Disruption of MEF2 activity in cardiomyoblasts inhibits cardiomyogenesis

Myocyte enhancer factors (MEF2s) bind to muscle-specific promoters and activate transcription. Drosophila Mef2 is essential for Drosophila heart development, however, neither MEF2C nor MEF2B are essential for the early stages of murine cardiomyogenesis. Although Mef2c-null mice were defective in the later stages of heart morphogenesis, differentiation of cardiomyocytes still occurred. Since there are four isoforms of MEF2 factors (MEF2A, MEF2B, MEF2C and MEF2D), the ability of cells to differentiate may have been confounded by genetic redundancy. To eliminate this variable, the effect of a dominant-negative MEF2 mutant (MEF2C/EnR) during cardiomyogenesis was examined in transgenic mice and P19 cells. Targeting the expression of MEF2C/EnR to cardiomyoblasts using an Nkx2-5 enhancer in the P19 system resulted in the loss of both cardiomyocyte development and the expression of GATA4, BMP4, Nkx2-5 and MEF2C. In transiently transgenic mice, MEF2C/EnR expression resulted in embryos that lacked heart structures and exhibited defective differentiation. Our results show that MEF2C, or genes containing MEF2 DNA-binding sites, is required for the efficient differentiation of cardiomyoblasts into cardiomyocytes, suggesting conservation in the role of MEF2 from Drosophila to mammals.

Cell adhesion and prostate tumor-suppressor activity of TSLL2/IGSF4C, an immunoglobulin superfamily molecule homologous to TSLC1/IGSF4

The TSLL2/IGSF4C encodes an immunoglobulin (Ig) superfamily molecule showing significant homology with a lung tumor suppressor, TSLC1. The TSLL2 protein of 55 kDa is mainly expressed in the kidney, bladder, and prostate in addition to the brain. Here, we report the biological significance of TSLL2 in the urinary tissues. An immunohistochemical study reveals that TSLL2 is expressed at the cell-cell attachment sites in the renal tubules, the transitional epithelia of the bladder, and the glandular epithelia of the prostate. Confocal microscopy analysis demonstrates that TSLL2 is localized in the lateral membranes in polarized Mardin-Darby canine kidney (MDCK) cells. TSLL2 forms homo-dimers and its overexpression induces aggregation of suspended MDCK cells in a Ca2+/Mg2+-independent manner, suggesting that it is involved in cell adhesion through homophilic trans-interaction. The TSLL2 gene is mapped on the chromosomal region 19q13.2, whose loss of heterozygosity has been frequently reported in prostate cancer. TSLL2 protein is lost in nine of nine primary prostate cancers and in a prostate cancer cell, PPC-1. Introduction of TSLL2 into PPC-1 strongly suppresses subcutaneous tumor formation in nude mice. These results suggest that TSLL2 is a new member of the Ig superfamily cell adhesion molecules and is a tumor-suppressor candidate in prostate cancer.

A secondary disruption of the dmpA gene encoding a large membrane protein allows aggregation defective Dictyostelium rasC- cells to form multicellular structures

The disruption of the gene encoding the Dictyostelium Ras subfamily protein, RasC, results in a strain that does not aggregate and has defects in both cAMP signal relay and cAMP chemotaxis. Disruption of a second gene in the rasC(-) strain by Restriction Enzyme Mediated Integration produced cells that were capable of forming multicellular structures in plaques on bacterial lawns. The disrupted gene (dmpA) encoded a novel membrane protein that was designated Dmp1. Although the rasC(-)/dmpA(-) cells progressed through early development, they did not form aggregation streams on a plastic surface under submerged starvation conditions. Phosphorylation of PKB in response to cAMP, which is significantly reduced in rasC(-) cells, remained low in the rasC(-)/dmpA(-) cells. However, in spite of this low PKB phosphorylation, the rasC(-)/dmpA(-) cells underwent efficient chemotaxis to cAMP in a spatial gradient. Cyclic AMP accumulation, which was greatly reduced in the rasC(-) cells, was restored in the rasC(-)/dmpA(-) strain, but cAMP relay in these cells was not apparent. These data indicate that although the rasC(-)/dmpA(-) cells were capable of associating to form multicellular structures, normal aggregative cell signaling was clearly not restored. Disruption of the dmpA gene in a wild-type background resulted in cells that exhibited a slight defect in aggregation and a more substantial defect in late development. These results indicate that, in addition to the role played by Dmp1 in aggregation, it is also involved in late development.

