and strain WCC 4521T ( = DSM 22362T = LMG 25273T) as the type strain of Sphingobacterium alimentarium sp. nov. (WS 4556 is a reference strain of S. alimentarium).

Metabolic engineering of D-xylose pathway in Clostridium beijerinckii to optimize solvent production from xylose mother liquid

Clostridium beijerinckii is an attractive butanol-producing microbe for its advantage in co-fermenting hexose and pentose sugars. However, this Clostridium strain exhibits undesired efficiency in utilizing D-xylose, one of the major building blocks contained in lignocellulosic materials. Here, we reported a useful metabolic engineering strategy to improve D-xylose consumption by C. beijerinckii. Gene cbei2385, encoding a putative D-xylose repressor XylR, was first disrupted in the C. beijerinckii NCIMB 8052, resulting in a significant increase in D-xylose consumption. A D-xylose proton-symporter (encoded by gene cbei0109) was identified and then overexpressed to further optimize D-xylose utilization, yielding an engineered strain 8052xylR-xylT(ptb) (xylR inactivation plus xylT overexpression driven by ptb promoter). We investigated the strain 8052xylR-xylT(ptb) in fermenting xylose mother liquid, an abundant by-product from industrial-scale xylose preparation from corncob and rich in D-xylose, finally achieving a 35% higher Acetone, Butanol and Ethanol (ABE) solvent titer (16.91 g/L) and a 38% higher yield (0.29 g/g) over those of the wild-type strain. The strategy used in this study enables C. beijerinckii more suitable for butanol production from lignocellulosic materials.

The Thermoanaerobacter glycobiome reveals mechanisms of pentose and hexose co-utilization in bacteria

Thermoanaerobic bacteria are of interest in cellulosic-biofuel production, due to their simultaneous pentose and hexose utilization (co-utilization) and thermophilic nature. In this study, we experimentally reconstructed the structure and dynamics of the first genome-wide carbon utilization network of thermoanaerobes. The network uncovers numerous novel pathways and identifies previously unrecognized but crucial pathway interactions and the associated key junctions. First, glucose, xylose, fructose, and cellobiose catabolism are each featured in distinct functional modules; the transport systems of hexose and pentose are apparently both regulated by transcriptional antiterminators of the BglG family, which is consistent with pentose and hexose co-utilization. Second, glucose and xylose modules cooperate in that the activity of the former promotes the activity of the latter via activating xylose transport and catabolism, while xylose delays cell lysis by sustaining coenzyme and ion metabolism. Third, the vitamin B₁₂ pathway appears to promote ethanologenesis through ethanolamine and 1, 2-propanediol, while the arginine deiminase pathway probably contributes to cell survival in stationary phase. Moreover, by experimentally validating the distinct yet collaborative nature of glucose and xylose catabolism, we demonstrated that these novel network-derived features can be rationally exploited for product-yield enhancement via optimized timing and balanced loading of the carbon supply in a substrate-specific manner. Thus, this thermoanaerobic glycobiome reveals novel genetic features in carbon catabolism that may have immediate industrial implications and provides novel strategies and targets for fermentation and genome engineering.

Renewable liquid fuels derived from lignocellulosic biomass could alleviate global energy shortage and climate change. Cellulose and hemicellulose are the main components of lignocellulosic biomass. Therefore, the ability to simultaneously utilize pentose and hexose (i.e., co-utilization) has been a crucial challenge for industrial microbes producing lignocellulosic biofuels. Certain thermoanaerobic bacteria demonstrate this unusual talent, but the genetic foundation and molecular mechanism of this process remain unknown. In this study, we reconstructed the structure and dynamics of the first genome-wide carbon utilization network of thermoanaerobes. This transcriptome-based co-expression network reveals that glucose, xylose, fructose, and cellobiose catabolism are each featured on distinct functional modules. Furthermore, the dynamics of the network suggests a distinct yet collaborative nature between glucose and xylose catabolism. In addition, we experimentally demonstrated that these novel network-derived features can be rationally exploited for product-yield enhancement via optimized timing and balanced loading of the carbon supply in a substrate-specific manner. Thus, the newly discovered modular and precisely regulated network elucidates unique features of thermoanaerobic glycobiomes and reveals novel perturbation strategies and targets for the enhanced thermophilic production of lignocellulosic biofuels.

Development of a sensitive gene expression reporter system and an inducible promoter-repressor system for Clostridium acetobutylicum

A sensitive gene expression reporter system was developed for Clostridium acetobutylicum ATCC 824 by using a customized gusA expression cassette. In discontinuous cultures, time course profiles of beta-glucuronidase specific activity reflected adequately in vivo dynamic up- and down-regulation of acidogenesis- and/or solventogenesis-associated promoter expression in C. acetobutylicum. Furthermore, a new inducible gene expression system was developed in C. acetobutylicum, based on the Staphylococcus xylosus xylose operon promoter-repressor regulatory system.

