Do peroxisome proliferating compounds pose a hepatocarcinogenic hazard to humans?

The purpose of the workshop "Do Peroxisome Proliferating Compounds Pose a Hepatocarcinogenic Hazard to Humans?" was to provide a review of the current state of the science on the relationship between peroxisome proliferation and hepatocarcinogenesis. There has been much debate regarding the mechanism by which peroxisome proliferators may induce liver tumors in rats and mice and whether these events occur in humans. A primary goal of the workshop was to determine where consensus might be reached regarding the interpretation of these data relative to the assessment of potential human risks. A core set of biochemical and cellular events has been identified in the rodent strains that are susceptible to the hepatocarcinogenic effects of peroxisome proliferators, including peroxisome proliferation, increases in fatty acyl-CoA oxidase levels, microsomal fatty acid oxidation, excess production of hydrogen peroxide, increases in rates of cell proliferation, and expression and activation of the alpha subtype of the peroxisome proliferator-activated receptor (PPAR-alpha). Such effects have not been identified clinically in liver biopsies from humans exposed to peroxisome proliferators or in in vitro studies with human hepatocytes, although PPAR-alpha is expressed at a very low level in human liver. Consensus was reached regarding the significant intermediary roles of cell proliferation and PPAR-alpha receptor expression and activation in tumor formation. Information considered necessary for characterizing a compound as a peroxisome proliferating hepatocarcinogen include hepatomegaly, enhanced cell proliferation, and an increase in hepatic acyl-CoA oxidase and/or palmitoyl-CoA oxidation levels. Given the lack of genotoxic potential of most peroxisome proliferating agents, and since humans appear likely to be refractive or insensitive to the tumorigenic response, risk assessments based on tumor data may not be appropriate. However, nontumor data on intermediate endpoints would provide appropriate toxicological endpoints to determine a point of departure such as the LED10 or NOAEL which would be the basis for a margin-of-exposure (MOE) risk assessment approach. Pertinent factors to be considered in the MOE evaluation would include the slope of the dose-response curve at the point of departure, the background exposure levels, and variability in the human response.

Negative control of quorum sensing by RpoN (sigma54) in Pseudomonas aeruginosa PAO1.

In Pseudomonas aeruginosa PAO1, the expression of several virulence factors such as elastase, rhamnolipids, and hydrogen cyanide depends on quorum-sensing regulation, which involves the lasRI and rhlRI systems controlled by N-(3-oxododecanoyl)-L-homoserine lactone and N-butyryl-L-homoserine lactone, respectively, as signal molecules. In rpoN mutants lacking the transcription factor sigma(54), the expression of the lasR and lasI genes was elevated at low cell densities, whereas expression of the rhlR and rhlI genes was markedly enhanced throughout growth by comparison with the wild type and the complemented mutant strains. As a consequence, the rpoN mutants had elevated levels of both signal molecules and overexpressed the biosynthetic genes for elastase, rhamnolipids, and hydrogen cyanide. The quorum-sensing regulatory protein QscR was not involved in the negative control exerted by RpoN. By contrast, in an rpoN mutant, the expression of the gacA global regulatory gene was significantly increased during the entire growth cycle, whereas another global regulatory gene, vfr, was downregulated at high cell densities. In conclusion, it appears that GacA levels play an important role, probably indirectly, in the RpoN-dependent modulation of the quorum-sensing machinery of P. aeruginosa.

The S. pombe cdc15 gene is a key element in the reorganization of F-actin at mitosis.

The S. pombe cdc15 gene is essential for cell division. cdc15ts mutants do not form a septum, but growth and nuclear division continue, leading to formation of multinucleate cells. The earliest step in septum formation and cytokinesis, rearrangement of actin to the center of the cell, is associated with appearance of hypophosphorylated cdc15p and formation of a cdc15p ring, which colocalizes with actin. Loss of cdc15p function impairs formation of the actin ring. The abundance of cdc15 mRNA varies through the cell division cycle, peaking in early mitosis before septation. Expression of cdc15 in G2-arrested cells induces actin rearrangement to the center of the cell. These data implicate cdc15p as a key element in mediating the cytoskeletal rearrangements required for cytokinesis.

Granular layer in the periplasmic space of gram-positive bacteria and fine structures of Enterococcus gallinarum and Streptococcus gordonii septa revealed by cryo-electron microscopy of vitreous sections.

