“Reductional anaphase” in replication-defective cells is caused by ubiquitin-conjugating enzyme Cdc34-mediated deregulation of the spindle

Equal partitioning of the duplicated chromosomes into two daughter cells during cell division is a coordinated process and is initiated only after completion of DNA synthesis. However, this strict order of execution breaks down in CDC6-deficient cells. Cdc6, an evolutionarily conserved protein, is required for the assembly of pre-replicative complexes (pre-RCs) and is essential for the initiation of DNA replication. Yeast cells lacking Cdc6 function, though unable to initiate DNA replication, proceed to undergo “reductional anaphase” by partitioning the unreplicated chromosomes and lose viability rapidly. This extreme form of genomic instability in cdc6 cells is thought to be due to inactivation of a pre-RC based, Cdc6-dependent checkpoint mechanism that, during normal cell cycle, inhibits premature onset of mitosis until pre-RC is assembled. Here, we show that chromosome segregation in cdc6 mutant is caused not by precocious initiation of mitosis in the absence of a checkpoint, but by the deregulation of spindle dynamics induced via a regulatory network involving the ubiquitin-conjugating enzyme Cdc34, microtubule-associated proteins (MAPs) and the anaphase-promoting complex (APC) activator Cdh1. This regulatory circuit governs spindle behavior in the early part of the division cycle and precipitates catastrophic chromosome segregation in the absence of DNA replication.     

Mitotic chromosome size scaling in Xenopus

As rapid divisions without growth generate progressively smaller cells within an embryo, mitotic chromosomes must also decrease in size to permit their proper segregation, but this scaling phenomenon is poorly understood. We demonstrated previously that nuclear and spindle size scale between egg extracts of the related frog species Xenopus tropicalis and Xenopus laevis, but show here that dimensions of isolated mitotic sperm chromosomes do not differ. This is consistent with the hypothesis that chromosome scaling does not occur in early embryonic development when cell and spindles sizes are large and anaphase B segregates chromosomes long distances. To recapitulate chromosome scaling during development, we combined nuclei isolated from different stage Xenopus laevis embryos with metaphase-arrested egg extracts. Mitotic chromosomes derived from nuclei of cleaving embryos through the blastula stage were similar in size to replicated sperm chromosomes, but decreased in area approximately 50% by the neurula stage, reproducing the trend in size changes observed in fixed embryos. Allowing G2 nuclei to swell in interphase prior to mitotic condensation did not increase mitotic chromosome size, but progression through a full cell cycle in egg extract did, suggesting that epigenetic mechanisms determining chromosome size can be altered during DNA replication. Comparison of different sized mitotic chromosomes assembled in vitro provides a tractable system to elucidate underlying molecular mechanisms.     

木薯ftsZ基因分离及在原核生物中功能初步鉴定

ftsZ基因是控制细胞分裂的关键基因,其蛋白能够在分裂位点形成一个环状结构而影响细胞分裂.为了研究木薯质体分裂与木薯淀粉品质形成的关系,根据木薯基因组数据库上的预测序列,设计引物,从木薯基因组中分离了与质体分裂相关的ftsZ家族3个新基因(ftsZ1,ftsZ2,ftsZ3).分别将它们与荧光蛋白基因(GFP)融合,构建了3个原核表达载体pET-fisZ1-GFP、pET-fisZ2-GFP、pET-fisZ3-GFP,并转化大肠杆菌BL21(DE3).通过荧光显微镜观察菌体的表型和分裂,初步鉴定了木薯质体分裂相关基因ftsZ家族对细胞分裂的作用.结果显示:尽管木薯与大肠杆菌的亲缘关系较远,ftsZ基因的同源性较低,但是两者表现出相似的功能,木薯ftsZ基因的表达能严重影响大肠杆菌细胞分裂.这一结果为进一步研究木薯ftsZ家族基因的功能奠定了基础.     