In vitro self-assembly of proepicardial cell aggregates: An embryonic vasculogenic model for vascular tissue engineering

Proepicardial/epicardial-derived cells are the main origin of the early embryonic coronary vascular bed. In vivo coronary vasculogenesis, which is a fast-occurring event, can be mimicked in vitro by culturing proepicardial tissue in different ways. The in vitro vasculogenic model presented in this study (a proepicardial suspension culture assay) partially reproduces coronary vascular development from its cellular precursors, a process known to be highly dependent on cell migration, cell differentiation, cell adhesion/sorting, and tissue fusion phenomena. The main aim of this study is to study the triggering signals and the cellular dynamics that regulate the differentiation of proepicardial cells into the angioblastic/endothelial lineage and their in vitro vasculogenic potential. Our results indicate that hanging drop-cultured proepicardia, which have an intrinsic vascular potential, behave like self-assembling cell aggregates or spheroids that can fuse to give rise to complex vascularized 3D structures. We believe that these self-assembling cell aggregates are an optimal choice to study the differentiation of coronary angioblasts, as well as a good method to reproduce vascular development in vitro. Finally, we propose the proepicardium as a suitable cellular source for vascular tissue engineering.

The alpha-synuclein mutation E46K promotes aggregation in cultured cells

Parkinson's disease (PD) is characterized by the polymerization of wild-type (WT) or mutant alpha-synuclein (AS) into aggregates and fibrils, which are observed as Lewy bodies (LBs) and Lewy neurites (LNs) in PD patients. However, inability to demonstrate aggregation in many cell culture systems is a major drawback for effective in vitro modeling of AS aggregation. Utilizing PCR-based cloning approach, we generated A30P, A53T, and the recently reported E46K encoding mutation in the KTKEGV repeat region of AS gene. While cloning E46K mutant, a glycine deletion mutation (E46KDeltaG) adjacent to the intended lysine mutation was serendipitously generated. Expression of mutant constructs and green fluorescent protein (GFP)-tagged mutant constructs in catecholaminergic SH-SY5Y (5Y) cells revealed 40% of AS-E46KDeltaG and 18% of AS-E46K transfected cells formed aggregates as compared to 12% in AS-A53T, 6% in AS-WT, and 2% in AS-A30P transfected cells. Western blot analysis demonstrated the formation of high molecular weight AS aggregates. Electron microscopic analysis of 5Y cells expressing the E46K and E46KDeltaG mutants demonstrated two distinct kinds of inclusions: Type I, which showed dense granular profile; and Type II, which were largely membranous vacuolar inclusions without granular material. These two inclusions are reminiscent of Lewy bodies and pale bodies observed in PD postmortem brain samples. Our results demonstrate that mutations in 4th KTKEGV repeat lead to higher propensity of aggregation of AS compared to other mutants.

Control of recent thymic emigrant survival by positive selection signals and early growth response gene 1

Early growth response gene 1 (Egr1) is a transcriptional regulator whose expression can be induced by multiple signals including the TCR. Egr1 has been shown to promote positive selection, but an investigation of its role in T cell homeostasis has not been reported. The possibility that similar signals control both positive selection and peripheral T cell homeostasis led us to investigate the role of Egr1 in the maintenance of peripheral T cells. We have found that on TCR transgenic backgrounds, Egr1-deficient mice have a reduction in their number of naive T cells. Although Egr1-deficient animals have a low percentage of mature thymocytes due to inefficient positive selection, the absolute number of mature thymocytes is only slightly reduced due to increased thymus size in Egr1-deficient mice. Despite possessing near normal numbers of mature thymocytes, we find that Egr1-deficient mice have poor accumulation of recent thymic emigrants (RTE) in the periphery. The poor accumulation of RTE in Egr1-deficient mice appears to originate from decreased survival of mature thymocytes and RTE, which we have observed both in vitro and in vivo. These findings suggest that an Egr1-mediated signal during positive selection promotes not only the production of single positive thymocytes, but also the survival of selected thymocytes until they can become established in the periphery.

