Variations on the theme of podosomes: A matter of context.

Extensive in vitro studies have described podosomes as actin-based structures at the plasma membrane, connecting the cell with its extracellular matrix and endowed with multiple capabilities. Contractile actin-myosin cables assemble them into a network that constitutes a multifaceted cellular superstructure taking different forms - with common characteristics - but manifesting different properties depending on the context of study. Their morphology and their role in cell functioning and behavior are therefore now apprehended in in vivo or in vitro situations relevant to physiological processes. We focus here on three of them, namely: macrophage migration, antigen presentation by dendritic cells and endothelial cell sprouting during angiogenesis to highlight the characteristics of podosomes and their functioning shaped by the microenvironment.

[Variations on the theme of podosomes, context matters]. / Variations sur le thème des podosomes, une affaire de contexte.

Podosomes are actin-based microdomains connecting the cell with its extracellular matrix. Contractile actin-myosin cables assemble them into a network that constitutes a versatile cellular superstructure. Discovered and extensively described in in vitro conditions, podosomes now appear as major actors of specific physiological processes. They share common characteristics but their morphology and their effect on cell functioning can only be apprehended in specific cellular contexts. We focus here on three cellular processes involving podosomes and discuss their properties in context.

VEGF-A/Notch-Induced Podosomes Proteolyse Basement Membrane Collagen-IV during Retinal Sprouting Angiogenesis.

During angiogenic sprouting, endothelial tip cells emerge from existing vessels in a process that requires vascular basement membrane degradation. Here, we show that F-actin/cortactin/P-Src-based matrix-degrading microdomains called podosomes contribute to this step. In vitro, VEGF-A/Notch signaling regulates the formation of functional podosomes in endothelial cells. Using a retinal neovascularization model, we demonstrate that tip cells assemble podosomes during physiological angiogenesis in vivo. In the retina, podosomes are also part of an interconnected network that surrounds large microvessels and impinges on the underlying basement membrane. Consistently, collagen-IV is scarce in podosome areas. Moreover, Notch inhibition exacerbates podosome formation and collagen-IV loss. We propose that the localized proteolytic action of podosomes on basement membrane collagen-IV facilitates endothelial cell sprouting and anastomosis within the developing vasculature. The identification of podosomes as key components of the sprouting machinery provides another opportunity to target angiogenesis therapeutically.

Podosomes: Multipurpose organelles?

Thirty years of research have accumulated ample evidence that podosome clusters qualify as genuine cellular organelles that are being found in more and more cell types. A podosome is a dynamic actin-based and membrane-bound microdomain and the organelle consists in an interconnected network of such basic units, forming a cytoskeletal superstructure linked to the plasma membrane. At this strategic location, podosomes are privileged sites of interactions with the pericellular environment that regulates their formation, density, lifetime, distribution, architecture and functioning. Actin polymerization is the driving force behind most podosome characteristics. In contrast to classical organelles, podosomes are not vital at the cell level but rather serve diverse and often intricate functions of which adhesion, matrix degradation and substrate sensing are the most established. These capabilities involve specific molecules, depend on podosome organization and may vary according to the cell type in which they form. Podosome-associated diseases manifest by loss or gain of podosome functions and include genetic diseases affecting podosome components and various cancers where tumor cells ectopically express podosome equivalents (invadopodia).

Education catching up with science: preparing students for three-dimensional literacy in cell biology.

The large number of experimentally determined molecular structures has led to the development of a new semiotic system in the life sciences, with increasing use of accurate molecular representations. To determine how this change impacts students' learning, we incorporated image tests into our introductory cell biology course. Groups of students used a single text dealing with signal transduction, which was supplemented with images made in one of three iconographic styles. Typically, we employed realistic renderings, using computer-generated Protein Data Bank (PDB) structures; realistic-schematic renderings, using shapes inspired by PDB structures; or schematic renderings, using simple geometric shapes to represent cellular components. The control group received a list of keywords. When students were asked to draw and describe the process in their own style and to reply to multiple-choice questions, the three iconographic approaches equally improved the overall outcome of the tests (relative to keywords). Students found the three approaches equally useful but, when asked to select a preferred style, they largely favored a realistic-schematic style. When students were asked to annotate "raw" realistic images, both keywords and schematic representations failed to prepare them for this task. We conclude that supplementary images facilitate the comprehension process and despite their visual clutter, realistic representations do not hinder learning in an introductory course.

Analysis of students' aptitude to provide meaning to images that represent cellular components at the molecular level.

