Using kin discrimination to construct synthetic microbial communities of Bacillus subtilis strains impacts the growth of black soldier fly larvae.

Using synthetic microbial communities to promote host growth is an effective approach. However, the construction of such communities lacks theoretical guidance. Kin discrimination is an effective means by which strains can recognize themselves from non-self, and construct competitive microbial communities to produce more secondary metabolites. However, the construction of cooperative communities benefits from the widespread use of beneficial microorganisms. We used kin discrimination to construct synthetic communities (SCs) comprising 13 Bacillus subtilis strains from the surface and gut of black soldier fly (BSF) larvae. We assessed larval growth promotion in a pigeon manure system and found that the synthetic community comprising 4 strains (SC 4) had the most profound effect. Genomic analyses of these 4 strains revealed that their complementary functional genes underpinned the robust functionality of the cooperative synthetic community, highlighting the importance of strain diversity. After analyzing the bacterial composition of BSF larvae and the pigeon manure substrate, we observed that SC 4 altered the bacterial abundance in both the larval gut and pigeon manure. This also influenced microbial metabolic functions and co-occurrence network complexity. Kin discrimination facilitates the rapid construction of synthetic communities. The positive effects of SC 4 on larval weight gain resulted from the functional redundancy and complementarity among the strains. Furthermore, SC 4 may enhance larval growth by inducing shifts in the bacterial composition of the larval gut and pigeon manure. This elucidated how the SC promoted larval growth by regulating bacterial composition and provided theoretical guidance for the construction of SCs.

Resveratrol attenuates atherosclerotic endothelial injury through the Pin1/Notch1 pathway.

The present study investigates whether resveratrol could modulate the endothelial dysfunction of atherosclerosis via the Pin1/Notch1 signaling pathway. To assess the vascular endothelial cell (VECs) injury in mice, the levels of serum soluble vascular cell adhesion molecule-1 (sVCAM-1), soluble intercellular adhesion molecule-1 (sICAM-1), soluble E-selectin (sE-selectin), soluble thrombomodulin (sTM), and von Willebrand factor (vWF) were measured. Expressions of Pin1 and Notch1 intracellular domain (NICD1), both mRNA and protein, were also measured. Human umbilical vein endothelial cells (HUVECs) treated with 100 µg/mL oxidized low-density lipoprotein (ox-LDL) were incubated with resveratrol at doses from 10 µM to 40 µM. Cell function was evaluated by measuring apoptosis, cell viability, lipid accumulation, and adherent human myeloid leukemia mononuclear (THP-1) cells. Resveratrol intervention in AS mice decreased the expression of serum sVCAM-1, sICAM-1, sE-selectin, sTM, and vWF and dose-dependently down-regulated Pin1 and NICD1 mRNA and protein expression in endothelial cells. Resveratrol intervention reversed ox-LDL-induced cell dysfunction by increasing viability and decreasing apoptosis, lipid accumulation, and the adhesion of THP-1 cells. These beneficial effects were reversed by the overexpression of Pin1. Resveratrol regulates endothelial cell injury of atherosclerosis by inhibiting the Pin1/Notch1 signaling pathway, suggesting novel therapeutic targets for atherosclerosis treatment.

Genomics and lipidomics analysis of the biotechnologically important oleaginous red yeast Rhodotorula glutinis ZHK provides new insights into its lipid and carotenoid metabolism.

BACKGROUND: Rhodotorula glutinis is recognized as a biotechnologically important oleaginous red yeast, which synthesizes numerous meritorious compounds with wide industrial usages. One of the most notable properties of R. glutinis is the formation of intracellular lipid droplets full of carotenoids. However, the basic genomic features that underlie the biosynthesis of these valuable compounds in R. glutinis have not been fully documented. To reveal the biotechnological potential of R. glutinis, the genomics and lipidomics analysis was performed through the Next-Generation Sequencing and HPLC-MS-based metabolomics technologies. RESULTS: Here, we firstly assemble the genome of R. glutinis ZHK into 21.8 Mb, containing 30 scaffolds and 6774 predicted genes with a N50 length of 14, 66,672 bp and GC content of 67.8%. Genome completeness assessment (BUSCO alignment: 95.3%) indicated the genome assembly with a high-quality features. According to the functional annotation of the genome, we predicted several key genes involved in lipids and carotenoids metabolism as well as certain industrial enzymes biosynthesis. Comparative genomics results suggested that most of orthologous genes have underwent the strong purifying selection within the five Rhodotorula species, especially genes responsible for carotenoids biosynthesis. Furthermore, a total of 982 lipids were identified using the lipidomics approaches, mainly including triacylglycerols, diacylglyceryltrimethylhomo-ser and phosphatidylethanolamine. CONCLUSION: Using whole genome shotgun sequencing, we comprehensively analyzed the genome of R. glutinis and predicted several key genes involved in lipids and carotenoids metabolism. By performing comparative genomic analysis, we show that most of the ortholog genes have undergone strong purifying selection within the five Rhodotorula species. Furthermore, we identified 982 lipid species using lipidomic approaches. These results provided valuable resources to further advance biotechnological applications of R .glutinis.

[Mitigating the repress of cinnamic acid to cucumber growth by microbial strain].

Cucumber is one of the most important vegetable species. Its continuous planting has become a common practice demand in many areas of China, but an obstacle from continuous planting made sustainable production of this crop to be prohibited. The self-toxic effect was considered as an important negative factor to continuous cropping cucumber. And cinnamic acid was found to be the main substance to cause self-toxic. Strain Ha8, which isolated from waste water estuary in Zhuhai city and has been authenticated as Cellulosimicrobium cellulans, was found to be able to degrade cinnamic acid, benzoic acid, paraaminobenzoic acid and phenol. Its biologic degrading rate to cinnamic acid was 64.1% and its total degrading rate to cinnamic acid was 79.32% . Therefore, strain Ha8 was used to mitigate the growth stress of cucumber caused by cinnamic acid in the research. In the experiment by hydroponic culturing method, it was found that the stem length, root length, stem weight, leaf weight, root weight, numbers of flower and harvest weight of cucumbers were lower than those untreated ones when added 2micromol/L or 10micromol/L cinnamic acid in culturing solution. But when added 10(7)cfu/L of strain Ha8 and 2micromol/L or 10micromol/L cinnamic acid in same culturing solution, these parameters were higher than those treated only by 2mircomol/L or 10micromol/L cinnamic acid. The result shown that strain Ha8 could mitigate the self-toxic effect caused by cinnamic acid. In edaphic culturing experiments, it was found that organic fertilizer mixed with strain Ha8 could mitigate the growth stress of cucumber caused by 100mg/kg cinnamic acid. When added 3mg/kg sterilized organic fertilizer with strain Ha8 (> or = 10(6)cfu/g dry organic fertilizer) in the culturing soil, the result was satisfied. This treatment could not only improve the growth of cucumber, enhance their root dehydrogenase activity and output, promote their nutrition absorption rate, but also adjust the microbial groups in nonrhizospheric soil of cucumber, increase the number of beneficial bacteria and actinomycete, decrease the number of fungi.