Genetic determinants of haloarchaeal secondary metabolites, with focus on terpenes
| Autor(a) principal: | |
|---|---|
| Data de Publicação: | 2021 |
| Tipo de documento: | Dissertação |
| Idioma: | eng |
| Título da fonte: | Repositório Científico de Acesso Aberto de Portugal (Repositórios Cientìficos) |
| Texto Completo: | http://hdl.handle.net/10773/30827 |
Resumo: | The knowledge on the secondary metabolites (SMs) produced by archaea is a field where few research and experimental testing ha s been done, when comparing to bacteria or fungi.The class Halobacteria, composed by haloarchaea that need high concentrations of salt to survive, has been one of the best well studied in the domain Archae a, in this regard. Some examples include the class model organisms Haloferax mediterranei, Haloferax volcanii and Halobacterium salinarum. Haloarchaea produce halocins that are peptides with anti-archaeal activity, but information regarding their biosynthesis and structure is still limited. Genes involved in the production of other peptides with post-translational modifications (RiPPs) have also been identifie d but, so far, none have been isolated or characterized. It is also known that the main carotenoid produced by haloarch aea is bacterioruberin, which has higher antioxidant capacity than β-carotene. Haloarchaea can also produce β-carotene (mainly as a precursor molecule) and canthaxanthin. The objectives of this study were: i) to characterize the diversity of SMs encoded in haloarchaeal genomes, in particular the diversity of genes involved in the production of carotenoids and ii) to evaluate the antibacterial activity of H. mediterranei ATCC 33500 and the impact of the production of bacterioruberin on its antimicrobial activity. Herein, 67 complete genomes of haloarchaea were analysed and 182 biosynthetic gene clusters (BGC) where 49% of them shared no homology. The BGCs identified encode the production of terpenes (70%), RiPPs (16%) and siderophores (14%). A closer inspection of the terpene BGCs allowed their division into two groups: those encoding a bifunctional protein lycopene cyclase/phytoene synthase gene (crtB, 53%) and those encoding a squalene synthase (sqs, 46.5%). The crtB gene was mostly found associated with the biosynthetic genes of bacterioruberin. However, in 22% of the strains, genes from retinal biosynthesis or genes not related with the production of carotene s were found in the proximity of crtB. The results obtained confirmed that all haloarchaeal strains should be able to produce bacterio ruberin. In addition , about 64% of the species may produce β -carotene as a precursor of retinal biosynthesis and 3% as a final product and/or precursor of canthaxanthin synthesis. A gene that putatively encodes a β - carotene ketolase (CrtO) was identified in Haloterrigena turkmenica. To date, these enzymes have not been characterized in haloarch aea, but may be involved in the biosynthesis of cant haxanthin . The crtB gene was associated to the bacterioruberin synthesis pathway through the generation of a kn ock -out mutant and carotenoid quantification. In addition to its anti -archaeal activity , it was determined that H. mediterranei is also able to inhibit the growth of Bacillus cereus. Finally, the H. mediterranei mutants lacking the crtB or sqs genes revealed the same antimicrobial profile as the wildtype strain. Thus, it was concluded that this bioactivity is not influenced by the production of bacterioruberin nor squalenes |
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Genetic determinants of haloarchaeal secondary metabolites, with focus on terpenesHaloarchaeaSecondary metabolitesBiosynthetic gene clustersBacterioruberinβ -caroteneRetinalEscalenoRiPPsCrtOPop -in/pop -outThe knowledge on the secondary metabolites (SMs) produced by archaea is a field where few research and experimental testing ha s been done, when comparing to bacteria or fungi.The class Halobacteria, composed by haloarchaea that need high concentrations of salt to survive, has been one of the best well studied in the domain Archae a, in this regard. Some examples include the class model organisms Haloferax mediterranei, Haloferax volcanii and Halobacterium salinarum. Haloarchaea produce halocins that are peptides with anti-archaeal activity, but information regarding their biosynthesis and structure is still limited. Genes involved in the production of other peptides with post-translational modifications (RiPPs) have also been identifie d but, so far, none have been isolated or characterized. It is also known that the main carotenoid produced by haloarch aea is bacterioruberin, which has higher antioxidant capacity than β-carotene. Haloarchaea can also produce β-carotene (mainly as a precursor molecule) and canthaxanthin. The objectives of this study were: i) to characterize the diversity of SMs encoded in haloarchaeal genomes, in particular the diversity of genes involved in the production of carotenoids and ii) to evaluate the antibacterial activity of H. mediterranei ATCC 33500 and the impact of the production of bacterioruberin on its antimicrobial activity. Herein, 67 complete genomes of haloarchaea were analysed and 182 biosynthetic gene clusters (BGC) where 49% of