Transcriptional regulation of pentose utilisation systems in the Bacillus/Clostridium group of bacteria

In Bacillus subtilis, utilisation of xylose, arabinose and ribose is controlled by the transcriptional factors XylR, AraR and RbsR, respectively. Here we apply the comparative approach to the analysis of these regulons in the Bacillus/Clostridium group. Evolutionary variability of operon structures is demonstrated and operator sites for the main transcription factors are predicted. The consensus sequences for the XylR and RbsR binding sites vary in different subgroups of genomes. The functional coupling of gene clusters and the conservation of regulatory sites allow for detection of non-orthologous gene displacement of ribulose kinase in Enterococcus faecium and Clostridium acetobutylicum. Moreover, candidate catabolite responsive elements found upstream of most pentose-utilising genes suggest CcpA-mediated catabolite repression.

Analysis of catabolite control protein A-dependent repression in Staphylococcus xylosus by a genomic reporter gene system

A single-copy reporter system for Staphylococcus xylosus has been developed, that uses a promoterless version of the endogenous beta-galactosidase gene lacH as a reporter gene and that allows integration of promoters cloned in front of lacH into the lactose utilization gene cluster by homologous recombination. The system was applied to analyze carbon catabolite repression of S. xylosus promoters by the catabolite control protein CcpA. To test if lacH is a suitable reporter gene, beta-galactosidase activities directed by two promoters known to be subject to CcpA regulation were measured. In these experiments, repression of the malRA maltose utilization operon promoter and autoregulation of the ccpA promoters were confirmed, proving the applicability of the system. Subsequently, putative CcpA operators, termed catabolite-responsive elements (cres), from promoter regions of several S. xylosus genes were tested for their ability to confer CcpA regulation upon a constitutive promoter, P(vegII). For that purpose, cre sequences were placed at position +3 or +4 within the transcribed region of P(vegII). Measurements of beta-galactosidase activities in the presence or absence of glucose yielded repression ratios between two- and eightfold. Inactivation of ccpA completely abolished glucose-dependent regulation. Therefore, the tested cres functioned as operator sites for CcpA. With promoters exclusively regulated by CcpA, signal transduction leading to CcpA activation in S. xylosus was examined. Glucose-dependent regulation was measured in a set of isogenic mutants showing defects in genes encoding glucose kinase GlkA, glucose uptake protein GlcU, and HPr kinase HPrK. GlkA and GlcU deficiency diminished glucose-dependent CcpA-mediated repression, but loss of HPr kinase activity abolished regulation. These results clearly show that HPr kinase provides the essential signal to activate CcpA in S. xylosus. Glucose uptake protein GlcU and glucose kinase GlkA participate in activation, but they are not able to trigger CcpA-mediated regulation independently from HPr kinase.

Dissolution of xylose metabolism in Lactococcus lactis

Xylose metabolism, a variable phenotype in strains of Lactococcus lactis, was studied and evidence was obtained for the accumulation of mutations that inactivate the xyl operon. The xylose metabolism operon (xylRAB) was sequenced from three strains of lactococci. Fragments of 4.2, 4.2, and 5.4 kb that included the xyl locus were sequenced from L. lactis subsp. lactis B-4449 (formerly Lactobacillus xylosus), L. lactis subsp. lactis IO-1, and L. lactis subsp. lactis 210, respectively. The two environmental isolates, L. lactis B-4449 and L. lactis IO-1, produce active xylose isomerases and xylulokinases and can metabolize xylose. L. lactis 210, a dairy starter culture strain, has neither xylose isomerase nor xylulokinase activity and is Xyl(-). Xylose isomerase and xylulokinase activities are induced by xylose and repressed by glucose in the two Xyl(+) strains. Sequence comparisons revealed a number of point mutations in the xylA, xylB, and xylR genes in L. lactis 210, IO-1, and B-4449. None of these mutations, with the exception of a premature stop codon in xylB, are obviously lethal, since they lie outside of regions recognized as critical for activity. Nevertheless, either cumulatively or because of indirect affects on the structures of catalytic sites, these mutations render some strains of L. lactis unable to metabolize xylose.

Molecular cloning and functional expression in lactobacillus plantarum 80 of xylT, encoding the D-xylose-H+ symporter of Lactobacillus brevis

A 3-kb region, located downstream of the Lactobacillus brevis xylA gene (encoding D-xylose isomerase), was cloned in Escherichia coli TG1. The sequence revealed two open reading frames which could code for the D-xylulose kinase gene (xylB) and another gene (xylT) encoding a protein of 457 amino acids with significant similarity to the D-xylose-H+ symporters of E. coli, XylE (57%), and Bacillus megaterium, XylT (58%), to the D-xylose-Na+ symporter of Tetragenococcus halophila, XylE (57%), and to the L-arabinose-H+ symporter of E. coli, AraE (60%). The L. brevis xylABT genes showed an arrangement similar to that of the B. megaterium xylABT operon and the T. halophila xylABE operon. Southern hybridization performed with the Lactobacillus pentosus xylR gene (encoding the D-xylose repressor protein) as a probe revealed the existence of a xylR homologue in L. brevis which is not located with the xyABT locus. The existence of a functional XylR was further suggested by the presence of xylO sequences upstream of xylA and xylT and by the requirement of D-xylose for the induction of D-xylose isomerase, D-xylulose kinase, and D-xylose transport activities in L. brevis. When L. brevis was cultivated in a mixture of D-glucose and D-xylose, the D-xylose isomerase and D-xylulose kinase activities were reduced fourfold and the D-xylose transport activity was reduced by sixfold, suggesting catabolite repression by D-glucose of D-xylose assimilation. The xylT gene was functionally expressed in Lactobacillus plantarum 80, a strain which lacks proton motive force-linked D-xylose transport activity. The role of the XylT protein was confirmed by the accumulation of D-xylose in L. plantarum 80 cells, and this accumulation was dependent on the proton motive force generated by either malolactic fermentation or by the metabolism of D-glucose. The apparent affinity constant of XylT for D-xylose was approximately 215 microM, and the maximal initial velocity of transport was 35 nmol/min per mg (dry weight). Furthermore, of a number of sugars tested, only 6-deoxy-D-glucose inhibited the transport of D-xylose by XylT competitively, with a Ki of 220 microM.

