Characterization of Polysaccharide Biosynthesis, Structure and Regulation in Vibrio vulnificus

Nakhamchik, Alina

20 January 2009

Vibrio vulnificus are marine bacteria causing fatal septicemia through wound infections or consumption of contaminated seafood. V. vulnificus is an excellent model for the study of surface polysaccharides, as it is capable of synthesizing capsular polysaccharide (CPS), lipopolysaccharide (LPS) and exopolysaccharide (EPS). V. vulnificus strains exhibit a multitude of carbotypes that evolve through unknown mechanisms. CPS is a confirmed virulence factor, but the genetics of its biosynthesis are unknown. The main objective of these experiments was to gain insight into the biosynthesis, regulation and evolution of ATCC 27562 outer surface polysaccharides. A miniTn10 transposon (Tn) system was used for mutagenesis and single insertions were confirmed through Southern analysis. A novel 25 kb CPS biosynthesis locus was identified through sequencing of regions surrounding Tn insertions; a region encoding putative LPS core biosynthetic functions was identified adjacent to the CPS cluster. The CPS locus contained features of O-antigen biosynthetic loci and was unusual in carrying characteristics of both group I and IV capsular biosynthetic loci. Mutations in this region resulted in elimination of CPS and LPS, and both were shown to be dependent on the activity of the polymerase Wzy. Evidence is presented here supporting horizontal transfer (HT) as a contributor to V. vulnificus CPS evolution. CPS regions of V. vulnificus 27562, YJ016 and CMCP6 contain strain specific genes surrounded by conserved regions, suggestive of HT. Moreover, a CPS locus virtually identical to that of 27562 was discovered in Shewanella putrefaciens strain 200. 27562 CPS is distinctive as it contains N-acetylmuramic acid. Genes encoding murA and murB activities were identified within the cluster and shown to be functionally redundant, supporting HT acquisition of this region. A screen of V. vulnificus gDNA library using CPS biosynthesis and transport mutants identified a cyclic diguanylate cyclase, dcpA. dcpA-mediated increase in cyclic diguanylate lead to EPS production, rugosity phenotypes and enhanced biofilm formation. Interestingly, virulence and motility were not affected suggesting complexity of cyclic diguanylate regulation in V. vulnificus, supported by the large number of cyclic diguanylate related proteins in Vulnificus strains.

Polysaccharide biosynthesis

Vibrio vulnificus

virulence factors

capsule

lipopolysaccharide

cyclic diguanylate

horizontal gene transfer

0410

0307

0369

Cloning And Characterization Of Streptomyces Clavuligerus Meso-diaminopimelate Decarboxylase (lysa) Gene

Yagcioglu, Cigdem

01 September 2004

In Streptomyces clavuligerus, the route to the biosynthesis of &amp / #945 / -aminoadipic acid (&amp / #945 / -AAA) represents an important primary metabolic pathway providing carbon flux to the synthetases of antibiotic formation. This carbon flow comes through the lysine-specific branch of the aspartate pathway and is rate limiting in the formation of cephamycin C, a second generation cephalosporin produced by this organism. In this study, the lysA gene which encodes for an important key enzyme of aspartate pathway / meso-diaminopimelic acid (DAP) decarboxylase (E.C.4.1.1.20) catalyzing the conversion of diaminopimelate to lysine was cloned and characterized for the first time from S. clavuligerus NRRL 3585. The attempts to clone the gene by constructing libraries of S. clavuligerus genomic DNA and screening of the libraries either by homologous probing or complementation approach gave no positive results. Then, PCR-based cloning was taken as the approach and the gene was amplified with PCR using the primers derived from the conserved sequences of lysA genes in two fragments (620 and 983 bp) which had overlapping regions. Fragments were then cloned and nucleotide sequencing revealed a complete open reading frame (ORF) encoding a protein of 463 aa (Mr 49, 907). The GC content of the gene was identified as 70.98 %. The gene sequence showed 83 % identity to the sequence of S. coelicolor lysA gene and 81 % identity to S. avermitilis lysA gene. By comparing the amino acid sequence of this protein to those available in database, the sites of the enzyme important for catalysis were identified.