Peptide-stimulated DO11.10 T cells divide well but accumulate poorly in the absence of TLR agonist treatment

Immunological adjuvants increase the clonal burst size of antigen-specific T cell populations by mechanisms that remain incompletely understood. Using the DO11.10 adoptive transfer system to study peptide-stimulated T cell responses, we found that TLR agonist treatment increased the extent of cellular division undergone by responding T cells, but not by enough to explain the net increases in T cell yield that were achieved. Two novel analyses involving CFSE dye dilution analysis were used to characterize the shortfall, both of which were consistent with the idea that DO11.10 T cells are frequently lost during proliferation unless TLR agonists are present. T cell loss during clonal expansion was correlated with decreased levels of Bcl-2, but TLR agonists did not appear to afford protection by restoring levels of Bcl-2 or of cell surface IL-7Ralpha chain expression. TLR-mediated protection also failed to correlate with increased expression of Bcl-x or decreased expression of pro-apoptotic Bim. Our findings suggest that DO11.10 T cells stimulated by antigenic peptide in vivo divide well, but fail to accumulate efficiently unless TLR agonists are present.

Differential contributions of connexin37 and connexin43 to oogenesis revealed in chimeric reaggregated mouse ovaries

The gap junction proteins connexin37 and connexin43 are required for ovarian folliculogenesis in the mouse. To define their respective roles in oogenesis, chimeric ovaries containing either null mutant oocytes and wild-type granulosa cells or the reverse combination were grafted to the renal capsules of immunodeficient female mice. After three weeks, the oocytes were tested for meiotic competence and fertilizability in vitro. Ovaries composed of connexin43-deficient oocytes and wild-type granulosa cells produced antral follicles enclosing oocytes that could develop to at least the two-cell stage, demonstrating that oocytes need not express connexin43 to reach maturity. Conversely, both follicle development and oocyte maturation were impaired in ovaries containing either wild-type oocytes and connexin43-deficient granulosa cells or connexin37-deficient oocytes and wild-type granulosa cells. Thus absence of connexin43 from granulosa cells or connexin37 from oocytes is sufficient to compromise both oocyte and follicle development. Wild-type oocytes paired with connexin37-deficient granulosa cells generated antral follicles containing oocytes that developed to at least the two-cell stage. Therefore, connexin37 absence from granulosa cells need not impair fertility in mice. Dye transfer experiments revealed persistent oocyte-granulosa cell coupling in those follicles, indicating functional compensation by another connexin. The results indicate that mouse oocytes do not need to express connexin43 in order to develop into meiotically competent, fertilizable gametes, but must express connexin37 for communication with granulosa cells, a requirement for oogenesis.

Chaperonin GroEL and its mutant D87K protect from ischemia in vivo and in vitro

Protein aggregation and misfolding are central mechanisms of both acute and chronic neurodegeneration. Overexpression of chaperone Hsp70 protects from stroke in animal and cell culture models. Although it is accepted that chaperones protect cells, the mechanism of protection by chaperones in ischemic injury is poorly understood. In particular, the relative importance of preventing protein aggregation compared to facilitating correct protein folding during ischemia and recovery is not known. To test the importance of protein folding and minimize interaction with co-chaperones we studied the bacterial chaperonin GroEL (HSPD1) and a folding-deficient mutant D87K. Both molecules protected cells from ischemia-like injury, and reduced infarct volume and improved neurological outcome after middle cerebral artery occlusion in rats. Protection was associated with reduced protein aggregation, assessed by ubiquitin immunohistochemistry. Marked neuroprotection by the folding-deficient chaperonin demonstrates that inhibition of aggregation is sufficient to protect the brain from ischemia. This suggests that strategies to maintain protein solubility and inhibit aggregation in the face of acute insults such as stroke may be a useful protective strategy.