them shared no homology. The BGCs identified encode the production of terpenes (70%), RiPPs (16%) and siderophores (14%). A closer inspection of the terpene BGCs allowed their division into two groups: those encoding a bifunctional protein lycopene cyclase/phytoene synthase gene (crtB, 53%) and those encoding a squalene synthase (sqs, 46.5%). The crtB gene was mostly found associated with the biosynthetic genes of bacterioruberin. However, in 22% of the strains, genes from retinal biosynthesis or genes not related with the production of carotene s were found in the proximity of crtB. The results obtained confirmed that all haloarchaeal strains should be able to produce bacterio ruberin. In addition , about 64% of the species may produce β -carotene as a precursor of retinal biosynthesis and 3% as a final product and/or precursor of canthaxanthin synthesis. A gene that putatively encodes a β - carotene ketolase (CrtO) was identified in Haloterrigena turkmenica. To date, these enzymes have not been characterized in haloarch aea, but may be involved in the biosynthesis of cant haxanthin . The crtB gene was associated to the bacterioruberin synthesis pathway through the generation of a kn ock -out mutant and carotenoid quantification. In addition to its anti -archaeal activity , it was determined that H. mediterranei is also able to inhibit the growth of Bacillus cereus. Finally, the H. mediterranei mutants lacking the crtB or sqs genes revealed the same antimicrobial profile as the wildtype strain. Thus, it was concluded that this bioactivity is not influenced by the production of bacterioruberin nor squalenesO conhecimento dos metabolitos secundários (MS) produzidos por arqueas é bastante limitado, quando comparado com os de bactérias e fungos. No domínio Arquea, a classe Halobacteria, que é constituída por haloarqueas que necessitam de elevadas concentrações de sal para sobreviverem, tem sido das mais bem estudadas a este nível. Alguns exemplos incluem organismos modelo de classes como Haloferax mediterranei, Haloferax volcanii e Halobacterium salinarum. As haloarqueas produzem halocinas, que são péptidos com atividade antiarquea, mas dos quais existe pouca informação relativamente à sua biossíntese e estrutura. Genes envolvidos na produção de outros péptidos com modificações pós-traducionais (RiPPs) foram também já identificados, mas nenhum destes compostos foi isolado ou caracterizado. O principal carotenóide produzido por haloarqueas é a bacterioruberina, que tem despertado o interesse da comunidade científica devido à sua capacidade antioxidante ser superior à do β-caroteno. As haloarqueas também podem produzir β-caroteno (principalmente como percursor) e cantaxantina. Os objetivos deste estudo foram: i) caracterizar a diversidade de MSs codificados nos genomas de haloarqueas, em particular a diversidade dos genes envolvidos na produção de carotenóides e ii) avaliar a atividade antibacteriana de H. mediterranei ATCC 33500 e o impacto da produção de bacterioruberina na sua actividade antimicrobiana. Analisaram-se 67 genomas completos de haloarqueas nos quais foram identificados 182 clusters biossintéticos (CB) sendo que 49% deles não apresentaram homologia entre si. Os CBs detetados codificam a produção de terpenos (70%), RiPPs (16%) e sideróferos (14%). A análise dos CBs de terpenos permitiu a sua divisão em dois grupos: os que codificam a proteína bifuncional licopeno ciclase/fitoeno sintase (crtB, 53%) e os que codificam esqualeno sintases (sqs, 46,5%). O gene crtB foi encontrado maioritariamente associado a genes que codificam as proteínas necessárias para a produção de bacterioruberina. No entanto, em 22% das estirpes, encontraram-se na sua proximidade genes da síntese de retinal ou genes não relacionados com a produção de carotenos. A análise mais detalhada de todos os genes envolvidos no processo de carotenogénese permitiu confirmar que todas as haloarqueas devem produzir bacterioruberina. Para além deste caroteno, cerca de 64% das espécies deverão produzir β-caroteno como precursor da síntese de retinal e 3% como produto final e/ou precursor da síntese de cantaxantina. Foi identificado um gene em Haloterrigena turkmenica, que poderá codificar uma β-caroteno cetolase (CrtO). Até à data, estas enzimas não foram caracterizadas em haloarquea, mas podem estar envolvidas na biossíntese de cantaxantina. Através de mutantes sem o gene crtB, verificou-se que este gene está associado à produção de bacterioruberina. Foi também determinado que, para além de outras haloarqueas, H. mediterranei é capaz de inibir o crescimento de Bacillus cereus. Finalmente, os mutantes de H. mediterranei sem os genes crtB ou sqs revelaram ter o mesmo perfil antimicrobiano da estirpe original. Concluiu-se, portanto, que esta bioatividade não é influenciada pela produção de bacterioruberina nem de nenhum composto com origem em esqualenos2023-03-01T00:00:00Z2021-02-15T00:00:00Z2021-02-15info:eu-repo/semantics/publishedVersioninfo:eu-repo/semantics/masterThesisapplication/pdfhttp://hdl.handle.net/10773/30827engSerrano, Susana Margarida Guerrainfo:eu-repo/semantics/embargoedAccessreponame:Repositório Científico de Acesso Aberto de Portugal (Repositórios Cientìficos)instname:Agência para a Sociedade do Conhecimento (UMIC) - FCT - Sociedade da Informaçãoinstacron:RCAAP2024-02-22T11:59:34Zoai:ria.ua.pt:10773/30827Portal AgregadorONGhttps://www.rcaap.pt/oai/openaireopendoar:71602024-03-20T03:02:49.532335Repositório Científico de Acesso Aberto de Portugal (Repositórios Cientìficos) - Agência para a Sociedade do Conhecimento (UMIC) - FCT - Sociedade da Informaçãofalse |