Differential proliferation rates generate patterns of mechanical tension that orient tissue growth

Orientation of cell divisions is a key mechanism of tissue morphogenesis. In the growing Drosophila wing imaginal disc epithelium, most of the cell divisions in the central wing pouch are oriented along the proximal–distal (P–D) axis by the Dachsous‐Fat‐Dachs planar polarity pathway. However, cells at the periphery of the wing pouch instead tend to orient their divisions perpendicular to the P–D axis despite strong Dachs polarization. Here, we show that these circumferential divisions are oriented by circumferential mechanical forces that influence cell shapes and thus orient the mitotic spindle. We propose that this circumferential pattern of force is not generated locally by polarized constriction of individual epithelial cells. Instead, these forces emerge as a global tension pattern that appears to originate from differential rates of cell proliferation within the wing pouch. Accordingly, we show that localized overgrowth is sufficient to induce neighbouring cell stretching and reorientation of cell division. Our results suggest that patterned rates of cell proliferation can influence tissue mechanics and thus determine the orientation of cell divisions and tissue shape.     

Defining the Epigenetic Mechanism of Asymmetric Cell Division of Schizosaccharomyces japonicus Yeast

A key question in developmental biology addresses the mechanism of asymmetric cell division. Asymmetry is crucial for generating cellular diversity required for development in multicellular organisms. As one of the potential mechanisms, chromosomally borne epigenetic difference between sister cells that changes mating/cell type has been demonstrated only in the Schizosaccharomyces pombe fission yeast. For technical reasons, it is nearly impossible to determine the existence of such a mechanism operating during embryonic development of multicellular organisms. Our work addresses whether such an epigenetic mechanism causes asymmetric cell division in the recently sequenced fission yeast, S. japonicus (with 36% GC content), which is highly diverged from the well-studied S. pombe species (with 44% GC content). We find that the genomic location and DNA sequences of the mating-type loci of S. japonicus differ vastly from those of the S. pombe species. Remarkably however, similar to S. pombe, the S. japonicus cells switch cell/mating type after undergoing two consecutive cycles of asymmetric cell divisions: only one among four “granddaughter” cells switches. The DNA-strand–specific epigenetic imprint at the mating-type locus1 initiates the recombination event, which is required for cellular differentiation. Therefore the S. pombe and S. japonicus mating systems provide the first two examples in which the intrinsic chirality of double helical structure of DNA forms the primary determinant of asymmetric cell division. Our results show that this unique strand-specific imprinting/segregation epigenetic mechanism for asymmetric cell division is evolutionary conserved. Motivated by these findings, we speculate that DNA-strand–specific epigenetic mechanisms might have evolved to dictate asymmetric cell division in diploid, higher eukaryotes as well.     

Polychlorinated biphenyls disrupt cell division and tip growth in two species of fucoid algae

Environmental contaminants, including poly‐chlorinated biphenyls (PCBs), are enriched in coastal sediments, and despite a 1977 moratorium by the United States Environmental Protection Agency on the production of PCBs, levels remain high, more so near former industrial plants. The effects of these contaminants on sessile species in the intertidal zone, particularly nonanimal species such as the ubiquitous fucoid brown algae, are not well known. We investigated the developmental effects of chronic PCB treatment beginning at fertilization on two species of marine rockweed, Fucus vesiculosus Linnaeus and Silvetia compressa (J.Agardh) E.Serrão, T.O.Cho, S.M.Boo & Brawley. A mixture of the most widely used PCB congeners, Aroclors 1221, 1242, and 1254, was delivered at concentrations well below levels found in contaminated sediments, and resulted in severely delayed mitosis and cytokinesis in both species. In F. vesiculosus, this delay was accompanied by abnormal spindle morphology. PCB treatment also dramatically slowed or arrested rhizoid growth after 2–4 d, and by 7 d F. vesiculosus embryos were dead; in contrast, polar secretion of adhesive, germination, and photopolar germination were not affected. The dramatic delay in the first cell division and reduction in tip growth within the first week of development are likely to compromise S. compressa's ability to reproduce and establish new generations. Thus, the data presented here suggest that PCBs still present in coastal sediments may be inhibiting recruitment in these species. Moreover, as sediment dredging causes temporary spikes in PCB concentrations, these kinds of bioremediation steps may exacerbate the disruption of fucoid development.     