The D-xylose-binding protein, XylF, from Thermoanaerobacter ethanolicus 39E: cloning, molecular analysis, and expression of the structural gene

Immediately downstream from the Thermoanaerobacter ethanolicus xylAB operon, comprising genes that encode D-xylose isomerase and D-xylulose kinase, lies a 1,101-bp open reading frame that exhibits 61% amino acid sequence identity to the Escherichia coli D-xylose binding periplasmic receptor, XylF, a component of the high-affinity binding-protein-dependent D-xylose transport. The 25-residue N-terminal fragment of the deduced T. ethanolicus XylF has typical features of bacterial leader peptides. The C-terminal portion of this leader sequence matches the cleavage consensus for lipoproteins and is followed by a 22-residue putative linker sequence rich in serine, threonine, and asparagine. The putative mature 341-amino-acid-residue XylF (calculated molecular mass of 37,069 Da) appears to be a lipoprotein attached to the cell membrane via a lipid anchor covalently linked to the N-terminal cysteine, as demonstrated by metabolic labelling of the recombinant XylF with [14C]palmitate. The induced E. coli avidly bound D-[14C]xylose, yielding additional evidence that T. ethanolicus XylF is the D-xylose-binding protein. On the basis of sequence comparison of XylFs to other monosaccharide-binding proteins, we propose that the sequence signature of binding proteins specific for hexoses and pentoses be refined as (KDQ)(LIVFAG)3IX3(DN)(SGP)X3(GS)X(LIVA) 2X2A. Transcription of the monocistronic 1.3-kb xylF mRNA is inducible by xylose and unaffected by glucose. Primer extension analysis indicated that xylF transcription initiates from two +1 sites, both situated within the xylAB operon. Unlike in similar transport systems in other bacteria, the genes specifying the membrane components (e.g., ATP-binding protein and permease) of the high-affinity D-xylose uptake system are not located in the vicinity of xylF in T. ethanolicus. This is the first report of a gene encoding a xylose-binding protein in a gram-positive or thermophilic bacterium.

Regulation of lactose utilization genes in Staphylococcus xylosus

The lactose utilization genes of Staphylococcus xylosus have been isolated and characterized. The system is comprised of two structural genes, lacP and lacH, encoding the lactose permease and the beta-galactosidase proteins, respectively, and a regulatory gene, lacR, coding for an activator of the AraC/XylS family. The lactose utilization genes are divergently arranged, the lacPH genes being opposite to lacR. The lacPH genes are cotranscribed from one promoter in front of lacP, whereas lacR is transcribed from two promoters of different strengths. Lactose transport as well as beta-galactosidase activity are inducible by the addition of lactose to the growth medium. Primer extension experiments demonstrated that regulation is achieved at the level of lacPH transcription initiation. Inducibility and efficient lacPH transcription are dependent on a functional lacR gene. Inactivation of lacR resulted in low and constitutive lacPH expression. Expression of lacR itself is practically constitutive, since transcription initiated at the major lacR promoter does not respond to the availability of lactose. Only the minor lacR promoter is lactose inducible. Apart from lactose-specific, LacR-dependent control, the lacPH promoter is also subject to carbon catabolite repression mediated by the catabolite control protein CcpA. When glucose is present in the growth medium, lacPH transcription initiation is reduced. Upon ccpA inactivation, repression at the lacPH promoter is relieved. Despite this loss of transcriptional regulation in the ccpA mutant strain, beta-galactosidase activity is still reduced by glucose, suggesting another level of control.

Cloning and characterization of transcription of the xylAB operon in Thermoanaerobacter ethanolicus

The genes encoding xylose isomerase (xylA) and xylulose kinase (xylB) from the thermophilic anaerobe Thermoanaerobacter ethanolicus were found to constitute an operon with the transcription initiation site 169 nucleotides upstream from the previously assigned (K. Dekker, H. Yamagata, K. Sakaguchi, and S. Udaka, Agric. Biol. Chem. 55:221-227, 1991) promoter region. The bicistronic xylAB mRNA was processed by cleavage within the 5'-terminal portion of the XylB-coding sequence. Transcription of xylAB was induced in the presence of xylose, and, unlike in all other xylose-utilizing bacteria studied, was not repressed by glucose. The existence of putative xyl operator sequences suggested that xylose utilization is controlled by a repressor-operator mechanism. The T. ethanolicus xylB gene coded for a 500-amino-acid-residue protein with a deduced amino acid sequence highly homologous to those of other XylBs. This is the first report of an xylB nucleotide sequence and an xyLAB operon from a thermophilic anaerobic bacterium.

