Utilização de Burkholderia sp. 89 para o controle biológico de fungos fitopatogênicos e identificação de moléculas de seu metabolismo secundário envolvidas nesse processo

Bach, Evelise

January 2016

O uso de bactérias promotoras de crescimento vegetal ou agentes de biocontrole como inoculantes agrícolas é uma alternativa importante e ecologicamente correta, com grandes benefícios na agricultura para substituir, ou ao menos suplementar, a excessiva utilização de fertilizantes e pesticidas. Neste trabalho avaliamos a capacidade de biocontrole e de competência rizosférica de três bactérias com características de promoção de crescimento vegetal (Plant growth promoting - PGP): Bacillus mycoides B38V, Paenibacillus riograndensis SBR5 e Burkholderia sp. 89. As três bactérias avaliadas apresentaram grande versatilidade na utilização de substratos, o que poderia lhes garantir uma vantagem competitiva no ambiente rizosférico. Porém, inconsistências foram observadas nos ensaios em câmara de crescimento, ou seja, as características de PGP e de biocontrole observadas in vitro não se refletiram em benefícios para a planta. A linhagem 89 destacou-se pela produção de um metabólito estável com ampla atividade contra fungos fitopatogênicos. Através de abordagens genômicas e de análises multilocus, descrevemos Burkholderia sp. 89 como uma nova espécie membro do complexo Burkholderia cepacia, denominada de B. catarinensis 89T. O sequenciamento de seu genoma, seguido de uma análise pela ferramenta AntiSMASH, revelou a presença de um agrupamento gênico de peptídeo sintetases não ribossomais (NRPS) relacionadas com a biossíntese do sideróforo ornibactina e um agrupamento híbrido NRPS-policetídeo sintetase responsável pela biossíntese do glicolipopeptideo cíclico com atividade antifúngica burkholdina. Como estratégia de purificação de metabólitos secundários foi utilizada a metodologia da mineração de genoma combinada com fracionamento guiado por bioensaios seguida de análises em espectrômetro de massas. Desta forma, purificamos com sucesso duas variantes de ornibactina, D e F (761 e 789 Da, respectivamente), e detectamos a variante ornibactina B (m/z= 733) e as moléculas sinalizadoras homoserina lactonas C6-HSL, 3OH-C8-HSL e C8-HSL. Análises de espectrometria de massas demonstraram a presença de um grupo de metabólitos com massas de 1240, 1254, 1268, 1216, 1244 e 1272 Da, que, provavelmente, são novas variantes do antifúngico burkoldina. Sendo assim, B. catarinensis 89T possui potencial biotecnológico com possíveis aplicações farmacêuticas e agronômicas para o biocontrole de fungos fitopatogênicos. / The use of plant growth promotion bacteria or biocontrol agents as agricultural inoculants is an important eco-friendly alternative to substitute, or at least supplement, the excessive use of fertilizers and pesticides. In this work, we evaluated the biocontrol potential and rhizosphere competence of three bacteria that had shown plant growth promotion (PGP) abilities: Bacillus mycoides B38V, Paenibacillus riograndensis SBR5 and Burkholderia sp. 89. All three bacteria presented great versatility in their substrate utilization, which could enable them to survive in a competitive rhizosphere environment. However, inconsistencies were observed in the greenhouse experiments, whereas their interesting abilities observed in vitro did not result in benefits to the plants. Strain 89 produces a stable metabolite with a wide range of antifungal activity. Genomic comparisons and multilocus sequence analysis revealed Burkholderia sp. 89 as a new species of the Burkholderia cepacia complex and we described it as B. catarinensis 89T. We sequenced its genome and analyzed it with the AntiSMASH tool. This in silico prediction revealed the presence of a nonribosomal peptide synthetase (NRPS) cluster, which is related to the production of the siderophore ornibactin. Moreover, a hybrid NRPS- polyketide synthetase cluster for the production of the antifungal cyclic glicolipopeptide burkholdin was also found. A genome mining combined with a bioassay-guided fractionation with further mass spectrometry analysis was applied for the purification of these compounds. This approach enabled us to purify and characterize two variants of the siderophore ornibactin, D and F (761 and 789 Da, respectively). Also, we could detect the variant ornibactin B (m/z= 733) and the quorum sensing molecules homoserine lactones C6-HSL, 3OH-C8-HSL and C8-HSL in the supernatant of B. catarinensis 89T. Mass spectrometry analysis showed the presence of a group of metabolites with the masses 1240, 1254, 1268, 1216, 1244 and 1272 Da, which are probably new variants of the antifungal metabolite burkoldin. Therefore, B. catarinensis 89T has a great biotechnological potential for the production of metabolites with pharmaceutical and agricultural applications for the biocontrol of phytopathogenic fungi.