QR Bacteria 75-99.5

Streptomyces clavuligerus

Gene cloning

DAP decarboxylase

Cephamycin C, antibiotic biosynthesis.

Effect Of Homologous Multiple Copies Of Aspartokinase Gene On Cephamycin C Biosynthesis In Streptomyces Clavuligerus

Taskin, Bilgin

01 September 2005

Streptomyces clavuligerus is a gram-positive filamentous bacterium well known for its ability to produce an array of &amp / #61538 / -lactam compounds (secondary metabolites) including cephamycin C, clavulanic acid and other structurally related clavams. Of these, cephamycin C is a second generation cephalosporin antibiotic having great medical significance. Biosynthesis of the &amp / #946 / -lactam nucleus begins with the non-ribosomal condensation of L-&amp / #945 / -aminoadipic acid (&amp / #945 / -AAA), L-cysteine and L-valine to form the tripeptide &amp / #945 / -aminoadipiyl-cysteinyl-valine (ACV). In Streptomyces clavuligerus, &amp / #945 / -aminoadipic acid (&amp / #945 / -AAA) is a catabolic product of L-lysine produced from the lysine branch of the aspartate pathway and its biosynthesis represents a key secondary metabolic regulatory step in carbon flow to &amp / #946 / -lactam synthesis through this core pathway. The ask (aspartokinase)-asd (aspartate semialdehyde dehydrogenase) gene cluster which encodes for the first key enzymes of aspartate pathway has already been cloned from S. clavuligerus, characterized and heterologously expressed for the first time in our laboratory. Amplification of ask-asd cluster or ask gene alone in a multi-copy Streptomyces plasmid vector and determination of the effects of multiple copies on cephamycin C biosynthesis were the goals of the present study. For this purpose, three different strategies were employed. Of these, two strategies involving the use of vector pIJ702 did not work because of the instability of resulting recombinant plasmids. In the third and last strategy, we used another multicopy Streptomyces vector, pIJ486, which we showed in this study to be very stable for the same purpose. Meanwhile, an efficient protoplast transformation protocol was developed in our laboratory. Ask gene was cloned into this vector and S. clavuligerus protoplasts were efficiently transformed with the recombinant plasmid (pTB486) using the newly-developed protocol. After stable recombinants were obtained, the effects of the multiple copies of ask gene on cephamycin C biosynthesis were determined. There was a profound reduction in the rate and extent of growth of Ask overproducers, as experienced by testing two independent ask-multicopy recombinants. Although one such recombinant strain (designated S. clavuligerus TB 3585) had a 5.5 fold increased level of Ask activity as compared to the parental strain, it displayed only a 1.1 fold increase in specific production of cephamycin C.

QR Bacteria 75-99.5

Streptomyces clavuligerus

gene cloning

aspartokinase

aspartate semialdehyde dehydrogenase

cephamycin C biosynthesis.

Polymerisation and export of alginate in Pseudomanas aeruginosa : functional assignment and catalytic mechanism of Alg8/44 : a thesis presented to Massey University in partial fulfilment of the requirement for the degree of Doctor of Philosophy in Microbiology