Organization and regulation of the D-xylose operons in Escherichia coli K-12: XylR acts as a transcriptional activator

The metabolism of D-xylose in Escherichia coli K-12 is known to be mediated by the xylAB gene. However, the nearby xylFGHR genes were found by genome sequencing and predicted to be responsible for transport and regulation for xylose based on their sequence similarities to other functionally related genes. Here, we investigated transcriptional organization and functions of the xyl genes. An analysis with random transposon insertions revealed that the xyl genes are organized into two major transcriptional units, xylAB and xylFGHR, governed by the promoters PA and PF, respectively. However, there is an additional weak promoter, PR, which is specific for xylR. Sites of transcription initiation were determined by primer extension analysis. When studied with operon fusions to lacZ, the PA and PF promoters were activated by D-xylose and repressed by glucose. In contrast, the PR promoter was not regulated by these sugars. A mutation in xylR completely abolished expression from the PA and PF promoters, causing a defect in both growth and transport. Binding of XylR to the xyl promoter was enhanced by the presence of D-xylose, suggesting that transcription was positively regulated by XylR. In vivo footprinting analysis revealed that XylR binds to at least two DNA regions, IA and IF, each with a direct repeat. It is very likely that XylR interacts with IA and IF as a dimer. The presumed binding sites are located just upstream of the promoter consensus sequences (-35), while IA is additionally flanked by a cyclic AMP receptor protein-binding site on the other side. The proposed structure of xyl promoters is consistent with the regulation of xyl gene expression and with phenotypes of transposon insertions obtained in the promoter regions.

Expression systems for industrial Gram-positive bacteria with low guanine and cytosine content

Recent years have seen an increase in the development of gene expression systems for industrial Gram-positive bacteria with low guanine and cytosine content that belong to the genera Bacillus, Clostridium, Lactococcus, Lactobacillus, Staphylococcus and Streptococcus. In particular, considerable advances have been made in the construction of inducible gene expression systems based on the capacity of these bacteria to utilize specific sugars or to secrete autoinducing peptides that are involved in quorum sensing. These controlled expression systems allow for present and future exploitation of these bacteria as cell factories in medical, agricultural, and food biotechnology.

Regulation of expression of the Lactobacillus pentosus xylAB operon

The xylose cluster of Lactobacillus pentosus consists of five genes, two of which, xylAB, form an operon and code for the enzymes involved in the catabolism of xylose, while a third encodes a regulatory protein, XylR. By introduction of a multicopy plasmid carrying the xyl operator and by disruption of the chromosomal xylR gene, it was shown that L. pentosus xylR encodes a repressor. Constitutive expression of xylAB in the xylR mutant is repressed by glucose, indicating that glucose repression does not require XylR. The xylR mutant displayed a prolonged lag phase compared to wild-type bacteria when bacteria were shifted from glucose to xylose medium. Differences in the growth rate in xylose medium at different stages of growth are not correlated with differences in levels of xylAB transcription in L. pentosus wild-type or xylR mutant bacteria but are positively correlated in Lactobacillus casei with a plasmid containing xylAB. Glucose repression was further investigated with a ccpA mutant. An 875-bp internal fragment of the ccpA gene of L. pentosus was isolated by PCR and used to construct a ccpA knockout mutant. Transcription analysis of L. pentosus xylA showed that CcpA is involved in glucose repression. CcpA was also shown to be involved in glucose repression of the alpha-amylase promoter of Lactobacillus amylovorus by demonstrating that glucose repression of the chloramphenicol acetyltransferase gene under control of the alpha-amylase promoter is strongly reduced in the L. pentosus ccpA mutant strain.

Expression of the tre operon of Bacillus subtilis 168 is regulated by the repressor TreR

The tre locus from Bacillus subtilis containing the genes treP, treA, and treR has been analyzed for its regulation. We demonstrate that at least treP and treA form an operon whose expression is regulated at the transcriptional level. TreR activity has been investigated in in vivo and in vitro studies. An insertional inactivation of treR led to a constitutive expression of treP and treA. Upstream of treP we identified a 248-bp DNA fragment containing a potential sigmaA-dependent promoter and two palindromes reflecting potential tre operators which led to complex formation with TreR-containing protein extracts in DNA retardation experiments. This complex formation is abolished in the presence of trehalose-6-phosphate, which probably acts as an inducer. Therefore, we assume that treR encodes the specific Tre repressor involved in regulation of the expression of the tre operon.

