Biologically active sequence (KDI) mediates the neurite outgrowth function of the gamma-1 chain of laminin-1.

A neurite outgrowth domain of the gamma1-chain of laminin-1 (RDIAEIIKDI) promotes axon guidance of rat hippocampal neurons, regulates the nuclear movement phase of neuronal migration, and binds to the cellular prion protein (Liesi et al. [1995] J. Neurosci. Res. 134:447-486; Matsuzawa et al. [1998] J. Neurosci. Res. 53:114-124; Graner et al. [2000] Brain Res. Mol. Brain Res. 76:85-92). Using electrophysiology and neuronal culture experiments, we show that this 10 amino acid peptide or its smaller domains induces potassium currents in primary central neurons. Both these currents and the neurotoxicity of high concentrations of the 10 amino acid peptide antigen are prevented by pertussis toxin. The smallest peptide domain capable of inducing both potassium currents and promoting neurite outgrowth of human spinal cord neurons is a tri-peptide KDI. Our results indicate that KDI may be the biologically active domain of the gamma1 laminin, capable of modulating electrical activity and survival of central neurons via a G-protein coupled mechanism. These results expand the wide variety of functions already reported for the members of the laminin-gene family. They suggest that biologically active peptide domains of the gamma1 laminin may provide tools to promote neuronal regeneration after injuries and to enhance neuronal survival during aging and neuronal degeneration.

Involvement of non-NMDA receptors in the rescue of weaver cerebellar granule neurons and sensitivity to ethanol of cerebellar AMPA receptors in oocytes.

The cellular mechanism responsible for the death of cerebellar granule neurons in the weaver mutant mouse is still being intensely investigated. To determine if alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) glutamate receptors are involved in producing the weaver phenotype or are altered by the weaver gene, we used (1) reverse transcription and polymerase chain reaction (RT-PCR) to detect transcripts of glutamate receptors (GluR1-4) from wild-type and mutant cerebella; (2) immunocytochemistry to establish the types of glutamate receptors present in granule neurons cultured from normal and homozygous weaver postnatal day 5-6 (P5-6) cerebella; (3) 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX), a blocker of glutamate (AMPA/Kainate/NMDA) receptors, and 6,7-dinitroquinoxaline-2,3-dione (NBQX), a blocker of AMPA and kainate receptors, to assess the number of neurons and the number of neurons with long neurites in cultures of homozygous weaver granule neurons; (4) two-electrode voltage clamp recordings to study AMPA glutamate receptor expression in Xenopus oocytes after injection of mRNA isolated from cerebella of normal and weaver P5-6, postnatal day 10 (P10) and postnatal day 23 (P23) mice; and (5) ethanol, which at low 1-10 mM concentrations had been shown previously to rescue homozygous weaver granule neurons in culture [Liesi et al., J. Neurosci. Res. 48 (1997) 571-579], to examine its effect on modulation of AMPA receptors expressed from mRNA. By RT-PCR, the mRNA coding for AMPA receptor subunits GluR1-4 were detected from +/+ and wv/wv cerebella, and by immunocytochemistry, GluR1, GluR2/3 and GluR4 were observed to be expressed in cultured +/+ and wv/wv granule cells. CNQX at 10 microM or NBQX at 10 microM significantly increased the number of surviving neurons and the number with long neurites as compared to wv/wv controls. In addition, CNQX was significantly more effective than NBQX. In oocytes injected with mRNA from P10 normal or weaver cerebella, the amplitudes of the responses to kainate were about equal. In contrast, the amplitudes of the kainate-activated currents in oocytes injected with weaver P23 mRNA were about twice as large as the currents observed in oocytes injected with mRNA from normal P23 cerebella, and both were larger than kainate-activated currents observed after injection of P10 normal and weaver mRNA. Kainate-activated AMPA receptor currents in oocytes injected with mRNA from P10 and P23 normal and homozygous weaver cerebella were inhibited by ethanol. There were no significant differences in the inhibition produced by ethanol on currents from P10 or P23 normal and wv/wv mRNA. Thus, P23 weaver cerebellar mRNA expressed more kainate-activated current in oocytes than P23 normal cerebellar mRNA; both normal and weaver cerebellar granule neurons express mRNA coding for functional AMPA receptors that are susceptible to ethanol inhibition.

Neurons and glial cells of the embryonic human brain and spinal cord express multiple and distinct isoforms of laminin.

We have identified by immunocytochemistry, Western blotting, and RT-PCR the isoforms of laminin expressed by glial cells and neurons cultured from human embryonic brain and spinal cord. We show that most of the known laminins are present in human neurons and glial cells. Importantly, Western analysis demonstrates that the isoforms of laminin present in embryonic human brain differ from those expressed in human spinal cord. Neurons of the brain and spinal cord also express their distinct and characteristic isoforms of laminin compared to the glial cells of the same CNS regions. These results suggest that, in addition to the known laminins, several novel isoforms may exist in the human embryonic CNS. The observed differences between the isoforms of laminin in brain and spinal cord neurons and glial cells may result from primary structural changes or from posttranslational modifications, e.g., variations in glycosylation. Thus, identification of these novel laminins and determination of their function(s) should further our understanding of the mechanisms of aging, disease, and trauma in the human CNS.

