Cell cycle and apoptosis

Apoptosis and proliferation are intimately coupled. Some cell cycle regulators can influence both cell division and programmed cell death. The linkage of cell cycle and apoptosis has been recognized for c-Myc, p53, pRb, Ras, PKA, PKC, Bcl-2, NF-kappa B, CDK, cyclins and CKI. This review summarizes the different functions of the proteins presently known to control both apoptosis and cell cycle progression. These proteins can influence apoptosis or proliferation but different variables, including cell type, cellular environment and genetic background, make it difficult to predict the outcome of cell proliferation, cell cycle arrest or cell death. These important decisions of cell proliferation or cell death are likely to be controlled by more than one signal and are necessary to ensure a proper cellular response.     

pRb and the cdks in apoptosis and the cell cycle

Apoptosis is a fundamental biological process present in metazoan cells. Linking apoptosis to the cell cycle machinery provides a mechanism to maintain proper control of cell proliferation in a multicellular organism. pRb and the cyclin-dependent kinases may have dual roles as integral components of the cell cycle and regulators of apoptosis. In many instances manipulation of the cell cycle through these molecules can induce or inhibit apoptosis. Recent studies also identify pRb as a substrate for an apoptotic protease; however, other cell cycle components are not known substrates. While it is clear that many common molecules can affect cell proliferation and cell death, the universality of any one cell cycle molecule in apoptosis has yet to be determined.     

地钱颈卵器发育和卵发生的显微观察及细胞化学研究

对地钱（Marchantia polymorpha）颈卵器发育和卵发生过程进行了显微观察和细胞化学的研究,颈卵器起始于原始细胞,该细胞呈乳突状,经横分裂产生基细胞和顶细胞,顶细胞经3次纵斜向分裂和1次横分裂产生初生细胞,初生细胞是颈卵器内的第一个细胞,经横分裂产生中央细胞和颈沟母细胞,前者产生1个腹沟细胞和1个卵细胞,后者最终产生4个颈沟细胞。颈卵器的成熟表现为颈部显著伸长和腹部膨大,卵细胞成熟时具有不规则的核,细胞质内含有丰富的囊泡和颗粒物,卵细胞周围充满粘性物质,细胞化学研究表明,该粘性物质为多糖,卵细胞质中深染色的颗粒可能为脂类物质,腹沟细胞自产生后就逐渐退化,颈沟细胞的退化迟于腹沟细胞,其数量通常为4个,偶尔可见5个颈沟细胞或具有双核的现象。     

Models of normal and transformed cell adhesion,and capping and locomotion in vitro

It is proposed that patching, capping and endocytosis, and cell locomotion are manifestations of a single process whereby the cell discards foreign materials. Capping results from the binding to the cell surface of particulate (or molecular) objects which cannot function as immovable substratum. This might be described as unsuccessful or abortive cell adhesion in that the particles adhere to the cell rather than the cell adhering to the substratum. Lateral particle movements on the cell surface membrane are effected by the submembranous microfilament-microtubule system, resulting in capping without displacement of the cell. Successful adhesion of the cell to a substratum renders capping and endocytosis impossible and the cell attempts to discard the substratum by mechanisms analogous to capping. The cell achieves this by lateral movement and detachment of the trailing edge.The concept of abortive adhesion leading to capping has been amplified by the development of molecular models of normal and neoplastic cell adhesion in vitro in the presence and absence of serum. In these models, the normal cells have molecule A (adhesion sites) on their surface; they can spread on the substratum in the absence of serum. In the presence of serum, the A molecules on the normal cell surface bind with B molecules in serum, which may be substratum-bound or free in suspension. Binding of free B molecules with cell surface A molecules results in blockage of adhesion sites; these are cleared via capping. New adhesion sites (A molecules) are produced at the active edges of the cell. Binding of cell surface A molecules with the substratum bound B molecules results in cell adhesion. Transformed cells do not have A molecules on their surface; they cannot spread in the absence of serum. The transformed cells may recruit A molecules from the serum to attain deformability and spreading.These models also relate to capping of gold or resin particles, cell locomotion and regulation of cell division, and lectin-induced agglutination of transformed cells.     