The effect of the disruption of a gene encoding a PI4 kinase on the developmental defect exhibited by Dictyostelium rasC(-) cells

The disruption of the gene encoding the Dictyostelium Ras subfamily protein, RasC results in a strain that fails to aggregate with defects in both cAMP signal relay and chemotaxis. Restriction enzyme mediated integration disruption of a second gene in the rasC(-) strain resulted in cells that were capable of forming multicellular structures in plaques on bacterial lawns. The disrupted gene, designated pikD(1), encodes a member of the phosphatidyl-inositol-4-kinase beta subfamily. Although the rasC(-)/pikD(1) cells were capable of progressing through early development, when starved on a plastic surface under submerged conditions, they did not form aggregation streams or exhibit pulsatile motion. The rasC(-)/pikD(1) cells were extremely efficient in their ability to chemotax to cAMP in a spatial gradient, although the reduced phosphorylation of PKB in response to cAMP observed in rasC(-) cells, was unchanged. In addition, the activation of adenylyl cyclase, which was greatly reduced in the rasC(-) cells, was only minimally increased in the rasC(-)/pikD(1) strain. Thus, although the rasC(-)/pikD(-) cells were capable of associating to form multicellular structures, normal cell signaling was clearly not restored. The disruption of the pikD gene in a wild type background resulted in a strain that was delayed in aggregation and formed large aggregation streams, when starved on a plastic surface under submerged conditions. This strain also exhibited a slight defect in terminal development. In conclusion, disruption of the pikD gene in a rasC(-) strain resulted in cells that were capable of forming multicellular structures, but which did so in the absence of normal signaling and aggregation stream formation.

A flow cytometry-based assay for the measurement of protein regulation of E-cadherin-mediated adhesion

Epithelial (E)-cadherin is a transmembrane protein that mediates calcium-dependent cell adhesion. E-cadherin has significant roles in tissue development, adhesion between keratinocytes and retention of Langerhans cells in the epidermis, and its loss on tumour cells is frequently associated with metastasis. Here we describe a simple, flow cytometric adhesion assay to measure the effects of potential regulators of cell surface E-cadherin expression on E-cadherin-mediated adhesion between cells. In this assay, cells that have been transiently transfected to express the protein of interest are enzymatically treated to remove cell surface E-cadherin. Cells are then incubated in low attachment plates, during which time the E-cadherin is re-expressed and E-cadherin-mediated aggregation occurs. The effect of the protein of interest on the percentage of E-cadherin-mediated aggregates that form during incubation is measured flow cytometrically, following staining with an E-cadherin specific antibody. A major advantage of this assay is that a potential regulatory protein of interest can be tested in a transient expression system by co-expression with green fluorescent protein and analysis of adhesion conducted on green fluorescent cells only. We have applied this assay to measure the regulatory effects of E6 protein from human papillomavirus type 16 on E-cadherin-mediated adhesion but this assay potentially has broad applicability for testing the effects of other proteins on E-cadherin-mediated adhesion in an accurate and highly reproducible manner.

Critical role of the fifth domain of E-cadherin for heterophilic adhesion with alpha E beta 7, but not for homophilic adhesion

The integrin alpha(E)beta(7) is expressed on intestinal intraepithelial T lymphocytes and CD8(+) T lymphocytes in inflammatory lesions near epithelial cells. Adhesion between alpha(E)beta(7)(+) T and epithelial cells is mediated by the adhesive interaction of alpha(E)beta(7) and E-cadherin; this interaction plays a key role in the damage of target epithelia. To explore the structure-function relationship of the heterophilic adhesive interaction between E-cadherin and alpha(E)beta(7), we performed cell aggregation assays using L cells transfected with an extracellular domain-deletion mutant of E-cadherin. In homophilic adhesion assays, L cells transfected with wild-type or a domain 5-deficient mutant formed aggregates, whereas transfectants with domain 1-, 2-, 3-, or 4-deficient mutants did not. These results indicate that not only domain 1, but domains 2, 3, and 4 are involved in homophilic adhesion. When alpha(E)beta(7)(+) K562 cells were incubated with L cells expressing the wild type, 23% of the resulting cell aggregates consisted of alpha(E)beta(7)(+) K562 cells. In contrast, the binding of alpha(E)beta(7)(+) K562 cells to L cells expressing a domain 5-deficient mutant was significantly decreased, with alpha(E)beta(7)(+) K562 cells accounting for only 4% of the cell aggregates, while homophilic adhesion was completely preserved. These results suggest that domain 5 is involved in heterophilic adhesion with alpha(E)beta(7), but not in homophilic adhesion, leading to the hypothesis that the fifth domain of E-cadherin may play a critical role in the regulation of heterophilic adhesion to alpha(E)beta(7) and may be a potential target for treatments altering the adhesion of alpha(E)beta(7)(+) T cells to epithelial cells in inflammatory epithelial diseases.

