Mecanismos de captação de ferro por sideróforos em Chromobacterium violaceum / Mechanisms of iron uptake by siderophores in Chromobacterium violaceum

Batista, Bianca Bontempi

03 September 2018

A pouca solubilidade do ferro impõe desafios para sua captação por bactérias e outros organismos. Uma solução eficaz para este problema é a utilização de sideróforos próprios ou exógenos para solubilizar o ferro do ambiente ou de proteínas do hospedeiro e transportá-lo para o interior da célula bacteriana. Neste trabalho, identificamos vias de produção e captação de ferro por sideróforos e definimos o papel destas moléculas na virulência da bactéria Chromobacterium violaceum, um abundante componente da microbiota de solo e água que ocasionalmente causa graves infecções em humanos. Por meio de análises in silico, vários genes relacionados com a síntese e captação de sideróforos foram encontrados no genoma de C. violaceum ATCC 12472 em dois clusters de síntese de metabólitos secundários. Obtenção de linhagens mutantes de vários destes genes e caracterização destas linhagens por ensaios de CAS, curvas de crescimento em carência de ferro e ensaios de estimulação de crescimento revelaram que C. violaceum produz sideróforos endógenos. Essa produção mostrou-se dependente do percursor comum 2,3-DHBA produzido pelas enzimas codificadas pelos genes entCEBA (CV_1485-84-83-82) e de duas enzimas sintetases de peptídeo não ribossomais (NRPSs CV_1486 e CV_2233), as quais provavelmente montam dois sideróforos distintos do tipo catecolato. Cada sideróforo foi captado por um receptor dependente de TonB (RDTB) específico, com o sideróforo produzido via NRPS CV_1486 sendo captado pelo RDTB CV_1491, e o sideróforo produzido via NRPS CV_2233 sendo captado pelo RDTB CV_2230, uma vez que mutantes sem esses RDTBs acumularam sideróforos no meio externo no ensaio de CAS. Além de seus sideróforos endógenos, C. violaceum foi capaz de utilizar xenosideróforos do tipo catecolato de outras bactérias via o RDTB CV_1491. Ensaios de infecção em camundongos revelaram que tanto a síntese quanto a captação de seus sideróforos endógenos são importantes para a virulência de C. violaceum, pois as linhagens mutantes que não produzem sideróforos (?CV_1485-84- 83-82, ?CV_1485-84-83-82/1486::pNPT e ?CV_1486/2233::pNPT) ou são incapazes8 de captá-los (?CV_2230/1491) tiveram sua virulência diminuída em relação a linhagem selvagem. Os dados mostrando que o mutante que não capta ambos sideróforos de C. violaceum teve atenuação mais acentuada da virulência e induziu menor produção de NET em ensaios com neutrófilos in vitro sugerem que o acúmulo de sideróforos na infecção pode ser benéfico para o hospedeiro. Por fim, demonstramos a possibilidade de gerar mutantes de transposon em C. violaceum e ao realizarmos varredura de uma coleção destes mutantes identificamos ao menos um potencial novo fator de transcrição envolvido na regulação da síntese de sideróforo nesta bactéria. Portanto, os dados obtidos neste trabalho revelaram que C. violaceum utiliza-se de diferentes sideróforos endógenos para captação de ferro e que estas moléculas são importantes para seu estabelecimento no hospedeiro. / The low solubility of iron imposes challenges for its uptake by bacteria and other organisms. An effective solution to this problem is the use of own or exogenous siderophores to solubilize the iron from environmental or host sources and transport it into the bacterial cell. In this work, we identified pathways for production and uptake of siderophores, and we defined the role of these molecules in virulence of the bacterium Chromobacterium violaceum, an abundant component of the microbiota of soil and water, which occasionally causes serious infections in humans. By performing an in silico analysis, we found several genes related with synthesis and uptake of siderophores in the genome of C. violaceum ATCC 12472 within two secondary metabolite biosynthesis gene clusters. Obtaining mutant strains from several of these genes and characterizing these strains by CAS assays, growth curves under iron deficiency and growth stimulation assays revealed that C. violaceum produces endogenous siderophores. This production was shown to be dependent on the common precursor 2,3-DHBA produced by the enzymes encoded by the genes entCEBA (CV_1485-84-83-82) and on two non-ribosomal peptide synthetase enzymes (NRPSs CV_1486 and CV_2233), which probably build two distinct catecholate siderophores. Each siderophore was picked up by a specific TonB-dependent receptor (RDTB), with the siderophore produced via NRPS CV_1486 being picked up by RDTB CV_1491, and the siderophore produced via NRPS CV_2233 being picked up by RDTB CV_2230, since mutants without those RDTBs accumulated siderophores in the external environment in the CAS assays. In addition to its endogenous siderophores, C. violaceum was able to use catecholate-type xenosiderophores from other bacteria via the RDTB CV_1491. Infection assays in mice revealed that both the synthesis and the uptake of its endogenous siderophores are important for the virulence of C. violaceum, since mutant strains that do not produce siderophores (?CV_1485-84-83- 82, ?CV_1485-84-83- 82/1486 :: pNPT and ?CV_1486/2233 :: pNPT) or are unable to uptake them (?CV_2230/1491) had their virulence decreased relative to the wild type strain. The data showing that the mutant strain unable to uptake both siderophores of10 C. violaceum had more pronounced attenuation of virulence and induced lower NET production in in vitro neutrophil assays suggest that the accumulation of siderophores in the infection may be beneficial to the host. Finally, we demonstrated the possibility of generating transposon mutants in C. violaceum, and by screening a collection of these mutants we identified at least one potential novel transcription factor involved in the regulation of siderophore synthesis in this bacterium. Therefore, the data obtained in this work revealed that C. violaceum uses different endogenous siderophores for iron uptake and that these molecules are important for its establishment in the host.

