An in vitro neurite-promoting antigen functions in axonal regeneration in vivo

Expression and regulation of alpha1beta1 integrin in Schwann cells

The interaction of cells with the extracellular matrix plays a critical role in morphogenesis and cell differentiation. To define how Schwann cells might interact with the extracellular matrix, we chose to study the expression of the laminin/collagen receptor alpha1beta1 integrin during nerve development in the rat from embryonic day 14 to maturity. We found that this integrin is expressed predominantly on mature non-myelin-forming cells and only at very low levels on myelin-forming cells. Significant levels of this integrin were not detected on Schwann cell precursors or embryonic Schwann cells in vivo. Experiments using transected and crushed sciatic nerve showed that alpha1beta1 integrin expression is regulated at least in part by axonal contact. Furthermore, Schwann cell culture experiments showed that alpha1beta1 integrin levels are strongly upregulated by transforming growth factor-beta(s) and phorbol esters.

Effects of extracellular matrix components on axonal outgrowth from peripheral nerves of adult animals in vitro

Relatively little is known of the growth requirements for regenerating axons of the peripheral nervous system of adult animals. In the present study, we show that extracellular matrix material secreted by the Engelbreth-Holm-Swarm tumor cell line (matrigel) supports axonal growth from explanted peripheral nerve-dorsal root ganglia (DRG) preparations of adult mice and amphibia in serum-free media, without addition of growth factors. Axonal growth in matrigel was much more profuse than that in the more commonly used gels of type 1 collagen and, after some days in culture, was accompanied by migration of Schwann cells along axons. The most abundant protein in matrigel is laminin, which has been shown in many studies to support axonal growth but, surprisingly, antisera to laminin did not inhibit axonal growth in matrigel. To determine the ability of the major components of matrigel, laminin, type IV collagen, and heparan sulfate proteoglycan (HSPG), to support axonal growth, these proteins were added to preparations of mouse peripheral nerve-DRGs in type I collagen gels. Regenerating axons were significantly longer in the presence of laminin and type IV collagen than in control cultures, while HSPG had a slight inhibitory effect. In this assay system, however, diluted matrigel solution was even more effective in stimulating axonal growth than laminin or type IV collagen, either alone or in combination. The results suggest that in addition to laminin and type IV collagen, other components within matrigel may contribute to its ability to support axonal growth.

Expression of the major basement membrane-associated proteins during postnatal development in the murine cochlea

The major basement membrane-associated proteins, including laminin-1, fibronectin, heparan sulfate proteoglycan (HSP), and entactin, were examined by immunofluorescence microscopy during postnatal development of the mouse cochlea. Samples were collected every 2 days through 8 days, and again at 14 days after birth. In the neonate, staining for HSP entactin and laminin-1 was barely visible; however, antibodies against fibronectin displayed intense immunoreactivity in nearly every cochlear tissue. Fibronectin is progressively inactivated in all tissues except the basilar membrane where it persists at high levels to adulthood. Laminin-1, entactin, and HSP illustrate remarkable temporal and spatial coordinate regulation. Elevated expression of these proteins is observed at 2 postnatal days (PND), and persists in the membranes surrounding the spiral ganglion cell bodies. Transient expression of laminin-1 and entactin, an to a lesser extent HSP, is observed from PND4 to PND8 in a track of membrane running from the interdental cells of the spiral limbus down the inner sulcus, across the basilar membrane, up the external sulcus to the spiral prominence, and branching into the spiral ligament ensheathing the root cell processes. By PND14 the abundance of these proteins is greatly reduced along this track. The abundance and dynamic regulation of these major basement membrane-associated proteins suggests that they play an important role in postnatal cochlear development.

Human SY5Y neuroblastoma cell interactions with laminin isoforms: neurite outgrowth on laminin-5 is mediated by integrin alpha 3 beta 1

Laminin (Ln) isoforms may play important roles in neuronal development, particularly axon guidance, but neural receptors mediating interactions with Ln are not entirely understood. In this paper, we have compared the adhesive and process outgrowth activities of a human neuroblastoma cell line SY5Y on various laminin isoforms. Cell adhesion and process outgrowth were examined on murine Ln-1 (Englebreth-Holm-Swarm sarcoma laminin), human placental Ln-1 (human Ln-1[p]), human Ln-2 (merosin), human Ln-5 (kalinin/epiligrin/nicein), and human foreskin keratinocyte extracellular matrix extract (human HFK-ECM). Ln-5 was shown to evoke process outgrowth in amounts comparable to other Ln isoforms. Antibody perturbation experiments showed that adhesion and process outgrowth on murine Ln-1 was primarily mediated by the integrin alpha 1 beta 1, whereas adhesion and outgrowth on human Ln-5 and human HFK-ECM were mediated by alpha 3 beta 1. Adhesion to human Ln-1(p) and Ln-2 was not blocked by addition of anti-alpha 1 or anti-alpha 3 antibodies alone, but adhesion was partially perturbed when these antibodies were added in combination. Process outgrowth on human Ln-1(p) was blocked when either anti-alpha 3 or anti-beta 1 antibodies were added, indicating that alpha 3 beta 1 is the primary integrin heterodimer responsible for process extension on this substrate. These results demonstrate that Ln-5 and other Ln isoforms support comparable levels of adhesion and process outgrowth, but different integrin heterodimers, alone and in combination, are used by SY5Y cells to mediate responses.

Antibodies against the T61 antigen inhibit neuronal migration in the chick optic tectum

Cell migration in the central nervous system depends, in part, on receptors and extracellular matrix molecules that likewise support axonal outgrowth. We have investigated the influence of T61, a monoclonal antibody that has been shown to inhibit growth cone motility in vitro, on neuronal migration in the developing optic tectum. Intraventricular injections of antibody-producing hybridoma cells or ascites fluid were used to determine the action of this antibody in an in vivo environment. To document alterations in tectal layer formation, a combination of cell-nuclei staining and axonal immunolabeling methods was employed. In the presence of T61 antibody, cells normally destined for superficial layers accumulated in the ventricular zone instead, leading to a reduction of the cell-dense layer in the tectal plate. Experiments with 5-bromo-2'-deoxyuridine labeling followed by antibody staining confirmed that the nonmigrating cells remaining in the ventricular zone were postmitotic and had differentiated. The structure of radial glial cells, as judged by staining with a glia-specific antibody and the fluorescent tracer 1,1'-dioctadecyl-3,3,3',3'-tetramethylindocarbocyanine perchlorate (DiI), remained intact in these embryos. Our findings suggest that the T61 epitope is involved in a mechanism underlying axonal extension and neuronal migration, possibly by influencing the motility of the leading process.

