哺乳动物神经发育中的Par极性复合体

哺乳动物的神经发育过程极其复杂, 其形态结构和机能变化受到严格的调控。细胞极性是哺乳动物神经发生中最基本的特征之一, 在其调控因素中, Par极性复合体是研究最多的蛋白质。神经发育过程中Par蛋白的分布与量呈现动态变化, 影响细胞连接建立、细胞极性形成、神经突触发生及神经元迁移, 也影响到神经前体细胞的命运。文章主要从胚胎新皮层神经前体细胞及体外培养神经元角度, 总结了近年在Par极性蛋白的细胞内分布、机能及作用机制方面的研究进展。     

Numb与神经发育

不对称性细胞分裂是一个母细胞通过一次分裂,产生两个不同命运的子细胞的分裂方式,是单细胞生物向多细胞生物进化的关键一步。根据现有的证据推论,不称性细胞分裂是在器官发育过程中产生细胞多样化的一种基本方式。Numb是第一个被发现决定多细胞生物不对称细胞分裂的信号蛋白。在果蝇中,Numb通过促进Notch泛素化拮抗Notch信号通路,从而决定子细胞的命运,后来的研究表明Numb是细胞内吞调节蛋白,并用通过内吞参与调节神经细胞的粘附,轴突的生长及细胞迁移等过程;并且发现Numb与肿瘤抑制基因p53、泛素化蛋白HDM2形成三聚体抑制p53的泛素化,从而调节肿瘤的恶性程度。本文系统地分析了Numb发现的历史及后来在脊椎动物中的作用和机制,重点介绍了Numb在神经发育过程中的功能。     

脊髓神经前体细胞由形成运动神经元转为形成少突胶质细胞的机制的研究进展

少突胶质细胞主要围绕神经元轴突形成髓鞘,能几十倍地加快神经冲动的传导速度,它的异常会严重影响人的行动和健康,因此对其发育的研究显得极为重要。最近的研究显示脊髓中绝大部分少突胶质细胞和运动神经元先后由相同的神经前体细胞区产生。然而,对脊髓神经干细胞如何有秩序地先后产生这两种不同细胞的具体机制还不清楚。基于近年来的研究进展,对运动神经元和少突胶质细胞发育上的关系以及其发育命运转变的机制进行探讨。     

人胚胎干细胞定向分化为神经前体细胞

采用单层贴壁分化的方法在无血清条件下诱导同源饲养层培养的人胚胎干细胞定向分化,得到了高比例的神经前体细胞(97.5±0.83)%(P<0.05)。这些神经前体细胞具有分化为神经元、星形胶质细胞和少突胶质细胞的能力。在长期的传代培养中发现,随着培养时间的延长,nestin阳性的神经前体细胞比例下降,同时发育能力也发生了变化。在传代培养的早期,神经前体细胞发育为神经元的比例很高,几乎没有胶质细胞分化出来。随着培养时间的延长,胶质细胞的比例逐渐上升。这与体内神经系统的发育过程非常相似。进一步研究发现具有bHLH(basic helix-loop-helix)结构域的转录因子neurogenein2(Ngn2)和Olig2可能在这一变化中起重要作用。因此,人胚胎干细胞来源的神经前体细胞能够模拟体内神经发育的模式,为在体外研究人的神经发育和再生医学奠定了基础。     

人胚胎干细胞定向分化为神经前体细胞

采用单层贴壁分化的方法在无血清条件下诱导同源饲养层培养的人胚胎干细胞定向分化，得到了高比例的神经前体细胞（97.5±0.83)%（P＜0.05)。这些神经前体细胞具有分化为神经元、星形胶质细胞和少突胶质细胞的能力。在长期的传代培养中发现，随着培养时间的延长，nestin阳性的神经前体细胞比例下降，同时发育能力也发生了变化。在传代培养的早期，神经前体细胞发育为神经元的比例很高，几乎没有胶质细胞分化出来。随着培养时间的延长，胶质细胞的比例逐渐上升。这与体内神经系统的发育过程非常相似。进一步研究发现具有bHLH (basic helix-loop-helix) 结构域的转录因子neurogenein2(Ngn2) 和Olig2可能在这一变化中起重要作用。因此，人胚胎干细胞来源的神经前体细胞能够模拟体内神经发育的模式，为在体外研究人的神经发育和再生医学奠定了基础。     