Coordinating cell polarity and cell cycle progression: what can we learn from flies and worms?

Spatio-temporal coordination of events during cell division is crucial for animal development. In recent years, emerging data have strengthened the notion that tight coupling of cell cycle progression and cell polarity in dividing cells is crucial for asymmetric cell division and ultimately for metazoan development. Although it is acknowledged that such coupling exists, the molecular mechanisms linking the cell cycle and cell polarity machineries are still under investigation. Key cell cycle regulators control cell polarity, and thus influence cell fate determination and/or differentiation, whereas some factors involved in cell polarity regulate cell cycle timing and proliferation potential. The scope of this review is to discuss the data linking cell polarity and cell cycle progression, and the importance of such coupling for asymmetric cell division. Because studies in model organisms such as Caenorhabditis elegans and Drosophila melanogaster have started to reveal the molecular mechanisms of this coordination, we will concentrate on these two systems. We review examples of molecular mechanisms suggesting a coupling between cell polarity and cell cycle progression.     

Cadherins and tissue formation: integrating adhesion and signaling

Cadherins and other cell–substrate and cell–cell adhesion molecules play an essential role during development. Through their cytoplasmic interaction with the cytoskeleton, cell adhesion molecules physically link cells with the extracellular matrix and/or with each other. These interactions create architectural and structural entities that enable the tissues in the embryo to restrain the physical forces encountered during development. Regulated cell adhesion is also often the driving force of morphogenetic movements. This review goes beyond the adhesive aspect of cadherins, focusing on their roles as signaling molecules in development. We discuss how cadherins, through their effects on cell proliferation, cell death, cell polarization, and differentiation, play a role in the formation of tissues and organs in the developing embryo. BioEssays 21:211–220, 1999. © 1999 John Wiley & Sons, Inc.     

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。     

Cell cycle and apoptosis: Common pathways to life and death

Programmed cell death, or apoptosis, is a highly regulated process used to eliminate unwanted or damaged cells from multicellular organisms. The morphology of cells undergoing apoptosis is similar to cells undergoing both normal mitosis and an aberrant form of mitosis called mitotic catastrophe. During each of these processes, cells release substrate attachments, lose cell volume, condense their chromatin, and disassemble the nuclear lamina. The morphological similarities among cells undergoing these processes suggest that the underlying biochemical changes also may be related. The susceptibility of cells to apoptosis frequently depends on the differentiation state of the cell. Additionally, cell cycle checkpoints appear to link the cell cycle to apoptosis. Deregulation of the cell cycle components has been shown to induce mitotic catastrophe and also may be involved in triggering apoptosis. Some apoptotic cells express abnormal levels of cell cycle proteins and often contain active Cdc2, the primary kinase active during mitosis. Although cell cycle components may not be involved in all forms of apoptosis, in many instances cell proliferation and cell death may share common pathways.     

Auxin-dependent cell division and cell elongation. 1-Naphthaleneacetic acid and 2,4-dichlorophenoxyacetic acid activate different pathways

During exponential phase, the tobacco (Nicotiana tabacum) cell line cv Virginia Bright Italia-0 divides axially to produce linear cell files of distinct polarity. This axial division is controlled by exogenous auxin. We used exponential tobacco cv Virginia Bright Italia-0 cells to dissect early auxin signaling, with cell division and cell elongation as physiological markers. Experiments with 1-naphthaleneacetic acid (NAA) and 2,4-dichlorophenoxyacetic acid (2,4-D) demonstrated that these 2 auxin species affect cell division and cell elongation differentially; NAA stimulates cell elongation at concentrations that are much lower than those required to stimulate cell division. In contrast, 2,4-D promotes cell division but not cell elongation. Pertussis toxin, a blocker of heterotrimeric G-proteins, inhibits the stimulation of cell division by 2,4-D but does not affect cell elongation. Aluminum tetrafluoride, an activator of the G-proteins, can induce cell division at NAA concentrations that are not permissive for division and even in the absence of any exogenous auxin. The data are discussed in a model where the two different auxins activate two different pathways for the control of cell division and cell elongation.     

