Comparative genomic analyses among closely related species can greatly enhance our understanding of plant gene and genome evolution. We report de novo-assembled AA-genome sequences for Oryza nivara, Oryza glaberrima, Oryza barthii, Oryza glumaepatula, and Oryza meridionalis. Our analyses reveal massive levels of genomic structural variation, including segmental duplication and rapid gene family turnover, with particularly high instability in defense-related genes. We show, on a genomic scale, how lineage-specific expansion or contraction of gene families has led to their morphological and reproductive diversification, thus enlightening the evolutionary process of speciation and adaptation. Despite strong purifying selective pressures on most Oryza genes, we documented a large number of positively selected genes, especially those genes involved in flower development, reproduction, and resistance-related processes. These diversifying genes are expected to have played key roles in adaptations to their ecological niches in Asia, South America, Africa and Australia. Extensive variation in noncoding RNA gene numbers, function enrichment, and rates of sequence divergence might also help account for the different genetic adaptations of these rice species. Collectively, these resources provide new opportunities for evolutionary genomics, numerous insights into recent speciation, a valuable database of functional variation for crop improvement, and tools for efficient conservation of wild rice germplasm.comparative genomics | full-genome sequencing | genomic variation | positive selection | Oryza D rawing the landscape of genomic divergence among multiple lineages is fundamental to understanding plant gene and genome evolution (1, 2). The comprehensive comparison of closely related genomes in different chronologically ordered stages under a well-resolved phylogenetic framework could dramatically improve the inference precision and sensitivity of gene evolution studies and should allow more robust results for investigating broad-scale patterns of genomic architecture in the course of the speciation process compared with analyses of single genomes (3, 4). For instance, studies of yeast, Drosophila, and human genomes have demonstrated how comparisons of closely related genome sequences can reveal mechanisms of gene and genome evolution in fungi and animals (5-7). In plants, however, we know little about broad-scale patterns of evolutionary dynamics, differentiation, and consequences. Studies are needed of very closely related plant species that span the speciation continuum and have well-characterized biogeographic histories.The genus Oryza, consisting of 24 species, provides a uniquely powerful system for studying comparative genomics and evolutionary biology, and can contribute to the improvement of rice, which is of pivotal significance in worldwide food production and security (8-10). Many genes involved in rice improvement are derived from wild AA-genome species, and broadening the gene pool of cultivated rice through i...
Polyploidy, or whole-genome duplication (WGD), serves as a key innovation in plant evolution and is an important genomic feature for all eukaryotes. Neopolyploids have to overcome difficulties in meiosis, genomic alterations, changes of gene expression, and epigenomic reorganization. However, the underlying mechanisms for these processes are poorly understood. One of the most interesting aspects is that genome doubling events increase the dosage of all genes. Unlike allopolyploids entangled by both hybridization and polyploidization, autopolyploids, especially artificial lines, in relatively uniform genetic background offer a model system to understand mechanisms of genome-dosage effects. To investigate DNA methylation effects in response to WGD rather than hybridization, we produced autotetraploid rice with its diploid donor, Oryza sativa ssp. indica cv. Aijiaonante, both of which were independently self-pollinated over 48 generations, and generated and compared their comprehensive transcriptomes, base pair-resolution methylomes, and siRNAomes. DNA methylation variation of transposable elements (TEs) was observed as widespread in autotetraploid rice, in which hypermethylation of class II DNA transposons was predominantly noted in CHG and CHH contexts. This was accompanied by changes of 24-nt siRNA abundance, indicating the role of the RNA-directed DNA methylation pathway. Our results showed that the increased methylation state of class II TEs may suppress the expression of neighboring genes in autotetraploid rice that has obtained double alleles, leading to no significant differences in transcriptome alterations for most genes from its diploid donor. Collectively, our findings suggest that chromosome doubling induces methylation variation in TEs that affect gene expression and may become a "genome shock" response factor to help neoautopolyploids adapt to genome-dosage effects.methylome | autotetraploid rice | gene expression | genome-dosage effect | transposable elements P olyploidy or whole-genome duplication (WGD), when two or more complete sets of chromosomes co-occur in a nucleus (1), has played a pervasive role in plant evolution (2-4). Notably, all angiosperms have experienced at least one WGD event during their evolutionary history (5, 6). In general, two major categories of polyploidy exist in plants. Autopolyploidy species carry multiple similar chromosome sets, and allopolyploidy species integrate divergent chromosome sets (2, 3). Allopolyploidy is thought to have played a significant role in plant diversification and remains an important speciation process (5, 7). However, increasing evidence indicates that the real appearance of autotetraploid plants in nature might be significantly underestimated (8, 9), despite potential weaknesses, such as meiotic instability and reduced fertility (10).WGD produced by polyploidization creates a vastly increased genetic reservoir and combinatorial complexity upon which selection might act over an extended period, ultimately prompting polyploids to be successful in...
Skin ulcers are a serious complication of diabetes. Diabetic patients suffer from vascular lesions and complications such as peripheral neuritis, peripheral vascular lesions, and collagen abnormalities, which result in skin wounds that are refractory and often develop into chronic ulcers. The healing of skin ulcers requires an inflammatory reaction, wound proliferation, remodeling regulation, and control of stem cells. Studies investigating diabetic cutaneous ulcers have focused on cellular and molecular levels. Diabetes can cause nerve and blood vessel damage, and persistent high blood sugar levels can cause systemic multisite nerve damage based on peripheral neuropathy. The long-term hyperglycemia state enables the polyol glucose metabolism pathway to be activated, increasing the accumulation of toxic substances in the vascular injured nerve tissue cells. Sustained hyperglycemia leads to dysfunction of epithelial cells, leading to a decrease in pro-angiogenic signaling and nitric oxide production. In addition, due to impaired leukocyte function in hyperglycemia, immune function is impaired and the immune response at relevant sites is insufficient, making diabetic foot more difficult to heal. The Wnt/β-catenin pathway is a highly conserved signal transduction pathway involved in a variety of biological processes, such as cell proliferation, apoptosis, and differentiation. It is considered an important pathway involved in the healing of skin wounds. This article summarizes the mechanism of action of the Wnt/β-catenin pathway involved in the inflammatory responses to diabetic ulcers, wound proliferation, wound remodeling, and stem cells. The interactions between the Wnt signal pathway and other metabolic pathways are also discussed.
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