Remminghorst, Uwe

January 2007

Alginate biosynthesis is not only a major contributor to pathogenicity of P. aeruginosa but also an important factor in colonization of adverse environmental habitats by biofilm formation. The requirement of proteins Alg8 and Alg44, encoded by their respective genes in the alginate biosynthesis gene cluster, for alginate biosynthesis of P. aeruginosa was demonstrated, since deletion mutants were unable to produce or polymerise alginate. AlgX deletion mutants failed to produce the alginate characteristic mucoid phenotype, but showed low concentrations of uronic acid monomers in the culture supernatants. Complementation experiments using PCR based approaches were used to determine the complementing ORF and all deletion mutants could be complemented to at least wildtype levels by introducing a plasmid harbouring the respective gene. Increased copy numbers of Alg44 did not impact on the amount of alginate produced, whereas increased copy numbers of the alg8 gene led to an at least 10 fold stronger alginate production impacting on biofilm structure and stability. Topological analysis using reporter protein fusions and subsequent subcellular fractionation experiments revealed that Alg8 is located in the cytoplasmic membrane and contains at least 4 transmembrane helices, 3 of them at its C terminus. Its large cytosolic loop showed similarities to inverting glycosyltransferases and the similarities were used to generate a threading model using SpsA, a glycosyltransferase involved in spore coat formation of B. subtilis, as a template. Site-directed mutagenesis confirmed the importance of identified motifs commonly detected in glycosyltransferases. Inactivation of the DXD motif, which has been shown to be involved in nucleotide sugar binding, led to loss-offunction mutants of Alg8 and further replacements revealed putative candidates for the catalytic residue(s). Contradicting the commonly reported prediction of being a transmembrane protein, Alg44 was shown to be a periplasmic protein. The highest specific alkaline phosphatase activity of its fusion protein could be detected in the periplasmic fraction and not in the insoluble membrane fraction. Bioinformatical analysis of Alg44 revealed structural similarities of its N terminus to PilZ domains, shown to bind cyclic-di-GMP, and of its C terminus to MexA, a membrane fusion protein involved in multi-drug efflux systems. Thus, it was suggested that Alg44 has a regulatory role for alginate biosynthesis in bridging the periplasm and connecting outer and cytoplasmic membrane components. AlgX was shown to interact with MucD, a periplasmic serine protease or chaperone homologue, and is suggested to exert its impact on alginate production via MucD interaction. In vitro alginate polymerisation assays revealed that alginate production requires protein components of the outer and cytoplasmic membrane as well as the periplasm, and these data were used to construct a model describing a multi-enzyme, membrane and periplasm spanning complex for alginate polymerisation, modification and export.

pseudomonas aeruginosa

alginates

biosynthesis

Transcriptional and metabolic responses of yeast Saccharomyces cerevisiae to the addition of L-serine

Lee, Johnny Chien-Yi, Biotechnology & Biomolecular Sciences, Faculty of Science, UNSW

January 2008

Sudden changes in nutrient resources are common in the natural environment. Cells are able to adapt and propagate under changing environmental conditions by making adjustments in their cellular processes. These cellular adaptations involve genome-wide transcriptional reprogramming that results in the induction or repression of metabolic pathways. Specific enzymes are then synthesised and activated to maximise the use of the newly available nutrient sources. L-serine is one of the twenty proteinogenic amino acids, and can be synthesised in yeast by the glycolytic and gluconeogenic pathways when growing on fermentable or non-fermentable carbon sources or taken up from the environment when available. L-serine is metabolically linked to glycine and is a predominant donor of one-carbon units in one-carbon metabolism. L-serine is also a source of pyruvate and ammonia and contributes to other cellular processes including the biosynthesis of cysteine and phospholipids. Previous work has shown that yeast cells exhibit transcriptional induction of the one-carbon pathway and the genes involved in the synthesis of purine and methionine after the addition of 10 mM glycine. Here it is shown that addition of 10 mM L-serine did not, however, elicit the same transcriptional response. This is primarily due to differences in the uptake of glycine and L-serine in yeast. High concentrations of extracellular L-serine were required for yeast to show an increase in intracellular L-serine concentration of the magnitude required to trigger a noticeable cellular response. Despite L-serine and glycine being interconvertable via the SHMT isozymes and being a one-carbon donor, the genome-wide transcriptional response exhibited by cells in response to L-serine addition was markedly different to that seen for glycine. The predominant response to an increase in intracellular L-serine was the induction of the general amino acid control system and the CHA1 gene encoding the serine (threonine) dehydratase. Unlike glycine, addition of L-serine triggered only minor induction of the one-carbon pathway. A large portion of intracellular L-serine was converted to pyruvate and ammonia in the mitochondrion as the result of induction of CHA1. The high intracellular concentration of L-serine stimulated the cell to increase the production of oxaloacetate and to increase the biosynthesis of L-aspartate. Transient increases in the intracellular L-glutamate and L-glutamine were also observed after the addition of L-serine. The work presented in this study shows that large increase in the intracellular concentration of amino acid is required to trigger a significant transcriptional response. Yeast cells exhibit different transcriptional and metabolic responses to the addition of L-serine and glycine even though these two amino acids are closely metabolically linked. Addition of L-serine provokes the GAAC response, expression of the CHA1 gene and stimulates the biosynthesis of L-aspartate in yeast whereas addition of glycine induces the one-carbon pathway which leads to the biosynthesis of the purine nucleotides.