Bactérias

Controle biologico

Burkholderia

Genoma bacteriano

Metabólito antifúngico

Biocontrol

Rhizosphere competence

Burkholderia identification

Bacterial genome

Antifungal metabolite

Utilização de Burkholderia sp. 89 para o controle biológico de fungos fitopatogênicos e identificação de moléculas de seu metabolismo secundário envolvidas nesse processo

Bach, Evelise

January 2016

O uso de bactérias promotoras de crescimento vegetal ou agentes de biocontrole como inoculantes agrícolas é uma alternativa importante e ecologicamente correta, com grandes benefícios na agricultura para substituir, ou ao menos suplementar, a excessiva utilização de fertilizantes e pesticidas. Neste trabalho avaliamos a capacidade de biocontrole e de competência rizosférica de três bactérias com características de promoção de crescimento vegetal (Plant growth promoting - PGP): Bacillus mycoides B38V, Paenibacillus riograndensis SBR5 e Burkholderia sp. 89. As três bactérias avaliadas apresentaram grande versatilidade na utilização de substratos, o que poderia lhes garantir uma vantagem competitiva no ambiente rizosférico. Porém, inconsistências foram observadas nos ensaios em câmara de crescimento, ou seja, as características de PGP e de biocontrole observadas in vitro não se refletiram em benefícios para a planta. A linhagem 89 destacou-se pela produção de um metabólito estável com ampla atividade contra fungos fitopatogênicos. Através de abordagens genômicas e de análises multilocus, descrevemos Burkholderia sp. 89 como uma nova espécie membro do complexo Burkholderia cepacia, denominada de B. catarinensis 89T. O sequenciamento de seu genoma, seguido de uma análise pela ferramenta AntiSMASH, revelou a presença de um agrupamento gênico de peptídeo sintetases não ribossomais (NRPS) relacionadas com a biossíntese do sideróforo ornibactina e um agrupamento híbrido NRPS-policetídeo sintetase responsável pela biossíntese do glicolipopeptideo cíclico com atividade antifúngica burkholdina. Como estratégia de purificação de metabólitos secundários foi utilizada a metodologia da mineração de genoma combinada com fracionamento guiado por bioensaios seguida de análises em espectrômetro de massas. Desta forma, purificamos com sucesso duas variantes de ornibactina, D e F (761 e 789 Da, respectivamente), e detectamos a variante ornibactina B (m/z= 733) e as moléculas sinalizadoras homoserina lactonas C6-HSL, 3OH-C8-HSL e C8-HSL. Análises de espectrometria de massas demonstraram a presença de um grupo de metabólitos com massas de 1240, 1254, 1268, 1216, 1244 e 1272 Da, que, provavelmente, são novas variantes do antifúngico burkoldina. Sendo assim, B. catarinensis 89T possui potencial biotecnológico com possíveis aplicações farmacêuticas e agronômicas para o biocontrole de fungos fitopatogênicos. / The use of plant growth promotion bacteria or biocontrol agents as agricultural inoculants is an important eco-friendly alternative to substitute, or at least supplement, the excessive use of fertilizers and pesticides. In this work, we evaluated the biocontrol potential and rhizosphere competence of three bacteria that had shown plant growth promotion (PGP) abilities: Bacillus mycoides B38V, Paenibacillus riograndensis SBR5 and Burkholderia sp. 89. All three bacteria presented great versatility in their substrate utilization, which could enable them to survive in a competitive rhizosphere environment. However, inconsistencies were observed in the greenhouse experiments, whereas their interesting abilities observed in vitro did not result in benefits to the plants. Strain 89 produces a stable metabolite with a wide range of antifungal activity. Genomic comparisons and multilocus sequence analysis revealed Burkholderia sp. 89 as a new species of the Burkholderia cepacia complex and we described it as B. catarinensis 89T. We sequenced its genome and analyzed it with the AntiSMASH tool. This in silico prediction revealed the presence of a nonribosomal peptide synthetase (NRPS) cluster, which is related to the production of the siderophore ornibactin. Moreover, a hybrid NRPS- polyketide synthetase cluster for the production of the antifungal cyclic glicolipopeptide burkholdin was also found. A genome mining combined with a bioassay-guided fractionation with further mass spectrometry analysis was applied for the purification of these compounds. This approach enabled us to purify and characterize two variants of the siderophore ornibactin, D and F (761 and 789 Da, respectively). Also, we could detect the variant ornibactin B (m/z= 733) and the quorum sensing molecules homoserine lactones C6-HSL, 3OH-C8-HSL and C8-HSL in the supernatant of B. catarinensis 89T. Mass spectrometry analysis showed the presence of a group of metabolites with the masses 1240, 1254, 1268, 1216, 1244 and 1272 Da, which are probably new variants of the antifungal metabolite burkoldin. Therefore, B. catarinensis 89T has a great biotechnological potential for the production of metabolites with pharmaceutical and agricultural applications for the biocontrol of phytopathogenic fungi.