Association of B-1 B cells with follicular dendritic cells in spleen

Although CD5(+) B-1 B cells have been recognized as an infrequent B cell subset in mice for many years, attempts to identify their histologic location in normal mouse spleen have proven difficult due to both their paucity and low level expression of CD5. In this study we have studied V(H)11/D(H)/J(H) gene-targeted mice, V(H)11t, that develop elevated numbers of CD5(+) V(H)11/V(k)9 B cells with an anti-phosphatidylcholine (anti-PtC) autoreactive specificity, allowing B-1 B cell detection by anti-PtC Id-specific Abs in spleen section staining. Using this approach we found that anti-PtC B-1 cells first appear within the white pulp in neonates, expand in association with follicular dendritic cells (FDC), and localize more centrally than other (non-B-1) IgD(high) follicular B cells in adults. Among neonatal B cells, CD5(+) B-1 cells in both normal and V(H)11t mouse spleen and peritoneal cavity express the highest levels of CXCR5, which is important for FDC development. Injection of purified spleen or peritoneal B-1 cells into RAG knockout mice resulted in B-1 cell follicle formation in spleen, inducing FDC development and plasma cell generation. These results indicate that B-1 B cells are the first B cells to express fully mature levels of CXCR5, thereby promoting the development of FDC.

Cutting Edge: Critical Role of CXCL16/CXCR6 in NKT Cell Trafficking in Allograft Tolerance

It is well-documented that certain chemokines or their receptors play important roles in the graft rejection. However, the roles of chemokines and their receptors in the maintenance of transplantation tolerance remain unclear. In this study, we demonstrate that blocking of the interaction between the chemokine receptor, CXCR6, highly expressed on V alpha14+ NKT cells and its ligand, CXCL16, resulted in the failure to maintain graft tolerance and thus in the induction of acceleration of graft rejection. In a mouse transplant tolerance model, the expression of CXCL16 was up-regulated in the tolerated allografts, and anti-CXCL16 mAb inhibited intragraft accumulation of NKT cells. In vitro experiments further showed that blocking of CXCL16/CXCR6 interaction significantly affected not only chemotaxis but also cell adhesion of NKT cells. These results demonstrate the unique role of CXCL16 and CXCR6 molecules in the maintenance of cardiac allograft tolerance mediated by NKT cells.

Opposing Effects of CXCR3 and CCR5 Deficiency on CD8+ T Cell-Mediated Inflammation in the Central Nervous System of Virus-Infected Mice

T cells play a key role in the control of viral infection in the CNS but may also contribute to immune-mediated cell damage. To study the redundancy of the chemokine receptors CXCR3 and CCR5 in regulating virus-induced CD8+ T cell-mediated inflammation in the brain, CXCR3/CCR5 double-deficient mice were generated and infected intracerebrally with noncytolytic lymphocytic choriomeningitis virus. Because these chemokine receptors are mostly expressed by overlapping subsets of activated CD8+ T cells, it was expected that absence of both receptors would synergistically impair effector T cell invasion and therefore protect mice against the otherwise fatal CD8+ T cell-mediated immune attack. Contrary to expectations, the accumulation of mononuclear cells in cerebrospinal fluid was only slightly delayed compared with mice with normal expression of both receptors. Even more surprising, CXCR3/CCR5 double-deficient mice were more susceptible to intracerebral infection than CXCR3-deficient mice. Analysis of effector T cell generation revealed an accelerated antiviral CD8+ T cell response in CXCR3/CCR5 double-deficient mice. Furthermore, while the accumulation of CD8+ T cells in the neural parenchyma was significantly delayed in both CXCR3- and CXCR3/CCR5-deficient mice, more CD8+ T cells were found in the parenchyma of double-deficient mice when these were analyzed around the time when the difference in clinical outcome becomes manifest. Taken together, these results indicate that while CXCR3 plays an important role in controlling CNS inflammation, other receptors but not CCR5 also contribute significantly. Additionally, our results suggest that CCR5 primarily functions as a negative regulator of the antiviral CD8+ T cell response.