Molecular and industrial aspects of glucose isomerase

Glucose isomerase (GI) (D-xylose ketol-isomerase; EC. 5.3.1.5) catalyzes the reversible isomerization of D-glucose and D-xylose to D-fructose and D-xylulose, respectively. The enzyme has the largest market in the food industry because of its application in the production of high-fructose corn syrup (HFCS). HFCS, an equilibrium mixture of glucose and fructose, is 1.3 times sweeter than sucrose and serves as a sweetener for use by diabetics. Interconversion of xylose to xylulose by GI serves a nutritional requirement in saprophytic bacteria and has a potential application in the bioconversion of hemicellulose to ethanol. The enzyme is widely distributed in prokaryotes. Intensive research efforts are directed toward improving its suitability for industrial application. Development of microbial strains capable of utilizing xylan-containing raw materials for growth or screening for constitutive mutants of GI is expected to lead to discontinuation of the use of xylose as an inducer for the production of the enzyme. Elimination of Co2+ from the fermentation medium is desirable for avoiding health problems arising from human consumption of HFCS. Immobilization of GI provides an efficient means for its easy recovery and reuse and lowers the cost of its use. X-ray crystallographic and genetic engineering studies support a hydride shift mechanism for the action of GI. Cloning of GI in homologous as well as heterologous hosts has been carried out, with the prime aim of overproducing the enzyme and deciphering the genetic organization of individual genes (xylA, xylB, and xylR) in the xyl operon of different microorganisms. The organization of xylA and xylB seems to be highly conserved in all bacteria. The two genes are transcribed from the same strand in Escherichia coli and Bacillus and Lactobacillus species, whereas they are transcribed divergently on different strands in Streptomyces species. A comparison of the xylA sequences from several bacterial sources revealed the presence of two signature sequences, VXW(GP)GREG(YSTAE)E and (LIVM)EPKPX(EQ)P. The use of an inexpensive inducer in the fermentation medium devoid of Co2+ and redesigning of a tailor-made GI with increased thermostability, higher affinity for glucose, and lower pH optimum will contribute significantly to the development of an economically feasible commercial process for enzymatic isomerization of glucose to fructose. Manipulation of the GI gene by site-directed mutagenesis holds promise that a GI suitable for biotechnological applications will be produced in the foreseeable future.

Molecular and industrial aspects of glucose isomerase

Glucose isomerase (GI) (D-xylose ketol-isomerase; EC. 5.3.1.5) catalyzes the reversible isomerization of D-glucose and D-xylose to D-fructose and D-xylulose, respectively. The enzyme has the largest market in the food industry because of its application in the production of high-fructose corn syrup (HFCS). HFCS, an equilibrium mixture of glucose and fructose, is 1.3 times sweeter than sucrose and serves as a sweetener for use by diabetics. Interconversion of xylose to xylulose by GI serves a nutritional requirement in saprophytic bacteria and has a potential application in the bioconversion of hemicellulose to ethanol. The enzyme is widely distributed in prokaryotes. Intensive research efforts are directed toward improving its suitability for industrial application. Development of microbial strains capable of utilizing xylan-containing raw materials for growth or screening for constitutive mutants of GI is expected to lead to discontinuation of the use of xylose as an inducer for the production of the enzyme. Elimination of Co2+ from the fermentation medium is desirable for avoiding health problems arising from human consumption of HFCS. Immobilization of GI provides an efficient means for its easy recovery and reuse and lowers the cost of its use. X-ray crystallographic and genetic engineering studies support a hydride shift mechanism for the action of GI. Cloning of GI in homologous as well as heterologous hosts has been carried out, with the prime aim of overproducing the enzyme and deciphering the genetic organization of individual genes (xylA, xylB, and xylR) in the xyl operon of different microorganisms. The organization of xylA and xylB seems to be highly conserved in all bacteria. The two genes are transcribed from the same strand in Escherichia coli and Bacillus and Lactobacillus species, whereas they are transcribed divergently on different strands in Streptomyces species. A comparison of the xylA sequences from several bacterial sources revealed the presence of two signature sequences, VXW(GP)GREG(YSTAE)E and (LIVM)EPKPX(EQ)P. The use of an inexpensive inducer in the fermentation medium devoid of Co2+ and redesigning of a tailor-made GI with increased thermostability, higher affinity for glucose, and lower pH optimum will contribute significantly to the development of an economically feasible commercial process for enzymatic isomerization of glucose to fructose. Manipulation of the GI gene by site-directed mutagenesis holds promise that a GI suitable for biotechnological applications will be produced in the foreseeable future.