Bactérias

Controle biologico

Burkholderia

Genoma bacteriano

Metabólito antifúngico

Biocontrol

Rhizosphere competence

Burkholderia identification

Bacterial genome

Antifungal metabolite

Utilização de Burkholderia sp. 89 para o controle biológico de fungos fitopatogênicos e identificação de moléculas de seu metabolismo secundário envolvidas nesse processo

Bach, Evelise

January 2016

O uso de bactérias promotoras de crescimento vegetal ou agentes de biocontrole como inoculantes agrícolas é uma alternativa importante e ecologicamente correta, com grandes benefícios na agricultura para substituir, ou ao menos suplementar, a excessiva utilização de fertilizantes e pesticidas. Neste trabalho avaliamos a capacidade de biocontrole e de competência rizosférica de três bactérias com características de promoção de crescimento vegetal (Plant growth promoting - PGP): Bacillus mycoides B38V, Paenibacillus riograndensis SBR5 e Burkholderia sp. 89. As três bactérias avaliadas apresentaram grande versatilidade na utilização de substratos, o que poderia lhes garantir uma vantagem competitiva no ambiente rizosférico. Porém, inconsistências foram observadas nos ensaios em câmara de crescimento, ou seja, as características de PGP e de biocontrole observadas in vitro não se refletiram em benefícios para a planta. A linhagem 89 destacou-se pela produção de um metabólito estável com ampla atividade contra fungos fitopatogênicos. Através de abordagens genômicas e de análises multilocus, descrevemos Burkholderia sp. 89 como uma nova espécie membro do complexo Burkholderia cepacia, denominada de B. catarinensis 89T. O sequenciamento de seu genoma, seguido de uma análise pela ferramenta AntiSMASH, revelou a presença de um agrupamento gênico de peptídeo sintetases não ribossomais (NRPS) relacionadas com a biossíntese do sideróforo ornibactina e um agrupamento híbrido NRPS-policetídeo sintetase responsável pela biossíntese do glicolipopeptideo cíclico com atividade antifúngica burkholdina. Como estratégia de purificação de metabólitos secundários foi utilizada a metodologia da mineração de genoma combinada com fracionamento guiado por bioensaios seguida de análises em espectrômetro de massas. Desta forma, purificamos com sucesso duas variantes de ornibactina, D e F (761 e 789 Da, respectivamente), e detectamos a variante ornibactina B (m/z= 733) e as moléculas sinalizadoras homoserina lactonas C6-HSL, 3OH-C8-HSL e C8-HSL. Análises de espectrometria de massas demonstraram a presença de um grupo de metabólitos com massas de 1240, 1254, 1268, 1216, 1244 e 1272 Da, que, provavelmente, são novas variantes do antifúngico burkoldina. Sendo assim, B. catarinensis 89T possui potencial biotecnológico com possíveis aplicações farmacêuticas e agronômicas para o biocontrole de fungos fitopatogênicos. / The use of plant growth promotion bacteria or biocontrol agents as agricultural inoculants is an important eco-friendly alternative to substitute, or at least supplement, the excessive use of fertilizers and pesticides. In this work, we evaluated the biocontrol potential and rhizosphere competence of three bacteria that had shown plant growth promotion (PGP) abilities: Bacillus mycoides B38V, Paenibacillus riograndensis SBR5 and Burkholderia sp. 89. All three bacteria presented great versatility in their substrate utilization, which could enable them to survive in a competitive rhizosphere environment. However, inconsistencies were observed in the greenhouse experiments, whereas their interesting abilities observed in vitro did not result in benefits to the plants. Strain 89 produces a stable metabolite with a wide range of antifungal activity. Genomic comparisons and multilocus sequence analysis revealed Burkholderia sp. 89 as a new species of the Burkholderia cepacia complex and we described it as B. catarinensis 89T. We sequenced its genome and analyzed it with the AntiSMASH tool. This in silico prediction revealed the presence of a nonribosomal peptide synthetase (NRPS) cluster, which is related to the production of the siderophore ornibactin. Moreover, a hybrid NRPS- polyketide synthetase cluster for the production of the antifungal cyclic glicolipopeptide burkholdin was also found. A genome mining combined with a bioassay-guided fractionation with further mass spectrometry analysis was applied for the purification of these compounds. This approach enabled us to purify and characterize two variants of the siderophore ornibactin, D and F (761 and 789 Da, respectively). Also, we could detect the variant ornibactin B (m/z= 733) and the quorum sensing molecules homoserine lactones C6-HSL, 3OH-C8-HSL and C8-HSL in the supernatant of B. catarinensis 89T. Mass spectrometry analysis showed the presence of a group of metabolites with the masses 1240, 1254, 1268, 1216, 1244 and 1272 Da, which are probably new variants of the antifungal metabolite burkoldin. Therefore, B. catarinensis 89T has a great biotechnological potential for the production of metabolites with pharmaceutical and agricultural applications for the biocontrol of phytopathogenic fungi.