Bacterial physiology

Bacterial virulence

Captação de ferro

Chromobacterium violaceum

Chromobacterium violaceum

Fisiologia bacteriana

Homeostase de ferro

Iron homeostasis

Iron uptake

Sideróforos

Siderophores

Virulência bacteriana

Mecanismos de captação de ferro por sideróforos em Chromobacterium violaceum / Mechanisms of iron uptake by siderophores in Chromobacterium violaceum

Bianca Bontempi Batista

03 September 2018

A pouca solubilidade do ferro impõe desafios para sua captação por bactérias e outros organismos. Uma solução eficaz para este problema é a utilização de sideróforos próprios ou exógenos para solubilizar o ferro do ambiente ou de proteínas do hospedeiro e transportá-lo para o interior da célula bacteriana. Neste trabalho, identificamos vias de produção e captação de ferro por sideróforos e definimos o papel destas moléculas na virulência da bactéria Chromobacterium violaceum, um abundante componente da microbiota de solo e água que ocasionalmente causa graves infecções em humanos. Por meio de análises in silico, vários genes relacionados com a síntese e captação de sideróforos foram encontrados no genoma de C. violaceum ATCC 12472 em dois clusters de síntese de metabólitos secundários. Obtenção de linhagens mutantes de vários destes genes e caracterização destas linhagens por ensaios de CAS, curvas de crescimento em carência de ferro e ensaios de estimulação de crescimento revelaram que C. violaceum produz sideróforos endógenos. Essa produção mostrou-se dependente do percursor comum 2,3-DHBA produzido pelas enzimas codificadas pelos genes entCEBA (CV_1485-84-83-82) e de duas enzimas sintetases de peptídeo não ribossomais (NRPSs CV_1486 e CV_2233), as quais provavelmente montam dois sideróforos distintos do tipo catecolato. Cada sideróforo foi captado por um receptor dependente de TonB (RDTB) específico, com o sideróforo produzido via NRPS CV_1486 sendo captado pelo RDTB CV_1491, e o sideróforo produzido via NRPS CV_2233 sendo captado pelo RDTB CV_2230, uma vez que mutantes sem esses RDTBs acumularam sideróforos no meio externo no ensaio de CAS. Além de seus sideróforos endógenos, C. violaceum foi capaz de utilizar xenosideróforos do tipo catecolato de outras bactérias via o RDTB CV_1491. Ensaios de infecção em camundongos revelaram que tanto a síntese quanto a captação de seus sideróforos endógenos são importantes para a virulência de C. violaceum, pois as linhagens mutantes que não produzem sideróforos (?CV_1485-84- 83-82, ?CV_1485-84-83-82/1486::pNPT e ?CV_1486/2233::pNPT) ou são incapazes8 de captá-los (?CV_2230/1491) tiveram sua virulência diminuída em relação a linhagem selvagem. Os dados mostrando que o mutante que não capta ambos sideróforos de C. violaceum teve atenuação mais acentuada da virulência e induziu menor produção de NET em ensaios com neutrófilos in vitro sugerem que o acúmulo de sideróforos na infecção pode ser benéfico para o hospedeiro. Por fim, demonstramos a possibilidade de gerar mutantes de transposon em C. violaceum e ao realizarmos varredura de uma coleção destes mutantes identificamos ao menos um potencial novo fator de transcrição envolvido na regulação da síntese de sideróforo nesta bactéria. Portanto, os dados obtidos neste trabalho revelaram que C. violaceum utiliza-se de diferentes sideróforos endógenos para captação de ferro e que estas moléculas são importantes para seu estabelecimento no hospedeiro. / The low solubility of iron imposes challenges for its uptake by bacteria and other organisms. An effective solution to this problem is the use of own or exogenous siderophores to solubilize the iron from environmental or host sources and transport it into the bacterial cell. In this work, we identified pathways for production and uptake of siderophores, and we defined the role of these molecules in virulence of the bacterium Chromobacterium violaceum, an abundant component of the microbiota of soil and water, which occasionally causes serious infections in humans. By performing an in silico analysis, we found several genes related with synthesis and uptake of siderophores in the genome of C. violaceum ATCC 12472 within two secondary metabolite biosynthesis gene clusters. Obtaining mutant strains from several of these genes and characterizing these strains by CAS assays, growth curves under iron deficiency and growth stimulation assays revealed that C. violaceum produces endogenous siderophores. This production was shown to be dependent on the common precursor 2,3-DHBA produced by the enzymes encoded by the genes entCEBA (CV_1485-84-83-82) and on two non-ribosomal peptide synthetase enzymes (NRPSs CV_1486 and CV_2233), which probably build two distinct catecholate siderophores. Each siderophore was picked up by a specific TonB-dependent receptor (RDTB), with the siderophore produced via NRPS CV_1486 being picked up by RDTB CV_1491, and the siderophore produced via NRPS CV_2233 being picked up by RDTB CV_2230, since mutants without those RDTBs accumulated siderophores in the external environment in the CAS assays. In addition to its endogenous siderophores, C. violaceum was able to use catecholate-type xenosiderophores from other bacteria via the RDTB CV_1491. Infection assays in mice revealed that both the synthesis and the uptake of its endogenous siderophores are important for the virulence of C. violaceum, since mutant strains that do not produce siderophores (?CV_1485-84-83- 82, ?CV_1485-84-83- 82/1486 :: pNPT and ?CV_1486/2233 :: pNPT) or are unable to uptake them (?CV_2230/1491) had their virulence decreased relative to the wild type strain. The data showing that the mutant strain unable to uptake both siderophores of10 C. violaceum had more pronounced attenuation of virulence and induced lower NET production in in vitro neutrophil assays suggest that the accumulation of siderophores in the infection may be beneficial to the host. Finally, we demonstrated the possibility of generating transposon mutants in C. violaceum, and by screening a collection of these mutants we identified at least one potential novel transcription factor involved in the regulation of siderophore synthesis in this bacterium. Therefore, the data obtained in this work revealed that C. violaceum uses different endogenous siderophores for iron uptake and that these molecules are important for its establishment in the host.