细胞周期蛋白和哺乳动物生殖

细胞周期蛋白是真核细胞周期循环中主要的调节因子,它们参与细胞周期的精密调控,维持细胞正常生长及发育平衡。近年来发现,细胞周期蛋白与哺乳动物生殖有着密切的关系,本文简要论述了细胞周期蛋白与配子发生、早期胚胎发育、胚胎着床、蜕膜化等的关系,以及细胞周期蛋白在生殖系统中的表达与调控。     

Wnt信号转导通路与神经发育研究进展

Wnt蛋白是一类分泌型糖蛋白家族,Wnt信号蛋白与细胞表面的多种受体相互作用,参与诸多生命过程。对神经系统发育的研究表明,Wnt信号通路在神经发生,神经祖细胞增值、分化,神经干细胞的自我更新,轴突导向等过程中起重要调控作用。多项研究已经证实,Wnt通路失调与诸多神经系统疾病有密切关系。Wnt信号通路的突变或异常,将会引起神经系统发育缺陷。然而,对Wnt非经典信号通路的研究,尤其是新受体Ryk的调控作用的认识迄今仍不全面。根据国内外相关研究,阐述了经典Wnt信号通路Wnt/β-catenin途径的同时也对Wnt/Ryk非经典信号途径这一研究新领域做了讨论。在非经典信号通路中,Ryk-ICD的剪接对于前体细胞的神经分化起重要作用。本文分析了Wnt/β-catenin和Wnt/Ryk信号通路在神经发育中的作用,有助于深入理解神经发育过程中Wnt信号通路的作用机制。然而,Ryk-ICD引导因子、分子机制等问题仍待进一步研究,而这将有利于理解神经干细胞分化机理。     

命运决定子Numb在神经干/祖细胞不对称分裂及分化中的调控作用 

不对称分裂是干/祖细胞发育分化中的基本过程,膜相关蛋白Numb在其中发挥重要作用.Numb极性分布于细胞一侧,在干/祖细胞有丝分裂时不对等分配至两个子代细胞,使子代细胞产生不同分化命运.如一个保持在干/祖细胞状态,而另一个发育为神经元,这一过程主要通过抑制Notch信号通路发挥作用.近年在哺乳动物中的研究中发现,高强度Notch信号又能够反馈抑制Numb活性.Numb具有维持神经干/祖细胞增殖与促进分化的双重作用,Numb的命运决定作用还与Shh信号通路和p53蛋白等相关.另外,Numb参与调控细胞的粘连、迁移以及神经元轴突的分支与延长.本文主要对Numb在果蝇及哺乳动物神经干/祖细胞中的定位以及其在决定细胞命运和分化中的调控作用进行综述.     

CDK5与神经退行性疾病

CDK5是细胞周期素依赖性蛋白激酶 (CDK)家族一特殊成员 ,主要在神经系统中激活 ,是脑发育、神经定位、突触发生与传递的重要调节因子。磷酸化包括微管相关蛋白、τau蛋白和神经丝蛋白在内的多种蛋白质。缺乏CDK5小鼠在出生前后即死亡 ,CDK5过度激活则引发培养细胞凋亡。CDK5及其激活因子p35的异常调节与神经退行性疾病发病的关系 ,已成为细胞生物学和神经科学研究热点。本文仅就CDK5概况、CDK5功能与神经退行性疾病的关系作一概述     