High-resolution structural information on optimally preserved bacterial cells can be obtained with cryo-electron microscopy of vitreous sections. With the help of this technique, the existence of a periplasmic space between the plasma membrane and the thick peptidoglycan layer of the gram-positive bacteria Bacillus subtilis and Staphylococcus aureus was recently shown. This raises questions about the mode of polymerization of peptidoglycan. In the present study, we report the structure of the cell envelope of three gram-positive bacteria (B. subtilis, Streptococcus gordonii, and Enterococcus gallinarum). In the three cases, a previously undescribed granular layer adjacent to the plasma membrane is found in the periplasmic space. In order to better understand how nascent peptidoglycan is incorporated into the mature peptidoglycan, we investigated cellular regions known to represent the sites of cell wall production. Each of these sites possesses a specific structure. We propose a hypothetic model of peptidoglycan polymerization that accommodates these differences: peptidoglycan precursors could be exported from the cytoplasm to the periplasmic space, where they could diffuse until they would interact with the interface between the granular layer and the thick peptidoglycan layer. They could then polymerize with mature peptidoglycan. We report cytoplasmic structures at the E. gallinarum septum that could be interpreted as cytoskeletal elements driving cell division (FtsZ ring). Although immunoelectron microscopy and fluorescence microscopy studies have demonstrated the septal and cytoplasmic localization of FtsZ, direct visualization of in situ FtsZ filaments has not been obtained in any electron microscopy study of fixed and dehydrated bacteria.

Methods for the ex vivo characterization of human CD8+ T subsets based on gene expression and replicative history analysis.

The generation of an antigen-specific T-lymphocyte response is a complex multi-step process. Upon T-cell receptor-mediated recognition of antigen presented by activated dendritic cells, naive T-lymphocytes enter a program of proliferation and differentiation, during the course of which they acquire effector functions and may ultimately become memory T-cells. A major goal of modern immunology is to precisely identify and characterize effector and memory T-cell subpopulations that may be most efficient in disease protection. Sensitive methods are required to address these questions in exceedingly low numbers of antigen-specific lymphocytes recovered from clinical samples, and not manipulated in vitro. We have developed new techniques to dissect immune responses against viral or tumor antigens. These allow the isolation of various subsets of antigen-specific T-cells (with major histocompatibility complex [MHC]-peptide multimers and five-color FACS sorting) and the monitoring of gene expression in individual cells (by five-cell reverse transcription-polymerase chain reaction [RT-PCR]). We can also follow their proliferative life history by flow-fluorescence in situ hybridization (FISH) analysis of average telomere length. Recently, using these tools, we have identified subpopulations of CD8+ T-lymphocytes with distinct proliferative history and partial effector-like properties. Our data suggest that these subsets descend from recently activated T-cells and are committed to become differentiated effector T-lymphocytes.

Notch signaling in the integrated control of keratinocyte growth/differentiation and tumor suppression.

Oncogenesis is closely linked to abnormalities in cell differentiation. Notch signaling provides an important form of intercellular communication involved in cell fate determination, stem cell potential and differentiation. Here we review the role of this pathway in the integrated growth/differentiation control of the keratinocyte cell type, and the maintenance of normal skin homeostasis. In parallel with the pro-differentiation function of Notch1 in keratinocytes, we discuss recent evidence pointing to a tumor suppressor function of this gene in both mouse skin and human cervical carcinogenesis. The possibility that Notch signaling elicits signals with a duality of growth positive and negative function will be discussed.

High throughput 3D super-resolution microscopy reveals Caulobacter crescentus in vivo Z-ring organization.

We created a high-throughput modality of photoactivated localization microscopy (PALM) that enables automated 3D PALM imaging of hundreds of synchronized bacteria during all stages of the cell cycle. We used high-throughput PALM to investigate the nanoscale organization of the bacterial cell division protein FtsZ in live Caulobacter crescentus. We observed that FtsZ predominantly localizes as a patchy midcell band, and only rarely as a continuous ring, supporting a model of "Z-ring" organization whereby FtsZ protofilaments are randomly distributed within the band and interact only weakly. We found evidence for a previously unidentified period of rapid ring contraction in the final stages of the cell cycle. We also found that DNA damage resulted in production of high-density continuous Z-rings, which may obstruct cytokinesis. Our results provide a detailed quantitative picture of in vivo Z-ring organization.

