New phosphatidylserine receptors: clearance of apoptotic cells and more

Phagocytes recognize apoptotic cells using cell surface receptors, and subsequently engulf these cells. In a recent issue of Nature, two papers reported the identification of novel phagocytic receptors that directly interact with apoptotic cell surface phosphatidylserine (PS). The studies provide new insights into the apoptotic cell clearance process and implicate PS receptors in additional signaling events.     

Spatial regulation of cytokinesis in bacteria

Cytokinesis in bacteria such as Escherichia coli is orchestrated by FtsZ, a tubulin-like protein that forms a circumferential Z ring at the division site. The Z ring then recruits a number of other essential cell division proteins, ultimately assembling the cytokinetic machine that splits the cell. It has been known for some time that the MinCDE proteins and the bacterial nucleoid provide positional information to negatively regulate cytokinesis. Recently, direct visualization of Z rings and Min proteins in whole cells have contributed important new insights into the molecular mechanisms behind this fundamental cellular process. This review summarizes and integrates these insights.     

Dictyostelium: a model for regulated cell movement during morphogenesis

Dictyostelium has played an important role in unraveling the pathways that control cell movement and chemotaxis. Recent studies have started to elucidate the pathways that control cell sorting, morphogenesis, and the establishment of spatial patterning in this system. In doing so, they provide new insights into how cell movements within a multicellular organism are regulated and the importance of pathways that are similar to those that regulate chemotaxis of cells on two-dimensional surfaces during aggregation.     

Tetraspanin functions and associated microdomains

Cell-surface proteins of the tetraspanin family are small, and often hidden by a canopy of tall glycoprotein neighbours in the cell membrane. Consequently, tetraspanins have been understudied and underappreciated, despite their presence on nearly all cell and tissue types. Important new genetic evidence has now emerged, and is bolstered by new insights into the cell biology, signalling and biochemistry of tetraspanins. These new findings provide a framework for better understanding of these mysterious molecules in the regulation of cellular processes, from signalling to motility.     

p27(Kip1) and stathmin share the stage for the first time

Cell migration is essential for development, morphogenesis, tissue repair and tumor metastasis. p27(Kip1) and stathmin are two cell-cycle-regulatory proteins that were recently shown to play important roles in the regulation of cell migration. In this article, we discuss a new study that places p27(Kip1) and stathmin in the same pathway by showing that stathmin, a microtubule-regulatory protein, mediates the effects of p27(Kip1) on cell motility. These findings provide new insights into migration and metastasis of tumor cells and the relationship of these processes to cell proliferation.     

Cell wall mutants

An ever growing collection of cell wall mutants is yielding new insights into the mechanisms underlying the synthesis and assembly of cell walls in plants. In this review, we will provide an update on the use of genetic tools in plant cell wall research and we will discuss the lessons that can be drawn from the study of the first generation of mutants.     

Curbing the excesses of youth: molecular insights into axonal pruning

The embryonic nervous system is refined over the course of development as a result of the twin processes of naturally occurring cell death and selective axon pruning. Recent studies provide new insights into the molecular events that underlie axon pruning and underscore the diversity of refinement processes employed by the nervous system during development.     

p75NTR is positively promiscuous: novel partners and new insights

Although identified almost 20 years ago, the precise physiological role of the p75 neurotrophin receptor (p75NTR) has remained elusive. Recent studies have revealed that p75NTR is a component of three distinct receptor platforms that bind different ligands and that, under differing circumstances, facilitate cell survival, cell death, or growth inhibition. These recent developments provide new insights into the functions of this enigmatic receptor.     

Expansion of the phragmoplast during plant cytokinesis: a MAPK pathway may MAP it out

Plant cytokinesis involves the formation of a cell plate. This is accomplished with the help of the phragmoplast, a plant-specific cytokinetic apparatus that consists of microtubules and microfilaments. During centrifugal growth of the cell plate, the phragmoplast expands to keep its microtubules at the leading edge of the cell plate. Recent studies have revealed potential regulators of phragmoplast microtubule dynamics and the involvement of a mitogen-activated protein kinase cascade in the control of phragmoplast expansion. These studies provide new insights into the molecular mechanisms of plant cytokinesis.     

Using transgenic zebrafish (Danio rerio) to study development of the craniofacial skeleton

Transgenic zebrafish provide amazing new tools for following and manipulating cells that form the skeleton. Transgenes that label distinct populations of embryonic cells, such as neural crest that forms most of the skull vault as well as the jaws and gills can be used to determine the embryonic origins of cartilages and bones. This provides a powerful model system for studies of the developmental basis for human birth defects and in a comparative context provides new insights into the developmental changes underlying morphological evolution. Targeting transgenes to nuclear or membrane compartments allows detailed tracking of cell shapes and movements. Here we review how such transgenic markers combined with mutants or tissue grafts to generate mosaic zebrafish embryos have already provided many new insights into skeletal development and disease. In the long run, transgenics designed to perturb gene expression hold great promise for studies of gene function.     

