The regulation of glutamate and melibiose utilisation in Escherichia coli

Kempsell, K.

January 1987

Wild type cells of <i>Escherichia coli</i> K-12 are unable to grow on glutamate as the sole source of carbon. Glutamate-utilising mutants have been isolated previously and found to exhibit enhanced glutamate transport. Mutations at two loci <i>gltS</i> and <i>gltR</i> and possibly a third <i>gltC</i> were previously shown by other workers to mediate enhanced glutamate permeability. The <i>gltR</i> locus was suggested to be a negative regulatory for the <i>gltS</i> gene. A mutation at the <i>gltS</i> locus, the <i>gltSo</i> mutation increases the activity of a Na⁺-stimulated glutamate transport system GltI. The regulation of the GltI system was investigated by the isolation of MudX gene fusions which abolished Na⁺-stimulated glutamate transport. Two fusions with 'strong' and 'weak' B-galactosidase activities were isolated. These were both found to map at the <i>gltS</i> locus. Subsequent mapping exercises, suggested that the MudX fusions may be located in separate genes. Transcription of the 'strong' fusion was found to be impaired in the presence of the <i>phs</i> mutation. This is a mutation in the <i>rpoA</i> gene which encodes the -subunit of RNA polymerase. Glutamate-utilising suppressor mutants were isolated in both the MudX gene fusion strains. The suppressor mutations were found to map at the <i>gltR</i> locus. This was found to be the map location of a second glutamate transport system GltII. Thus, the <i>gltR</i> locus was found not to be the location of a negative regulator for the <i>gltS</i> gene. The <i>melAB</i> operon encodes the proteins for melibiose transport and utilisation. No regulatory locus has previously been reported for this transport system. The regulation of the <i>melAB</i> operon was investigated by cloning the <i>melAB</i> promoter into an <i>lacZ</i> expression vector. The region upstream from the <i>melAB</i> promoter was subsequently found to encode a trans-acting positive regulatory necessary for <i>melAB</i> expression. Transcription from the <i>melAB</i> promoter was also found to be impaired by the <i>phs</i> mutation. The results presented in this study substantiate previous observations that the <i>phs</i> mutation causes a generalised transcription defect.

579

Genetics][Bacterial transport/nutrition

Molecular basis for Clostridium perfringens spore resistance to heat and other environmental stress factors /

Raju, Deepa.

January 1900

Thesis (Ph. D.)--Oregon State University, 2007. / Printout. Includes bibliographical references (leaves 101-109). Also available on the World Wide Web.

Quantitative genetic analysis for flowering time in primitive Upland cotton, Gossypium hirsutum L., and chromosome assignment of BAC-derived SSR markers

Guo, Yufang,

January 2007

Thesis (Ph.D.)--Mississippi State University. Department of Plant and Soil Sciences. / Title from title screen. Includes bibliographical references.

Investigation of the basis for persistent porin serotypes of Neisseria gonorrhoeae /

Garvin, Lotisha Erin

January 2006

Thesis (M.S.)--Uniformed Services University of the Health Sciences, 2006 / Typescript (photocopy)

Molecular characterisation of Shigella flexneri outer membrane protease IcsP.

Tran, Elizabeth Ngoc Hoa.