Catabolite repression and inducer control in Gram-positive bacteria

Results currently available clearly indicate that the metabolite-activated protein kinase-mediated phosphorylation of Ser-46 in HPr plays a key role in catabolite repression and the control of inducer levels in low-GC Gram-positive bacteria. This protein kinase is not found in enteric bacteria such as E. coli and Salmonella typhimurium where an entirely different PTS-mediated regulatory mechanism is responsible for catabolite repression and inducer concentration control. In Table 2 these two mechanistically dissimilar but functionally related processes are compared (Saier et al., 1995b). In Gram-negative enteric bacteria, an external sugar is sensed by the sugar-recognition constituent of an Enzyme II complex of the PTS (IIC), and a dephosphorylating signal is transmitted via the Enzyme IIB/HPr proteins to the central regulatory protein, IIAGlc. Targets regulated include (1) permeases specific for lactose, maltose, melibiose and raffinose, (2) catabolic enzymes such as glycerol kinase that generate cytoplasmic inducers, and (3) the cAMP biosynthetic enzyme, adenylate cyclase that mediates catabolite repression (Saier, 1989, 1993). In low-GC Gram-positive bacteria, cytoplasmic phosphorylated sugar metabolites are sensed by the HPr kinase which is allostericlaly activated. HPr becomes phosphorylated on Ser-46, and this phosphorylated derivative regulates the activities of its target proteins. These targets include (1) the PTS, (2) non-PTS permeases (both of which are inhibited) and (3) a cytoplasmic sugar-P phosphatase which is activated to reduce cytoplasmic inducer levels. Other important targets of HPr(ser-P) action are (4) the CcpA protein and probably (5) the CepB transcription factor. These two proteins together are believed to determine the intensity of catabolite repression. Their relative importance depends on physiological conditions. Both proteins may respond to the cytoplasmic concentration of HPr(ser-P) and appropriate metabolites. CepA possibly binds sugar metabolites such as FBP as well as HPr(ser-P). Because HPr(his-P, ser-P) does not bind to CepA, the regulatory cascade is also sensitive to the external PTS sugar concentration. Mutational analyses (unpublished results) suggest that CepA may bind to a site that includes His-15. Interestingly, both the CepA protein in the Gram-positive bacterium, B. subtilis, and glycerol kinase in the Gram-negative bacterium, E. coli, sense both a PTS protein and a cytoplasmic metabolic intermediate. The same may be true of target permeases and enzymes in both types of organisms, but this possibility has not yet been tested. The parallels between the Gram-negative and Gram-positive bacterial regulatory systems are superficial at the mechanistic level but fundamental at the functional level. Thus, the PTS participates in regulation in both cases, and phosphorylation of its protein constituents plays key roles. However, the stimuli sensed, the transmission mechanisms, the central PTS regulatory proteins that effect allosteric regulation, and some of the target proteins are completely different. It seems clear that these two transmission mechanisms evolved independently. They provide a prime example of functional convergence.

Glucose and glucose-6-phosphate interaction with Xyl repressor proteins from Bacillus spp. may contribute to regulation of xylose utilization

The xyl operons of several gram-positive bacteria are regulated at the level of transcription by xylose-responsive repressor proteins (XylR). In addition, they are catabolite repressed. Here, we describe a mechanism by which glucose metabolism can affect both regulatory mechanisms. Glucose-6-phosphate appeared to be an anti-inducer of xyl operon transcription, since it could compete with xylose in interaction in vitro with XylR from Bacillus subtilis, B. megaterium, and B. licheniformis. On the other hand, glucose was a low-efficiency inactivator of XylR from B. subtilis and B. megaterium and a weak anti-inducer of XylR from B. licheniformis. Thus, the chemical nature of the substituent at C-5 of xylose and the primary structure of XylR determine the effect of these compounds on xyl operon transcription.

Extracellular expression of native human anti-lysozyme fragments in Staphylococcus carnosus

Xylose-inducible vectors have been constructed for extracellular production of antibody fragments in Staphylococcus carnosus. The pre-pro sequence of S. hyicus lipase was taken as secretional signal sequence, and the S. xylosus Xyl repressor was used to confer xylose inducibility of transcription. Cleavage sites for the IgA protease were engineered between the pre-pro sequence and the antibody fragments to permit removal of the pro sequence. Extracellular expression of the light chain and the Fd fragment of a chimeric Fab fragment containing the variable regions of the anti-lysozyme antibody D1.3 was achieved with these vectors. The pro sequence could be removed from the expression product by IgA protease treatment. When the light chain and the Fd fragment were co-secreted as a protein fusion they accumulated in a structure capable of heterodimerization after IgA cleavage. This fusion contains the pre-pro sequence followed by the light chain, a second IgA site and the Fd fragment.

A promoter-screening plasmid and xylose-inducible, glucose-repressible expression vectors for Staphylococcus carnosus

We describe a series of plasmid vectors for DNA cloning in staphylococci. pPS11 is a promoter probe plasmid containing a promoterless lipase (Lip)-encoding gene (lip). Insertion of a promoter-bearing DNA fragment at the single BamHI site turns on lip expression. Lip activity can be easily determined to estimate the strength of the inserted promoter. pPS11 served also as a basis for the construction of vectors which allow xylose-inducible gene expression in Staphylococcus carnosus (Sc). Using plasmid pCX15, we studied xylose-inducible lip expression in Sc. The lip expression is under transcriptional control of the repressor, XylR. The xylR gene, the XylR target sequence and the xylA promoter/operator sequence with the cis-acting catabolite-responsive element (cre) are derived from the xyl operon of S. xylosus. The single BamHI site in front of the lip ribosome-binding site (RBS) also makes it possible to put other promoterless genes under transcriptional control of XylR. To facilitate the controlled expression of genes which merely start with the start codon and have no RBS, or to insert genes with their own RBS, pCX26 and pCX26 delta lip were constructed. The influence of xylose and glucose on lip expression was studied both in a batch culture and in a fermentor under controlled pH conditions. With pCX15, the presence of xylose led to a 40-fold increase in extracellular Lip activity, while the presence of glucose caused a repression of lip expression. The results suggest that the xylA promoter is subject to two different regulatory mechanisms, one of which involves the repression of the xylA promoter by XylR in the absence of xylose, and the other involves a glucose-mediated catabolite repression which dominates over the xylose induction.

