Prdm9 and Meiotic Cohesin Proteins Cooperatively Promote DNA Double-Strand Break Formation in Mammalian Spermatocytes

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The evolution of molluscs

Molluscs are extremely diverse invertebrate animals with a rich fossil record, highly divergent life cycles, and considerable economical and ecological importance. Key representatives include worm‐like aplacophorans, armoured groups (e.g. polyplacophorans, gastropods, bivalves) and the highly complex cephalopods. Molluscan origins and evolution of their different phenotypes have largely remained unresolved, but significant progress has been made over recent years. Phylogenomic studies revealed a dichotomy of the phylum, resulting in Aculifera (shell‐less aplacophorans and multi‐shelled polyplacophorans) and Conchifera (all other, primarily uni‐shelled groups). This challenged traditional hypotheses that proposed that molluscs gradually evolved complex phenotypes from simple, worm‐like animals, a view that is corroborated by developmental studies that showed that aplacophorans are secondarily simplified. Gene expression data indicate that key regulators involved in anterior–posterior patterning (the homeobox‐containing Hox genes) lost this function and were co‐opted into the evolution of taxon‐specific novelties in conchiferans. While the bone morphogenetic protein (BMP)/decapentaplegic (Dpp) signalling pathway, that mediates dorso‐ventral axis formation, and molecular components that establish chirality appear to be more conserved between molluscs and other metazoans, variations from the common scheme occur within molluscan sublineages. The deviation of various molluscs from developmental pathways that otherwise appear widely conserved among metazoans provides novel hypotheses on molluscan evolution that can be tested with genome editing tools such as the CRISPR/Cas9 (clustered regularly interspaced short palindromic repeats/clustered regularly interspaced short palindromic repeats‐associated protein9) system.     

The anterior visceral endoderm of the mouse embryo is established from both preimplantation precursor cells and by de novo gene expression after implantation

Initiation of the development of the anterior-posterior axis in the mouse embryo has been thought to take place only when the anterior visceral endoderm (AVE) emerges and starts its asymmetric migration. However, expression of Lefty1, a marker of the AVE, was recently found to initiate before embryo implantation. This finding has raised two important questions: are the cells that show such early, preimplantation expression of this AVE marker the real precursors of the AVE and, if so, how does this contribute to the establishment of the AVE? Here, we address both of these questions. First, we show that the expression of another AVE marker, Cer1, also commences before implantation and its expression becomes consolidated in the subset of ICM cells that comprise the primitive endoderm. Second, to determine whether the cells showing this early Cer1 expression are true precursors of the AVE, we set up conditions to trace these cells in time-lapse studies from early periimplantation stages until the AVE emerges and becomes asymmetrically displaced. We found that Cer1-expressing cells are asymmetrically located after implantation and, as the embryo grows, they become dispersed into two or three clusters. The expression of Cer1 in the proximal domain is progressively diminished, whilst it is reinforced in the distal-lateral domain. Our time-lapse studies demonstrate that this distal-lateral domain is incorporated into the AVE together with cells in which Cer1 expression begins only after implantation. Thus, the AVE is formed from both part of an ancestral population of Cerl-expressing cells and cells that acquire Cer1 expression later. Finally, we demonstrate that when the AVE shifts asymmetrically to establish the anterior pole, this occurs towards the region where the earlier postimplantation expression of Cer1 was strongest. Together, these results suggest that the orientation of the anterior-posterior axis is already anticipated before AVE migration.     

Apoptosis regulates notochord development in Xenopus

The notochord is the defining characteristic of the chordate embryo and plays critical roles as a signaling center and as the primitive skeleton. In this study we show that early notochord development in Xenopus embryos is regulated by apoptosis. We find apoptotic cells in the notochord beginning at the neural groove stage and increasing in number as the embryo develops. These dying cells are distributed in an anterior to posterior pattern that is correlated with notochord extension through vacuolization. In axial mesoderm explants, inhibition of this apoptosis causes the length of the notochord to approximately double compared to controls. In embryos, however, inhibition of apoptosis decreases the length of the notochord and it is severely kinked. This kinking also spreads from the anterior with developmental stage such that, by the tadpole stage, the notochord lacks any recognizable structure, although notochord markers are expressed in a normal temporal pattern. Extension of the somites and neural plate mirrors that of the notochord in these embryos, and the somites are severely disorganized. These data indicate that apoptosis is required for normal notochord development during the formation of the anterior-posterior axis, and its role in this process is discussed.     

CYP26A1 and CYP26C1 cooperatively regulate anterior-posterior patterning of the developing brain and the production of migratory cranial neural crest cells in the mouse

The appropriate regulation of retinoic acid signaling is indispensable for patterning of the vertebrate central nervous system along the anteroposterior (A-P) axis. Although both CYP26A1 and CYP26C1, retinoic acid-degrading enzymes that are expressed at the anterior end of the gastrulating mouse embryo, have been thought to play an important role in central nervous system patterning, the detailed mechanism of their contribution has remained largely unknown. We have now analyzed CYP26A1 and CYP26C1 function by generating knockout mice. Loss of CYP26C1 did not appear to affect embryonic development, suggesting that CYP26A1 and CYP26C1 are functionally redundant. In contrast, mice lacking both CYP26A1 and CYP26C1 were found to manifest a pronounced anterior truncation of the brain associated with A-P patterning defects that reflect expansion of posterior identity at the expense of anterior identity. Furthermore, Cyp26a1-/-Cyp26c1-/- mice fail to produce migratory cranial neural crest cells in the forebrain and midbrain. These observations, together with a reevaluation of Cyp26a1 mutant mice, suggest that the activity of CYP26A1 and CYP26C1 is required for correct A-P patterning and production of migratory cranial neural crest cells in the developing mammalian brain.     