Molecular basis of interactions between regenerating adult rat thalamic axons and Schwann cells in peripheral nerve grafts. II. Tenascin-C

Tenascin-C is a developmentally regulated extracellular matrix component. There is evidence that it may be involved in axon growth and regeneration in peripheral nerves. We have used in situ hybridization and immunocytochemistry to investigate the association of tenascin-C with central nervous system axons regenerating through a peripheral nerve autograft inserted into the thalamus of adult rats. Between 3 days and 4 weeks after implantation, tenascin-C immunoreactivity was increased in the grafts, first at the graft/brain interface, then in the endoneurium of the graft, and finally within the Schwann cell columns of the graft. By electron microscopy, reaction product was present around collagen fibrils and basal laminae in the endoneurium, but the heaviest deposits were found at the surface of regenerating thalamic axons within Schwann cell columns. Schwann cell surfaces were not associated with tenascin-C reaction product except where they faced the tenascin-rich basal lamina or were immediately opposite axons surrounded by tenascin-C. By 8 weeks after graft implantation tenascin-C in the endoneurium and around axons of the graft was decreased. In the brain parenchyma around the proximal part of the graft, axonal sprouts associated with tenascin-C could not be identified earlier than 2 weeks after grafting and were sparse at this stage. Larger numbers of such axons were present at 8-13 weeks after grafting and were located predominantly where the glia limitans between brain and graft appeared to be incomplete, suggesting that the tenascin-C may have penetrated the brain parenchyma from the graft. By in situ hybridization, cells expressing tenascin-C mRNA (probably Schwann cells) appeared first at the brain/graft interface 3 days after grafting and thereafter were mainly located within the grafts. Lightly labelled cells containing tenascin-C mRNA (probably glial cells) were scattered in the thalamic parenchyma both ipsilateral and contralateral to the graft and a few heavily labelled cells were located very close to the tip of the graft. These results show that regenerating adult thalamic axons, unlike regenerating peripheral axons, become intimately associated with peripheral nerve graft-derived tenascin-C, suggesting that they express a tenascin-C receptor, as many neurons do during development, and that tenascin-C derived from Schwann cells may play a role in the regenerative growth of such axons through the grafts.

Expression and in vitro function of beta 1-integrin laminin receptors in the developing avian ciliary ganglion

In chick development, ciliary ganglion (CG) neurons go through a period of axon extension from approximately embryonic day (E)4 to E8, followed by a period of synaptogenesis and neuronal cell death. By examining the immunohistochemical localization of laminin, in conjunction with Dil labeling of the ciliary nerve projection, we have determined that the pathway taken by these neurons is rich in laminin expression. Therefore, laminins are good candidate molecules for mediating outgrowth of these neurons in vivo. In vitro, the ability of CG neurons to extend neurites on laminin-1 (EHS laminin, alpha 1 beta 1 gamma 1) is maximal up to E8, then declines dramatically. CG neuron outgrowth on laminin-1 requires the activity of beta 1-class integrins. We have used subunit-specific antibodies to determine which of the five beta 1-containing heterodimers known to be laminin receptors (alpha 1 beta 1, alpha 2 beta 1, alpha 6 beta 1, alpha 7 beta 1) are expressed, and which mediate neurite outgrowth. While we could not detect expression of alpha 2 or alpha 7, we have found that alpha 1, alpha 3 beta 1, and alpha 6 beta 1 are expressed on the surface of ciliary ganglion neuron cell bodies and axons, both in vitro and in vivo. Furthermore, antibodies against alpha 3 and alpha 6, but not alpha 1, interfered with CG neurite outgrowth on laminin-1 in vitro. Taken together, these data suggest that interactions of cell surface alpha 3 beta 1 and alpha 6 beta 1 integrins with laminin-1 are likely to mediate growth of CG neurons during pathfinding in vivo.

Up-regulation of a chondroitin sulphate epitope during regeneration of mouse sciatic nerve: evidence that the immunoreactive molecules are related to the chondroitin sulphate proteoglycans decorin and versican

After transection of adult mouse sciatic nerve, the expression of a chondroitin sulphate epitope recognized by the monoclonal antibody 473-HD (mAb 473-HD) was found to be up-regulated. The epitope was localized immunocytochemically mainly in Schwann cell basal laminae and, more weakly, also in the endoneurium. In cultures of mouse dorsal root ganglion cells, Schwann cells expressed high levels but fibroblasts only low levels of the epitope. To identify the molecule(s) carrying this chondroitin sulphate epitope, human sciatic nerves were extracted with phosphate-buffered saline and shown to contain two chondroitin sulphate proteoglycans of apparent molecular weights of 130 and 900 kDa. The 900 kDa and, more weakly, the 130 kDa proteoglycan were reactive with mAb 473-HD, which was found to recognize chondroitin-6-sulphate as epitope. Following chondroitinase ABC treatment of the 130 kDa proteoglycan, a core protein of approximately 45 kDa was seen and shown to react with polyclonal antibodies against the chondroitin-dermatan sulphate proteoglycan decorin from human fibroblasts. Chondroitinase ABC treatment of the 900 kDa proteoglycan yielded a core protein with a molecular weight of approximately 400 kDa that was recognized by polyclonal antibodies against recombinantly expressed fusion proteins from human versican. After transection of adult mouse sciatic nerves, the distal nerve stumps showed up-regulation of the chondroitin-6-sulphate epitope of the 900 kDa proteoglycan, whereas the core protein of this proteoglycan did not show any detectable change in the level of expression. In contrast, the core protein of the 130 kDa proteoglycan was up-regulated in expression. These observations suggest that versican- and decorin-like molecules may contribute to successful regeneration in the peripheral nervous system of mammals.

Spinal axons in central nervous system scar tissue are closely related to laminin-immunoreactive astrocytes

Although transected central nervous system axons fail to regrow after injuries in adult mammals, they send sprouts into the scar tissue that forms at the lesion. We have investigated the relation between scar cells, laminin-like immunoreactivity and cut spinal axons in two previously characterized spinal cord lesion types. Labeling with antisera to glial fibrillary acidic protein and laminin demonstrated that the scar tissue formed after lesions in the rat and cat dorsal and ventral funiculi showed prominent gliosis and strong laminin-like immunoreactivity four days to one year postlesion. Axonal sprouts in the scar, visualized with antibodies to neurofilament (RT97) or by tracing using fluorescein-conjugated dextran, were ensheathed by a thin layer of strongly laminin-immunoreactive tissue. Immunoelectron microscopy demonstrated that axons in the scar were ensheathed predominantly by astrocytes, and that the surface of the cells outlining the axons in the scar showed strong laminin-like immunoreactivity. Adhesive and neurite orienting properties in the scar tissue were assessed in an in vitro system where PC12 cells were cultured on spinal cord slices from dorsal funiculus-lesioned rats. Very few cells adhered to the spinal cord section except for the part where the scar tissue had formed, where numerous cells were attached. The PC12 cells that had adhered to the scar tissue were mainly seen in parts of the scar that showed laminin-like immunoreactivity and their neurites predominantly followed tissue showing laminin-like immunoreactivity. The close association between axonal sprouts and laminin-like immunoreactivity indicates a role for laminin in axonal growth and/or guidance in the injured spinal cord.