In vivo expansion of T reg cells with IL-2-mAb complexes: induction of resistance to EAE and long-term acceptance of islet allografts without immunosuppression.

Via a transcription factor, Foxp3, immunoregulatory CD4(+)CD25(+) T cells (T reg cells) play an important role in suppressing the function of other T cells. Adoptively transferring high numbers of T reg cells can reduce the intensity of the immune response, thereby providing an attractive prospect for inducing tolerance. Extending our previous findings, we describe an in vivo approach for inducing rapid expansion of T reg cells by injecting mice with interleukin (IL)-2 mixed with a particular IL-2 monoclonal antibody (mAb). Injection of these IL-2-IL-2 mAb complexes for a short period of 3 d induces a marked (>10-fold) increase in T reg cell numbers in many organs, including the liver and gut as well as the spleen and lymph nodes, and a modest increase in the thymus. The expanded T reg cells survive for 1-2 wk and are highly activated and display superior suppressive function. Pretreating with the IL-2-IL-2 mAb complexes renders the mice resistant to induction of experimental autoimmune encephalomyelitis; combined with rapamycin, the complexes can also be used to treat ongoing disease. In addition, pretreating mice with the complexes induces tolerance to fully major histocompatibility complex-incompatible pancreatic islets in the absence of immunosuppression. Tolerance is robust and the majority of grafts are accepted indefinitely. The approach described for T reg cell expansion has clinical potential for treating autoimmune disease and promoting organ transplantation.

Controlling cytokinesis in the fission yeast Schizosaccharomyces pombe : the role of dma1; and ubc8

ABSTRACT The fission yeast Schizosaccharomyces pombe is a single celled eukaryote that has proved to be an excellent model system for the study of cell cycle control. S. pombe cells are rod shaped and grow mainly by elongation at their tips. They divide by formation of medially-placed cell wall, or septum, which cleaves the cell in two. Once the cell commits itself to mitosis the site of division is determined by formation of an acto-myosin based contractile ring at the cell cortex. The ring is assembled in stages throughout mitosis and contracts at the end of anaphase, coincident with spindle disassembly. The contraction, but not the assembly, of the ring requires the signal transduction network called the septation initiation network or SIN. The core components of the SIN are three protein kinases (cdc7p, sidl p and sid2p) and their regulatory subunits (spg1 p, cdcl4p and moblp, respectively). Signalling is dependent upon the nucleotide status of the GTPase spgl p, which is regulated by a two-component GAP protein, cdc16p-byr4p. Signalling is thought to emanate from the spindle pole body, where core SIN components are anchored to a scaffold comprised of sid4p and cdc11p. Activation of the SIN requires the protein kinase plolp, which also has additional roles in mitosis. SIN signalling is tightly regulated to assure the proper co-ordination of mitosis and cytokinesis. Ectopic activation of the SIN in interphase can uncouple septum formation from mitosis, while deregulated SIN signalling leads to formation of cells with multiple septa that do not cleave. Regulators of SIN activity are therefore of considerable interest. This study has concentrated upon two of these, dma1 and ubc8. I have demonstrated that dmal becomes essential when