Yeast.

L-serine.

Saccharomyces cerevisiae.

Amino acids -- Analysis.

Amino acids -- Biosynthesis.

Polymerisation and export of alginate in Pseudomanas aeruginosa : functional assignment and catalytic mechanism of Alg8/44 : a thesis presented to Massey University in partial fulfilment of the requirement for the degree of Doctor of Philosophy in Microbiology

Remminghorst, Uwe

January 2007

Alginate biosynthesis is not only a major contributor to pathogenicity of P. aeruginosa but also an important factor in colonization of adverse environmental habitats by biofilm formation. The requirement of proteins Alg8 and Alg44, encoded by their respective genes in the alginate biosynthesis gene cluster, for alginate biosynthesis of P. aeruginosa was demonstrated, since deletion mutants were unable to produce or polymerise alginate. AlgX deletion mutants failed to produce the alginate characteristic mucoid phenotype, but showed low concentrations of uronic acid monomers in the culture supernatants. Complementation experiments using PCR based approaches were used to determine the complementing ORF and all deletion mutants could be complemented to at least wildtype levels by introducing a plasmid harbouring the respective gene. Increased copy numbers of Alg44 did not impact on the amount of alginate produced, whereas increased copy numbers of the alg8 gene led to an at least 10 fold stronger alginate production impacting on biofilm structure and stability. Topological analysis using reporter protein fusions and subsequent subcellular fractionation experiments revealed that Alg8 is located in the cytoplasmic membrane and contains at least 4 transmembrane helices, 3 of them at its C terminus. Its large cytosolic loop showed similarities to inverting glycosyltransferases and the similarities were used to generate a threading model using SpsA, a glycosyltransferase involved in spore coat formation of B. subtilis, as a template. Site-directed mutagenesis confirmed the importance of identified motifs commonly detected in glycosyltransferases. Inactivation of the DXD motif, which has been shown to be involved in nucleotide sugar binding, led to loss-offunction mutants of Alg8 and further replacements revealed putative candidates for the catalytic residue(s). Contradicting the commonly reported prediction of being a transmembrane protein, Alg44 was shown to be a periplasmic protein. The highest specific alkaline phosphatase activity of its fusion protein could be detected in the periplasmic fraction and not in the insoluble membrane fraction. Bioinformatical analysis of Alg44 revealed structural similarities of its N terminus to PilZ domains, shown to bind cyclic-di-GMP, and of its C terminus to MexA, a membrane fusion protein involved in multi-drug efflux systems. Thus, it was suggested that Alg44 has a regulatory role for alginate biosynthesis in bridging the periplasm and connecting outer and cytoplasmic membrane components. AlgX was shown to interact with MucD, a periplasmic serine protease or chaperone homologue, and is suggested to exert its impact on alginate production via MucD interaction. In vitro alginate polymerisation assays revealed that alginate production requires protein components of the outer and cytoplasmic membrane as well as the periplasm, and these data were used to construct a model describing a multi-enzyme, membrane and periplasm spanning complex for alginate polymerisation, modification and export.