Inhibition of retinal regeneration in larval Rana by an antibody directed against a laminin-heparan sulfate proteoglycan

In vivo and in vitro experiments have demonstrated that the retinal pigmented epithelium can give rise to neuronal precursors during retinal regeneration in amphibians. In vitro experiments have further demonstrated that this process is greatly facilitated by two molecules associated with basement membranes: laminin and fibroblast growth factor. We now report that retinal regeneration can be blocked in vivo by an antibody that inhibits the interaction of cells with the laminin-heparan sulfate proteoglycan complex. These results further support a role for the extracellular matrix in regulating cellular phenotype during retinal regeneration.

Differential effects of glycosaminoglycans on neurite outgrowth from hippocampal and thalamic neurones

Chondroitin sulphate proteoglycans are expressed in a temporally restricted pattern from embryonic day 17 to postnatal day 0 in both the thalamus and the cortical subplate, to which thalamic neurones transiently project. To study whether chondroitin sulphate proteoglycans could be specifically involved in the modulation of thalamic axon outgrowth, we compared neurite outgrowth from cultured rat embryonic hippocampal and thalamic neurones, in the presence of chondroitin sulphate type C (isolated from shark cartilage) and chondroitin sulphate type B (dermatan sulphate; isolated from bovine mucosa). When added to the culture medium, both types of glycosaminoglycan lowered the adhesion to laminin and polylysine of both hippocampal and thalamic neurones. However, only chondroitin sulphate specifically modified the pattern of thalamic but not hippocampal neurone outgrowth, promoting axon growth. The morphological changes induced by chondroitin sulphate were concentration dependent and correlated with the selective binding of chondroitin sulphate to the neuronal plasma membrane and its subsequent internalisation. Chondroitin sulphate loosely bound to the surface of hippocampal neurones, but was not internalised. These results indicate that proteoglycans, and in particular the glycosaminoglycan component of these molecules, can differentially modulate neurite outgrowth, depending on their biochemical composition and on the type of neurones they bind to; this would be a possible mechanism of controlling axon guidance in vivo.

Botulinum A toxin stimulates neurite branching in nerve-muscle cocultures

In addition to skeletal muscle paralysis, type A botulinum toxin commonly causes sprouting of motor axons in various experimental whole-animal systems. The use of type A botulinum toxin in clinical treatment of muscle spasm disorders is becoming increasingly popular. The eventual, unwanted return of involuntary activity in the treated muscles may be a consequence of such axon sprouting. We have developed a coculture model allowing the quantification of botulinum toxin-induced sprouting that shows promise for future studies on its mechanism and control. Chick embryo ciliary ganglion motor neurons were cocultured with chick leg muscle cells. The presence of type A botulinum toxin in the coculture medium was correlated with significantly increased branching frequency of neurites. Toxin-increased branching frequency occurred even when the neurons and muscle cells were separated from each other on the culture dishes, suggesting a presynaptic effect of toxin. Cocultures incubated in the presence of curare, a post-synaptic blocker, had control levels of neurite branching, ruling out the possibility that simple synaptic blockade causes sprouting but again supporting the hypothesis of a pre-synaptic activity of botulinum toxin.

Carbohydrates play a role in neurite outgrowth in vivo during development and regeneration

We have used the alpha-glucosidase inhibitor, castanospermine, to investigate the possible involvement of N-linked glycosylation in the process of neurite outgrowth both during the development and regeneration of sympathetic nerve fibres into the iris of the rat. The effects on nerve growth were assessed qualitatively using catecholamine histochemistry and quantitatively by measuring the uptake of [3H]noradrenaline. Castanospermine was injected during the first, second or third postnatal week or during the second to fourth week after degeneration of adrenergic nerve terminals with the neurotoxin, 6-hydroxydopamine. Results showed that both the initial growth of sympathetic nerve fibres, as well as the regeneration of these fibres, was inhibited by castanospermine treatment. The inhibitory effects were restricted to injection of castanospermine at particular time periods during postnatal development and regeneration. These results suggest that N-linked carbohydrates may be important in particular stages of the processes of initial nerve growth and regeneration of sympathetic nerve fibres in the iris.

Functional identification of integrin laminin receptors that mediate process outgrowth by human SY5Y neuroblastoma cells

Treatment of the human neuroblastoma cell line SY5Y with nerve growth factor (NGF) induces terminal neuronal differentiation of a subpopulation of cells which can be selected by treatment with a DNA synthesis inhibitor. We have examined the interactions of naive (untreated) and NGF-differentiated SY5Y cells with laminin, and identified integrin receptors that mediate laminin-induced process outgrowth. Differentiated cells displayed a greater capacity for process extension, which correlated with increased expression of integrin laminin receptors. Both naive and differentiated cells expressed integrins alpha 1/beta 1, alpha 2/beta 1, and alpha 3/beta 1 but the differentiated population expressed about 5-fold higher levels of alpha 1/beta 1 and about 2-fold more alpha 2/beta 1 and alpha 3/beta 1 on their surface. Function blocking monoclonal antibodies were used to identify integrin receptors mediating process outgrowth. The anti-alpha 1 monoclonal antibody SR84 was shown to block alpha 1 function and inhibit process outgrowth on laminin. Despite the presence of multiple integrins which have been shown to bind laminin in other cell types, alpha 1/beta 1 mediated the majority of process outgrowth in both naive and differentiated cells, with a minor role played by alpha 3/beta 1. These data indicate that alpha 1/beta 1 function is required for process outgrowth on laminin by SY5Y cells and suggest that increased expression may be a crucial aspect of neuronal differentiation.

Expression and functional roles of neural cell surface molecules and extracellular matrix components during development and regeneration of peripheral nerves

By combining both immunocytochemical and functional investigations, a hypothetical framework will be developed for the molecular mechanisms underlying neuron-glia interactions during development and regeneration of peripheral nerves. In particular, the immunoglobulin-like molecules L1, N-CAM, MAG and P0, the extracellular matrix molecules laminin and tenascin, and the carbohydrates PSA and L2/HNK-1 will be considered. During early stages of limb bud innervation in embryos, L1 and N-CAM are expressed on axons and Schwann cells and are involved in axonal fasciculation, whereas tenascin is thought to be involved in forming a scaffold around the nerve possibly preventing axons and/or Schwann cells from leaving the nerve. PSA has been shown to be involved in pathway selection at initial stages of limb bud innervation. Later on, when motor axons enter muscles, the carbohydrates determine the branching pattern of the nerves. During myelination, L1 appears to play a pivotal role during the formation of the first Schwann cell loops around the prospective myelin-containing axons. MAG and P0 appear also to be functionally involved at initial stages of myelin formation. Additionally, MAG may contribute to the formation and maintenance of non-compacted myelin and axon-Schwann cell apposition whereas P0 is involved in myelin compaction. Under regenerative conditions, L1, N-CAM, laminin, and tenascin are strongly up-regulated by denervated Schwann cells. In vitro observations strongly suggest that these molecules might foster axonal regeneration. The carbohydrate PSA is confined to regrowing axons and is also a candidate to support axonal regrowth. L2/HNK-1, which is found on motor axon-associated Schwann cells, may provide regenerating motor axons with a selective advantage over others resulting in appropriate reinnervation of motor pathways. Since many of the functional studies this review refers to have been performed in vitro, some of the conclusions drawn need reexamination in vivo. Gene manipulations, such as the generation of null mutants followed by a thorough morphological and immunocytochemical investigation may be a powerful tool to resolve this problem.