| dc.title.none.fl_str_mv |
Genetic determinants of haloarchaeal secondary metabolites, with focus on terpenes |
| title |
Genetic determinants of haloarchaeal secondary metabolites, with focus on terpenes |
| spellingShingle |
Genetic determinants of haloarchaeal secondary metabolites, with focus on terpenes Serrano, Susana Margarida Guerra Haloarchaea Secondary metabolites Biosynthetic gene clusters Bacterioruberin β -carotene Retinal Escaleno RiPPs CrtO Pop -in/pop -out |
| title_short |
Genetic determinants of haloarchaeal secondary metabolites, with focus on terpenes |
| title_full |
Genetic determinants of haloarchaeal secondary metabolites, with focus on terpenes |
| title_fullStr |
Genetic determinants of haloarchaeal secondary metabolites, with focus on terpenes |
| title_full_unstemmed |
Genetic determinants of haloarchaeal secondary metabolites, with focus on terpenes |
| title_sort |
Genetic determinants of haloarchaeal secondary metabolites, with focus on terpenes |
| author |
Serrano, Susana Margarida Guerra |
| author_facet |
Serrano, Susana Margarida Guerra |
| author_role |
author |
| dc.contributor.author.fl_str_mv |
Serrano, Susana Margarida Guerra |
| dc.subject.por.fl_str_mv |
Haloarchaea Secondary metabolites Biosynthetic gene clusters Bacterioruberin β -carotene Retinal Escaleno RiPPs CrtO Pop -in/pop -out |
| topic |
Haloarchaea Secondary metabolites Biosynthetic gene clusters Bacterioruberin β -carotene Retinal Escaleno RiPPs CrtO Pop -in/pop -out |
| description |
The knowledge on the secondary metabolites (SMs) produced by archaea is a field where few research and experimental testing ha s been done, when comparing to bacteria or fungi.The class Halobacteria, composed by haloarchaea that need high concentrations of salt to survive, has been one of the best well studied in the domain Archae a, in this regard. Some examples include the class model organisms Haloferax mediterranei, Haloferax volcanii and Halobacterium salinarum. Haloarchaea produce halocins that are peptides with anti-archaeal activity, but information regarding their biosynthesis and structure is still limited. Genes involved in the production of other peptides with post-translational modifications (RiPPs) have also been identifie d but, so far, none have been isolated or characterized. It is also known that the main carotenoid produced by haloarch aea is bacterioruberin, which has higher antioxidant capacity than β-carotene. Haloarchaea can also produce β-carotene (mainly as a precursor molecule) and canthaxanthin. The objectives of this study were: i) to characterize the diversity of SMs encoded in haloarchaeal genomes, in particular the diversity of genes involved in the production of carotenoids and ii) to evaluate the antibacterial activity of H. mediterranei ATCC 33500 and the impact of the production of bacterioruberin on its antimicrobial activity. Herein, 67 complete genomes of haloarchaea were analysed and 182 biosynthetic gene clusters (BGC) where 49% of them shared no homology. The BGCs identified encode the production of terpenes (70%), RiPPs (16%) and siderophores (14%). A closer inspection of the terpene BGCs allowed their division into two groups: those encoding a bifunctional protein lycopene cyclase/phytoene synthase gene (crtB, 53%) and those encoding a squalene synthase (sqs, 46.5%). The crtB gene was mostly found associated with the biosynthetic genes of bacterioruberin. However, in 22% of the strains, genes from retinal biosynthesis or genes not related with the production of carotene s were found in the proximity of crtB. The results obtained confirmed that all haloarchaeal strains should be able to produce bacterio ruberin. In addition , about 64% of the species may produce β -carotene as a precursor of retinal biosynthesis and 3% as a final product and/or precursor of canthaxanthin synthesis. A gene that putatively encodes a β - carotene ketolase (CrtO) was identified in Haloterrigena turkmenica. To date, these enzymes have not been characterized in haloarch aea, but may be involved in the biosynthesis of cant haxanthin . The crtB gene was associated to the bacterioruberin synthesis pathway through the generation of a kn ock -out mutant and carotenoid quantification. In addition to its anti -archaeal activity , it was determined that H. mediterranei is also able to inhibit the growth of Bacillus cereus. Finally, the H. mediterranei mutants lacking the crtB or sqs genes revealed the same antimicrobial profile as the wildtype strain. Thus, it was concluded that this bioactivity is not influenced by the production of bacterioruberin nor squalenes |
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2021 |
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2021-02-15T00:00:00Z 2021-02-15 2023-03-01T00:00:00Z |
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