pseudomonas aeruginosa

alginates

biosynthesis

Structural Genomics of Mycobacterium tuberculosis

Johnston, Jodie Margaret

January 2004

In 1998 the genome sequence of Mycobacterium tuberculosis H37Rv was published1. M. tuberculosis is the primary causative agent of tuberculosis, a disease with a long history in humans, which still has a great impact on human mortality today. As part of the M. tuberculosis Structural Genomics Consortium we selected nine target genes (Rv0534c (menA); Rv0548c (menB); Rv0553 (menC); Rv0555 (menD); Rv0542c (menE); Rv3853 (menG); Rv0558 (ubiE); Rv0989c (grcC2) and Rv0990c) from M. tuberculosis, including all known members of the menaquinone biosynthesis pathway, for structural studies. All nine genes were taken through the structural genomics “pipeline”, either becoming stuck at various “bottlenecks” or continuing successfully to structure solution. At the initial bioinformatics analysis step, eight of the nine targeted genes were deemed suitable for further study. PCR amplification and cloning of these genes into several different expression vectors followed. Expression of the gene products for the seven successfully cloned genes was undertaken in an E. coli expression host, followed by experiments (refolding, lysis buffer and expression temperature screens) aimed at obtaining soluble protein in sufficient quantities for crystallisation. Of the seven proteins successfully overexpressed, five remain at this stage as they could not be obtained in soluble form. The remaining two, Rv3853 (MenG), solubilised by refolding, and MenB, solubilised by 24ºC expression, were purified and both successfully produced diffracting crystals. The crystal structure of Rv3853 was determined by isomorphous replacement (SIRAS) and refined at 1.9 Å resolution (R = 19.0% and Rfree = 22.0%). The structure of several different crystal forms of MenB, were determined by molecular replacement. Refinement of two of these structures, MenB_P43212 at 2.15Å resolution (R = 20.3% and Rfree = 23.1%) and MenB_C2-NCoA at 2.3 Å resolution (R = 19.7% and Rfree = 22.5%), has been completed. The structure of Rv3853, combined with the discovery that UbiE was more likely to catalyse the final, S-adenosylmethionine-dependent, methyltransfer step of menaquinone biosynthesis, led to the conclusion that Rv3853 had been misannotated as MenG. Combined with further bioinformatics analysis the Rv3853 structure has been useful in providing new ideas as to the real function of Rv3853. In contrast, the structure of MenB confirmed its place as a member of the crotonase superfamily although the C-terminus was located in a position not observed in other crotonase superfamily structures. Several flexible regions likely to be important in MenB function have been identified by examination of the various MenB structures / Author was the recipient of a University of Auckland Doctoral Scholarship and a Foundation of Research Science & Technology Top Achiever Doctoral Scholarship

Structural genomics

tuberculosis

Mycobacterium tuberculosis

menaquinone biosynthesis

protein structure

biological sciences

structural biology

Polymerisation and export of alginate in Pseudomanas aeruginosa : functional assignment and catalytic mechanism of Alg8/44 : a thesis presented to Massey University in partial fulfilment of the requirement for the degree of Doctor of Philosophy in Microbiology