Culture of hypoglossal cells, dissociated from foetal and new-born rats

Primary cultures of dissociated cells from brainstem cranial nuclei have not been described in the literature. The present paper shows that dissociated rat posterior brainstem cells, as well as cells from the hypoglossal nucleus, taken from both foetal and postnatal animals, can be maintained in long-term culture. This can be achieved by using a DMEM/F-12 medium with defined supplements, with or without foetal calf serum. Under such conditions, the growth of neuritic processes as well as the formation of neural networks can be observed. The different cell types present in the cultures can be identified by immunohistochemistry with antibodies raised against neuron specific enolase, glial fibrillary acidic protein, galactocerebroside and choline-acetyl transferase. As previously demonstrated for other brain-dissociated neurones maintained in cultures, the use of molecules, involved in cell adhesive mechanisms, can modify the morphological properties of the growing cells. This was particularly observed when poly-L-lysine and laminin were used as substrata.

An analysis of the effects of Alzheimer's plaques on living neurons

Although senile plaques represent a consistent neuropathological feature in Alzheimer's brains, it is not known what role plaques play in the etiology of the disease. Both growth-promoting and growth-inhibiting influences have been postulated. One of the major components in plaques, beta-amyloid, has been shown to affect neuron survival and neurite outgrowth in vitro. Because plaques consist of other components in addition to beta-amyloid, we undertook the present study to determine whether neuronal survival and neurite outgrowth are affected by the presence of a senile plaque. This was accomplished by using cryostat sections from the cerebral cortex of Alzheimer's patients as a substratum for cultured rat hippocampal neurons. Evaluation of these living neurons on Alzheimer's tissue demonstrated that senile plaques affect the amount, complexity, and direction of neurite outgrowth. In addition, neurons were more likely to extend processes away from plaques rather than toward a plaque. Although cell survival on plaques and in control regions was similar, cell survival was significantly reduced in the peri-plaque region. These observations suggest that senile plaques could have deleterious effects on neural organization in situ.

UNC-6, a laminin-related protein, guides cell and pioneer axon migrations in C. elegans

The unc-6 gene is required for the guidance of pioneer axons and migrating cells along the body wall in C. elegans. In mutants, dorsal and ventral migrations are disrupted, but longitudinal movements are largely unaffected. The gene was tagged for molecular cloning by two independent transposon insertions. Based on genomic and cDNA sequencing, the gene encodes a novel laminin-related protein, UNC-6 (591 amino acids). The N-terminus is homologous to the N-termini (i.e., domains V1, V-1, V-2, and V-3) of laminin subunits, while the C-terminus is a unique domain. We propose that UNC-6 is a component of an extracellular matrix cue that guides dorsoventral migrations on the epidermis.

Regulation of expression of fibronectin and its receptor, alpha 5 beta 1, during development and regeneration of peripheral nerve

The extracellular matrix glycoprotein, fibronectin, is a potent promoter of peripheral neurite outgrowth. Interactions of peripheral neurons with fibronectin have been shown to be primarily mediated by the beta 1 class of integrin heterodimers. In the present study, we have examined the expression and regulation of fibronectin and its integrin receptor, alpha 5 beta 1, in developing and regenerating chick peripheral nerve. We show that fibronectin and alpha 5 beta 1 are expressed at comparatively high levels in developing nerve with alpha 5 beta 1 expression on axons and non-neuronal cells. With nerve maturation, both proteins are less prominently expressed and the cellular pattern of alpha 5 beta 1 expression becomes more restricted. Following lesion of mature nerve, both fibronectin and alpha 5 beta 1 are strongly induced with prominent expression of alpha 5 beta 1 on regenerating neurites and Schwann cells. The elevation in fibronectin levels in the regenerating nerve is highest in the vicinity of the lesion, an area undergoing extensive cellular remodeling including Schwann cell migration and growth cone extension. Our results suggest that fibronectin and its receptor, alpha 5 beta 1, may mediate functionally important interactions in the development and regeneration of peripheral nerve.

Laminin--developmental expression and role in axonal outgrowth in the peripheral nervous system of the chick

The possible role of laminin on axon outgrowth and guidance in vivo was examined by: (1) determining its developmental expression, and relationship to outgrowth of sensory, motor and sympathetic axons in the chick embryo; and (2) evaluating the changes in the pattern of sympathetic preganglionic projections subsequent to injections of laminin, antilaminin and other laminin function blockers (JG22, INO) into their pathways during axon outgrowth. Double immunofluorescent staining for laminin and neurofilaments in peripheral nerves prior to and during initial outgrowth showed no obvious relationship between laminin and potential nerve pathways. Even though weak laminin immunostaining is apparent throughout the mesenchyme through which axons grow, the most prominent laminin immunostaining is on basement membranes of the neural tube, notochord and dermamyotome. However, as peripheral nerves mature, laminin becomes localized to nerve fascicles throughout the peripheral nervous system, beginning with the dorsal and ventral roots, and progressing later to more distal spinal nerves. Microinjections of antilaminin, JG22 (a monoclonal antibody against laminin/fibronectin receptors) and INO (a monoclonal antibody against a laminin-heparan sulfate proteoglycan complex) into the pathway of sympathetic preganglionic axons prior to and during outgrowth had no effect on the spatio-temporal patterns of sympathetic preganglionic projections. An alternate laminin-rich pathway produced by injecting laminin into the region of the sympathetic trunk immediately adjacent but caudal to the T1 spinal level also did not alter the projection of T1 preganglionic axons. These results suggest that laminin may not be crucial to the initial of peripheral axons. The localization of laminin in nerve fascicles in later stages of development suggests instead that laminin may be important in the maintenance of these structures.