January 2008

Shigella is a genus of Gram-negative bacteria responsible for bacillary dysentery in humans. Shigella flexneri type 2a in particular is responsible for the majority of incidents in developing countries. The S. flexneri protease IcsP, is a member of the Omptin family of outer membrane (OM) proteases which cleaves IcsA, a polarly localised OM protein required for Shigella virulence. Mutations in icsP have been shown to effect the observed distribution of IcsA, however the significance of IcsP in Shigella virulence is incompletely understood. In this study, aspects of IcsP biology were investigated. S. flexneri 2457T and M90T icsP mutants were constructed to investigate the role of IcsP in Shigella intercellular spread, and it was found that icsP in both S. flexneri backgrounds did not appear to be essential for cell-tocell spread in human cervical cancer HeLa cells, but enhanced cell-to-cell spread in monkey kidney CV-1 cells (as determined by plaque assays). Complementation with icsP returned the mutant phenotype to wild-type. The results suggest IcsP does play a role in Shigella intercellular spread. The 2457T icsP mutant was subsequently complemented with an altered icsP gene encoding a haemagglutinin epitope tagged IcsP (IcsPHA) to determine the distribution of IcsP on the cell surface. In both S. flexneri and E. coli K-12 possessing smooth and rough lipopolysaccharide (LPS), the distribution of IcsPHA was found to be punctate across the cell surface. Deconvolution analysis revealed that IcsP distribution was punctate and banded in both LPS backgrounds. A smooth LPS E. coli K-12 yfdI mutant strain expressing IcsPHA was also constructed, and experiments involving treatment of this strain with bacteriophage Sf6 tail spike protein suggested that LPS O antigen chains masked IcsP in smooth LPS strains. During these studies, double-labelling of IcsPHA and LPS in a S. flexneri 5a M90T strain revealed a helical distribution of LPS in this strain. Overall, the results suggest IcsP has a punctate, banded distribution across the cell surface. The effect of virK and rmlD mutations on IcsP was then investigated by constructing a virK, rmlD and virK/rmlD double mutant in S. flexneri 2457T. Western immunoblotting showed no change in IcsP expression levels in either the virK, rmlD or virK/rmlD mutants compared to wild-type. Surprisingly, the virK mutant showed no change in IcsA expression levels by Western immunoblotting and plaque assays (using HeLa and CV-1 cells) suggested that virK was not essential for Shigella intercellular spread (contradicting the published data on this gene). No effect was also observed on IcsP expression level or on IcsP’s ability to cleave IcsA into culture supernatants. Finally alternative substrates for the protease activity of IcsP were investigated against known Omptin substrates (plasminogen, α2-antiplasmin, complement, protamine and colicins). However, IcsP appeared to have no effect on these substrates as determined by proteolytic cleavage assays and antimicrobial assay. Interestingly, Plg cleavage by rough LPS S. flexneri, and α2AP cleavage by both smooth and rough LPS S. flexneri, was observed. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1339487 / Thesis (Ph.D.) - University of Adelaide, School of Molecular and Biomedical Science, 2008

Molecular characterisation of Shigella flexneri outer membrane protease IcsP.

Tran, Elizabeth Ngoc Hoa.

January 2008

Shigella is a genus of Gram-negative bacteria responsible for bacillary dysentery in humans. Shigella flexneri type 2a in particular is responsible for the majority of incidents in developing countries. The S. flexneri protease IcsP, is a member of the Omptin family of outer membrane (OM) proteases which cleaves IcsA, a polarly localised OM protein required for Shigella virulence. Mutations in icsP have been shown to effect the observed distribution of IcsA, however the significance of IcsP in Shigella virulence is incompletely understood. In this study, aspects of IcsP biology were investigated. S. flexneri 2457T and M90T icsP mutants were constructed to investigate the role of IcsP in Shigella intercellular spread, and it was found that icsP in both S. flexneri backgrounds did not appear to be essential for cell-tocell spread in human cervical cancer HeLa cells, but enhanced cell-to-cell spread in monkey kidney CV-1 cells (as determined by plaque assays). Complementation with icsP returned the mutant phenotype to wild-type. The results suggest IcsP does play a role in Shigella intercellular spread. The 2457T icsP mutant was subsequently complemented with an altered icsP gene encoding a haemagglutinin epitope tagged IcsP (IcsPHA) to determine the distribution of IcsP on the cell surface. In both S. flexneri and E. coli K-12 possessing smooth and rough lipopolysaccharide (LPS), the distribution of IcsPHA was found to be punctate across the cell surface. Deconvolution analysis revealed that IcsP distribution was punctate and banded in both LPS backgrounds. A smooth LPS E. coli K-12 yfdI mutant strain expressing IcsPHA was also constructed, and experiments involving treatment of this strain with bacteriophage Sf6 tail spike protein suggested that LPS O antigen chains masked IcsP in smooth LPS strains. During these studies, double-labelling of IcsPHA and LPS in a S. flexneri 5a M90T strain revealed a helical distribution of LPS in this strain. Overall, the results suggest IcsP has a punctate, banded distribution across the cell surface. The effect of virK and rmlD mutations on IcsP was then investigated by constructing a virK, rmlD and virK/rmlD double mutant in S. flexneri 2457T. Western immunoblotting showed no change in IcsP expression levels in either the virK, rmlD or virK/rmlD mutants compared to wild-type. Surprisingly, the virK mutant showed no change in IcsA expression levels by Western immunoblotting and plaque assays (using HeLa and CV-1 cells) suggested that virK was not essential for Shigella intercellular spread (contradicting the published data on this gene). No effect was also observed on IcsP expression level or on IcsP’s ability to cleave IcsA into culture supernatants. Finally alternative substrates for the protease activity of IcsP were investigated against known Omptin substrates (plasminogen, α2-antiplasmin, complement, protamine and colicins). However, IcsP appeared to have no effect on these substrates as determined by proteolytic cleavage assays and antimicrobial assay. Interestingly, Plg cleavage by rough LPS S. flexneri, and α2AP cleavage by both smooth and rough LPS S. flexneri, was observed. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1339487 / Thesis (Ph.D.) - University of Adelaide, School of Molecular and Biomedical Science, 2008