Remminghorst, Uwe

January 2007

Alginate biosynthesis is not only a major contributor to pathogenicity of P. aeruginosa but also an important factor in colonization of adverse environmental habitats by biofilm formation. The requirement of proteins Alg8 and Alg44, encoded by their respective genes in the alginate biosynthesis gene cluster, for alginate biosynthesis of P. aeruginosa was demonstrated, since deletion mutants were unable to produce or polymerise alginate. AlgX deletion mutants failed to produce the alginate characteristic mucoid phenotype, but showed low concentrations of uronic acid monomers in the culture supernatants. Complementation experiments using PCR based approaches were used to determine the complementing ORF and all deletion mutants could be complemented to at least wildtype levels by introducing a plasmid harbouring the respective gene. Increased copy numbers of Alg44 did not impact on the amount of alginate produced, whereas increased copy numbers of the alg8 gene led to an at least 10 fold stronger alginate production impacting on biofilm structure and stability. Topological analysis using reporter protein fusions and subsequent subcellular fractionation experiments revealed that Alg8 is located in the cytoplasmic membrane and contains at least 4 transmembrane helices, 3 of them at its C terminus. Its large cytosolic loop showed similarities to inverting glycosyltransferases and the similarities were used to generate a threading model using SpsA, a glycosyltransferase involved in spore coat formation of B. subtilis, as a template. Site-directed mutagenesis confirmed the importance of identified motifs commonly detected in glycosyltransferases. Inactivation of the DXD motif, which has been shown to be involved in nucleotide sugar binding, led to loss-offunction mutants of Alg8 and further replacements revealed putative candidates for the catalytic residue(s). Contradicting the commonly reported prediction of being a transmembrane protein, Alg44 was shown to be a periplasmic protein. The highest specific alkaline phosphatase activity of its fusion protein could be detected in the periplasmic fraction and not in the insoluble membrane fraction. Bioinformatical analysis of Alg44 revealed structural similarities of its N terminus to PilZ domains, shown to bind cyclic-di-GMP, and of its C terminus to MexA, a membrane fusion protein involved in multi-drug efflux systems. Thus, it was suggested that Alg44 has a regulatory role for alginate biosynthesis in bridging the periplasm and connecting outer and cytoplasmic membrane components. AlgX was shown to interact with MucD, a periplasmic serine protease or chaperone homologue, and is suggested to exert its impact on alginate production via MucD interaction. In vitro alginate polymerisation assays revealed that alginate production requires protein components of the outer and cytoplasmic membrane as well as the periplasm, and these data were used to construct a model describing a multi-enzyme, membrane and periplasm spanning complex for alginate polymerisation, modification and export.

pseudomonas aeruginosa

alginates

biosynthesis

Structural Genomics of Mycobacterium tuberculosis

Johnston, Jodie Margaret

January 2004

In 1998 the genome sequence of Mycobacterium tuberculosis H37Rv was published1. M. tuberculosis is the primary causative agent of tuberculosis, a disease with a long history in humans, which still has a great impact on human mortality today. As part of the M. tuberculosis Structural Genomics Consortium we selected nine target genes (Rv0534c (menA); Rv0548c (menB); Rv0553 (menC); Rv0555 (menD); Rv0542c (menE); Rv3853 (menG); Rv0558 (ubiE); Rv0989c (grcC2) and Rv0990c) from M. tuberculosis, including all known members of the menaquinone biosynthesis pathway, for structural studies. All nine genes were taken through the structural genomics “pipeline”, either becoming stuck at various “bottlenecks” or continuing successfully to structure solution. At the initial bioinformatics analysis step, eight of the nine targeted genes were deemed suitable for further study. PCR amplification and cloning of these genes into several different expression vectors followed. Expression of the gene products for the seven successfully cloned genes was undertaken in an E. coli expression host, followed by experiments (refolding, lysis buffer and expression temperature screens) aimed at obtaining soluble protein in sufficient quantities for crystallisation. Of the seven proteins successfully overexpressed, five remain at this stage as they could not be obtained in soluble form. The remaining two, Rv3853 (MenG), solubilised by refolding, and MenB, solubilised by 24ºC expression, were purified and both successfully produced diffracting crystals. The crystal structure of Rv3853 was determined by isomorphous replacement (SIRAS) and refined at 1.9 Å resolution (R = 19.0% and Rfree = 22.0%). The structure of several different crystal forms of MenB, were determined by molecular replacement. Refinement of two of these structures, MenB_P43212 at 2.15Å resolution (R = 20.3% and Rfree = 23.1%) and MenB_C2-NCoA at 2.3 Å resolution (R = 19.7% and Rfree = 22.5%), has been completed. The structure of Rv3853, combined with the discovery that UbiE was more likely to catalyse the final, S-adenosylmethionine-dependent, methyltransfer step of menaquinone biosynthesis, led to the conclusion that Rv3853 had been misannotated as MenG. Combined with further bioinformatics analysis the Rv3853 structure has been useful in providing new ideas as to the real function of Rv3853. In contrast, the structure of MenB confirmed its place as a member of the crotonase superfamily although the C-terminus was located in a position not observed in other crotonase superfamily structures. Several flexible regions likely to be important in MenB function have been identified by examination of the various MenB structures / Author was the recipient of a University of Auckland Doctoral Scholarship and a Foundation of Research Science & Technology Top Achiever Doctoral Scholarship