SIN signalling is activated. This leads me to propose a tripartite model for regulation of the SIN during the mitotic cell cycle. Increased expression of dma1 inhibits SIN signalling and prevents cell division. To identify potential targets and mediators of this, multicopy suppressors of dma1 toxicity were identified. One of these, ubc8, is the subject of this thesis. Genetic and molecular analyses are consistent with the view that ubc8p acts as an inhibitor of the SIN Localisation of ubc8p indicates that it is a nuclear protein. The ubc8 gene is not essential, but in its absence cells are unable to prevent septum formation if progression through mitosis is impaired. These data suggest that it may be an effector of the spindle assembly checkpoint. Together, these data shed new light upon the mechanisms by which cytokinesis is regulated in S. pombe. RESUME La levure Schizosaccharomyces pombe est un eucaryote unicellulaire qui est un bon système d'étude du cycle cellulaire. Les cellules de S. pombe sont en forme de bâtonnets et poussent par allongement aux deux bouts. Elles se divisent en formant une paroi au milieu de la cellule, qui s'appelle un septum et qui sépare la cellule en deux. Une fois que la cellule est engagée dans la mitose, le site de clivage est déterminé par la formation d'un anneau contractile d'acto-myosine au niveau du cortex cellulaire. Cet anneau est séquentiellement assemblé au cours de la mitose et se contacte à la fin de l'anaphase, au moment où le fuseau mitotique et désassemblé. La contraction, mais non pas l'assemblage, de l'anneau dépend d'un réseau de signalisation appelé septation initiation netvvork' ou SIN. Les composants centraux du SIN sont trois kinases (cdc7, sidi et sid2) ainsi que leurs sous-unités régulatrices (spgl, cdc14 et mob1, respectivement). La signalisation dépend du nucléotide rattaché à la GTPase spgl qui est régulée par une GAP comprenant deux sous-unités cdc16 et byr4. La signalisation est présumée provenir du pôle du fuseau où les composants centraux du SIN sont ancrés grâce à un échafaudage comprenant sid4 et cdcl 1. La signalisation est étroitement régulée pour assurer une bonne coordination entre mitose et cytokinèse. Une activation ectopique du SIN en interphase peut découpler la formation du septum de la mitose, engendrant des cellules à multiples septa qui ne sont pas clivés. C'est pourquoi les régulateurs du SIN sont d'un intérêt considérable. Cette étude se concentre autour de deux ces régulateurs, dma1 et ubc8. J'ai montré que dma1 devient essentiel quand la signalisation du SIN est activée. Ceci m'amène à proposer un modèle en trois parties pour la régulation du SIN durant la mitose. Une expression élevée de dma1 inhibe la signalisation du SIN et empêche la division cellulaire. Afin d'identifier des substrats ou médiateurs potentiels de la toxicité de dma1, des supresseurs en copies multiples ont été identifiés. Un de ces supresseurs, ubc8, constitue le deuxième sujet de cette thèse. Les études génétiques et moléculaires suggèrent un rôle inhibiteur du SIN par ubc8. Ubc8p est une protéine nucléaire, non essentielle, mais en son absence les cellules ne peuvent pas restreindre la fomation du septum, lorsque la progression de la mitose est perturbée. Les données suggèrent que ubc8 pourrait être un effecteur de point de contrôle de l'assemblage du fuseau mitotique. Prises dans leur ensemble, ces données apportent un nouvel éclairage sur les mécanismes de régulation de la cytokinèse dans S. pombe.