Molecular characterisation of Shigella flexneri outer membrane protease IcsP.

Tran, Elizabeth Ngoc Hoa.

January 2008

Shigella is a genus of Gram-negative bacteria responsible for bacillary dysentery in humans. Shigella flexneri type 2a in particular is responsible for the majority of incidents in developing countries. The S. flexneri protease IcsP, is a member of the Omptin family of outer membrane (OM) proteases which cleaves IcsA, a polarly localised OM protein required for Shigella virulence. Mutations in icsP have been shown to effect the observed distribution of IcsA, however the significance of IcsP in Shigella virulence is incompletely understood. In this study, aspects of IcsP biology were investigated. S. flexneri 2457T and M90T icsP mutants were constructed to investigate the role of IcsP in Shigella intercellular spread, and it was found that icsP in both S. flexneri backgrounds did not appear to be essential for cell-tocell spread in human cervical cancer HeLa cells, but enhanced cell-to-cell spread in monkey kidney CV-1 cells (as determined by plaque assays). Complementation with icsP returned the mutant phenotype to wild-type. The results suggest IcsP does play a role in Shigella intercellular spread. The 2457T icsP mutant was subsequently complemented with an altered icsP gene encoding a haemagglutinin epitope tagged IcsP (IcsPHA) to determine the distribution of IcsP on the cell surface. In both S. flexneri and E. coli K-12 possessing smooth and rough lipopolysaccharide (LPS), the distribution of IcsPHA was found to be punctate across the cell surface. Deconvolution analysis revealed that IcsP distribution was punctate and banded in both LPS backgrounds. A smooth LPS E. coli K-12 yfdI mutant strain expressing IcsPHA was also constructed, and experiments involving treatment of this strain with bacteriophage Sf6 tail spike protein suggested that LPS O antigen chains masked IcsP in smooth LPS strains. During these studies, double-labelling of IcsPHA and LPS in a S. flexneri 5a M90T strain revealed a helical distribution of LPS in this strain. Overall, the results suggest IcsP has a punctate, banded distribution across the cell surface. The effect of virK and rmlD mutations on IcsP was then investigated by constructing a virK, rmlD and virK/rmlD double mutant in S. flexneri 2457T. Western immunoblotting showed no change in IcsP expression levels in either the virK, rmlD or virK/rmlD mutants compared to wild-type. Surprisingly, the virK mutant showed no change in IcsA expression levels by Western immunoblotting and plaque assays (using HeLa and CV-1 cells) suggested that virK was not essential for Shigella intercellular spread (contradicting the published data on this gene). No effect was also observed on IcsP expression level or on IcsP’s ability to cleave IcsA into culture supernatants. Finally alternative substrates for the protease activity of IcsP were investigated against known Omptin substrates (plasminogen, α2-antiplasmin, complement, protamine and colicins). However, IcsP appeared to have no effect on these substrates as determined by proteolytic cleavage assays and antimicrobial assay. Interestingly, Plg cleavage by rough LPS S. flexneri, and α2AP cleavage by both smooth and rough LPS S. flexneri, was observed. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1339487 / Thesis (Ph.D.) - University of Adelaide, School of Molecular and Biomedical Science, 2008