Structural genomics

tuberculosis

Mycobacterium tuberculosis

menaquinone biosynthesis

protein structure

biological sciences

structural biology

Polymerisation and export of alginate in Pseudomanas aeruginosa : functional assignment and catalytic mechanism of Alg8/44 : a thesis presented to Massey University in partial fulfilment of the requirement for the degree of Doctor of Philosophy in Microbiology

Remminghorst, Uwe

January 2007

Alginate biosynthesis is not only a major contributor to pathogenicity of P. aeruginosa but also an important factor in colonization of adverse environmental habitats by biofilm formation. The requirement of proteins Alg8 and Alg44, encoded by their respective genes in the alginate biosynthesis gene cluster, for alginate biosynthesis of P. aeruginosa was demonstrated, since deletion mutants were unable to produce or polymerise alginate. AlgX deletion mutants failed to produce the alginate characteristic mucoid phenotype, but showed low concentrations of uronic acid monomers in the culture supernatants. Complementation experiments using PCR based approaches were used to determine the complementing ORF and all deletion mutants could be complemented to at least wildtype levels by introducing a plasmid harbouring the respective gene. Increased copy numbers of Alg44 did not impact on the amount of alginate produced, whereas increased copy numbers of the alg8 gene led to an at least 10 fold stronger alginate production impacting on biofilm structure and stability. Topological analysis using reporter protein fusions and subsequent subcellular fractionation experiments revealed that Alg8 is located in the cytoplasmic membrane and contains at least 4 transmembrane helices, 3 of them at its C terminus. Its large cytosolic loop showed similarities to inverting glycosyltransferases and the similarities were used to generate a threading model using SpsA, a glycosyltransferase involved in spore coat formation of B. subtilis, as a template. Site-directed mutagenesis confirmed the importance of identified motifs commonly detected in glycosyltransferases. Inactivation of the DXD motif, which has been shown to be involved in nucleotide sugar binding, led to loss-offunction mutants of Alg8 and further replacements revealed putative candidates for the catalytic residue(s). Contradicting the commonly reported prediction of being a transmembrane protein, Alg44 was shown to be a periplasmic protein. The highest specific alkaline phosphatase activity of its fusion protein could be detected in the periplasmic fraction and not in the insoluble membrane fraction. Bioinformatical analysis of Alg44 revealed structural similarities of its N terminus to PilZ domains, shown to bind cyclic-di-GMP, and of its C terminus to MexA, a membrane fusion protein involved in multi-drug efflux systems. Thus, it was suggested that Alg44 has a regulatory role for alginate biosynthesis in bridging the periplasm and connecting outer and cytoplasmic membrane components. AlgX was shown to interact with MucD, a periplasmic serine protease or chaperone homologue, and is suggested to exert its impact on alginate production via MucD interaction. In vitro alginate polymerisation assays revealed that alginate production requires protein components of the outer and cytoplasmic membrane as well as the periplasm, and these data were used to construct a model describing a multi-enzyme, membrane and periplasm spanning complex for alginate polymerisation, modification and export.

pseudomonas aeruginosa

alginates

biosynthesis