The number of experimentally derived structures of cellular components is rapidly expanding, and this phenomenon is accompanied by the development of a new semiotic system for teaching. The infographic approach is shifting from a schematic toward a more realistic representation of cellular components. By realistic we mean artist-prepared or computer graphic images that closely resemble experimentally derived structures and are characterized by a low level of styling and simplification. This change brings about a new challenge for teachers: designing course instructions that allow students to interpret these images in a meaningful way. To determine how students deal with this change, we designed several image-based, in-course assessments. The images were highly relevant for the cell biology course but did not resemble any of the images in the teaching documents. We asked students to label the cellular components, describe their function, or both. What we learned from these tests is that realistic images, with a higher apparent level of complexity, do not deter students from investigating their meaning. When given a choice, the students do not necessarily choose the most simplified representation, and they were sensitive to functional indications embedded in realistic images.

TGFbeta1 regulates endothelial cell spreading and hypertrophy through a Rac-p38-mediated pathway.

BACKGROUND INFORMATION: TGFbeta (transforming growth factor beta) is a multifunctional cytokine and a potent regulator of cell growth, migration and differentiation in many cell types. In the vascular system, TGFbeta plays crucial roles in vascular remodelling, but the signalling pathways involved remain poorly characterized. RESULTS: Using the model of porcine aortic endothelial cells, we demonstrated that TGFbeta stimulates cellular spreading when cells are on collagen I. TGFbeta-stimulated Rac1-GTP accumulation, which was associated with increased MAPK (mitogen-activated protein kinase) p38 phosphorylation. Furthermore, ectopic expression of a dominant-negative Rac mutant, or treatment of the cells with the p38 pharmacological inhibitor SB203580, abrogated TGFbeta-induced cell spreading. Our results demonstrate for the first time that prolonged exposure to TGFbeta stimulates endothelial cell hypertrophy and flattening. Collectively, these data indicate that TGFbeta-induced cell spreading and increase in cell surface areas occurs via a Rac-p38-dependent pathway. CONCLUSIONS: The Rac-p38 pathway may have conceptual implications in pathophysiological endothelial cell responses to TGFbeta, such as wound healing or development of atherosclerotic lesions.

Meeting report: teaching signal transduction.

In July, 2005, the European Institute of Chemistry and Biology at the campus of the University of Bordeaux, France, hosted a focused week of seminars, workshops, and discussions around the theme of "teaching signal transduction." The purpose of the summer school was to offer both junior and senior university instructors a chance to reflect on the development and delivery of their teaching activities in this area. This was achieved by combining open seminars with restricted access workshops and discussion events. The results suggest ways in which systems biology, information and communication technology, Web-based investigations, and high standard illustrations might be more effectively and efficiently incorporated into modern cell biology courses.

Transforming growth factor beta induces rosettes of podosomes in primary aortic endothelial cells.

Cytoskeletal rearrangements are central to endothelial cell physiology and are controlled by soluble factors, matrix proteins, cell-cell interactions, and mechanical forces. We previously reported that aortic endothelial cells can rearrange their cytoskeletons into complex actin-based structures called podosomes when a constitutively active mutant of Cdc42 is expressed. We now report that transforming growth factor beta (TGF-beta) promotes podosome formation in primary aortic endothelial cells. TGF-beta-induced podosomes assembled together into large ring- or crescent-shaped structures. Their formation was dependent on protein synthesis and required functional Src, phosphatidylinositide 3-kinase, Cdc42, RhoA, and Smad signaling. MT1-MMP and metalloprotease 9 (MMP9), both upregulated by TGF-beta, were detected at sites of podosome formation, and MT1-MMP was found to be involved in the local degradation of extracellular matrix proteins beneath the podosomes and required for the invasion of collagen gels by endothelial cells. We propose that TGF-beta plays an important role in endothelial cell physiology by inducing the formation of podosomal structures endowed with metalloprotease activity that may contribute to arterial remodeling.

CD44 and TGFbeta1 synergise to induce expression of a functional NADPH oxidase in promyelocytic cells.

Bone marrow stromal cells produce large amounts of extracellular matrix and cytokines. Amongst them, hyaluronan, a glycosaminoglycan and ligand for the cell surface molecule CD44, and TGFbeta1, a cytokine particularly important in monocyte differentiation. We have studied in vitro the role of hyaluronan and TGFbeta1 in the differentiation process of U937 monocytic progenitor cells. We provide evidence that, in the presence of whole blood-derived serum, the addition of hyaluronan is sufficient to induce the expression of NADPH-oxidase components but not of other monocytic markers (CD14, CD11b, and VLA-4). In the presence of plasma-derived serum, besides hyaluronan, the additional presence of TGFbeta1 was required for the expression of all of the components of the NADPH oxidase. We further show that hyaluronan mediates its effect through CD44. We conclude that cell matrix factors act cooperatively with cytokines to induce the expression of the components of the NADPH-oxidase in monocytic progenitor cells.

RhoGTPases and p53 are involved in the morphological appearance and interferon-alpha response of hairy cells.

