Single-Cell RNA Sequencing Maps Endothelial Metabolic Plasticity in Pathological Angiogenesis

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Cell cycle control of cell morphogenesis in Caulobacter

In Caulobacter crescentus, morphogenic events, such as cytokinesis, the establishment of asymmetry and the biogenesis of polar structures, are precisely regulated during the cell cycle by internal cues, such as cell division and the initiation of DNA replication. Recent studies have revealed that the converse is also true. That is, differentiation events impose regulatory controls on other differentiation events, as well as on progression of the cell cycle. Thus, there are pathways that sense the assembly of structures or the localization of complexes and then transduce this information to subsequent biogenesis or cell cycle events. In this review, we examine the interplay between flagellar assembly and the C. crescentus cell cycle.     

The plant cell cycle in context

Biological scientists are eagerly confronting the challenge of understanding the regulatory mechanisms that control the cell division cycle in eukaryotes. New information will have major implications for the treatment of growth-related diseases and cancer in animals. In plants, cell division has a key role in root and shoot growth as well as in the development of vegetative storage organs and reproductive tissues such as flowers and seeds. Many of the strategies for crop improvement, especially those aimed at increasing yield, involve the manipulation of cell division. This review describes, in some detail, the current status of our understanding of the regulation of cell division in eukaryotes and especially in plants. It also features an outline of some preliminary attempts to exploit transgenesis for manipulation of plant cell division.     

Temporal fluxomics reveals oscillations in TCA cycle flux throughout the mammalian cell cycle

Cellular metabolic demands change throughout the cell cycle. Nevertheless, a characterization of how metabolic fluxes adapt to the changing demands throughout the cell cycle is lacking. Here, we developed a temporal‐fluxomics approach to derive a comprehensive and quantitative view of alterations in metabolic fluxes throughout the mammalian cell cycle. This is achieved by combining pulse‐chase LC‐MS‐based isotope tracing in synchronized cell populations with computational deconvolution and metabolic flux modeling. We find that TCA cycle fluxes are rewired as cells progress through the cell cycle with complementary oscillations of glucose versus glutamine‐derived fluxes: Oxidation of glucose‐derived flux peaks in late G1 phase, while oxidative and reductive glutamine metabolism dominates S phase. These complementary flux oscillations maintain a constant production rate of reducing equivalents and oxidative phosphorylation flux throughout the cell cycle. The shift from glucose to glutamine oxidation in S phase plays an important role in cell cycle progression and cell proliferation.     

细胞周期调控的研究进展

细胞周期是一种非常复杂和精细的调节过程,有大量调节蛋白参与其中。此过程的核心是细胞周期依赖性蛋白激酶（CDKs）。CDKs的激活又依赖于另一类呈细胞周期特异性或时相性表达的细胞周期蛋白（cyclins）,而CDKs调节的关键步骤是细胞周期检查点。PLKs是多种细胞周期检查点的主要调节因子,Aurora蛋白激酶主要在细胞有丝分裂期起作用。本文就上述因素在细胞周期进程中的作用作一综述。     

细胞周期研究的新进展

细胞周期研究的新进展陆长德（中国科学院上海生物化学研究所２０００３１）主要来自三方面的研究以及它们之间的相互交叉对于细胞周期研究的进展起了很大的作用。十多年来酵母分子遗传学的研究鉴定了许多与细胞周期的控制有关的基因,提供了许多突变株（如ＣＤＣ）;１９８８年对蛙卵成熟促进因子ＭＰＦ成分的鉴定和对它生物学功能的确定使人们对细胞周期的认识有了一个飞跃;人类的致癌基因（如Ｔａｇ）,肿瘤抑制基因（如p53,pRB)以及其他一些疾病(如对电离辐射敏感的遗传病,AT的分子机制的研究也大大地促进了细胞周期的研究。     

The auxin-binding protein 1 is essential for the control of cell cycle

The phytohormone auxin has been known for >50 years to be required for entry into the cell cycle. Despite the critical effects exerted by auxin on the control of cell division, the molecular mechanism by which auxin controls this pathway is poorly understood, and how auxin is perceived upstream of any change in the cell cycle is unknown. Auxin Binding Protein 1 (ABP1) is considered to be a candidate auxin receptor, triggering early modification of ion fluxes across the plasma membrane in response to auxin. ABP1 has also been proposed to mediate auxin-dependent cell expansion, and is essential for early embryonic development. We investigated whether ABP1 has a role in the cell cycle. Functional inactivation of ABP1 in the model plant cell system BY2 was achieved through cellular immunization via the conditional expression of a single-chain fragment variable (scFv). This scFv was derived from a well characterized anti-ABP1 monoclonal antibody previously shown to block the activity of the protein. We demonstrate that functional inactivation of ABP1 results in cell-cycle arrest, and provide evidence that ABP1 plays a critical role in regulation of the cell cycle by acting at both the G1/S and G2/M checkpoints. We conclude that ABP1 is essential for the auxin control of cell division and is likely to constitute the first step of the auxin-signalling pathway mediating auxin effects on the cell cycle.     