Regenerative medicine bioprocessing: Concentration and behavior of adherent cell suspensions and pastes

Regenerative medicines based on human cells demand their harvesting, culture, and processing. Manufacturing processes are likely to include cell concentration and subsequent controlled dosing of concentrates, for example, to the patient or tissue construct. The integrity and functionality of the cells must be maintained during these processing stages. In this study the performance of two different cell concentration protocols (involving centrifugation and resuspension) are compared and consideration given to possible causes of cell loss. Further studies examine cell size and rheological behavior of anchorage‐dependent mammalian cell suspensions, and the effect of capillary flow stress (0.5–15 Pa, laminar flow regime) on cell number and membrane integrity as quantified by flow cytometry. The cell concentration protocols achieved maximum cell volume fraction of around 0.3 and the improved protocol exhibited intact cell yield of 80 ± 13%, demonstrating proof‐of principle for achieving tissue‐like cell concentrations by a process of centrifugation and orbital shaking. Volume mean cell diameter (cell diameter at the mean cell volume) for the rat aortic smooth muscle cells (CRL‐1444) used in this study was 22.4 µm. Concentrated cell suspension rheology approximated to power law behavior and exhibited similar trends to reports for plant and yeast cells. Capillary transfer at 2–15 Pa (wall shear stress) did not significantly affect cell number or membrane integrity while losses observed at low shear (0.5, 1.0 Pa) were probably due to surface attachment of cells in the apparatus. Biotechnol. Bioeng. 2009;103: 1236–1247. © 2009 Wiley Periodicals, Inc.     

双色FISH和DNA纤维FISH方法的建立与应用

在构建了含毛细胞白血病相关的结构性倒位inv (5) (p13.1q13.3)的细胞系后,为了确定该新建细胞系在建株过程中其倒位断裂点关键区遗传物质是否发生改变,以生物素或地高辛标记的cCI5-216 和cCI5-267黏粒DNA为探针,进行染色体中期、间期和DNA纤维3种双色荧光原位杂交的分析。结果表明：该新建细胞系的3种双色荧光原位杂交结果,均与该细胞系的原代细胞的完全相同,证实了该细胞系倒位断裂点关键区的遗传物质结构未发生改变。该细胞系是揭示毛细胞白血病发病的分子机理的重要研究材料。     

Structure and phylogeny of cell coverings

Various cell coverings in structure and composition occur in algae. They include intracellular cell coverings, scaly cell coverings, and cell walls. Chemical components of cell coverings vary depending on phylogenetic groups and generations. In this paper, the evolution of cell coverings is discussed. Electronic Publication     

Pathways of apoptosis and importance in development

The elimination of cells by programmed cell death is a fundamental event in development where multicellular organisms regulate cell numbers or eliminate cells that are functionally redundant or potentially detrimental to the organism. The evolutionary conservation of the biochemical and genetic regulation of programmed cell death across species has allowed the genetic pathways of programmed cell death determined in lower species, such as the nematode Caenorhabditis elegans and the fruitfly Drosophila melanogaster to act as models to delineate the genetics and regulation of cell death in mammalian cells. These studies have identified cell autonomous and non-autonomous mechanisms that regulate of cell death and reveal that developmental cell death can either be a pre-determined cell fate or the consequence of insufficient cell interactions that normally promote cell survival.     

Control of division and differentiation of plant stem cells and their derivatives

The core mechanism of the plant cell cycle is conserved with all other eukaryotes but several aspects are unique to plant cells. Key characteristics of plant development include indeterminate growth and repetitive organogenesis derived from stem cell pools and they may explain the existence of the high number of cell cycle regulators in plants. In this review, we give an overview of the plant cell cycle and its regulatory components. Furthermore, we discuss the cell cycle aspects of plant stem cell maintenance and how the cell cycle relates to cellular differentiation during development. We exemplify this transition by focusing on organ initiation in the shoot.     