Hairy cell leukemia is an uncommon B-cell lymphoproliferative disease of unknown etiology in which tumor cells display characteristic microfilamentous membrane projections. Another striking feature of the disease is its exquisite sensitivity to interferon (IFN)-alpha. So far, none of the known IFN-alpha regulatory properties have explained IFN-alpha responsiveness nor have they taken into account the morphological characteristics of hairy cells. IFN-alpha profoundly alters cytoskeletal organization of hairy cells and causes reversion of the hairy appearance into a rounded morphology. Because cytoskeletal rearrangements are controlled by the Rho family of GTPases, we investigated the GTPase activation status in hairy cells and their regulation by IFN-alpha. Using immunolocalization techniques and biochemical assays, we demonstrate that hairy cells display high levels of active Cdc42 and Rac1 and that IFN-alpha down-regulates these activities. In sharp contrast, RhoA activity was low in hairy cells but was increased by IFN-alpha treatment. Finally, IFN-alpha-mediated morphological changes also implicated a p53-induced response. These observations shed light on the mechanism of action of IFN-alpha in hairy cell leukemia and are of potential relevance for the therapeutical applications of this cytokine.

Inhibitory control of TGF-beta1 on the activation of Rap1, CD11b, and transendothelial migration of leukocytes.

Beta2-integrins are a family of dimeric adhesion molecules expressed on leukocytes. Their capacity to bind ligand is regulated by their state of activation. CD11b, an alphaMbeta2 integrin, is implicated in a number of physiological and pathological events such as inflammation, thrombosis, or atherosclerosis. The GTPase Rap1 is essential for its activation and could therefore play a strategic role in the regulation of leukocyte functioning. Because low levels of circulating TGF-beta have been linked with severe atherosclerosis, we have assessed the role of this cytokine in the regulation of Rap1 and CD11b activation in differentiated U937 cells and in human peripheral blood monocytes. TGF-beta1 caused a significant reduction in the expression of CD11b but not in the expression of other integrins tested. More importantly, TGF-beta1 greatly reduced the capacity of PMA or chemokines to activate CD11b and Rap1, a phenomenon paralleled by a loss of the Epac transcript and a reduction in 8-pCPT-2'-O-Me-cAMP-mediated activation of Rap1. This inhibition diminished the capacity of monocytes to migrate across a monolayer of endothelial cells. The inhibitory effect of TGF-beta1 on Rap1 activity may exert a general protective influence against aberrant transendothelial migration, thereby holding inflammatory responses in check.

Rheumatoid arthritis: targeting the proliferative fibroblasts.

Our flexible joints are synovial joints composed of bone, hyaline cartilage, synovial membrane, ligaments and tendons. Rheumatoid arthritis is a disease that affects multiple synovial joints and involves inflammation of the synovial membrane, often resulting in loss of function due to erosion of bone and cartilage. Inflammation is accompanied by an influx of immune-competent cells and by aberrant proliferation of resident fibroblast-like synoviocytes. Accretion of fibroblasts directly contributes to joint destruction, through enhanced production of matrix-degrading enzymes, and indirectly, through excessive release of cytokines that boost the immune system. Targeting the proliferative fibroblast could facilitate regeneration of synovial joints.

Influence of epitopes CD44v3 and CD44v6 in the invasive behavior of fibroblast-like synoviocytes derived from rheumatoid arthritic joints.

OBJECTIVE: To investigate the functional implications of CD44 splice variant expression in fibroblast-like synoviocytes (FLS) obtained from patients with rheumatoid arthritis (RA). METHODS: FLS were isolated from synovial tissue obtained from both diseased and nondiseased joints. The expression of splice variants containing exons v3 and v6 was analyzed using immunocytochemistry with exon-specific antibodies and reverse transcription-polymerase chain reaction followed by Southern blotting. The invasive capacity of the cells was studied in a transwell invasion assay. RESULTS: FLS obtained from RA joints expressed various CD44 splicing combinations containing the variant exons v3 and/or v6. These cells were highly invasive, whereas cells from normal tissues, which lacked expression of CD44 splice variants, were not. Variant exons CD44v3 and CD44v6 were instrumental in matrix invasion in vitro, with cells enriched for CD44v3 and v6 exhibiting greater invasion and antibodies that specifically recognize CD44v3 and v6 abrogating this capacity to invade. Invasive cells showed a reduced expression of CD44v7/8, and antibodies against this epitope had no significant effect on cellular infiltration of the matrix. The antibodies had no effect on cell migration into the porous section of the transwell. CONCLUSION: FLS obtained from patients with RA express CD44 splice variants and are highly invasive, whereas cells obtained from healthy tissue do not express these variants and are not invasive. Expression of the epitopes CD44v3 and CD44v6 is instrumental in the invasive capacity but not in cell migration. This finding highlights a functional implication for the expression of CD44 splice variants at the level of matrix degradation.