Analysis of Centrosome duplication in "Caenorhabditis elegans" : the role of "sas" genes

Abstract: The centrosome is the major microtubule organizing center (MTOC) of most animal cells. As such, it is essential for a number of processes, including polarized secretion or bipolar spindle assembly. Hence, centrosome number needs to be controlled precisely in coordination with DNA replication. Cells early in the cell cycle contain one centrosome that duplicates during S-phase to give rise to two centrosomes that organize a bipolar spindle during mitosis. A failure in this process is likely to engage the spindle assembly checkpoint and threaten genome stability. Despite its importance for normal and uncontrolled proliferation the mechanisms underlying centrosome duplication are still unclear. The Caenorhabditis elegans embryo is well suited to study the mechanisms of centrosome duplication. It allows for the analysis of cellular processes with high temporal and spatial resolution. Gene identification and inactivation techniques are very powerful and a wide set of mutant and transgenic strains facilitates analysis. My thesis project consisted of characterizing three sas-genes: sas-4, sas-5 and sas-¬6. Embryos lacking these genes fail to form a bipolar spindle, hence their name (spindle assembly). I established that sas-4(RNAi) and sas-6(RNAi) embryos do not form daughter centrioles and thus do not duplicate their centrosomes. Furthermore, I showed that both proteins localize to the cytoplasm and are strikingly enriched at centrioles throughout the cell cycle. By performing fluorescent recovery after photobleaching (FRAP) experiments and differentially labeling centrioles, I established that both proteins are recruited to centrioles once per cell cycle when daughter centrioles form. In contrast, SAS-5, PLK-1 and SPD-2 shuttle permanently between the cytoplasm and centrioles. By showing that SAS-5 and SAS-6 interact in vivo, I established a functional relationship between the proteins. Testing the putative human homologue of SAS-6 (HsSAS-6) and a distant relative of SAS-4 (CPAP), I was able to show that these proteins are required for centrosome duplication in human cells. In addition I found that overexpression of GFP¬HsSAS-6 leads to formation of extra centrosomes. In conclusion, we identified and gained important insights into proteins required for centrosome duplication in C. elegans and in human cells. Thus, our work contributes to further elucidate an important step of cell division in normal and malignant tissues. Eventually, this may allow for the development of novel diagnostic or therapeutic reagents to treat cancer patients. Résumé: Le centrosome est le principal centre organisateur des microtubules dans les cellules animales. De ce fait, il est essentiel pour un certain nombre de processus, comme l'adressage polarisé ou la mise en place d'un fuseau bipolaire. Le nombre de centrosome doit être contrôlé de façon précise et en coordination avec la réplication de l'ADN. Au début du cycle cellulaire, les cellules n'ont qu'un seul centrosome qui se duplique au cours de la phase S pour donner naissance à deux centrosomes qui forment le fuseau bipolaire pendant la mitose. Des défauts dans ce processus déclencheront probablement le "checkpoint" d'assemblage du fuseau et menaceront la stabilité du génome. Malgré leurs importances pour la prolifération normale ou incontrôlée des cellules, les mécanismes gouvernant la duplication des centrosomes restent obscures. L'embryon de Caenorhabditis elegans est bien adapté pour étudier les mécanismes de duplication des centrosomes. Il permet l'analyse des processus cellulaires avec une haute résolution spatiale et temporelle. L'identification des gènes et les techniques d'inactivation sont très puissantes et de larges collections de mutants et de lignées transgéniques facilitent les analyses. Mon projet de thèse a consisté à caractérisé trois gènes: sas-4, sas-5 et sas-6. Les embryons ne possédant pas ces gènes ne forment pas de fuseaux bipolaires, d'où leur nom (spindle assembly). J'ai établi que les embryons sas-4(RNAi) et sas-6(RNAi) ne forment pas de centrioles fils, et donc ne dupliquent pas leur centrosome. De plus, j'ai montré que les deux protéines sont localisées dans le cytoplasme et sont étonnamment enrichies aux centrioles tout le long du cycle cellulaire. En réalisant des expériences de FRAP (fluorscence recovery after photobleaching) et en marquant différentiellement les centrioles, j'ai établi que ces deux protéines sont recrutées une fois par cycle cellulaire aux centrioles, au moment de la duplication. Au contraire, SAS-5, PLK-1 et SPD-2 oscillent en permanence entre le cytoplasme et les centrioles. En montrant que SAS-5 et SAS-6 interagissent in vivo, j'ai établi une relation fonctionnelle entre les deux protéines. En testant les homologues humains putatifs de SAS-6 (HsSAS-6) et de SAS-4 (CPAP), j'ai été capable de montrer que ces protéines étaient aussi requises pour la duplication des centrosomes dans les cellules humaines. De plus, j'ai montré que la surexpression de GFP-HsSAS-6 entrainait la formation de centrosomes surnuméraires. En conclusion, nous avons identifié et progressé dans la compréhension de protéines requises pour la duplication des centrosomes chez C. elegans et dans les cellules humaines. Ainsi, notre travail contribue à mieux élucider une étape importante du la division cellulaire dans les cellules normales et malignes. A terme, ceci devrait aider au développement de nouveaux diagnostics ou de traitements thérapeuthiques pour soigner les malades du cancer.

