Effects of Low Luteinizing Hormone During Ovarian Stimulation on Endometrial Gene Expression and Function - Transcriptome Analysis During the Implantation Window.

This study explored the impact of low luteinizing hormone (LH) levels during ovarian stimulation on endometrial function. Based on previous studies by us and others, we divided the patients into low (< 4 IU/L), medium (4-10 IU/L), and high (> 10 IU/L) LH groups. The study utilized a comparison control group design with three groups of 10 patients. Gene set enrichment analysis (GSEA) was applied for functional annotation. By analyzing the exon differentially expressed genes in the endometrium of these three patient groups during the embryo implantation window, we found that when compared to the medium LH group, low LH downregulated endometrial cell metabolism, including mitochondrial-nicotinamide adenine dinucleotide (Normalized Enrichment Scores, NES = - 1.53) and glycolytic metabolism (NES = - 1.22), immune regulation, and autophagy (NES = - 1.58). Transcription factors were the main regulators of cell function. We found that MCM2 was probably involved in regulating the endometrial function induced by low LH. MCM2 target genes were enriched in low LH group, NES = - 1.54. Low LH, but not high LH, altered the endometrial receptivity assay gene expression in comparison to the medium LH. Our results indicated that low LH impacted the endometrial cell function, with a greater effect than high LH. This research provides timely and necessary data on the involvement of LH in important endometrial cellular processes and these data support further clinical development of endometrial receptivity.

[Differences of bacterial and fungal communities in the tree and rhizosphere of the healthy and twig blight-diseased bayberry]. / å¥åº·ä¸Žå‡‹èŽç— æ¨æ¢ æ ‘ä½“åŠæ ¹å›´èŒç¾¤çš„å·®å¼‚.

Twig blight is a serious disease of bayberry, which limits bayberry production. In order to prevent and manage the disease, we used high-throughput sequencing technology to analyze bacterial and fungal community richness and diversity in various organs of the tree, bulk and rhizosphere soil of healthy and diseased bayberry. The results showed significant differences in richness and diversity of bacteria and fungi in bulk soil, rhizosphere soil, roots, trunks, barks, and leaves between twig blight diseased trees and healthy trees. In bulk soil, the richness and diversity of bacteria significantly decreased, while that of fungi significantly increased. In barks of diseased trees, the richness and diversity of bacteria significantly increased, and those of fungi significantly decreased. The relative abundance of dominant bacteria and fungi in various organs, bulk soil, and root surface soil changed significantly at phylum, class, and genus levels in the diseased trees. The relative abundance of Pseudomonas sp. on the trunks, roots, and root surface soils of diseased trees significantly decreased, and Fusarium sp. of the diseased root surface and bulk soils also significantly decreased, while the relative abundance of Penicillium sp. on the diseased root surface and bulk soils significantly increased. Pestalotiopsis sp., from the same genus as the twig blight pathogen, was less abundant in the roots but more abundant in the leaves, trunks, barks as well as root surface soils and bulk soils of the diseased bayberry trees than those of the health trees. The relative abundance of Pestalotiopsis sp. was positively correlated with those of most of the fungi. Our results might provide useful theoretical basis for the development of ecological improvement and healthy-tree cultivation technology, and biological control of bayberry twig blight disease.

Expression of harpin(xoo) in transgenic tobacco induces pathogen defense in the absence of hypersensitive cell death.

ABSTRACT Harpin(Xoo), encoded by the hpaG(Xoo) gene of Xanthomonas oryzae pv. oryzae, is a member of the harpin group of proteins that induce pathogen resistance and hypersensitive cell death (HCD) in plants. We elaborated whether both processes are correlated in hpaG(Xoo)-expressing tobacco (HARTOB) plants, which produced harpin(Xoo) intracellularly. Resistance to fungal, bacterial, and viral pathogens increased in HARTOB, in correlation with the expression of hpaG(Xoo), the gene NPR1 that regulates several resistance pathways, and defense genes GST1, Chia5, PR-1a, and PR-1b that are mediated by different signals. However, reactive oxygen intermediate burst, the expression of HCD marker genes hsr203 and hin1, and cell death did not occur spontaneously in HARTOB, though they did in untransformed and HARTOB plants treated exogenously with harpin(Xoo). Thus, the transgenic expression of harpin(Xoo) confers nonspecific pathogen defense in the absence of HCD.