Nonintegrin laminin receptors in the nervous system: evidence for lack of a relationship to P40

Laminins are extracellular matrix proteins that mediate their effects on cells through integrin and nonintegrin receptors. Two receptors of 67 and 110 kD that bind laminin with a high affinity (Kd approximately nM) have been reported in neural cells. Here, we discuss these and other nonintegrin laminin receptors that have been implicated in neural function. In addition, we report studies characterizing a 43 kD protein, (P40), immunologically related to the 67 kD laminin receptor, which may be involved in retinal development. In our studies, polyclonal antisera (anti-P-20-A) to a synthetic peptide derived from the sequence of a cDNA for a putative high-affinity laminin receptor (67 kD) detected a protein of 43 kD in immunoblots of adult rat retinas. Immunohistochemistry with this antiserum showed that the retinal immunoreactivity was predominantly localized in the ganglion cell layer of both adult chicken and rat retinas where it appeared to be intracellular. Retinal ganglion cells were shown to be immunoreactive by retrogradely labeling them from the superior colliculus with a lipophilic dye and subsequently with anti-P-20-A antisera. Consistent with the preferential localization of the P-20-A immunoreactivity in ganglion cells, there was a substantial decrease in the amounts of P40 on Western blots following optic nerve section and resulting retinal ganglion cell death. Screening of a rat (PC12 cell) cDNA library with the anti-P-20-A antiserum further confirmed the specificity of the antiserum for the rat homologue of P40. Rat P40 is 97% identical to the mouse and 87% identical to human P40 at the nucleic acid level and 98% at the protein level. Restriction mapping of the rather abundant positive clones in the library that cross-hybridized with a human cDNA probe for P40 indicated that the full-length cDNA of 1.2 kb was the major and perhaps the only cDNA in the library. In Northern blots of adult rat retina, these clones hybridized to a single 1.2-kb transcript. Electroblots of retinal homogenates probed with radioiodinated laminin demonstrated binding to a broad band at 110 kD, but none at 43 kD. Taken together these findings suggest that P40 may not be a laminin receptor and are in keeping with the hydrophilic composition of the protein, its intracellular localization, as well as other features predicted by its nucleic acid sequence.(ABSTRACT TRUNCATED AT 400 WORDS)

Thrombospondin promotes process outgrowth in neurons from the peripheral and central nervous systems

Thrombospondin (TSP) is a prominent constituent of the extracellular matrix of the developing nervous system. We have examined the effects of TSP on the morphological differentiation of neurons. In short-term cultures (less than or equal to 24 hr) of embryonic rat sympathetic neurons, TSP stimulated neurite outgrowth, causing significant increase in the number of processes and their length. Similar effects were observed in cultures of rat dorsal root ganglion, hippocampal, and cerebral cortical neurons. Moreover, in cultures of central neurons, TSP was more effective than laminin in enhancing process extension. Analysis of long-term (5-7 days) cultures of sympathetic neurons indicated that processes formed in the presence of TSP had the cytochemical characteristics of axons. Thus, TSP can influence neuronal development by selectively enhancing axonal growth. The neurite-promoting region of the molecule was identified using a panel of monoclonal antibodies targeted to different regions of the protein. Process outgrowth could be totally inhibited with antibody A4.1, which recognizes the stalk region of TSP. These data suggest that the neurite-promoting activity is localized to a single region of the TSP molecule.

Facilitatory and inhibitory effects of glial cells and extracellular matrix in axonal regeneration

Recent studies have shown that Schwann cells stimulate nerve regeneration by producing nerve growth factor in response to macrophage activation as well as by mediating growth through cell-surface and extracellular matrix adhesion molecules. Neurons sprouting in the central nervous system, however, encounter a hostile environment including mature oligodendrocytes with contact inhibitors of growth cone motility, masses of proliferating astrocytes with surface properties that may block regeneration, and an extracellular environment relatively rich in chondroitin sulfate and tenascin forming a matrix less permissive for regeneration than that found in the peripheral nervous system. In addition, as neurons mature, integrins and cell adhesion molecules are reduced in number (transcriptionally) or in efficacy (post-translationally).

An in vitro method assaying recognition ability of nerve terminals for special substances

The present study provides a simple in vitro method for detecting the ability of nerve terminals to recognize special molecules. Test molecules were applied to a restricted narrow region on the surface of culture dishes, and dissociated sympathetic neurons which were embedded in a collagen gel were placed on the surface next to the region. Sympathetic fibers distributed densely on the laminin-applied region, whereas they were missing on the heparin- or hyaluronic acid-applied regions. The neurites showed no response to the fibronectin- or heparan sulfate-applied region. These results indicate that sympathetic fibers have an affinity for laminin, whereas they recognize a repellent property of heparin or hyaluronic acid.

Neurite-promoting activities of phosphatidylinositol and other lipids on fetal rat septal neurons in culture

Neurite-promoting activities of lipids were assessed using serum-free cultures of fetal rat septal neurons. The most potent one was phosphatidylinositol (PI), followed by PI 4-phosphate, phosphatidylserine, sphingomyelin, and phosphatidylcholine. The EC50 value for PI was 1.5 micrograms/ml (1.8 microM), and activity was maximal at 4 micrograms/ml (56% of total cells had neurites after 24 h). Cerebroside, sulfatide, and di- and triacylglycerols showed relatively low activities. Synthetic dipalmitoyl phosphatidylcholine was also active, with a maximal activity (47%) at 100 micrograms/ml, a finding implying that the unsaturated fatty acid moiety is not released and further used as substrate for the arachidonic acid cascade. Lysophospholipids, phosphatidylglycerol, and cardiolipin were rather cytotoxic and lacked activity, an observation suggesting that membrane perturbation is not responsible for the neurite-promoting activity. Treatment with a protein kinase C inhibitor, H-7, or an Na+,K(+)-ATPase inhibitor, ouabain, inhibited the PI-induced neurite outgrowth, but the cyclic AMP- and cyclic GMP-dependent protein kinase inhibitor HA1004 did not inhibit this activity, a result indicating that multiple elements (protein kinase C and Na+,K(+)-ATPase) are involved in the induction of neurites. Because phospholipids can be provided either as lipid vesicles or as lipoproteins produced by macrophages at regeneration sites, they may play an important role in the regeneration of certain populations of neurons.

The NC1 domain of type IV collagen promotes axonal growth in sympathetic neurons through interaction with the alpha 1 beta 1 integrin

We have examined the effects of collagen IV on the morphological development of embryonic rat sympathetic neurons in vitro. In short-term (less than or equal to 24 h) culture, collagen IV accelerated process outgrowth, causing increases in the number of neurites and total neuritic length. Analysis of proteolytic fragments of collagen IV indicated that the NC1 domain was nearly as active as the intact molecule in stimulating process outgrowth; in contrast, the 7S domain and triple helix-rich fragments of collagen IV were inactive. Moreover, anti-NC1 antiserum inhibited neuritic outgrowth on collagen IV by 79%. In long-term (up to 28 d) cultures, neurons chronically exposed to collagen IV maintained a single axon but failed to form dendrites. Thus, the NC1 domain of collagen IV can alter neuronal development by selectively stimulating axonal growth. Comparison of collagen IV's effects to those of laminin revealed that these molecules exert quantitatively different effects on the rate of initial axon growth and the number of axons extended by sympathetic neurons. Moreover, neuritic outgrowth on collagen IV, but not laminin, was blocked by cycloheximide. We also observed differences in the receptors mediating the neurite-promoting activity of these proteins. Two different antisera that recognize beta 1 integrins each blocked neuritic outgrowth on both collagen IV and laminin; however, an mAb (3A3) specific for the alpha 1 beta 1 integrin inhibited collagen IV but not laminin-induced process growth in cultures of both sympathetic and dorsal root neurons. These data suggest that immunologically distinct integrins mediate the response of peripheral neurons to collagen IV and laminin.