Lymphotoxin-beta receptor-dependent genes in lymph node and follicular dendritic cell transcriptomes

Affinity maturation and Ab class switches occur in lymphoid germinal centers (GCs), in which differentiation and maintenance depend on lymphotoxin (LT) signaling and include differentiation of follicular dendritic cells (FDCs). The events leading to FDC and GC maturation are poorly defined. Using several approaches of functional genomics, we enumerated transcripts affected in mice by suppressing LT beta receptor (LTbetaR) signaling and/or overrepresented in FDC-enriched GC isolates. Protein expression analysis of 3 of 12 genes both enriched in FDCs and down-regulated by LTbetaR signaling suppression validated them as FDC markers. Functional analysis of one of these three, clusterin, suggests a role as an FDC-derived trophic factor for GC B cells. Hence, the set of genes presented in this study includes markers emanating from LTbetaR signaling and transcripts relevant to GC and FDC function.

A hemocyte-specific integrin required for hemocytic encapsulation in the tobacco hornworm, Manduca sexta

Upon encountering an object recognized as foreign, insect hemocytes aggregate in multiple layers on the surfaces of the object in a process known as encapsulation. For encapsulation to occur, hemocytes must switch from their usual nonadherent state to an adherent state, presumably by regulating the activity of adhesion proteins. Although detailed knowledge exists regarding the adhesion receptors for cells of the mammalian immune system, comparable information on adhesion molecules of insect hemocytes and their function in immune responses is extremely limited. We report here the identification of an integrin present exclusively on the surface of hemocytes in the tobacco hornworm, Manduca sexta. Monoclonal antibodies MS13 and MS34, which bind to plasmatocytes and block encapsulation, were used for immunoaffinity chromatography to isolate their corresponding hemocyte antigen, which was revealed to be the same integrin beta subunit. A cDNA for this M. sexta integrin beta1 was cloned and characterized. Integrin-beta1 mRNA was detected by Northern analysis in hemocytes and not in other tissues tested. MS13 and MS34 were demonstrated to bind to a recombinant fragment of integrin beta1 consisting of the I-like domain, consistent with their blocking of a ligand-binding site and subsequent disruption of plasmatocyte adhesion. Injection of double stranded integrin-beta1 RNA into larvae resulted in decreased integrin beta1 expression in plasmatocytes and significantly suppressed encapsulation. These results indicate that activation of ligand-binding by the hemocyte-specific integrin plays a key role in stimulating plasmatocyte adhesion leading to encapsulation.

Assembly of filamentous tau aggregates in human neuronal cells

Intraneuronal deposition of microtubule-associated protein tau in filamentous aggregates constitutes a pathological hallmark of neurofibrillary degeneration that is characteristic of Alzheimer's disease (AD) and related disorders known collectively as tauopathies. Formation of such fibril inclusions, consisting of hyperphosphorylated tau in multiple isoforms, correlates with the severity of cognitive decline in AD. How neurofibrillary pathology evolves in tauopathy remains unclear at present, but availability of a cellular model with robust tau aggregation will permit experimental scrutiny of the mechanistic process leading to such neurodegeneration. Through the use of a serial transfection strategy in conjunction with a tau minigene construct, we succeeded in generating conditional transfectants of human neuronal lineage that overproduce wild-type human brain tau in isoforms 4R0N, 3R1N and 4R1N via TetOff and ecdysone inducible expression mechanisms. Such transgenic overexpression of tau in multiple isoforms facilitated the assembly of filamentous tau aggregates that exhibit immunoreactivities, physicochemical properties, and ultrastructural attributes reminiscent of those found in human tauopathies. The conditional tau transfectants thus provide us with a useful tool to elucidate the molecular and cellular events leading to neurofibrillary degeneration and a convenient means to test hypothetical mechanisms implicated in the etiopathogenesis of AD and related tauopathies.