Bactérias

Controle biologico

Burkholderia

Genoma bacteriano

Metabólito antifúngico

Biocontrol

Rhizosphere competence

Burkholderia identification

Bacterial genome

Antifungal metabolite

Ecology and diversity of indigenous Trichoderma species in vegetable cropping systems

Bourguignon, Emmanuel

January 2008

The overall aim of this research was to improve the understanding of the ecology and diversity of Trichoderma species within the soil and rhizosphere of onion (Allium cepa L.) and potato (Solanum tuberosum L.) under intensive management in New Zealand. The indigenous Trichoderma population was measured in a field trial at Pukekohe over a three year period under six different crop rotation treatments. The treatments included two continuous onion and potato rotations (intensive), two onion/potato mixed rotation (conventional), and two green manure rotations (sustainable). Results showed that Trichoderma populations were stable in both the rhizosphere and bulk soil (1.5 x 10² to 8.5 x 10³ CFU g⁻¹ ODS). The planting and incorporation of an oat (Avena sativa L.) green manure in the sustainable rotations positively increased Trichoderma colony forming unit (CFU) numbers in the rhizosphere soil from 3.4 x 10² to 2.5 x 10³ g⁻¹ ODS. A Trichoderma species identification method was developed based on colony morphology. Representative isolates were verified using restriction fragment length polymorphism (RFLP) and DNA sequencing. The method allowed for rapid and reliable identification of isolated Trichoderma species. Five species were identified in the Pukekohe soil: T. asperellum, T. atroviride, T. hamatum, T. harzianum and T. koningii. Results showed identical species diversity between the rhizosphere, rhizoplane and bulk soil. The species did not strongly compete between each other for the rhizosphere ecological niche and differences in species proportions seemed to be caused by environmental factors rather than the rotation treatments. The incorporation of oat green manure in pots did not significantly promote the indigenous Trichoderma population size and diversity in the rhizosphere of onion plants up to 4 months old. The identified species were the same as in the field trial. The incorporation of onion scale residues was shown to result in low Trichoderma and high Penicillium CFU numbers and a reduction in plant size. Additionally, the presence of high levels (6.0 x 10⁵ CFU g⁻¹ ODS) of Penicillium CFU was negatively correlated with the presence of Trichoderma CFU. The effect of oat incorporation on Trichoderma saprophytic growth was also investigated in a soil sandwich assay and revealed no significant differences. A series of experiments indicated that onion extract obtained from dry onion scale residues had no antifungal activity against either Trichoderma or Penicillium and instead tended to promote their hyphal growth and sporulation. It also showed that competition between Penicillium and Trichoderma isolates was limited despite the ability of Penicillium to produce a wide range of inhibitory substances. Four indigenous Trichoderma species (T. atroviride, T. hamatum, T. harzianum and T. koningii) were shown to be rhizosphere competent in a split tube experiment over a 6 week period. The results of this experiment revealed that, the Trichoderma species clearly displayed differences in their ability to colonise the rhizosphere of young onion seedlings. Species such as T. koningii had the greatest rhizosphere colonising ability regardless of soil depth while T. harzianum displayed the weakest ability. Results also indicated that when inoculated as a mixture the four species competed with one another to colonise the rhizosphere. Overall, this research indicated that the studied crop rotation treatments and the use of oat as a green manure did not strongly promote indigenous Trichoderma populations. Species diversity was constant throughout the research with T. hamatum and T. koningii being the most frequently isolated species.

Trichoderma

rhizosphere

ecology

indigenous

population

crop rotation

Allium cepa L.

Solanum tuberosum L.

Avena sativa L.

green manure

amendments

species diversity

identification

RFLP

Penicillium

rhizosphere competence