Extracellular matrix molecules in development and regeneration of the leech CNS

As neurons grow to their targets their processes elongate, branch and form specialized endings into which are inserted appropriate ion channels. Our aim has been to analyse the role of the extracellular matrix molecules laminin and tenascin in inducing growth and in determining the form and physiological properties of growing neurites. A preparation in which development and regeneration can be followed at the cellular and molecular level in the animal and in tissue culture is the central nervous system (CNS) of the leech. In leech extracellular matrix (ECM) both laminin and tenascin are present; the molecules are structurally similar but not identical to their vertebrate counterparts. Tenascin extracted from leech ECM shows a typical hexabrachial structure whereas laminin shows a typical cruciform structure in rotary shadowed preparations. Leech laminin purified by means of a monoclonal antibody is a molecule of about 1000 kDa, with a polypeptide composition of 340, 200, 180 and 160 kDa. Substrates that contain tenascin or laminin produce rapid and reliable outgrowth of neurites by identified cells. A remarkable finding is that the outgrowth pattern produced by an individual neuron depends in part on its identity, in part on the substrate upon which it is placed. For example, a Retzius cell grows in a quite different configuration and far more rapidly on laminin substrate than does another type of neuron containing the same transmitter (serotonin); and the pattern of outgrowth of the Retzius cell is different on laminin and on the plant lectin Con A (concanavalin A). Thus Con A induces the growth of processes that are shorter, thicker, more curved and contain fewer calcium channels than those grown on laminin. To determine whether laminin can also influence neurite outgrowth in the animal, immunocytological techniques have been used to follow its distribution in the extracellular matrix of normal, developing and regenerating leech CNS. In adult leeches neuronal processes in the CNS are not in contact with laminin which is confined to the surrounding extracellular matrix. In embryos however, laminin staining appears between ganglionic primordia along the pathways that neurons will follow. Similarly, after injury to the adult CNS, laminin accumulates at the very sites at which sprouting and regeneration begin. How the laminin becomes redistributed to appear in the region of injury has not yet been established. Together these findings suggest a key role for laminin and for other extracellular matrix molecules.(ABSTRACT TRUNCATED AT 250 WORDS)

The neuronal growth cone as a specialized transduction system

Neuronal growth and remodelling are guided by both intracellular gene programs and extracellular stimuli. The growth cone is one site where the effects of these extrinsic and intrinsic factors converge upon the mechanical determinants of cell shape. We review the growth cone as a transduction device, converting extracellular signals into mechanical forces. A variety of soluble, extracellular matrix and membrane bound molecules control growth cone behavior. In addition, GAP-43 is discussed as a possible component of the intraneuronal gene program which modulates growth cone activity. The GTP-binding protein, Go, is a major growth cone membrane protein that may transduce signals not only from outside the cell, but from within as well. This may provide a molecular site in the growth cone for the coordination of a genetic growth program with environmental signals.

Identification of meningeal cell released neurite promoting activities for embryonic hippocampal neurons

Primary cultures of meningeal cells from embryonic rat cerebra secrete neurite growth-inducing components into serum-free culture medium. This conditioned medium (CM) was analyzed by FPLC and immunochemical and enzymatic treatments and tested for neurite promoting activity (NPA) in a quantitative bioassay using hippocampal neurons from embryonic rat. By immunoprecipitation or specific adsorption we identified laminin (LN)-proteoglycan complexes and fibronectin (FN), respectively, as the major neurite promoting components within meningeal cell CM. The LN-proteoglycan complexes and their NPA were sensitive to chondroitinase (chondroitin ABC lyase, EC 4.2.2.4) and to a smaller extent to heparitinase (heparitin sulfate lyase, EC 4.2.2.8). Minor fractions of the total NPA in CM correlated with free LN and a putative but not yet characterized FN-proteoglycan complex.

Isolation and biochemical characterization of a neural proteoglycan expressing the L5 carbohydrate epitope

The monoclonal L5 antibody reacts with an N-glycosidically linked carbohydrate structure which is present on the neural cell adhesion molecule L1, neural chondroitin sulfate proteoglycans, and other not yet identified glycosylated proteins. Using this antibody, we isolated and characterized proteoglycans from adult mouse brain and cultured astrocytes biosynthetically labeled with Na2 35SO4 and a 3H-amino acid mixture. Our data suggest that the L5 proteoglycans of both sources are identical in their biochemical properties. The apparent molecular mass of the L5 proteoglycan is approximately 500 kDa. Digestion of the iodinated L5 proteoglycan from mouse brain and of the [35S]methionine-labeled L5 proteoglycan from cultured astrocytes with proteinase-free chondroitinases ABC and AC revealed three major core proteins with apparent molecular masses of approximately 380, 360, and 260 kDa. These represent molecularly distinct protein cores.

Enhanced expression of the extracellular matrix molecule J1/tenascin in the regenerating adult mouse sciatic nerve

We have investigated the expression of J1/tenascin in the sciatic nerve of the adult mouse under normal and regenerating conditions by immunocytological and immunochemical methods. In the normal nerve, J1/tenascin expression was confined to the extracellular matrix at the node of Ranvier and in the perineurium. At 2 days after nerve transection, J1/tenascin was detectable in the fibroblast-containing caps of the distal and proximal nerve stumps, in the distal nerve stump along its entire length and in the distal end of the proximal nerve stump. In the nerve stumps immunoreactivity was predominantly associated with extracellular matrix consisting of collagen fibrils and Schwann cell basal laminae. Approximately 7 days after transection, the caps of the nerve stumps had usually grown together forming a bridge. This bridge consisted of a J1/tenascin-negative perineurium-like structure and an inner part of predominantly fibroblasts, endothelial cells and macrophages. All cell types in this inner part were embedded in a J1/tenascin-positive matrix of collagen fibrils indicating the prospective direction of growth of neural elements. A few days later, J1/tenascin in the bridge was confined to the extracellular matrix around small Schwann cell-containing nerve fascicles. In nerves chronically denervated for 19 days, J1/tenascin was poorly detectable in the cap of the distal stump, although Schwann cells had infiltrated this cap. Approximately 19 days after the lesion, J1/tenascin expression returned to control levels in the proximal nerve stump. In the distal nerve stump, J1/tenascin immunoreactivity reached a peak at approximately 14 days after nerve transection and vanished only at approximately 35 days, thus correlating with the time of active regrowth of axons into the distal nerve stump. This reduction was prevented by chronic denervation, suggesting that reinnervation of target structures may be related to the down-regulation of J1/tenascin. These combined observations suggest that J1/tenascin is differentially regulated in the individual parts of the regenerating nerve, possibly triggered by different cellular and molecular signals.