Captação de ferro

Chromobacterium violaceum

Fisiologia bacteriana

Homeostase de ferro

Sideróforos

Virulência bacteriana

Bacterial physiology

Bacterial virulence

Chromobacterium violaceum

Iron homeostasis

Iron uptake

Siderophores

Characterization of arsenic-binding siderophores from environmental bacteria and evaluation of their role in arsenic tolerance

Retamal-Morales, Gerardo

14 June 2019

Arsenic (As) is a toxic metalloid and the remediation of soils and waters from this contaminant as well as the prevention of future contamination are still pending tasks in Chile. There are bacteria able to live in environments polluted with arsenic, as they have tolerance mechanisms for this metalloid, or even can use it for energy metabolism. The potential tolerance mechanisms include the production of siderophores, metabolites with chelating activity that can decrease the toxicity of metals and metalloids. Although a correlation between siderophore production and metalloid tolerance has been described, the structure of arsenic-binding siderophores and their implications in tolerance have not been elucidated yet. In this work, it is proposed that bacteria isolated from contaminated environments produce arsenic-binding siderophores. The main aims of this work are to study the production of the siderophores by arsenic-tolerant bacteria, to characterize these compounds and to determine their relation with tolerance to arsenic. Fourteen arsenic-tolerant bacteria were isolated from contaminated water, From these, four strains belonging to the species Rhodococcus erythropolis, Arthrobacter oxydans and Kocuria rosea were selected, in addition to the previously isolated Rhodococcus erythropolis S43, for a more detailed study. The isolates were used to produce siderophore extracts, which were then evaluated for their iron- and arsenic-binding activity. To detect the latter, a new method (As-mCAS) was set up, based on the Chrome Azurol S (CAS) test, an assay to detect iron-chelating activity of siderophores. After testing the extracts, R. erythropolis S43 was selected as the strain with the best arsenic-binding activity. For the subsequent chemical characterization, siderophores were produced under control conditions (iron-free M9 medium) and under stress conditions with arsenic (iron-free M9 medium with sodium arsenite). HPLC analysis of the extracts for both culture conditions showed the presence of a single compound with both an iron-chelating and an arsenic-binding activity. Analyses by nuclear magnetic resonance (NMR) spectroscopy and mass spectrometry (MS) for both culture conditions suggested the main presence of the siderophore heterobactin B. In addition, the genome of strain S43 was sequenced. A cluster of ars-genes was predicted, probably responsible for the arsenic-tolerance of the strain. In addition, a complete gene cluster for heterobactin production was found. However, no significant difference was obtained in the expression of these determinants in the presence or absence of arsenic, suggesting that the production of this siderophore in strain S43 is not responsible for the tolerance to the metalloid.

info:eu-repo/classification/ddc/570

ddc:570

Arsen

Arsenbelastung

Siderophore

Produktion

Strahlenpilze

Bioremediation