Classical cadherins control nucleus and centrosome position and cell polarity

Control of cell polarity is crucial during tissue morphogenesis and renewal, and depends on spatial cues provided by the extracellular environment. Using micropatterned substrates to impose reproducible cell–cell interactions, we show that in the absence of other polarizing cues, cell–cell contacts are the main regulator of nucleus and centrosome positioning, and intracellular polarized organization. In a variety of cell types, including astrocytes, epithelial cells, and endothelial cells, calcium-dependent cadherin-mediated cell–cell interactions induce nucleus and centrosome off-centering toward cell–cell contacts, and promote orientation of the nucleus–centrosome axis toward free cell edges. Nucleus and centrosome off-centering is controlled by N-cadherin through the regulation of cell interactions with the extracellular matrix, whereas the orientation of the nucleus–centrosome axis is determined by the geometry of N-cadherin–mediated contacts. Our results demonstrate that in addition to the specific function of E-cadherin in regulating baso-apical epithelial polarity, classical cadherins control cell polarization in otherwise nonpolarized cells.     

Stems cells and the pathways to aging and cancer

The aging of tissue-specific stem cell and progenitor cell compartments is believed to be central to the decline of tissue and organ integrity and function in the elderly. Here, we examine evidence linking stem cell dysfunction to the pathophysiological conditions accompanying aging, focusing on the mechanisms underlying stem cell decline and their contribution to disease pathogenesis.     

Cell replication and aging: in vitro and in vivo studies.

The relationship between human aging and cell replication has been investigated using two complementary approaches: in vitro studies of human fibroblasts derived from young and old volunteer members of the Baltimore Longitudinal Study and in vivo examinations of bone marrow cell populations from young and old mice and rats. Total proliferative capacity measured as either the onset of cell culture senescence or as in vitro life span was significantly diminished in cell cultures derived from old human donors when compared to parallel cultures established from young donors. Acute replicative abilities as measured by percent replicating cells, cell pupulation doubling time, cell number at confluency, and colony size distribution were also significantly decreased in human old cell populations. An in vivo cytogenetic technique for measuring cell replication was developed utilizing the differential staining properties of metaphase chromosomes of cells that have replicated in the presence of bromodeoxyuridine. With this technique, cell cycle times have been derived in vivo as well as in vitro. Preliminary in vivo results in both mice and rats indicate that cell replication is slowed in old animal cell populations. Further research will be directed both in vitro and in vivo at discerning the mechanisms for this impairment of cellular replication with aging.     

Sialic acids in T cell development and function

Virtually all cell surface proteins and many cell membrane lipids are glycosylated, creating a cell surface glycocalyx. The glycan chains attached to cell surface glycoproteins and glycolipids are complex structures with specific additions that determine functions of the glycans in cell–cell communication and cell sensing of the environment. One type of specific modification of cell surface glycans is decoration of glycan termini by sialic acids. On T cells, these terminal sialic acid residues are involved in almost every aspect of T cell fate and function, from cell maturation, differentiation, and migration to cell survival and cell death. The roles that sialylated glycans play in T cell development and function, including binding to specific sialic acid-binding lectins, are reviewed here.     

Ion channels and apoptosis in cancer

Humans maintain a constant cell number throughout their lifespan. This equilibrium of cell number is accomplished when cell proliferation and cell death are kept balanced, achieving a steady-state cell number. Abnormalities in cell growth or cell death can lead to an overabundance of cells known as neoplasm or tumours. While the perception of cancer is often that of an uncontrollable rate of cell growth or increased proliferation, a decrease in cell death can also lead to tumour formation. Most cells when detached from their normal tissue die. However, cancer cells evade cell death, tipping the balance to an overabundance of cell number. Therefore, overcoming this resistance to cell death is a decisive factor in the treatment of cancer. Ion channels play a critical role in cancer in regards to cell proliferation, malignant angiogenesis, migration and metastasis. Additionally, ion channels are also known to be critical components of apoptosis. In this review, we discuss the modes of cell death focusing on the ability of cancer cells to evade apoptosis. Specifically, we focus on the role ion channels play in controlling and regulating life/death decisions and how they can be used to overcome resistance to apoptosis in the treatment of cancer.