中枢神经系统少突胶质细胞前体细胞产生的研究进展

少突胶质细胞(oligodendrocytes,OLs)在脊椎动物中枢神经系统(central nervous system,CNS)中负责形成包裹神经元轴突的髓鞘,保证神经冲动沿轴突的快速传导,并为其提供营养支持。OLs发育异常及损伤会导致严重的神经系统疾病,比如脑白质营养不良(leukodystrophy)、多发性硬化症(multiple sclerosis,MS)等。少突胶质细胞前体细胞(oligodendrocyte progenitor cells,OPCs)在胚胎期由神经前体细胞(neural progenitor cells,NPCs)产生,该过程受到一系列细胞内外因素的调控,对这一问题的研究也是神经系统研究的重要内容。现主要基于遗传学结果,简述关于OPCs产生的调控机制的最新研究进展。     

Gastrulation in the nematode Caenorhabditis elegans

Gastrulation in Caenorhabditis elegans has been described by following the movements of individual nuclei in living embryos by Nomarski microscopy. Gastrulation starts in the 26-cell stage when the two gut precursors, Ea and Ep, move into the blastocoele. The migration of Ea and Ep does not depend on interactions with specific neighboring cells and appears to rely on the earlier fate specification of the E lineage. In particular, the long cell cycle length of Ea and Ep appears important for gastrulation. Later in embryogenesis, the precursors to the germline, muscle and pharynx join the E descendants in the interior. As in other organisms, the movement of gastrulation permit novel cell contacts that are important for the specification of certain cell fates.     

Expression of Cell Cycle-Related Genes During Neuronal Apoptosis: Is there a Distinct Pattern?

An emerging hypothesis considers the process of neuronal apoptosis as a consequence of unscheduled and unsynchronized induction of cell cycle mediators. Induction of several cell cycle genes precedes neuronal apoptosis and may be involved in determination of cell fate. We have now characterized changes in expression of cell cycle genes during apoptosis induced by oxidative stress in chick post-mitotic sympathetic neurons. Induction of cyclin B occurred prior to the commitment of neurons to both dopamine- and peroxide-triggered apoptosis. Both the neuronal death and the rise in cyclin B were inhibited by antioxidant treatment, suggesting a functional role for cyclin B induction during neuronal apoptosis. Induction of the cyclin dependent kinase CDK5 protein coincided with the time point when neurons were irreversibly committed to die. Expression of other cell cycle mediators such as cyclin D1 and the cyclin dependent kinases CDC2 and CDK2 was undetected and not induced by exposure to oxidative stress. Comparative analysis of the profile of cell cycle mediators induced during neuronal apoptosis of different neuronal cell populations revealed no distinct pattern of events. There are no cell cycle stage-specific mediators that are ultimately stimulated during neuronal apoptosis, suggesting that multiple pathways of re-activating the dormant cell-cycle, converge to determine entry into apoptosis. Nevertheless, the existence of some cell cycle mediators, that were not reported so far to be induced in post mitotic neurons during oxidative stress, substantiate them as part of the strong differentiating forces.     

Role and regulation of kinesin-8 motors through the cell cycle

Members of the kinesin-8 motor family play a central role in controlling microtubule length throughout the eukaryotic cell cycle. Inactivation of kinesin-8 causes defects in cell polarity during interphase and astral and mitotic spindle length, metaphase chromosome alignment, timing of anaphase onset and accuracy of chromosome segregation. Although the biophysical mechanism by which kinesin-8 molecules influence microtubule dynamics has been studied extensively in a variety of species, a consensus view has yet to emerge. One reason for this might be that some members of the kinesin-8 family can associate to other microtubule-associated proteins, cell cycle regulatory proteins and other kinesin family members. In this review we consider how cell cycle specific modification and its association to other regulatory proteins may modulate the function of kinesin-8 to enable it to function as a master regulator of microtubule dynamics.     

When timing is everything: role of cell cycle regulation in asymmetric division

Asymmetric division is a fundamental mechanism of generating cell diversity during development. One of its hallmarks is asymmetric localization during mitosis of proteins that specify daughter cell fate. Studies in Drosophila show that subcellular localization of many proteins required for asymmetric division of neuronal progenitors correlates with progression through mitosis. Yet, how cell cycle and asymmetric division machineries cooperate remains unclear. Recent data show that (1) key cell cycle regulators are required for asymmetric localization of cell fate determinants and for cell fate determination and (2) molecules that mediate asymmetric division can also act to modulate proliferation potential of progenitor cells.     

