Antibiotic resistance has become one of the world’s most severe problems because of the overuse of antibiotics. Antibiotic-resistant bacteria are more difficult to kill and more expensive to treat. Researchers have been studied on antibiotic alternatives such as antimicrobial peptides and lipopeptides. A functional bacteria MB01 producing lipopeptides which can be used as bacteriostat was isolated from the Bohai Sea sediments, which had been identified as Bacillus licheniformis by the morphological, physiological, and biochemical identification and 16s rDNA sequence. The lipopeptides produced by MB01 were determined to be cyclic surfactin homologs by LC-ESI-MS structural identification after crude extraction and LH-20 chromatography. [M+H]+
m/z 994, 1008, 1022, and 1036 were all the characteristic molecular weight of surfactin homologs. CID analysis revealed that the molecular structure of the lipopeptides was Rn-Glu1-Leu/Ile2-Leu3-Val4-Asp5-Leu6-Leu/Ile7. The lipopeptides showed well resistance to UV light and the change of pH and temperature.
Metamorphism and deformation significantly affect the macromolecular structure of coal. In this study, experiments were conducted using coal samples with different metamorphic degrees and deformation types from different regions of Hebei, Henan, Shanxi, and Anhui province, followed by laser Raman spectral analysis. The results indicated that the Raman spectrum of all coal samples consist of two characteristic peaks, namely the D peak and the G peak, ranging from 1336.7 cm −1 to 1360 cm −1 and from 1591.2 cm −1 to 1600.6 cm −1 , respectively. Simultaneously, with the metamorphic degree of coal increasing, certain change rules were observed in both strong and weak tectonically deformed coals: G and D peaks were gradually separated and the sharpness of these peaks was clearly enhanced. In addition, the D-peak position, full width at half maximum for the G-peak (fwhm-G), and the intensity ratio between the D and G-peaks (I D /I G ) decreased, but the G-peak position and d(G−D) values increased, while the analysis results indicated that the change trends in the d(G−D) values can serve as a measure of the change trends in the metamorphic degree of coal. Meanwhile, tectonic deformation can somewhat promote the order degree of the aromatic structure in the internal microscopic structure of coal, and the effects of tectonic deformation on macromolecular structure of coal are even greater than those of high metamorphic stage in the low metamorphic stage.
Amino acids are required for the mammalian target of rapamycin (mTOR) signaling pathway and milk synthesis in bovine mammary epithelial cells (BMECs). However, the mechanism through which amino acids activate this pathway is largely unknown. Here we show that glycyl-tRNA synthetase (GlyRS) mediates amino acid-induced activation of the mTOR-S6K1/4EBP1 pathway, and milk protein and fat synthesis in BMECs. Among 19 aminoacyl-tRNA synthetases, only the mRNA expression of GlyRS and Leucyl-tRNA synthetase (LeuRS) were significantly increased by several amino acids including Met and Leu. We then observed that GlyRS knockdown abolished the stimulation of Met on milk protein and fat synthesis in BMECs, whereas GlyRS overexpression led to more significantly increased milk synthesis in cells treated with Met. By western blotting and qualitative real time-polymerase chain reaction analysis (qRT-PCR) analysis, we next revealed that GlyRS is required for amino acid-induced activation of the mTOR-S6K1/4EBP1 pathway. Thus, this study establishes that GlyRS mediates amino acid-induced activation of the mTOR pathway, thereby regulating milk protein and fat synthesis.
The intracellular fatty acid-binding proteins (FABPs) are a well-conserved family that function as lipid chaperones. Ongoing studies are focused on identification of the mechanistic complexity and vast biological diversity of different isoforms of FABPs. However, the molecular mechanism of FABP5 in the regulation of milk fat synthesis in the mammary gland of dairy cows is still largely unknown. Here, we report that FABP5 acts as a critical regulator of terol response element-binding protein-1c (SREBP-1c) gene expression induced by methionine (Met) and estrogen (E2) in bovine mammary epithelial cells (BMECs). We observed that the expression of FABP5 was markedly higher in dairy cow mammary tissue during the lactating period than the puberty period and the dry period. FABP5 is located in the cytoplasm, and Met and E2 significantly increase the protein levels of FABP5 in BMECs. Using gene function study approaches, we revealed that FABP5 positively regulates SREBP-1c gene expression and promotes milk fat synthesis. We confirmed that FABP5 is required for Met- and E2-induced SREBP-1c gene expression and milk fat synthesis. We further uncovered that fatty acids are needed for FABP5-mediated SREBP-1c gene expression. Thus, our study demonstrates that FABP5 is a critical regulator of Met- and E2-induced SREBP-1c gene expression leading to milk fat synthesis.
Sequence-related amplified polymorphism (SRAP) markers were used to assess genetic relationships among 76 grape genotypes including Chinese indigenous and newly bred varieties, representatives of foreign grape varieties, and wild Vitis species. Nineteen informative primers were selected from 100 SRAP primer pairs due to their ability to produce clearly and repeatedly polymorphic and unambiguous bands among the varieties. A total of 228 bands were produced; 78.63% of them were polymorphic; the average polymorphism information content (PIC) is 0.76. Genetic relationships were obtained using Nei and Li similarity coefficients. Cluster analysis of SRAP markers through the unweighted pairgroup method of arithmetic averages (UPGMA) analysis and principal coordinate analysis (PCoA) were largely consistent. The definition of clusters in the dendrogram and PCoA plot is the same and some degree of grouping by types of grape, ecogeographical origin, and taxonomic status of the varieties was revealed. Three main groups were found after cluster analysis, i.e., table grape of Vitis vinifera; table grape of Euro-America hybrid and wine grape of V. vinifera; wild Vitis species. Groupings indicated a divergence between the table and wine-type varieties of V. vinifera. The results showed that the wild Vitis species that originated from America and China could be clearly differentiated and Vitis hancockii is the most distant from the others of Asian Vitis species. The results also indicated that SRAP markers are informative and could distinguish bud sports of grape. The present analysis revealed that Chinese cultivated and wild grape germplasm are highly variable and have abundant genetic diversity.
Drought stress severely impairs plant growth and production. Lipoxygenase (LOX), a master regulator for lipid peroxidation, is critical for direct or indirect response to abiotic stresses. Here, we found that drought stress induced the transcription of CmLOX10 in leaves of oriental melon seedlings. Reverse genetic approaches and physiological analyses revealed that silencing CmLOX10 increased drought susceptibility and stomatal aperture in oriental melon seedlings, and that ectopic overexpression of CmLOX10 in Arabidopsis enhanced drought tolerance and decreased the stomatal aperture. Moreover, the transcription of jasmonic acid (JA)-related genes and JA accumulation were significantly induced in CmLOX10-overexpressed Arabidopsis, which were reversely suppressed in CmLOX10-silenced seedlings during the stage of drought stress. Foliar application of JA further verified that JA enhanced drought tolerance and induced stomatal closure in leaves of melon seedlings. In addition, the feedback regulation of CmLOX10 was induced by JA signaling, and the expression level of CmMYC2 was increased by JA and drought treatment. Yeast one-hybrid analysis showed that CmMYC2 directly bound to the promoter of CmLOX10. In summary, we identified the important roles of CmLOX10 in the regulation of drought tolerance in oriental melon seedlings through JA- mediated stomatal closure and JA signaling-mediated feedback through CmMYC2.
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