Role of c-Myc in homeostasis of memory CD8 T cells

RESUME La mémoire immunologique est essentielle durant la vie et permet aux lymphocytes de répondre plus rapidement et efficacement lors d'une deuxième rencontre avec un antigène connu. Les facteurs contrôlant l'homéostasie des cellules T CD8 mémoires in vivo ne sont pas encore bien définis. Cependant, la prolifération homéostatique de ces cellules dans un hôte déplété en cellules hématopoietiques nécessite l'intéraction du TCR avec les molecules du MHC de class I du soi. De plus, le rôle de cytokines, telles que 1'IL-15 et l'IL-7, est essentiel dans ce mécanisme, aussi bien que dans la maintenance des cellules T CD8 mémoires. Puisque la protéine c-Myc - impliquée dans des mécanismes tells que la division, la prolifération, l'apoptose et la differentiation - a été définie comme étant impliquée dans la réponse à différentes cytokines, nous nous sommes intéressés à l'analyse de l'homéostasie des lymphocytes T CD8 mémoires dans des souris déficientes en c-Myc (c_rnycΔORF/+), qui expriment un niveau réduit de cette protéine. Bien que le développement des cellules T dans le thymus soit normal dans les souris c_rnycΔORF/+, nous avons observé une réduction de 2 à 3 fois dans la population des cellules T CD8 de phenotype mémoire (CD44+) dans les organes lymphoïdes de la périphérie de ces souris. Cette différence ne correspond pas à une réduction de prolifération ou d'expression de protéines de survie telles que Bel-2. Cependant, la prolifération homéostatique de cellules T CD8 c_rnycΔORF/+, mais pas T CD4 c_rnycΔORF/+, est reduite de manière dramatique lorsqu'elles sont transférées dans un hôte irradié. De plus, le transfert adoptif de lymphocytes T dans des souris irradiées déficientes en l'IL-15 nous a permis de montrer que la prolifération homéostatique dépendante de l'IL-15 des cellules T CD8 nécessite l'expression de c-Myc. De plus, contrairement aux cellules T CD8 CD44+ de type sauvage, nous avons observé que l'expansion induite par l'IL-15 des cellules T CD8 CD44+ c_rnycΔORF/+ est altérée aussi bien in vivo (en réponse à une injection de polyI:C) et in vitro. Par conséquent, nos résultats identifient c-Myc comme une nouvelle protéine régulatrice de la signalisation par l'IL-15 impliquée dans l'homéostasie des cellules T CD8 CD44+. SUMMARY Immunological memory is essential throughout life and allows memory lymphocytes to respond faster and more efficiently upon re-encounter of a known antigen. Factors controlling homeostasis of memory CD8 T cells under steady-state conditions in vivo are currently not well defined. However, the homeostatic proliferation of memory CD8 T cells in lymphopenic hosts requires the interaction of the TCR with self MHC class I molecules. In addition, cytokines, such as IL-15 and to a lesser extent IL-7, are essential for both homeostatic proliferation and maintenance of memory CD8 T cells. Since c-Myc, a proto-oncogene involved in cell division, proliferation, apoptosis and differentiation, has been widely implicated in responsiveness to cytokines, we were interested in analyzing homeostasis of memory CD8 T cells in c-myc hypomorph (c_rnycΔORF/+) mice, which express reduced levels of c-Myc. Although T cell development in the thymus was normal in c_rnycΔORF/+ mice, we found a selective 2- to 3-fold reduction in the memory-phenotype CD44high CD8 T cell population in the periphery. Reduced numbers of CD44high CD8 T cells did not correlate with decreased steady-state turnover rate or low expression of survival factors such as Bcl- 2. However, homeostatic proliferation of c_rnycΔORF/+ CD8 T cells, but not c_rnycΔORF/+ CD4 T cells, was dramatically reduced upon transfer into sublethally irradiated wild-type recipients. In addition, upon transfer of c_rnycΔORF/+ and c-myc WT cells into IL-15-/- mice, we observed that IL-15-induced homeostatic proliferation of CD8 T cells requires c-Myc. Moreover, in contrast to c-myc WT CD44high CD8 T cells, IL-15-induced expansion of c_rnycΔORF/+ CD44high CD8 T cells was strongly impaired both in vivo (in response to polyI:C injection) and in vitro. Collectively, our data identify c-Myc as a novel downstream regulator of IL-15 signaling involved in homeostasis of memory CD8 T cells.

Peroxisome proliferator-activated receptor-beta signaling contributes to enhanced proliferation of hepatic stellate cells.

