Cdc2 phosphorylation of BAD links the cell cycle to the cell death machinery

A mechanism that triggers neuronal apoptosis has been characterized. We report that the cell cycle-regulated protein kinase Cdc2 is expressed in postmitotic granule neurons of the developing rat cerebellum and that Cdc2 mediates apoptosis of cerebellar granule neurons upon the suppression of neuronal activity. Cdc2 catalyzes the phosphorylation of the BH3-only protein BAD at a distinct site, serine 128, and thereby induces BAD-mediated apoptosis in primary neurons by opposing growth factor inhibition of the apoptotic effect of BAD. The phosphorylation of BAD serine 128 inhibits the interaction of growth factor-induced serine 136-phosphorylated BAD with 14-3-3 proteins. Our results suggest that a critical component of the cell cycle couples an apoptotic signal to the cell death machinery via a phosphorylation-dependent mechanism that may generally modulate protein-protein interactions.     

Mechanotransduction and endothelial cell homeostasis: the wisdom of the cell

Vascular endothelial cells (ECs) play significant roles in regulating circulatory functions. Mechanical stimuli, including the stretch and shear stress resulting from circulatory pressure and flow, modulate EC functions by activating mechanosensors, signaling pathways, and gene and protein expressions. Mechanical forces with a clear direction (e.g., the pulsatile shear stress and the uniaxial circumferential stretch existing in the straight part of the arterial tree) cause only transient molecular signaling of pro-inflammatory and proliferative pathways, which become downregulated when such directed mechanical forces are sustained. In contrast, mechanical forces without a definitive direction (e.g., disturbed flow and relatively undirected stretch seen at branch points and other regions of complex geometry) cause sustained molecular signaling of pro-inflammatory and proliferative pathways. The EC responses to directed mechanical stimuli involve the remodeling of EC structure to minimize alterations in intracellular stress/strain and elicit adaptive changes in EC signaling in the face of sustained stimuli; these cellular events constitute a feedback control mechanism to maintain vascular homeostasis and are atheroprotective. Such a feedback mechanism does not operate effectively in regions of complex geometry, where the mechanical stimuli do not have clear directions, thus placing these areas at risk for atherogenesis. The mechanotransduction-induced EC adaptive processes in the straight part of the aorta represent a case of the "Wisdom of the Cell," as a part of the more general concept of the "Wisdom of the Body" promulgated by Cannon, to maintain cellular homeostasis in the face of external perturbations.     

Constructing and deconstructing the bacterial cell wall

The history of modern medicine cannot be written apart from the history of the antibiotics. Antibiotics are cytotoxic secondary metabolites that are isolated from Nature. The antibacterial antibiotics disproportionately target bacterial protein structure that is distinct from eukaryotic protein structure, notably within the ribosome and within the pathways for bacterial cell‐wall biosynthesis (for which there is not a eukaryotic counterpart). This review focuses on a pre‐eminent class of antibiotics—the β‐lactams, exemplified by the penicillins and cephalosporins—from the perspective of the evolving mechanisms for bacterial resistance. The mechanism of action of the β‐lactams is bacterial cell‐wall destruction. In the monoderm (single membrane, Gram‐positive staining) pathogen Staphylococcus aureus the dominant resistance mechanism is expression of a β‐lactam‐unreactive transpeptidase enzyme that functions in cell‐wall construction. In the diderm (dual membrane, Gram‐negative staining) pathogen Pseudomonas aeruginosa a dominant resistance mechanism (among several) is expression of a hydrolytic enzyme that destroys the critical β‐lactam ring of the antibiotic. The key sensing mechanism used by P. aeruginosa is monitoring the molecular difference between cell‐wall construction and cell‐wall deconstruction. In both bacteria, the resistance pathways are manifested only when the bacteria detect the presence of β‐lactams. This review summarizes how the β‐lactams are sensed and how the resistance mechanisms are manifested, with the expectation that preventing these processes will be critical to future chemotherapeutic control of multidrug resistant bacteria.     

On the reinitiation of cell growth in culture

The reinitiation of growth by rat C₆ glioma cultures following dissociation, dilution, and replating arises from the disruption of cooperative cell interactions rather than from the effects of the dissociating agent upon the cell surface or an anchorage dependent event. The cell interaction mechanism responsible for this effect does not involve the extracellular matrix or a conditioned medium factor, and is therefore probably contact in nature. Three distinct components of C₆ growth regulation can now be recognized: (1) an endogenous growth program which specifies the time base of growth events and causes growth inhibition; (2) a density dependent mechanism that regulates the amplitude of the growth rate; and (3) a second density dependent mechanism which ‘locks’ cells into a state of growth inhibition, thereby preventing growth reinitiation. Both of the density dependent mechanisms appear to involve contact mediation.     