Distinct roles of ligand affinity and cytoskeletal anchorage in alphaIIbbeta3 (GP IIb/IIIa)-mediated cell aggregation and adhesion

Platelet integrin alphaIIbbeta3 (GP IIb/IIla) is functionally modulated by changes in ligand affinity or in cytoskeletal anchorage. CHO cells transfected with wild-type/mutated alphaIIbbeta3 allow the dissection of the relative contributions of the two regulatory mechanisms in alphaIIbbeta3-mediated adhesion and aggregation. Mutations included a truncation of the cytoplasmic domain of the beta-subunit, resulting in a loss of cytoskeletal anchorage of alphaIIbbeta3, and a VGFFK-deletion of the alpha-subunit, resulting in a permanent high affinity state. alphaIIbbeta3-mediated cell aggregation is dependent on the high affinity state but only partially on the cytoskeletal anchorage of alphaIIbbeta3. In contrast, alphaIIbbeta3-mediated cell adhesion is dependent on the cytoskeletal anchorage but only partially on the high affinity state of alphaIIbbeta3. Thus, the functional evaluation of mutated alphaIIbbeta3 implies a differential role of affinity state and cytoskeletal anchorage for alphaIIbbeta3-mediated cell adhesion and aggregation.

Maintenance of neuronal positions in organized ganglia by SAX-7, a Caenorhabditis elegans homologue of L1

The L1 family of cell adhesion molecules is predominantly expressed in the nervous system. Mutations in human L1 cause neuronal diseases such as HSAS, MASA, and SPG1. Here we show that sax-7 gene encodes an L1 homologue in Caenorhabditis elegans. In sax-7 mutants, the organization of ganglia and positioning of neurons are abnormal in the adult stage, but these abnormalities are not observed in early larval stage. Misplacement of neurons in sax-7 mutants is triggered by mechanical force linked to body movement. Short and long forms of SAX-7 exhibited strong and weak homophilic adhesion activities in in vitro aggregation assay, respectively, which correlated with their different activities in vivo. SAX-7 was localized on plasma membranes of neurons in vivo. Expression of SAX-7 only in a single neuron in sax-7 mutants cell-autonomously restored its normal neuronal position. Expression of SAX-7 in two different head neurons in sax-7 mutants led to the forced attachment of these neurons. We propose that both homophilic and heterophilic interactions of SAX-7 are essential for maintenance of neuronal positions in organized ganglia.

Differential control of CD28-regulated in vivo immunity by the E3 ligase Cbl-b

The E3 ubiquitin ligase Casitas B cell lymphoma-b (Cbl-b) plays a critical role in the development of autoimmunity and sets the threshold for T cell activation. In the absence of Cbl-b, T cells stimulated via the TCR respond similarly to those that have received a CD28-mediated costimulatory signal, suggesting that the absence of Cbl-b substitutes for CD28-mediated costimulation. In this study, we show that loss of Cbl-b restores Ig class switching and germinal center formation in Vav1 mutant mice in response to an in vivo viral challenge. Genetic inactivation of Cbl-b also rescues impaired antiviral IgG production in CD28-mutant mice. Moreover, loss of CD28 results in disorganization of follicular dendritic cell clusters, which is also rescued by the Cbl-b mutation. Intriguingly, despite restored antiviral in vivo immunity and follicular dendritic cell clusters, loss of Cbl-b did not rescue germinal center formation in CD28-deficient mice. Mechanistically, in vivo vesicular stomatitis virus-induced IL-4 and IFN-gamma production and up-regulation of the inducible costimulatory molecule ICOS were dependent on CD28, and could not be rescued by the loss of Cbl-b. These data provide genetic evidence that CD28-dependent in vivo immune responses and Ig class switching can be genetically uncoupled from germinal center formation and ICOS induction by Cbl-b-Vav1-regulated signaling pathways.