基于Holdridge和CCA分析的中国生态地理分区的比较

在前人工作基础上,对中国自然地理要素与生态地理区域的关系进行了综合分析,采用全国地形、土壤、气候、植被及遥感植被指数等数据,综合分析中国范围生态地理区域的分异规律,制订了生态地理分区的初步方案,并建立了相应的地理信息系统.基于Holdridge模型和CCA分析划分中国生态地理分区,建立了分区的指标体系,得到中国生态分区的大致界线,初步总结了各生态地理分区的地形、植被、气候等综合自然地理特征,完成对中国区域生态地理分区的划分.基于CCA分析的生态地理的分区,不仅结合自然区划和生态地理两种方法,而且加入了生态群落和遥感数据的综合应用.结果显示,由于受到模型适用性及数据误差的原因,基于CCA分析的结果比Holdridge模型的结果更合理一些.     

Monogamy,strongly bonded groups,and the evolution of human social structure

Human social evolution has most often been treated in a piecemeal fashion, with studies focusing on the evolution of specific components of human society such as pair‐bonding, cooperative hunting, male provisioning, grandmothering, cooperative breeding, food sharing, male competition, male violence, sexual coercion, territoriality, and between‐group conflicts. Evolutionary models about any one of those components are usually concerned with two categories of questions, one relating to the origins of the component and the other to its impact on the evolution of human cognition and social life. Remarkably few studies have been concerned with the evolution of the entity that integrates all components, the human social system itself. That social system has as its core feature human social structure, which I define here as the common denominator of all human societies in terms of group composition, mating system, residence patterns, and kinship structures. The paucity of information on the evolution of human social structure poses substantial problems because that information is useful, if not essential, to assess both the origins and impact of any particular aspect of human society.     

植物叶绿体分裂的分子机制

叶绿体是植物细胞内一种重要的细胞器．它不仅是光合作用的场所,还是其它多种中间代谢的场所．叶绿体起源于蓝细菌,与其原核祖先类似,通过二分裂方式进行增殖．最近的研究表明,叶绿体的分裂装置包含原核起源和真核起源的蛋白质,它们在叶绿体的内膜内侧和外膜外侧协同作用以完成叶绿体的分裂．在过去十几年里,包括丝状温度敏感蛋白Z（FtsZ）、Min系统蛋白、质体分裂蛋白（PDV）和ARC蛋白等在内的多个叶绿体分裂相关组分被分离鉴定．本文简要介绍了叶绿体分裂装置各成员的发现、叶绿体被膜的收缩和叶绿体分裂位点的选择机制．另外,植物发育过程中叶绿体分裂可能受到细胞的控制,但目前对细胞如何调控叶绿体分裂知之甚少．本文对该领域的最新研究进展也进行了综述．     

SPERMATOGENESIS IN A TRICHUROID NEMATODE,TRICHURIS MURIS. II. FINE STRUCTURE OF PRIMARY SPERMATOCYTE AND FIRST MEIOTIC DIVISION

Ultrastructural observations indicate that the primary spermatocyte of Trichuris muris is larger than the spermatogonial stage with an increased cytoplasm to nucleus ratio. The cytoplasm contains an extensive reticular system, mitochondria, numerous free ribosomes and prominent Golgi complexes which may contribute to the formation of a sub-surface, vesicular complex. Although only two spermatocytes were seen to be linked by a cytoplasmic bridge it is suggested that the number of conjoined cells is probably greater. The rearrangement of mitochondria in a ring around the nucleus and the indentation and vesiculation of the nuclear envelope preceeded its disappearance and indicated the onset of meiosis. Centrioles were frequently resolved at this stage. They were composed of nine peripheral doublets surrounded by a dense pericentriolar sheath. Three dense chromatin areas indicative of haploid chromosomes were present in later meiotic stages. Each chromosome was surrounded by a number of mitochondria and there was a clear separation of the chromosome-mitochondrial clusters from the remainder of the cytoplasm. This was particularly evident at telophase when two daughter cells were partially separated by membrane infoldings. This reflects incomplete cytokinesis in the dividing spermatocyte of T. muris and is similar to that described in other trichuroid species. A close association with processes of the non-germinal, sustentacular cells was noted throughout the spermatocyte stage.