Evolution of networks and sequences in eukaryotic cell cycle control

The molecular networks regulating the G1-S transition in budding yeast and mammals are strikingly similar in network structure. However, many of the individual proteins performing similar network roles appear to have unrelated amino acid sequences, suggesting either extremely rapid sequence evolution, or true polyphyly of proteins carrying out identical network roles. A yeast/mammal comparison suggests that network topology, and its associated dynamic properties, rather than regulatory proteins themselves may be the most important elements conserved through evolution. However, recent deep phylogenetic studies show that fungal and animal lineages are relatively closely related in the opisthokont branch of eukaryotes. The presence in plants of cell cycle regulators such as Rb, E2F and cyclins A and D, that appear lost in yeast, suggests cell cycle control in the last common ancestor of the eukaryotes was implemented with this set of regulatory proteins. Forward genetics in non-opisthokonts, such as plants or their green algal relatives, will provide direct information on cell cycle control in these organisms, and may elucidate the potentially more complex cell cycle control network of the last common eukaryotic ancestor.     

Two-way communication between the metabolic and cell cycle machineries: the molecular basis

The relationship between cellular metabolism and the cell cycle machinery is by no means unidirectional. The ability of a cell to enter the cell cycle critically depends on the availability of metabolites. Conversely, the cell cycle machinery commits to regulating metabolic networks in order to support cell survival and proliferation. In this review, we will give an account of how the cell cycle machinery and metabolism are interconnected. Acquiring information on how communication takes place among metabolic signaling networks and the cell cycle controllers is crucial to increase our understanding of the deregulation thereof in disease, including cancer.     

Thymidine nucleotide synthesis and catabolism by CHO cells and their changes during the cell cycle

At 0°C, CHO cells efficiently incorporated [³H]thymidine into the nucleotide fraction, but not into DNA. Upon reincubation of asynchronous cultures at 37°C, 15–25% of the radioactivity contained in the cellular nucleotide fraction was released, in the form of thymidine, into the culture medium. At 0°C, however, radioactivity of the nucleotide fraction was retained within the cells. Similarly, dTMP phosphatase (EC 3.1.3.35) in cell extracts was active at 37°C, but not at 0°C, whereas thymidine kinase (EC 2.7.1.21) was active at both temperatures. If synchronous cultures in Gl phase were prelabeled at 0°C and reincubated at 37°C, almost all radioactivity in the nucleotide fraction was released into the medium, whereas in S-phase cultures nearly all radioactivity of the nucleotide fraction was incorporated into DNA. In synchronous S-phase cultures treated with hydroxyurea, radioactivity in the nucleotide fraction was released into the medium at a rate considerably lower than that observed for Gl-phase cells. Rates of endogenous synthesis of thymidine nucleotides were calculated from changes of cellular thymidine nucleotide content, incorporation of thymidine nucleotides into DNA and release of thymidine into the medium during reincubation of prelabeled cultures in thymidine-free medium. The results obtained (see Table III) reveal marked differences between Gl and S phases with respect to the determinants of thymidine nucleotide metabolism.     

A discrete cell cycle checkpoint in late G(1) that is cytoskeleton-dependent and MAP kinase (Erk)-independent

Cell spreading on extracellular matrix and associated changes in the actin cytoskeleton (CSK) are necessary for progression through G(1) and entry into S phase of the cell cycle. Pharmacological disruption of CSK integrity inhibits early mitogenic signaling to the extracellular signal-regulated kinase (Erk) subfamily of the mitogen-activated protein kinases (MAPKs) and arrests the cell cycle in G(1). Here we show that this block of G(1) progression is not simply a consequence of inhibition of the MAPK/Erk pathway but instead it reveals the existence of a discrete CSK-sensitive checkpoint. Use of PD98059 to inhibit MAPK/Erk and cytochalasin D (Cyto D) to disrupt the actin CSK at progressive time points in G(1) revealed that the requirement for MAPK/Erk activation lasts only to mid-G(1), while the actin CSK must remain intact up to late G(1) restriction point, R, in order for capillary endothelial cells to enter S phase. Additional analysis using Cyto D pulses defined a narrow time window of 3 h just prior to R in which CSK integrity was shown to be critical for the G(1)/S transition. Cyto D treatment led to down-regulation of cyclin D1 protein and accumulation of the cdk inhibitor, p27(Kip1), independent of cell cycle phase, suggesting that these changes resulted directly from CSK disruption rather than from a general cell cycle block. Together, these data indicate the existence of a distinct time window in late G(1) in which signals elicited by the CSK act independently of early MAPK/Erk signals to drive the cell cycle machinery through the G(1)/S boundary and, hence, promote cell growth.     

Nobel Lecture. Cyclin dependent kinases and cell cycle control

The discovery of major regulators of the eukaryotic cell cycle is described.     

Inhibition of topoisomerase II overrides the G2/M check points of the cell cycle in EBV-lymphocytes

Epstein-Barr virus (EBV) is associated with a number of human malignancies. In vitro EBV infection transforms human lymphocytes into proliferating cell lines (EBV-lymphocytes). Etoposide, topoisomerase II inhibitor, induced apoptosis in EBV-lymphocytes as shown by expression of phosphatidylserine, loss of DNA and mitochondrial membrane potential, and cell shrinkage. In contrast, those cells, which had yet to display signs of apoptosis, grew to exceed their normal size. These EBV-lymphocytes had unusual cellular and nuclear morphology, higher mitochondrial membrane potential, increased expression of proteins and an amount of DNA that exceeded the maximum DNA content in normal EBV-lymphocytes by more than two-fold. Application of the caspase inhibitor Z-VAD-FMK in the presence of etoposide increased the numbers of such large cells. This data suggests that inhibition of topoisomerase II by etoposide does not inhibit DNA synthesis but rather overrides the G₂/M check points of the cell cycle, resulting in cells growth over their genetically determined size. This may trigger apoptosis to eliminate cells, which failed to complete mitosis.