BACKGROUND & AIMS: The peroxisome proliferator-activated nuclear receptors (PPAR-alpha, PPAR-beta, and PPAR-gamma), which modulate the expression of genes involved in energy homeostasis, cell cycle, and immune function, may play a role in hepatic stellate cell activation. Previous studies focused on the decreased expression of PPAR-gamma in hepatic stellate cell activation but did not investigate the expression and role of the PPAR-alpha and -beta isotypes. The aim of this study was to evaluate the expression of the different PPARs during hepatic stellate cell activation in vitro and in situ and to analyze possible factors that might contribute to their expression. In a second part of the study, the effect of a PPAR-beta agonist on acute liver injury was evaluated. METHODS: The effects of PPAR isotype-specific ligands on hepatic stellate cell transition were evaluated by bromodeoxyuridine incorporation, gel shifts, immunoprecipitation, and use of antisense PPAR-beta RNA-expressing adenoviruses. Tumor necrosis factor alpha-induced PPAR-beta phosphorylation and expression was evaluated by metabolic labeling and by using specific P38 inhibitors. RESULTS: Hepatic stellate cells constitutively express high levels of PPAR-beta, which become further induced during culture activation and in vivo fibrogenesis. No significant expression of PPAR-alpha or -gamma was found. Stimulation of the P38 mitogen-activated protein kinase pathway modulated the expression of PPAR-beta. Transcriptional activation of PPAR-beta by L165041 enhanced hepatic stellate cell proliferation. Treatment of rats with a single bolus of CCl(4) in combination with L165041 further enhanced the expression of fibrotic markers. CONCLUSIONS: PPAR-beta is an important signal-transducing factor contributing to hepatic stellate cell proliferation during acute and chronic liver inflammation.

A dynamic view of hepatitis C virus replication complexes.

Hepatitis C virus (HCV) replicates its genome in a membrane-associated replication complex (RC). Specific membrane alterations, designated membranous webs, represent predominant sites of HCV RNA replication. The principles governing HCV RC and membranous web formation are poorly understood. Here, we used replicons harboring a green fluorescent protein (GFP) insertion in nonstructural protein 5A (NS5A) to study HCV RCs in live cells. Two distinct patterns of NS5A-GFP were observed. (i) Large structures, representing membranous webs, showed restricted motility, were stable over many hours, were partitioned among daughter cells during cell division, and displayed a static internal architecture without detectable exchange of NS5A-GFP. (ii) In contrast, small structures, presumably representing small RCs, showed fast, saltatory movements over long distances. Both populations were associated with endoplasmic reticulum (ER) tubules, but only small RCs showed ER-independent, microtubule (MT)-dependent transport. We suggest that this MT-dependent transport sustains two distinct RC populations, which are both required during the HCV life cycle.

A new factor stimulating peptidoglycan hydrolysis to separate daughter cells in Caulobacter crescentus.

Cell division in Gram-negative bacteria involves the co-ordinated invagination of the three cell envelope layers to form two new daughter cell poles. This complex process starts with the polymerization of the tubulin-like protein FtsZ into a Z-ring at mid-cell, which drives cytokinesis and recruits numerous other proteins to the division site. These proteins are involved in Z-ring constriction, inner- and outer-membrane invagination, peptidoglycan remodelling and daughter cell separation. Three papers in this issue of Molecular Microbiology, from the teams of Lucy Shapiro, Martin Thanbichler and Christine Jacobs-Wagner, describe a novel protein, called DipM for Division Involved Protein with LysM domains, that is required for cell division in Caulobacter crescentus. DipM localizes to the mid-cell during cell division, where it is necessary for the hydrolysis of the septal peptidoglycan to remodel the cell wall. Loss of DipM results in severe defects in cell envelope constriction, which is deleterious under fast-growth conditions. State-of-the-art microscopy experiments reveal that the peptidoglycan is thicker and that the cell wall is incorrectly organized in DipM-depleted cells compared with wild-type cells, demonstrating that DipM is essential for reorganizing the cell wall at the division site, for envelope invagination and cell separation in Caulobacter.

Oscillation modes of microtubules.

Microtubules are long, filamentous protein complexes which play a central role in several cellular physiological processes, such as cell division transport and locomotion. Their mechanical properties are extremely important since they determine the biological function. In a recently published experiment [Phys. Rev. Lett. 89 (2002) 248101], microtubule's Young's and shear moduli were simultaneously measured, proving that they are highly anisotropic. Together with the known structure, this finding opens the way to better understand and predict their mechanical behavior under a particular set of conditions. In the present study, we modeled microtubules by using the finite elements method and analyzed their oscillation modes. The analysis revealed that oscillation modes involving a change in the diameter of the microtubules strongly depend on the shear modulus. In these modes, the correlation times of the movements are just slightly shorter than diffusion times of free molecules surrounding the microtubule. It could be therefore speculated that the matching of the two timescales could play a role in facilitating the interactions between microtubules and MT associated proteins, and between microtubules and tubulins themselves.