Promoter analysis and transcriptional regulation of Lactobacillus pentosus genes involved in xylose catabolism

The xyl genes in Lactobacillus pentosus are induced by xylose and repressed by glucose, ribose, and arabinose. Northern blot analysis showed that regulation is mediated at the transcriptional level. Under inducing conditions, two xylA transcripts were detected, a major transcript of 1.5 kb and a minor transcript of 3 kb. The 3 kb transcript also comprises sequences from xylB, suggesting that xylA and xylB are transcribed together. A 1.2 kb xylR transcript was found under inducing and non-inducing conditions. In the presence of xylose, a second xylR transcript (> 7 kb) was detected, which includes sequences from two upstream genes, xylQ and xylP. The transcription start sites for xylA and xylR were mapped by primer extension and S1 nuclease experiments at 42 and 83 nucleotides, respectively upstream of the translation start sites. Induction by xylose of the chloramphenicol acetyltransferase (CAT) gene under control of the xylA promoter, on a multicopy plasmid, was 60 to 80-fold, but only 3 to 10-fold in the presence of glucose and xylose. Expression of CAT under control of the xylR promoter was constitutive at a level tenfold less than that observed under control of the xylA promoter. Sequence analysis suggests the presence of two operator-like elements, one overlapping with the promoter -35 region of xylA and controlling the expression of xylA by binding factors involved in catabolite repression, and a second operator downstream of the promoter -10 region of xylA, which may bind the product of xylR, the repressor.(ABSTRACT TRUNCATED AT 250 WORDS)

Analysis of a cis-active sequence mediating catabolite repression in gram-positive bacteria

One form of catabolite repression (CR) in the Gram-positive genus, Bacillus, is mediated by a cis-acting element (CRE). We use here a consensus sequence to identify such elements in sequenced genes of Gram-positive bacteria. These are analysed with respect to position and type of gene in which they occur. CRE sequences near the promoter region are mainly identified in genes encoding carbon catabolic enzymes, which are thus likely to be subject to CR by a global mechanism. Functional aspects of CREs are evaluated.

Regulation of xylose utilization in Bacillus licheniformis: Xyl repressor-xyl-operator interaction studied by DNA modification protection and interference

Xylose utilization in Bacillus licheniformis is inducible by xylose. We establish here that the Xyl repressor recognizes and binds an xyl operator sequence located 12 nucleotides downstream from the transcription start site of the xyl operon. DNA-retardation experiments employing xyl regulatory DNA and soluble protein extracts indicate complex formation in the presence of Xyl repressor. Two repressor-operator complexes are distinguished by different gel mobilities. They yield the same in situ copper-phenanthroline footprint. This result suggests that a single xyl operator may be bound by different oligomers of Xyl repressor. Methylation and hydroxyl radical cleavage protection of the xyl operator by Xyl repressor binding and ethylation interference of Xyl repressor binding to the xyl operator reveals symmetrical interaction of the repressor with two half sites of the operator, which show palindromic symmetry and are located on the same side of the B-form DNA structure.

Substrate induction and catabolite repression of the Streptomyces coelicolor glycerol operon are mediated through the GylR protein

The pathway for glycerol catabolism in Streptomyces coelicolor is determined by the gylCABX operon, which is transcribed from two closely spaced glycerol-inducible, glucose-repressible promoters. Glucose (or catabolite) repression of gyl is known to be exerted by a general catabolite repression system in which the soluble glucose kinase plays a central role. The gylR gene is contained in a separate glycerol-inducible, weakly glucose-repressible transcription unit immediately upstream from the gyl operon. The role of gylR in the regulation of gyl transcription was assessed by introducing specific null mutations into the chromosomal gylR gene. Direct quantification of gyl transcripts from the gylR null mutants grown on different carbon sources demonstrated that GylR is the repressor of the gylCABX operon and also revealed that GylR functions as a negative autoregulator. Moreover, the transcriptional analysis revealed that the gylR null mutants were relieved of glucose repression of both gylCABX and gylR. We conclude that both substrate induction and catabolite repression of gyl are mediated through the GylR protein. This is the first direct evidence that catabolite repression in Streptomyces is not exerted at the transcriptional level by a general 'catabolite repressor protein'. Models for catabolite repression are discussed.

Catabolite repression of the Bacillus subtilis xyl operon involves a cis element functional in the context of an unrelated sequence, and glucose exerts additional xylR-dependent repression

Catabolite repression (CR) of xylose utilization by Bacillus subtilis involves a 14-bp cis-acting element (CRE) located in the translated region of the gene encoding xylose isomerase (xylA). Mutations of CRE making it more similar to a previously proposed consensus element lead to increased CR exerted by glucose, fructose, and glycerol. Fusion of CRE to an unrelated, constitutive promoter confers CR to beta-galactosidase expression directed by that promoter. This result demonstrates that CRE can function independently of sequence context and suggests that it is indeed a generally active cis element for CR. In contrast to the other carbon sources studied here, glucose leads to an additional repression of xylA expression, which is independent of CRE and is not found when CRE is fused to the unrelated promoter. This repression requires a functional xylR encoding Xyl repressor and is dependent on the concentrations of glucose and the inducer xylose in the culture broth. Potential mechanisms for this glucose-specific repression are discussed.