[Flow cytometric analysis of Enterococcus faecalis aph2"(+) response to aph2" (-) strains with high and low gene transfer rate]

Resistance genes, as aph2" are usually encoded on conjugate plasmids and spread with high rate 2 among Gram-positive cocci. The conjugation is inducted by recipient strains by secreting specific pheromone involved in formation of mating aggregates with donor cells. The project aimed to check if strain with lower rate of gene transfer differ also from strains with high gene transfer in ability to aggregate to donor strains. In our study we used two aph2"(+), three aph2"(-) with low transfer e and three aph2"(-) with high transfer strains. Each time one aph2"(+) and one aph2" strains were cultivated for 18h in BHI. The bacteria was washed, stained with carboksyfluorescein, and analyzed by flow cytometry in FACS BD cytometr. Relative fluorescence and size of aggregation was used to compare influence on particular stains. In result of induction of aph2"(+) strains with aph2" recipients with high transfer rate we observed increase of size and number aggregates. Surprisingly, induction with aph2" recipients with low transfer rate result in two different reaction of aph2"(+) donors. In case of one of the , according to expectation we do not observe increase of aggregation. Second of the donors aggregate with induction with aph2" recipients with low transfer rate, but in contrast to reaction to presence of other recipients, fluorescence of such aggregates increased. The results show that strain with lower rate of gene transfer in fact differ from strains with high gene transfer in ability to aggregate to donor strains ant that analysis of aggregation alone is insufficient to distinguish between recipients of high and low transfer rate.

Aggregation in Huntington's disease: insights through modelling

Huntington's Disease (HD) is a late-onset, progressively degenerative brain disorder characterized by cell loss in the striatum and cortex. HD is caused by a polyglutamine (polyQ) expansion in the protein huntingtin (Htt). The mutant Htt is a substrate for caspases -2, -3 and -6. The cleavage of mutant Htt by caspase-2 has been suggested to underlie the selective neuronal death in HD. Once the mutant Htt is cleaved, a sticky and toxic fragment with the potential to form aggregates is released. The role of aggregation in the progression of HD has been extensively studied, yielding a plethora of ambivalent results. It has been shown that these are the diffuse, monomeric and oligomeric, forms of the mutant Htt fragment rather than the aggregates that are the major source of toxicity to the cells. We present here a mathematical model for aggregation in HD and discuss how it can relate to the selective neuronal death and the dependence of the disease onset on polyQ length. We describe the dynamical behavior of caspase-2, the release of monomeric forms of the mutant Htt fragment and the aggregation of these fragments through intermediate steps. Our model predicts that the concentration of toxic, intermediate oligomeric structures does not increase with increased caspase activity. We therefore suggest that the intermediate oligomeric forms of toxic Htt fragment do not account for selective and polyQ dependent neuronal death.

Differential regulation of Th2 and Th1 lung inflammatory responses by protein kinase C theta

In vitro and recent in vivo studies have identified protein kinase Ctheta (PKCtheta) as an important intermediate in signaling pathways leading to T cell activation, proliferation, and cytokine production. However, the importance of PKCtheta to many T cell-driven inflammatory responses has not been demonstrated. In this study we show that although PKCtheta is required for the development of a robust lung inflammatory response controlled by Th2 cells, it plays a lesser role in the development of a similar lung inflammatory response controlled by Th1 cells. PKCtheta-deficient mice were strongly compromised in generating Th2 cells and exhibited reduced airway eosinophilia and Th2 cytokine production in lungs. PKCtheta was required for the initial development of Th1 cells, with these cells exhibiting delayed kinetics of differentiation and accumulation. However, with recall Ag challenge via the airways, this defect was overcome, and lung infiltration and Th1 cytokine production were largely unimpaired in PKCtheta-deficient animals. These data suggest that PKCtheta can play roles in aspects of both Th2 and Th1 responses, but lung inflammation induced by Th2 cells is more dependent on this protein kinase than lung inflammation induced by Th1 cells.