Plant–pollinator interactions in a Mexican Acacia community

Competition for pollination is thought to be an important factor structuring flowering in many plant communities, particularly among plant taxa with morphologically similar and easily accessible flowers. We examined the potential for heterospecific pollen transfer (HPT) in a community of four Acacia species in a highly seasonal tropical habitat in Mexico. Partitioning of pollen flow among sympatric species appears to be achieved, in part, through segregation of flowering in seasonal time, and interspecific differences in pollinator guilds. However, two coflowering species (Acacia macracantha and Acacia angustissima) shared multiple flower visitors, raising the possibility of HPT. Each of these coflowering species showed high intraspecific daily synchrony in pollen release, but dehisce at different times of day. Pollinators rapidly harvested available pollen from one species before abandoning it to visit the flowers of the second later in the day. The activity of shared pollinators, predominantly bees, is thus structured throughout the day, and potential for HPT reduced. Suggestive evidence in favour of a resource partitioning explanation for this pattern is provided by the fact that A. macracantha showed significantly greater intraspecific synchrony when coflowering with a potential competitor (A. angustissima) than when flowering alone. We discuss our results in light of previous work on coflowering acacia assemblages in Tanzania and Australia. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.

西那卡塞联合碳酸司维拉姆对血液透析并发继发性甲状旁腺功能亢进患者钙磷代谢、FGF23/Klotho轴和心血管事件的影响

摘要 目的：观察西那卡塞联合碳酸司维拉姆对血液透析并发继发性甲状旁腺功能亢进（SHPT）患者钙磷代谢、成纤维细胞生长因子23（FGF23）/Klotho轴和心血管事件的影响。方法：选取2018年3月-2020年5月新疆医科大学第一附属医院收治的200例血液透析并发SHPT患者,根据随机数字表法分成观察组（n=100）与对照组（n=100）。对照组患者接受碳酸司维拉姆治疗,观察组患者接受西那卡塞联合碳酸司维拉姆治疗,两组患者均连续治疗3个月。观察两组疗效以及钙磷代谢指标、全段甲状旁腺激素（iPTH）、甲状旁腺体积、FGF23、Klotho水平变化,记录治疗期间发生的心血管事件。结果：观察组的临床总有效率较对照组高（P<0.05）。治疗后两组血钙升高,血磷、钙磷乘积下降（P<0.05）,且观察组治疗后血钙较对照组高,血磷、钙磷乘积较对照组低（P<0.05）。两组治疗后血清iPTH水平下降,甲状旁腺体积缩小,且观察组的变化程度较对照组大（P<0.05）。两组治疗后Klotho水平升高,FGF23水平下降,且观察组的变化程度大于对照组（P<0.05）。观察组的非致死性心血管事件发生率明显低于对照组（P<0.05）。结论：西那卡塞联合碳酸司维拉姆治疗血液透析并发SHPT患者疗效显著,可调节钙磷代谢,降低血清iPTH水平,缩小甲状旁腺体积,调节Klotho、FGF23水平,降低非致死性心血管事件发生率。     

睡眠障碍通过下丘脑-垂体-卵巢轴影响女性生育能力的临床研究

摘要 目的：探究睡眠障碍是如何通过下丘脑-垂体-卵巢轴影响女性生育能力的。方法：选择2018年10月至2021年10月于我院妇科内分泌科就诊的育龄期女性80例作为研究对象,根据匹兹堡睡眠质量指数量表（PSQI）评估结果,将所有研究对象按照是否存在睡眠障碍分为睡眠障碍组（n=34例）和非睡眠障碍组（n=46例）。对比分析两组PSQI评分,血清性激素水平,月经周期,生育能力,通过Pearson法分析睡眠障碍与女性生育能力的相关性。结果：（1）睡眠障碍组PSQI总分以及睡眠质量、入睡时间、睡眠时间、睡眠效率、睡眠障碍和日间功能障碍各方面得分均显著高于对照组（P<0.05）;（2）睡眠障碍组卵泡刺激素（FSH）、黄体生成素（LH）较非睡眠障碍组升高,而雌二醇（E₂）水平低于非睡眠障碍组（P<0.05）;（3）两组月经周期比较,睡眠障碍组月经紊乱比例显著高于对照组（P<0.05）;（4）两组生育能力比较,睡眠障碍组生育能力显著低于对照组（P<0.05）。（5）睡眠障碍与FSH和LH均存在负相关性,和E₂存在正相关（P<0.05）。结论：睡眠障碍可减弱下丘脑-垂体-卵巢轴的驱动,导致卵泡刺激素释放缓慢,延长了月经周期,并导致黄体功能下降,增加了未受孕或者再次异位妊娠的发生率。