MAB19294 Sigma-AldrichAnti-Integrin β1 Antibody, active β1 integrins, clone TASC/9D11

Growth cones integrate a remarkably complex concert of chemical cues to guide axons to their appropriate destinations. Recent work suggests that integrins contribute to axon guidance by interacting with a wide range of extracellular molecules including axon guidance molecules, by mechanisms that are not fully understood. Here, we describe an interaction between integrins and netrin-1 in growth cones that contributes to growth cone collapse. Our data show that netrin-1 causes growth cone collapse in a substratum-specific manner and is integrin-dependent. Netrin-1 causes collapse of cultured chick dorsal root ganglion (DRG) growth cones extending on high levels of laminin-1 (LN) but not growth cones extending on low levels of LN or on fibronectin. Blocking integrin function significantly decreases netrin-induced growth cone collapse on high LN. Netrin-1 and integrins interact on growth cones; netrin-1 causes integrin activation, a conformational shift to a high ligand-affinity state. Netrin-1 directly binds to integrin α3 and α6 peptides, further suggesting a netrin-integrin interaction. Interestingly, our data reveal that netrin-1 increases growth cone levels of cAMP in a substratum-specific manner and that netrin-induced growth cone collapse requires increased cAMP in combination with integrin activation. Manipulations that either decrease cAMP levels or integrin activation block netrin-induced collapse. These results imply a common mechanism for growth cone collapse and novel interactions between integrins, netrin-1 and cAMP that contribute to growth cone guidance.

In the prospective lumbo-sacral region of the chick embryo, neurulation is achieved by cavitation of the medullary cord, a process called secondary neurulation. Neural crest cells (NCC) are generated in this region and they give rise to the same types of derivatives as in more rostral parts of the trunk where neurulation occurs by dorsal fusion of the neural plate borders (primary neurulation). However, no molecular data were available concerning the different steps of their ontogeny. We thus performed a detailed expression study of molecular players likely to participate in the generation of secondary NCC in chick embryos between Hamburger and Hamilton stages 18-20 (HH18-20) at the level of somites 30 to 43. We found that specification of secondary NCC involves, as in primary neurulation, the activity of several transcription factors such as Pax3, Pax7, Snail2, FoxD3 and Sox9, which are all expressed in the dorsal secondary neural tube as soon as full cavitation is achieved. Moreover, once specification has occurred, emigration of NCC from the dorsal neuroepithelium starts facing early dissociating somites and involves a series of changes in cell shape and adhesion, as well as interactions with the extracellular matrix. Furthermore, Bmp4 and Wnt1 expression precedes the detection of migratory secondary NCC and is coincident with maturation of adjacent somites. Altogether, this first study of molecular aspects of secondary NCC ontogeny has revealed that the mechanisms of neural crest generation occurring along the trunk region of the chick embryo are generally conserved and independent of the type of neurulation involved.

Cyclic nucleotides regulate the response of both developing and regenerating growth cones to a wide range of guidance molecules through poorly understood mechanisms. It is not clear how cAMP levels are regulated or how they translate into altered growth cone behavior. Here, we show that intracellular cAMP levels are influenced by substrata and integrin receptors. We also show that growth cones require a substratum-specific balance between cAMP levels, integrin function and Rho GTPases to maintain motility and prevent collapse. Embryonic chick dorsal root ganglion neurons plated on different concentrations of laminin extend growth cones at similar speeds, yet have distinct levels of integrin expression, integrin activation and intracellular cAMP levels. Either increasing cAMP signaling or activating integrins enhances the rate of growth cone motility, but only on substrata where these two factors are endogenously low (i.e. low concentrations of laminin). Surprisingly, combining these two positive manipulations induces growth cone collapse and retraction on laminin but not on fibronectin. Collapse and retraction on laminin are Rho and Rac1 GTPase dependent and are associated with internalization of integrins, the primary receptors responsible for adhesion. These observations define a novel pathway through which cAMP influences growth cone motility and establish a link between integrins, cAMP and Rho GTPases in growth cones.

Extracellular matrix (ECM) glycoproteins regulate neuronal development and axonal growth. In this paper, the ECM glycoprotein vitronectin was identified and localized in the embryonic chick neuroretina. To identify potentially important neurite outgrowth-promoting molecules, responses of embryonic chick retinal neurons to vitronectin and thrombospondin, another retinal ECM constituent, were examined. These neurons were shown to attach and extend neurites on either glycoprotein. Integrins containing the alpha v or beta 1 subunits mediate both responses to vitronectin and neurite outgrowth on thrombospondin. Attachment to thrombospondin was inhibited by heparin, suggesting that neurons also utilize a proteoglycan or sulfated glycolipid as a receptor for this glycoprotein. Thus, retinal neurons use specific receptors to interact with vitronectin and thrombospondin, two glycoproteins present in the embryonic neuroretina, suggesting roles for these ligands and their receptors in retinal development.

Integrins are a family of alpha beta heterodimeric receptors that mediate cell-cell and cell-substratum interactions. Integrin binding to extracellular ligands regulates cell adhesion, shape, motility, intracellular signalling and gene expression. Mechanisms that regulate integrin function are, therefore, central to the participation of integrins in a diverse set of cellular events. Here we report the identification of TASC, a monoclonal antibody to a novel epitope on the integrin beta 1 subunit, which inhibits cell adhesion to vitronectin but promotes adhesion to laminin and collagen types I and IV. We show that developing retinal neurons that have lost responsiveness to laminin regain the ability to bind laminin in the presence of TASC. Thus, beta 1-class integrins are likely to occupy multiple affinity states that can be modulated at the cell surface.