Binding of ArsR, the repressor of the Staphylococcus xylosus (pSX267) arsenic resistance operon to a sequence with dyad symmetry within the ars promoter

arsR, the first gene of the Staphylococcus xylosus (pSX267) arsenic/antimonite resistance (ars) operon encodes a negative regulatory protein, ArsR, which mediates inducibility of the resistances by arsenic and antimony compounds. ArsR, which has no obvious DNA-binding motif in its primary structure, was purified from an ArsR-overproducing Escherichia coli strain and identified as a DNA-binding protein by its behaviour in gel mobility shift assays. ArsR had a specific affinity for a 312 bp DNA restriction fragment carrying the ars promoter; the minimum sequence complexed by ArsR was a 75 bp polymerase chain reaction (PCR) fragment, which mainly comprised the -35 and -10 regions of the promoter. The effect of inducers on the DNA-binding activity of ArsR was examined by in vitro induction assays; only arsenite inhibited DNA-binding of the repressor. DNase I footprinting revealed two protected regions within the promoter region, spanning 23 and 9 nucleotides, respectively. Furthermore, a new cleavage site for DNase I between the protected regions was made accessible by binding of the repressor. The footprints cover a region of three inverted repeats located between the -35 and -10 motifs of the ars promoter. By high resolution footprinting with the hydroxy radical, five sites of close contact between the protein and DNA were identified.

Phosphoenolpyruvate:carbohydrate phosphotransferase systems of bacteria

Numerous gram-negative and gram-positive bacteria take up carbohydrates through the phosphoenolpyruvate (PEP):carbohydrate phosphotransferase system (PTS). This system transports and phosphorylates carbohydrates at the expense of PEP and is the subject of this review. The PTS consists of two general proteins, enzyme I and HPr, and a number of carbohydrate-specific enzymes, the enzymes II. PTS proteins are phosphoproteins in which the phospho group is attached to either a histidine residue or, in a number of cases, a cysteine residue. After phosphorylation of enzyme I by PEP, the phospho group is transferred to HPr. The enzymes II are required for the transport of the carbohydrates across the membrane and the transfer of the phospho group from phospho-HPr to the carbohydrates. Biochemical, structural, and molecular genetic studies have shown that the various enzymes II have the same basic structure. Each enzyme II consists of domains for specific functions, e.g., binding of the carbohydrate or phosphorylation. Each enzyme II complex can consist of one to four different polypeptides. The enzymes II can be placed into at least four classes on the basis of sequence similarity. The genetics of the PTS is complex, and the expression of PTS proteins is intricately regulated because of the central roles of these proteins in nutrient acquisition. In addition to classical induction-repression mechanisms involving repressor and activator proteins, other types of regulation, such as antitermination, have been observed in some PTSs. Apart from their role in carbohydrate transport, PTS proteins are involved in chemotaxis toward PTS carbohydrates. Furthermore, the IIAGlc protein, part of the glucose-specific PTS, is a central regulatory protein which in its nonphosphorylated form can bind to and inhibit several non-PTS uptake systems and thus prevent entry of inducers. In its phosphorylated form, P-IIAGlc is involved in the activation of adenylate cyclase and thus in the regulation of gene expression. By sensing the presence of PTS carbohydrates in the medium and adjusting the phosphorylation state of IIAGlc, cells can adapt quickly to changing conditions in the environment. In gram-positive bacteria, it has been demonstrated that HPr can be phosphorylated by ATP on a serine residue and this modification may perform a regulatory function.

Regulation of epidermin biosynthetic genes by EpiQ

We investigated the role of epiQ in the biosynthesis of the lantibiotic epidermin. epiQ was essential for epidermin production. It was shown that EpiQ controls epidermin production by transcriptionally activating the epiA promoter, used for transcription of most of the epidermin biosynthetic genes. Additional copies of epiQ increased epidermin production in the epidermin-producing wild-type strain Staphylococcus epidermidis Tü3298. The epiA promoter region was characterized by primer extension analysis. Two inverted repeats, putative operator sites for EpiQ binding, are located upstream of the -35 region and one is localized downstream of the -10 region. Crude protein extracts from S. epidermidis Tü3298 and epiQ expressing Escherichia coli cells led to gel mobility shifts of a DNA fragment bearing the inverted repeat which is located immediately upstream of the -35 region. DNA fragments bearing the other two inverted repeats were not shifted. The epiQ gene product could be detected by overexpression in the E. coli T7 system using antiserum raised against synthetic peptides of EpiQ. Furthermore, EpiQ, like other DNA-binding proteins, was shown to bind strongly to heparin sepharose.

Using fusions with luxAB from Vibrio harveyi MAV to quantify induction and catabolite repression of the xyl operon in Staphylococcus carnosus TM300

The luxA,B genes from the Gram-negative marine bacterium Vibrio harveyi MAV were used in Staphylococcus carnosus TM300 as a reporter system for regulated expression of xylose utilization. The luciferase genes were fused to the xyl operon from Staphylococcus xylosus C2a. Expression of bioluminescence was induced through addition of xylose and repressed in the presence of glucose. A method to quantitate bioluminescence directly from the culture is described.