Removing the brakes on cell identity

In this issue of Developmental Cell, Dhawan et?al. (2011) show that deletion of the Dnmt1 DNA methyltransferase gene in pancreatic insulin-producing cells makes these cells convert into glucagon-producing cells. This suggests that manipulation of a general epigenetic mechanism may be used to redirect cell fates.     

Archaea and the cell cycle

Sequence similarity data suggest that archaeal chromosome replication is eukaryotic in character. Putative nucleoid-processing proteins display similarities to both eukaryotic and bacterial counterparts, whereas cell division may occur through a predominantly bacterial mechanism. Insights into the organization of the archaeal cell cycle are therefore of interest, not only for understanding archaeal biology, but also for investigating how components from the other two domains interact and work in concert within the same cell; in addition, archaea may have the potential to provide insights into eukaryotic initiation of chromosome replication.     

Diversity in the mechanisms of neuronal cell death

Neurons may die as a normal physiological process during development or as a pathological process in diseases. The best-understood mechanism of neuronal cell death is apoptosis, which is regulated by an evolutionarily conserved cellular pathway that consists of the caspase family, the Bcl-2 family, and the adaptor protein Apaf-1. Apoptosis, however, may not be the only cellular mechanism that regulates neuronal cell death. Neuronal cell death may exhibit morphological features of autophagy or necrosis, which differ from that of the canonical apoptosis. This review evaluates the evidence supporting the existence of alternative mechanisms of neuronal cell death and proposes the possible existence of an evolutionarily conserved pathway of necrosis.     

A mechanism for the establishment of polar cell morphology based on the cytoskeleton-derived forces exerted on the cell boundary

A mechanism for the establishment of polar cell morphology is presented, based on the internal forces that the cytoskeletal structures exert on the cell boundary. Cell shapes are determined by postulating that they correspond to the minimum of the total energy of the system, which is the sum of the bending energy of the cell boundary and the potential energies of the involved forces. Axisymmetrical cell shapes are considered, and it is assumed that the cytoskeletal structures exert an extensional axial force and are involved in controlling the area of the cell boundary. The dependence of cell shapes on the axial force is presented for different values of this area. The results show that, at increasing axial force, the cell undergoes a discontinuous transition from an oval shape, exhibiting an equatorial mirror symmetry into a polar shape. The proposed mechanism is related to previously documented specific effects of microtubule- and actin-modifying drugs on polar shapes of developing isolated retinal photoreceptor cells. Received: 28 January 1998 / Revised version: 25 July 1998 / Accepted: 29 July 1998     

Plant steroids recognized at the cell surface

Plants might use a markedly different mechanism for steroid signaling than animals. In animals, steroid hormone signals are generally mediated by receptors inside the cell. However, a recent report by He et al. indicates that, in plants, steroids appear to be perceived at the plasma membrane rather than by intracellular receptors.     

A mortalization theory for the control of the cell proliferation and for the origin of immortal cell lines.

An increasing rate of cellular mortalization sets a limit to the proliferation of fibroblast populations. Failure of the mortalization mechanism leads to the formation of immortal clones of cells. A possible molecular model for the mortalization process is described.     

Linking cell division to cell growth in a spatiotemporal model of the cell cycle

Cell division must be tightly coupled to cell growth in order to maintain cell size, yet the mechanisms linking these two processes are unclear. It is known that almost all proteins involved in cell division shuttle between cytoplasm and nucleus during the cell cycle; however, the implications of this process for cell cycle dynamics and its coupling to cell growth remains to be elucidated. We developed mathematical models of the cell cycle which incorporate protein translocation between cytoplasm and nucleus. We show that protein translocation between cytoplasm and nucleus not only modulates temporal cell cycle dynamics, but also provides a natural mechanism coupling cell division to cell growth. This coupling is mediated by the effect of cytoplasmic-to-nuclear size ratio on the activation threshold of critical cell cycle proteins, leading to the size-sensing checkpoint (sizer) and the size-independent clock (timer) observed in many cell cycle experiments.     