Rb family proteins differentially regulate distinct cell lineages during epithelial development

pRb, p107 and p130 are important regulators of cell cycle and have extensive overlapping functions; however, only Rb has been shown to be a bone fide tumor suppressor. Defining the overlapping versus distinct pocket protein functions is therefore an important step to understanding the unique role of Rb. Using lung as a model, the present studies demonstrate that pocket proteins are important not only in regulating cell cycle and survival but also in cell lineage specification. An inducible lung-specific Rb knockout strategy was used to demonstrate that Rb is specifically required for restricting neuroendocrine cell fate despite functional compensation for Rb deficiency in other cell types. Ablation of total Rb family function resulted in opposing effects in specification along distinct cell lineages, providing evidence that pocket proteins inhibit neuroendocrine cell fate while being required for differentiation in other cell types. These findings identify a novel role for pocket proteins in cell fate determination, and establish a unique cell lineage-specific function for Rb that explains, at least in part, why Rb and p16 are inactivated in phenotypically distinct carcinomas.     

Control of vulval cell division number in the nematode Oscheius/Dolichorhabditis sp. CEW1

Spatial patterning of vulval precursor cell fates is achieved through a different two-stage induction mechanism in the nematode Oscheius/Dolichorhabditis sp. CEW1 compared with Caenorhabditis elegans. We therefore performed a genetic screen for vulva mutants in Oscheius sp. CEW1. Most mutants display phenotypes unknown in C. elegans. Here we present the largest mutant category, which affects division number of the vulva precursors P(4-8).p without changing their fate. Among these mutations, some reduce the number of divisions of P4.p and P8.p specifically. Two mutants omit the second cell cycle of all vulval lineages. A large subset of mutants undergo additional rounds of vulval divisions. We also found precocious and retarded heterochronic mutants. Whereas the C. elegans vulval lineage mutants can be interpreted as overall (homeotic) changes in precursor cell fates with concomitant cell cycle changes, the mutants described in Oscheius sp. CEW1 do not affect overall precursor fate and thereby dissociate the genetic mechanisms controlling vulval cell cycle and fate. Laser ablation experiments in these mutants reveal that the two first vulval divisions in Oscheius sp. CEW1 appear to be redundantly controlled by a gonad-independent mechanism and by a gonadal signal that operates partially independently of vulval fate induction.     

Integration of glycosphingolipid metabolism and cell-fate decisions in cancer and stem cells: Review and Hypothesis

The metabolism of glycosphingolipids is strictly regulated during the mitotic cell cycle. Before the G1-to-S transition, the ceramide and glucosylceramide concentration is elevated. Ceramide induces apoptosis synergistically with the pro-apoptotic protein prostate apoptosis response 4 (PAR-4) that may be asymmetrically inherited during cell division. Only one daughter cell dies shortly after mitosis, a mechanism we suggested to regulate the number of neural stem cells during embryonic development. The progeny cells, however, may protect themselves by converting ceramide to glucosylceramide and other glycosphingolipids. In particular, complex gangliosides have been found to sustain cell survival and differentiation. The cell cycle may thus be a turning point for (glyco)sphingolipid metabolism and explain rapid changes of the sphingolipid composition in cells that undergo mitotic cell-fate decisions. In the proposed model termed "Shiva cycle", progression through the cell cycle, differentiation, or apoptosis may rely on a delicate balance of (glyco)sphingolipid second messengers that modulate the retinoblastoma-dependent G1-to-S transition or caspase-dependent G1-to-apoptosis program. Ceramide-induced cell cycle delay at G0/G1 is either followed by ceramide-induced apoptosis or by conversion of ceramide to glucosylceramide, a proposed key regulatory rheostat that rescues cells from re-entry into a life/death decision at G1-to-S. We propose a mechanistic model for sphingolpid-induced protein scaffolds ("slip") that regulate cell-fate decisions and will discuss the biological consequences and pharmacological potential of manipulating the (glyco)sphingolipid-dependent cell fate program in cancer and stem cells.