短枝木麻黄种群苗期表型多样性评价

以来源于大洋洲原生种源区、亚洲原生种源区、亚洲引种次生区以及非洲引种次生区4个区域的20个种源短枝木麻黄种子和当年生幼苗为材料,通过种子千粒重以及幼苗苗高、地径、一级侧枝粗度、一级侧枝长度等7个性状对短枝木麻黄表型多样性进行了研究,以探讨种群苗期表型遗传差异,为短枝木麻黄早期遗传选择和遗传改良提供基本资料。结果表明:(1)短枝木麻黄种子千粒重在区域间和区域内种源间差异极显著,且千粒重具有显著的地理变异模式,随经度的增大而降低。(2)当年生幼苗苗高、地径在不同区域间及区域内种源间均存在极显著差异,其中泰国干东港种源幼苗生长最好(苗高76.6cm,地径4.64mm),而种源汤加的幼苗生长最差(苗高28.3cm,地径2.58mm)。(3)当年生幼苗一级侧枝粗度、一级侧枝长度、二级侧枝长度、每小枝节数和齿叶数在不同区域间及区域内种源间均存在极显著差异,其中齿叶数在区域间的变异系数最大(82.15%)。(4)通径分析表明,一级侧枝长度对苗高具有显著的正向影响作用,而一级侧枝粗度和二级侧枝长度对地径具有显著正向影响作用,它们可作为短枝木麻黄优良新品种筛选的参考因子。     

PTEN regulates RPA1 and protects DNA replication forks

Tumor suppressor PTEN regulates cellular activities and controls genome stability through multiple mechanisms. In this study, we report that PTEN is necessary for the protection of DNA replication forks against replication stress. We show that deletion of PTEN leads to replication fork collapse and chromosomal instability upon fork stalling following nucleotide depletion induced by hydroxyurea. PTEN is physically associated with replication protein A 1 (RPA1) via the RPA1 C-terminal domain. STORM and iPOND reveal that PTEN is localized at replication sites and promotes RPA1 accumulation on replication forks. PTEN recruits the deubiquitinase OTUB1 to mediate RPA1 deubiquitination. RPA1 deletion confers a phenotype like that observed in PTEN knockout cells with stalling of replication forks. Expression of PTEN and RPA1 shows strong correlation in colorectal cancer. Heterozygous disruption of RPA1 promotes tumorigenesis in mice. These results demonstrate that PTEN is essential for DNA replication fork protection. We propose that RPA1 is a target of PTEN function in fork protection and that PTEN maintains genome stability through regulation of DNA replication.     

Prostate Sphere-forming Stem Cells Are Derived from the P63-expressing Basal Compartment

Prostate stem cells (P-SCs) are capable of giving rise to all three lineages of prostate epithelial cells, including basal, luminal, and neuroendocrine cells. Multiple methods have been used to identify P-SCs in adult prostates. These include in vivo renal capsule implantation of a single epithelial cell with urogenital mesenchymal cells, in vitro prostasphere and organoid cultures, and lineage tracing with castration-resistant Nkx3.1 expression (CARN), in conjunction with expression of cell type-specific markers. Both organoid culture and CARN tracing show the existence of P-SCs in the luminal compartment. Although prostasphere cells predominantly express basal cell-specific cytokeratin and P63, the lineage of prostasphere-forming cells in the P-SC hierarchy remains to be determined. Using lineage tracing with P63^CreERT2, we show here that the sphere-forming P-SCs are P63-expressing cells and reside in the basal compartment. Therefore we designate them as basal P-SCs (P-bSCs). P-bSCs are capable of differentiating into AR⁺ and CK18⁺ organoid cells, but organoid cells cannot form spheres. We also report that prostaspheres contain quiescent stem cells. Therefore, the results show that P-bSCs represent stem cells that are early in the hierarchy of overall prostate tissue stem cells. Understanding the contribution of the two types of P-SCs to prostate development and prostate cancer stem cells and how to manipulate them may open new avenues for control of prostate cancer progression and relapse.     

Thematic Review Series: Intestinal Lipid Metabolism: New Developments and Current Insights: Circadian regulators of intestinal lipid absorption

Among all the metabolites present in the plasma, lipids, mainly triacylglycerol and diacylglycerol, show extensive circadian rhythms. These lipids are transported in the plasma as part of lipoproteins. Lipoproteins are synthesized primarily in the liver and intestine and their production exhibits circadian rhythmicity. Studies have shown that various proteins involved in lipid absorption and lipoprotein biosynthesis show circadian expression. Further, intestinal epithelial cells express circadian clock genes and these genes might control circadian expression of different proteins involved in intestinal lipid absorption. Intestinal circadian clock genes are synchronized by signals emanating from the suprachiasmatic nuclei that constitute a master clock and from signals coming from other environmental factors, such as food availability. Disruptions in central clock, as happens due to disruptions in the sleep/wake cycle, affect intestinal function. Similarly, irregularities in temporal food intake affect intestinal function. These changes predispose individuals to various metabolic disorders, such as metabolic syndrome, obesity, diabetes, and atherosclerosis. Here, we summarize how circadian rhythms regulate microsomal triglyceride transfer protein, apoAIV, and nocturnin to affect diurnal regulation of lipid absorption.