DISCOVERY AND CHARACTERIZATION OF INHIBITORS OF BACTERIAL METABOLISM / CHEMICAL GENETICS AND METABOLIC SUPPRESSION PROFILING IDENTIFY NOVEL INHIBITORS OF BACTERIAL BIOSYNTHETIC PATHWAYS

Zlitni, Soumaya

30 September 2014

The alarming rise of antibacterial drug resistance and the dwindling supply of novel antibiotics highlight the need for innovative approaches in combating bacterial infections. Traditionally, antibacterial drug discovery campaigns have largely been conducted in rich media. Such growth conditions are not representative of the host environment and render many metabolic pathways, otherwise needed for survival and infection, dispensable. Such pathways have been overlooked in conventional drug discovery campaigns despite their validity as potential antibacterial targets. The work presented in this thesis focuses on the development and validation of a screening strategy for the identification and mechanism of action determination of novel inhibitors of metabolic pathways in bacteria under nutrient-limited conditions. This screen led to the identification of MAC168425, MAC173979 and MAC13772 as inhibitors that target glycine metabolism, p-aminobenzoic acid biosynthesis and biotin biosynthesis, respectively. Moreover, it established this approach as a general platform that can be applied for different organisms with synthetic or natural product libraries. Additional mechanistic studies of the biotin biosynthesis inhibitor, MAC13772, resulted in solving the crystal structure of BioA in complex with MAC13772. Analysis of the co-structure confirmed our proposed mode of inhibition and provided information for strategies for rational drug design. Investigation of the antibacterial activity of MAC13772 revealed its potency against a number of pathogens. Furthermore, we show how MAC13772 acts synergistically with rifampicin in clearing growing mycobacterial cultures. The potential of this inhibitor as a lead for preclinical pharmacokinetic studies and for antibacterial drug development is discussed. We also discuss our current efforts to develop a metabolomic platform for the characterization of novel antibacterials that can be used in concert with our current approach to chart the metabolic response of bacteria to chemical perturbants and to generate testable hypotheses regarding the mode of action of novel inhibitors of bacterial metabolism. / Thesis / Doctor of Philosophy (PhD)

Identificação de genes envolvidos na síntese de polihidroxialcanoatos em Burkholderia cepacia linhagem IPT64. / Identification of genes involved in the synthesis of polyhydroxyalkanoates on Burkholderia cepacia strain IPT64.

Caulkins, Juliana Carvalho de Arruda

05 December 2008

Os polihidroxialcanoatos (PHAs) são poliésteres acumulados por microrganismos como material de reserva. O conhecimento das vias bioquímicas e enzimas envolvidas na biossíntese e degradação dos PHAs é uma importante ferramenta para auxiliar na produção industrial. A linhagem Burkholderia cepacia IPT64 é capaz de acumular uma blenda composta de P(3HB) e P(3H4PE) a partir de sacarose. Este trabalho está focado em duas das principais enzimas envolvidas na biossíntese de PHAs: a b-cetotiolase (phaA) e a PHA sintase (phaC). A primeira está associada à especificidade pelo substrato, e a segunda é considerada a enzima chave na síntese de PHAs. Neste trabalho a linhagem mutante phaC foi avaliada quanto à atividade enzimática de PHB sintase, que se constatou ter sido perdida. A presença de mais de uma tiolase no genoma de B. cepacia foi detectada. A inativação do gene phaABc identificado anteriormente, bloqueou totalmente a síntese de P(3HB), e não promoveu o aumento da quantidade total de polímero. Este resultado indica que a tiolase identificada é responsável direta do acúmulo de P(3HB). Outra indicação é que não há uma competição das vias de síntese dos dois polímeros P(3HB) e P(3H4PE), já que não houve alteração na quantidade de P(3H4PE) acumulado, mesmo quando P(3HB) deixou de ser acumulado. / The polyhydroxyalkanoates (PHAs) are polyesters accumulated by microorganisms as storage compounds. Knowing the biochemistry pathway and enzymes involved in the biosynthesis and degradation of PHAs is an important tool to help industrial production. The Burkholderia cepacia IPT64 strain is able to accumulate a blend of P(3HB) and P(3H4PE) from sucrose. The focus of this work is on the two main enzymes involved in PHA biosynthesis: the b-ketothiolase (phaA) and the PHA synthase (phaC). The first one is associated with substrate specificity, and the second one is considered the key enzyme in PHA synthesis. In this work a mutant strain phaC was evaluated on its PHB synthase enzymatic activity, that was discovered to have been lost. The presence of other thiolases in the B. cepacia genome was detected. The inactivation of phaABc gene identified previously, blocked totally the P(3HB) synthesis, and didnt increase the polymer content. This result indicates that the identified thiolase is directly responsible for P(3HB) accumulation. Another indication is that the synthesis pathways of the two polymers, P(3HB) and P(3H4PE), dont compete with each other, because the content of P(3H4PE) was not altered, even when the P(3HB) was not accumulated.