Inhibitory mechanism of a cross-class serpin,the squamous cell carcinoma antigen 1

The squamous cell carcinoma antigen (SCCA) 1 and its homologous molecule, SCCA2, belong to the ovalbumin-serpin family. Although SCCA2 inhibits serine proteinases such as cathepsin G and mast cell chymase, SCCA1 targets cysteine proteinases such as cathepsin S, K, L, and papain. SCCA1 is therefore called a cross-class serpin. The inhibitory mechanism of the standard serpins is well characterized; those use a suicide substrate-like inhibitory mechanism during which an acyl-enzyme intermediate by a covalent bond is formed, and this complex is stable against hydrolysis. However, the inhibitory mechanism of cross-class serpins remains unresolved. In this article, we analyzed the inhibitory mechanism of SCCA1 on a cysteine proteinase, papain. SCCA1 interacted with papain at its reactive site loop, which was then cleaved, as the standard serpins. However, gel-filtration analyses showed that SCCA1 did not form a covalent complex with papain, in contrast to other serpins. Interaction with SCCA1 severely impaired the proteinase activity of papain, probably by inducing conformational change. The decreased, but still existing, proteinase activity of papain was completely inhibited by SCCA1 according to the suicide substrate-like inhibitory mechanism; however, papain recovered its proteinase activity with the compromised level, when all of intact SCCA1 was cleaved. These results suggest that the inhibitory mechanism of SCCA1 is unique among the serpin superfamily in that SCCA1 performs its inhibitory activity in two ways, contributing the suicide substrate-like mechanism without formation of a covalent complex and causing irreversible impairment of the catalytic activity of a proteinase.     

Incorporation of fucose into HeLa cell plasma membranes during the cell cycle

The metabolism of HeLa cell plasma membranes during the cell cycle was studied by following the incorporation of radioactive precursor l-[³H]fucose into plasma membranes of synchronized cells. Maximal incorporation of the radioactive precursor was observed in late S phase of the cell cycle. This discrete period of increased incorporation of precursor into the plasma membranes implies the existence of a distinct control mechanism which may relate cell surface phenomena to the cell cycle.     

Myosin-II puts the squeeze on asymmetric cell division

Asymmetric cell division--where two dissimilar daughter cells are produced--relies on asymmetric positioning of the telophase spindle midzone, which specifies the cleavage furrow. Ou et al. (2010) now report in Science a mechanism of asymmetric midzone positioning driven by a polarized cortical distribution of the contractile motor myosin-II.     

Motoring down the highways of the cell

All eukaryotic cells contain large numbers of motor proteins (kinesins, dyneins and myosins), each of which appears to carry out a specialized force-generating function within the cell. They are known to have roles in muscle contraction, ciliary movement, organelle and vesicle transport, mitosis and cytokinesis. These motor proteins operate on different cytoskeletal filaments; myosins move along actin filaments, and kinesins and dyneins along microtubules. Recently published crystal structures of the motor domains of two members of the kinesin superfamily reveal that they share the same overall fold that is also found at the core of the larger myosin motor. This suggests that they may share a common mechanism as well as a common ancestry.     

Visiting the cell biology of Salmonella infection

Salmonella, a Gram-negative facultative intracellular pathogen is capable of infecting vast array of hosts. The striking ability of Salmonella to overcome every hurdle encountered in the host proves that they are true survivors. In the host, Salmonella infects various cell types and needs to survive and replicate by countering the defense mechanism of the specific cell. In this review, we will summarize the recent insights into the cell biology of Salmonella infection. Here, we will focus on the findings that deal with the specific mechanism of various cell types to control Salmonella infection. Further, the survival strategies of the pathogen in response to the host immunity will also be discussed in detail. Better understanding of the mechanisms by which Salmonella evade the host defense system and establish pathogenesis will be critical in disease management.     

Bora在细胞功能调控中的作用和机制研究进展

Aurora蛋白激酶A及Polo样蛋白激酶1（PLK在）作为重要的细胞周期调节蛋白可参与调控纺锤体组装、有丝分裂等细胞进程,但其激活机制及在有丝分裂中的作用机制仍然不是很清楚。Bora作为Aurora蛋白激酶A的结合蛋白,在果蝇和脊椎动物中功能高度保守,其主要通过结合Aurora蛋白激酶A从而调节Aurora蛋白激酶A的活性、促进PLK1的磷酸化、调节纺锤体的组装以及调控细胞周期进程等。随着对Bora研究的深入,人们对AuroraA和PLK1的激活机制以及Bora、Aurora蛋白激酶A、PLK1三者对细胞的调控也有了进一步的认识。主要综述Bora在细胞功能调控中的作用和研究机制。