A dual laminin/collagen receptor acts in peripheral nerve regeneration

A regeneration chamber was created in vivo by suturing a synthetic tube sealed at its distal end onto the proximal stump of a severed rat sciatic nerve. Nerves regenerated into tubes coated with laminin at a rate of 0.33 mm/day after a lag of about 2 days. At 25 days, regenerating nerves had extended 23% farther into laminin-coated tubes as compared with uncoated ones. Monoclonal antibody 3A3, which functionally interferes with a dual laminin/collagen receptor, inhibited nerve regeneration into laminin-coated tubes by 32%. In contrast, monoclonal antibody JG22, which inhibits chicken matrix receptors, had no significant effect on regeneration. Immunohistochemical studies of teased adult rat sciatic nerves indicate that 3A3 bound to Schwann cells and possibly to axons. In other studies, the heterodimeric, laminin/collagen receptor recognized by 3A3 has been shown to be a member of the integrin superfamily of adhesive receptors. These data provide evidence that an integrin receptor functions in nerve regeneration in vivo.

Adhesion molecules and animal development

In recent years considerable progress has been made in the identification and characterization of molecules that mediate cell adhesion during animal development. This review attempts to pick out from the vast amount of information in this rapidly expanding field some of the key features of adhesion molecules, to present ideas about their role in development, and to indicate the directions in which the field is now moving.

Distribution and biochemical characterization of the INO antigen during chick neural crest cell migration

The INO (inhibitor of neurite outgrowth) antibody recognizes a laminin-heparan sulfate proteoglycan complex and was isolated for its ability to functionally inhibit axonal outgrowth of peripheral neurons. Here, we examine the distribution and biochemical characteristics of INO in the early chick embryo. Because the INO antigen is sensitive to most classical fixation procedures and fixation leads to abundant nuclear staining, the antibody was directly injected into 1.5-2.5-day-old embryos prior to fixation. The distribution of the injected antibody was then observed in cryostat sections by indirect immunofluorescence. Particular attention was focussed upon regions of ongoing neural crest cell migration. The INO antigen was observed along both cranial and trunk neural crest cell migratory pathways. The antigen was seen around the basement membrane surrounding the neural tube and notochord, and underneath the ectoderm and endoderm. In addition, fibrillar staining was observed in the cranial mesenchyme and in both rostral and caudal halves of the somitic sclerotome in the trunk. The distribution pattern was identical to that previously observed for laminin or heparan sulfate proteoglycan. To confirm the nature of the INO antigen, we performed immunoprecipitations of chick embryos ranging from 1.5 to 9 days of incubation. Half of each sample was digested with heparinase prior to SDS-PAGE and silver staining. In material from young embryos, bands of 200 and 180 kD (probably corresponding to the B-chains of laminin) plus two broad smears of bands at 180-150 kD and 130-85 kD were observed without heparinase digestion. Following enzymatic digestion, the 200-kD and 180-kD bands remained, while the smears disappeared and were replaced by numerous low-molecular-weight bands. In contrast to preparations from young embryos, samples taken from embryos at day 3 or beyond did not enter the 8% gel without heparinase digestion, though the banding pattern appeared identical to younger samples after heparinase digestion in the presence or absence of Ca2+. This change in the INO antigen with age could result from an increase in the heparin-side-chains attached to similar core proteins, or from an increase in the stability of the laminin-heparan sulfate proteoglycan containing complex with time.

Laminin and a basement membrane extract have different effects on axonal and dendritic outgrowth from embryonic rat sympathetic neurons in vitro

We have characterized the effects of laminin and a basement membrane extract (BME) on the morphology of embryonic rat sympathetic neurons maintained in tissue culture in the absence of nonneuronal cells. Neurons were grown on polylysine-coated coverslips in the presence or absence of laminin or BME in serum-free medium. Axons were distinguished from dendrites using intracellular dye injections, immunocytochemistry, and [3H]uridine autoradiography. In short-term (less than or equal to 24 hr) culture, laminin had a potent neurite-promoting effect, causing increases in the number of processes, total neuritic length, and neuritic branching. In long-term (3-35 days) cultures chronically exposed to laminin, most (greater than 75%) neurons maintained supernumerary axons but failed to form dendrites. In contrast, most neurons (greater than 70%) grown in long-term culture on polylysine in the absence of laminin were unipolar, extending a single axon. BME caused sympathetic neurons to extend multiple (range, 1-15) dendrites. Morphometric measurements made after 1 month of exposure to BME indicated that the amount of dendritic growth that occurred in vitro was similar to that normally occurring during a comparable period in situ. BME did not cause changes in the number of axons per neuron or in the uptake of neurotransmitter. Preliminary characterization of the dendrite-promoting activity of BME suggests that it resides in extracellular matrix (ECM) molecules and not in low-molecular weight contaminants. These observations indicate that (1) axonal and dendritic growth may be differentially regulated by various constituents of the ECM, and (2) such process-specific interactions can significantly affect the morphological development of sympathetic neurons.

Transient modulation of Schwann cell antigens after peripheral nerve transection and subsequent regeneration

Schwann cells within the distal portion of a transected nerve undergo a series of poorly understood events in response to injury and loss of axonal contact. These events may influence the regeneration of PNS neurons. In this study we examined the alteration of antigens located in the basal lamina, plasma membrane and cytoplasm of Schwann cells within the distal nerve stump: (a) after a complete transection of the sciatic nerve, and (b) subsequent to reestablished contact between regenerating axons and dedifferentated Schwann cells separated from contact with neurons. Visualization of laminin and heparan sulphate proteoglycan molecules at various intervals after nerve transection always revealed intact basal lamina channels. In response to loss of axonal contact, vimentin expression by Schwann cells within the distal nerve stump increased, becoming a predominant intermediate filament protein of the cytoskeleton while glial fibrillary acid protein (GFAP) expression decreased. This reversal in the prominence of intermediate filament protein was maintained until the onset of axonal reinnervation, at which point expression of GFAP increased and vimentin decreased. Expression of the Schwann cell plasma membrane associated protein, C4, closely mimicked GFAP expression during axon degeneration and subsequent reinnervation. In the normal uninjured nerve, tissue plasminogen activator (tPA) and S-100 were localized in the region near the Schwann cell-axon interface and the outer Schwann cell plasma membrane. In response to loss of axonal contact, the S-100 and tPA immunoreactivity associated with the Schwann cell-axon interface was lost while that localized around the outer Schwann cell plasma membrane remained unchanged. The results of this study demonstrate that Schwann cells modulate a portion of their antigenic repertoire in response to a loss of axonal contact and after contact with regenerating axons.