b-cetotiolase

Burkholderia cepacia

Burkholderia cepacia

Biodegradable polymers

Biotechnology

Biotecnologia

Genética bacteriana

Genetics bacterial

PHA- Sintase

PHA-synthase

PHB

PHB

Polihidroxialcanoatos

Polímeros biodegradáveis

Polyhydroxyalkanoates

Identificação de genes envolvidos na síntese de polihidroxialcanoatos em Burkholderia cepacia linhagem IPT64. / Identification of genes involved in the synthesis of polyhydroxyalkanoates on Burkholderia cepacia strain IPT64.

Juliana Carvalho de Arruda Caulkins

05 December 2008

Os polihidroxialcanoatos (PHAs) são poliésteres acumulados por microrganismos como material de reserva. O conhecimento das vias bioquímicas e enzimas envolvidas na biossíntese e degradação dos PHAs é uma importante ferramenta para auxiliar na produção industrial. A linhagem Burkholderia cepacia IPT64 é capaz de acumular uma blenda composta de P(3HB) e P(3H4PE) a partir de sacarose. Este trabalho está focado em duas das principais enzimas envolvidas na biossíntese de PHAs: a b-cetotiolase (phaA) e a PHA sintase (phaC). A primeira está associada à especificidade pelo substrato, e a segunda é considerada a enzima chave na síntese de PHAs. Neste trabalho a linhagem mutante phaC foi avaliada quanto à atividade enzimática de PHB sintase, que se constatou ter sido perdida. A presença de mais de uma tiolase no genoma de B. cepacia foi detectada. A inativação do gene phaABc identificado anteriormente, bloqueou totalmente a síntese de P(3HB), e não promoveu o aumento da quantidade total de polímero. Este resultado indica que a tiolase identificada é responsável direta do acúmulo de P(3HB). Outra indicação é que não há uma competição das vias de síntese dos dois polímeros P(3HB) e P(3H4PE), já que não houve alteração na quantidade de P(3H4PE) acumulado, mesmo quando P(3HB) deixou de ser acumulado. / The polyhydroxyalkanoates (PHAs) are polyesters accumulated by microorganisms as storage compounds. Knowing the biochemistry pathway and enzymes involved in the biosynthesis and degradation of PHAs is an important tool to help industrial production. The Burkholderia cepacia IPT64 strain is able to accumulate a blend of P(3HB) and P(3H4PE) from sucrose. The focus of this work is on the two main enzymes involved in PHA biosynthesis: the b-ketothiolase (phaA) and the PHA synthase (phaC). The first one is associated with substrate specificity, and the second one is considered the key enzyme in PHA synthesis. In this work a mutant strain phaC was evaluated on its PHB synthase enzymatic activity, that was discovered to have been lost. The presence of other thiolases in the B. cepacia genome was detected. The inactivation of phaABc gene identified previously, blocked totally the P(3HB) synthesis, and didnt increase the polymer content. This result indicates that the identified thiolase is directly responsible for P(3HB) accumulation. Another indication is that the synthesis pathways of the two polymers, P(3HB) and P(3H4PE), dont compete with each other, because the content of P(3H4PE) was not altered, even when the P(3HB) was not accumulated.

b-cetotiolase

Burkholderia cepacia

Biotecnologia

Genética bacteriana

PHA- Sintase

PHB

Polihidroxialcanoatos

Polímeros biodegradáveis

Burkholderia cepacia

Biodegradable polymers

Biotechnology

Genetics bacterial

PHA-synthase

PHB

Polyhydroxyalkanoates