Bovine mature adipocytes readily return to a proliferative state

The dynamics of human and animal adipogenesis has been defined using several traditional cell systems including stromal vascular cells and adipocyte-related cell lines. But a relatively new cell system using progeny cells stemming from the dedifferentiation of purified cultures of mature adipocytes may be used for studying the development and biology of adipocytes. In this research, we show that isolated (and purified) mature adipocytes derived from Wagyu cattle dedifferentiate into progeny cells, and that these spindle-shaped, proliferative-competent daughter cells possess ability to proliferate. We outline the optimum cell culture system and offer precautionary thoughts for effective mature adipocyte culture. Collectively, this represents a novel cell model which may provide new insights into cell development, physiology and use as a model for animal production/composition, tissue engineering and disease treatment.     

Applying proteomics to signaling networks

The information from genome sequencing provides a new framework for a systems-wide understanding of protein networks and cellular function. Whereas microarray technologies provide information about global gene expression within cells, complementary proteomic strategies monitor expression of proteins and their posttranslational modifications. Improved technologies that have emerged for comprehensive and high-throughput protein analysis yield novel insights into cell regulation.     

The immunological synapse and actin assembly: a regulatory role for PKC theta

Engagement of the T cell receptor leads to the accumulation of filamentous actin, which is necessary for the formation of the immunological synapse and subsequent T cell activation. In the December issue of Molecular Cell, Sasahara et al. provide new insights into the link between the T cell receptor and actin assembly in the immunological synapse, and reveal a critical regulatory role for PKC theta in this process.     

Protein Kinase C Regulates the Cell Surface Activity of Endothelin-Converting Enzyme-1

The potent vasoconstrictor endothelin is a 21 amino acid peptide whose principal physiological function is to regulate vascular tone. The generation of endothelin is crucially dependent on the local presence and activity of endothelin converting enzyme-1 (ECE-1) expressed on the surface of vascular endothelial cells. In this study, we have shown in endothelial cells that the enzyme is phosphorylated, and that phosphorylation is increased by phorbol ester stimulation of protein kinase C (PKC). Furthermore, by monitoring specific ECE-1 activity on the surface of live cells, we also show that following PKC activation, enzyme activity is significantly increased at the cell surface, where it is positioned to catalyse the generation of active endothelin. We believe this novel finding is unprecedented for a peptide processing enzyme. Indeed, this new knowledge regarding the control of endothelin production by regulating ECE-1 activity at the cell surface opens up a new area of endothelin biology and will provide novel insights into the physiology and pathophysiology of endothelin and endothelin-associated diseases. In addition, the information generated in these studies may provide valuable new insights into potential extra- and intracellular targets for the pharmacological and perhaps even therapeutic regulation of endothelin production and thus vascular tone.Australian Peptide Conference Issue.     

Dynamic organization of the cell nucleus

The dynamic organization of the cell nucleus into subcompartments with distinct biological activities represents an important regulatory layer for cell function. Recent studies provide new insights into the principles, by which nuclear organelles form. This process frequently occurs in a self-organizing manner leading to the assembly of stable but plastic structures from multiple relatively weak interaction forces. These can rearrange into different functional states in response to specific modifications of the constituting components or changes in the nuclear environment.     

NMR spectroscopy and imaging of the neonatal brain

Magnetic resonance spectroscopy and imaging provide unique information about the brain to the biochemist and the clinician. In particular, the ability to image metabolites other than water and to get detailed information about dynamic cellular processes (such as blood flow, blood oxygenation and cell swelling) is leading to many new insights into brain function and dysfunction. This review describes the use of old and new NMR techniques which demonstrate that mitochondrial dysfunction plays an important role in the cell death that occurs following an hypoxic-ischaemic insult to the neonatal brain.     

Living with p53, dying of p53

The p53 tumor suppressor protein acts as a major defense against cancer. Among its most distinctive features is the ability to elicit both apoptotic death and cell cycle arrest. In this issue of Cell, Das et al. (2007) and Tanaka et al. (2007) provide new insights into the mechanisms that dictate the life and death decisions of p53.     

Regulation of host cell translation by viruses and effects on cell function

Viruses have evolved a remarkable variety of strategies to modulate the host cell translation apparatus with the aim of optimizing viral mRNA translation and replication. Recent studies have revealed that modulation of both host and viral mRNA translation can be accomplished by selective alteration of translation factors in virus-infected cells. These findings provide new insights into the functioning of the translational apparatus in both uninfected and infected cells.     

Lectins in the endoplasmic reticulum: the sweet side of protein quality control

In a recent study in Nature Cell Biology, Christianson et al. provide intriguing insights into the mechanisms of mammalian protein quality control in the endoplasmic reticulum. Their findings open up new perspectives on the versatility and diversity of how protein quality control sorts out defective polypeptides to prevent damage to the cell.