Metagenomic analysis and antimicrobial activity of two fermented milk kefir samples.

In recent years, the fermented milk product kefir has been intensively studied because of its health benefits. Here, we evaluated the microbial consortia of two kefir samples, from Escarcega, Campeche, and Campeche (México). We considered a functional comparison between both samples, including fungal and bacterial inhibition; second, we applied shotgun metagenomics to assess the structure and functional diversity of the communities of microorganisms. These two samples exhibited antagonisms against bacterial and fungal pathogens. Bioactive polyketides and nonribosomal peptides were identified by LC-HRMS analysis. We also observed a high bacterial diversity and an abundance of Actinobacteria in both kefir samples, and a greater abundance of Saccharomyces species in kefir of Escarcega than in the Campeche kefir. When the prophage compositions were evaluated, the Campeche sample showed a higher diversity of prophage sequences. In Escarcega, we observed a prevalence of prophage families that infect Enterobacteria and Lactobacillus. The sequences associated with secondary metabolites, such as plipastatin, fengycin, and bacillaene, and also bacteriocins like helveticin and zoocin, were also found in different proportions, with greater diversity in the Escarcega sample. The analyses described in this work open the opportunity to understand the microbial diversity in kefir samples from two distant localities.

Inhibición del crecimiento y modificación genética de Phytophthora capsici usando quitosano de bajo grado de polimerización / Growth inhibition and genetic modification of Phytophthora capsici using chitosan with low degree of polymerization

Phytophtora capsici es un patógeno que incide sobre cultivos de la familia de las solanáceas causando pérdidas económicas en cultivos de pimientos, tomates, berenjenas y cur-cubitáceas. En este trabajo evaluamos el efecto del quitosano de bajo grado de polimerización (QBP) sobre el crecimiento de P. capsici y sobre la regulación génica de este fitopatógeno a nivel transcripcional. A una concentración de 0,4mg/l de QBP se obtuvo un 88% de inhibición en el crecimiento; concentraciones superiores a 1,6 mg/l inhibieron el crecimiento en un 100%. Mediante ensayos de cambio en la movilidad electroforética de ácidos nucleicos se comprobó que el quitosano interactúa con el ADN y el ARN del hongo frente a concentraciones entre 2 y 4 mg/l de ADN y entre 0,5 y 3 mg/l de ARN. Además, se efectuó un análisis de despliegue diferencial de los productos de amplificación por RT-PCR de los ARN mensajeros de P. capsici obtenidos en presencia o ausencia de QBP; este mostró cambios en el perfil de expresión inducidos por el tratamiento con quitosano. El análisis bioinformático de las secuencias de los transcritos expresados diferencialmente sugiere que el QBP afectó la regulación génica de elementos involucrados en la síntesis de quitina y de proteínas de unión a hidratos de carbono.

Phytophthora blight of peppers, caused by oomycete Phytophthora capsici, currently causes economic losses in crops such as peppers, tomatoes, eggplant and cucurbits. In this work, we evaluated the effect of chitosan with low degree of polymerization (LDP) on growth and gene expression of P. capsici cultures. LDP chitosan inhibited 88% of P. capsici mycelial growth at concentrations up to 0,4 mg/l, whereas at concentrations higher than 1,6 mg/l it completely inhibit growth. Gel mobility shift assays demonstrated that chitosan interacts with DNA and RNA of the fungus at concentrations ranging from 2 to 4 mg/l for DNA and 0,5 to 3 mg/l for RNA. The differential display analysis of RT-PCR-amplification products of P. capsici messenger RNA revealed changes in gene expression profiles after the chitosan treatment. Bioinformatic analysis of sequences from selected differentially-expressed bands showed the gene regulation of elements involved in chitin synthesis and carbohydrate-binding proteins.

[Growth inhibition and genetic modification of Phytophthora capsici using chitosan with low degree of polymerization]. / Inhibición del crecimiento y modificación genética de Phytophthora capsici usando quitosano de bajo grado de polimerización.

Phytophthora blight of peppers, caused by oomycete Phytophthora capsici, currently causes economic losses in crops such as peppers, tomatoes, eggplant and cucurbits. In this work, we evaluated the effect of chitosan with low degree of polymerization (LDP) on growth and gene expression of P. capsici cultures. LDP chitosan inhibited 88% of P. capsici mycelial growth at concentrations up to 0,4 mg/l, whereas at concentrations higher than 1,6 mg/l it completely inhibit growth. Gel mobility shift assays demonstrated that chitosan interacts with DNA and RNA of the fungus at concentrations ranging from 2 to 4mg/l for DNA and 0,5 to 3mg/l for RNA. The differential display analysis of RT-PCR-amplification products of P. capsici messenger RNA revealed changes in gene expression profiles after the chitosan treatment. Bioinformatic analysis of sequences from selected differentially-expressed bands showed the gene regulation of elements involved in chitin synthesis and carbohydrate-binding proteins.