A laminin-pepsin fragment with cell attachment and neurite outgrowth activity at distinct sites

Laminin is a large basement membrane glycoprotein which influences the behavior and morphology of a variety of cells. We have found that laminin and a pepsin fragment of laminin (P-lam) contain distinct sites for HT-1080 human fibrosarcoma cell attachment and for neurite outgrowth activity of PC12 and NG108-15 cell lines. Reduction and alkylation of laminin and P-lam fragment disulfide bonds, in the absence of denaturing agents, markedly reduced the cell attachment activity without reducing the neurite outgrowth response. The P-lam fragment (approximately 375 kDa) was found to contain part of the cross region of laminin and a portion of the long arm, on the basis of recognition by antisera against laminin synthetic peptides and fusion proteins. Modification of arginine residues by cyclohexanedione also had no effect on neurite outgrowth but reduced HT-1080 cell adhesion. Modification of lysine residues by succinic and citraconic anhydride, however, abolished laminin neurite outgrowth but not cell attachment activity. Neurite outgrowth activity was recovered by reversing the lysine modification. These data support the existence on laminin of separate sites for cell attachment and for neurite outgrowth.

How well do we understand neurotrophic factors and the control of CNS neuronal growth?

The review of Hefti et al. (7) presents current theories and concepts about the functions and activities of neurotrophic factors (NTF). The validity of several components and assumptions may be questionable. Should NTFs be divided into small diffusible survival-promoting factors and large, insoluble neurite-promoting factors? How are NTFs and neurotransmitters related? Do neurons need one or several NTFs? Can NTFs be multifunctional trophic factors? Are there endogenous inhibitory modulators of neuronal growth? Answers to these questions may have significant impact on the design of therapies using NTFs.

Immunoreactivity in pituitary gonadotropes and hypothalamic vasopressinergic neurons for the monoclonal antibody INO

The monoclonal antibody INO (inhibitor of neurite outgrowth) has been shown to bind to a complex of laminin and a heparan sulfate proteoglycan and to block the action of this complex in promoting neurite outgrowth. We now report that the same antibody binds to cytoplasmic constituents in rat adenohypophyseal gonadotropes, as well as to vasopressinergic neurons in the hypothalamus and their terminals in the neurohypophysis. INO immunoreactivity in fixed sections of pituitary does not colocalize with the immunoreactive laminin in blood vessels and glandular basement membranes, although when unfixed tissue is washed in buffer prior to fixation, the INO immunoreactivity appears in these laminin-rich structures. These observations suggest similarities between the INO hypophyseal antigen and the neurite-promoting proteoglycan complex characterized in conditioned media. Presence of this complex in specific neurosecretory cell types suggests that it is involved with specific secretory products with function yet to be determined.

Purification and characterization of mammalian integrins expressed by a rat neuronal cell line (PC12): evidence that they function as alpha/beta heterodimeric receptors for laminin and type IV collagen

Cells of the rat neuronal line, PC12, adhere well to substrates coated with laminin and type IV collagen, but attach poorly to fibronectin. Adhesion and neurite extension in response to these extracellular matrix proteins are inhibited by Fab fragments of an antiserum (anti-ECMR) that recognizes PC12 cell surface integrin subunits of Mr 120,000, 140,000, and 180,000 (Tomaselli, K. J., C. H. Damsky, and L. F. Reichardt. 1987. J. Cell Biol. 105:2347-2358). Here we extend our study of integrin structure and function in PC12 cells using integrin subunit-specific antibodies prepared against synthetic peptides corresponding to the cytoplasmic domains of the human integrin beta 1 and the fibronectin receptor alpha (alpha FN) subunits. Anti-integrin beta 1 immunoprecipitated a 120-kD beta 1 subunit and two noncovalently associated integrin alpha subunits of 140 and 180 kD from detergent extracts of surface-labeled PC12 cells. Immunodepletion studies using anti-integrin beta 1 demonstrated that these two putative alpha/beta heterodimers are identical to those recognized by the adhesion-perturbing ECMR antiserum. Anti-alpha FN immunoprecipitated fibronectin receptor heterodimers in human and rat fibroblastic cells, but not in PC12 cells. Thus, low levels of expression of the integrin alpha FN subunit can explain the poor attachment of PC12 cells to FN. The PC12 cell integrins were purified using a combination of lectin and ECMR antibody affinity chromatography. The purified integrins: (a) completely neutralize the ability of the anti-ECMR serum to inhibit PC12 cell adhesion to laminin and collagen IV; (b) have hydrodynamic properties that are very similar to those of previously characterized integrin alpha/beta heterodimeric receptors for ECM proteins; and (c) can be incorporated into phosphatidylcholine vesicles that then bind specifically to substrates coated with laminin or collagen IV but not fibronectin. Thus, the ligand-binding specificity of the liposomes containing the purified PC12 integrins closely parallels the substrate-binding preference of intact PC12 cells. These results demonstrate that mammalian integrins purified from a neuronal cell line can, when incorporated into lipid vesicles, function as receptors for laminin and type IV collagen.

A monoclonal antibody against a laminin-heparan sulfate proteoglycan complex perturbs cranial neural crest migration in vivo

INO (inhibitor of neurite outgrowth) is a monoclonal antibody that blocks axon outgrowth, presumably by functionally blocking a laminin-heparan sulfate proteoglycan complex (Chiu, A. Y., W. D. Matthew, and P. H. Patterson. 1986. J. Cell Biol. 103: 1382-1398). Here the effect of this antibody on avian neural crest cells was examined by microinjecting INO onto the pathways of cranial neural crest migration. After injection lateral to the mesencephalic neural tube, the antibody had a primarily unilateral distribution. INO binding was observed in the basal laminae surrounding the neural tube, ectoderm, and endoderm, as well as within the cranial mesenchyme on the injected side of the embryo. This staining pattern was indistinguishable from those observed with antibodies against laminin or heparan sulfate proteoglycan. The injected antibody remained detectable for 18 h after injection, with the intensity of immuno-reactivity decreasing with time. Embryos ranging from the neural fold stage to the 9-somite stage were injected with INO and subsequently allowed to survive for up to 1 d after injection. These embryos demonstrated severe abnormalities in cranial neural crest migration. The predominant defects were ectopic neural crest cells external to the neural tube, neural crest cells within the lumen of the neural tube, and neural tube deformities. In contrast, embryos injected with antibodies against laminin or heparan sulfate proteoglycan were unaffected. When embryos with ten or more somites were injected with INO, no effects were noted, suggesting that embryos are sensitive for only a limited time during their development. Immunoprecipitation of the INO antigen from 2-d chicken embryos revealed a 200-kD band characteristic of laminin and two broad smears between 180 and 85 kD, which were resolved into several bands at lower molecular mass after heparinase digestion. These results indicate that INO precipitates both laminin and proteoglycans bearing heparan sulfate residues. Thus, microinjection of INO causes functional blockage of a laminin-heparan sulfate proteoglycan complex, resulting in abnormal cranial neural crest migration. This is the first evidence that a laminin-heparan sulfate proteoglycan complex is involved in aspects of neural crest migration in vivo.