Involvement of GIRK2 in postnatal development of the weaver cerebellum.

We demonstrate that the homozygous weaver granule neurons cultured on a laminin substratum fail to express inwardly rectifying potassium currents, including a functional G-protein coupled inwardly rectifying potassium (GIRK)2 potassium channel. By contrast, both normal and weaver Purkinje cells express inwardly rectifying potassium currents, and normal granule cells exhibit inwardly rectifying potassium currents inducible with GTP-gamma-S. In protein extracts of the vermal postnatal day (P)5-9 weaver cerebellum, the GIRK2 protein could not be detected by Western analysis, although the GIRK2 protein was detectable in extracts of the normal vermis. Northern analysis indicated that during early postnatal cerebellar development, the GIRK2 mRNA is expressed at extremely low levels being detectable at P18-23 in the normal but not yet in the homozygous weaver cerebellum. Using reverse transcriptase-polymerase chain reaction (RT-PCR), the GIRK2 mRNA was detected in both normal and weaver cerebella, but quantitative PCR confirmed that the weaver cerebellum expressed the GIRK2 gene at significantly lower levels as compared to the normal cerebellum (P = 0.01, paired t-test). Sequencing indicated that the weaver GIRK2 channel gene had the point mutation proposed to be responsible for the weaver phenotype. Rescue of both survival and neurite outgrowth of the cultured vermal weaver granule neurons by verapamil (Liesi and Wright, 1996; Liesi et al., 1999) induced expression of immunocytochemically detectable levels of the GIRK2 protein. Sequencing revealed that the GIRK2 mRNA of the rescued weaver granule neurons remained the mutated variant of the GIRK2 channel gene. Our results indicate that expression of the mutated GIRK2 protein and/or mRNA in the weaver granule neurons may be an indicator of rescue rather than death of the weaver granule neurons. That the weaver granule neurons expressed no functional GIRK2 receptors during a time period of neuronal death and migration failure suggests that the point mutation in the H5 membrane spanning region of the GIRK2 gene may associate with, but not be responsible for the weaver phenotype.

Neurofilament proteins are constitutively expressed in F9 teratocarcinoma cells.

We examined neuronal differentiation of F9 teratocarcinoma cells using retinoic acid (RA) and cyclic AMP (cAMP) as inducing agents. Neuronal differentiation was monitored using (1) cDNA probes for the rat 68-kDa neurofilament gene, (2) RT-PCR for neurofilament genes and (3) antibodies against several neuronal differentiation markers. We found by Northern blotting that the uninduced F9 cells, grown in 10% serum, expressed mRNA for the 68-kDa neurofilament protein whereas the control cells, grown in 3% serum, failed to express detectable levels of the 68-kDa neurofilament transcripts. However, RT-PCR allowed detection of both the 68- and 200-kDa neurofilament gene transcripts in F9 cells with or without the inducing agents. Under serum deprivation, a prolonged (> 10-15 days) cultivation of the F9 cells in the presence of RA and cAMP was required for the expression of detectable levels of the 68-kDa neurofilament transcripts and immunocytochemically detectable neurofilament proteins. Treatment of the F9 cells with RA and cAMP was also required for induction of their neuronal phenotype. Immunocytochemically, the uninduced F9 cells expressed several neuronal antigens including the 68-kDa neurofilament protein, the 200-kDa neurofilament protein, neural cell adhesion molecule (N-CAM) and a neuronal specific tubulin isoform (TUJI). The control cells expressed N-CAM and TUJI, but failed to express the neurofilament proteins. A subclone, D9L2, derived from a single F9 parent cell, expressed both TUJI and neurofilament proteins, but no N-CAM molecule. The present results indicate that both the 68- and the 200-kDa neurofilament genes are constitutively active in uninduced F9 teratocarcinoma cells. Under serum deprivation both RA and cAMP are required for expression of detectable levels of neurofilament mRNA and protein. Thus, serum deprivation of the F9 cells either down-regulates the NF gene expression, stability of mRNA or degradation of the NF-proteins. Importantly, expression of a neuronal phenotype by a subpopulation of F9 cells appears to require administration of RA and cAMP, although expression of neuronal marker proteins is not dependent on these agents. Lastly, we demonstrate cloning of a novel cell line (D9L2), derived from a single F9 parent cells, capable of extending neurites and expressing several neuronal antigens under serum deprivation without the requirement of RA and cAMP. We propose that the D9L2 cell line may offer a simplified F9 cell model system to investigate the mechanisms of neuronal differentiation.

Weaver cerebellar granule neurons show altered expression of NMDA receptor subunits both in vivo and in vitro.

Biochemical, immunocytochemical, and molecular biological techniques were used to investigate the expression of N-methyl-D-aspartate (NMDA) receptor subunits in migration-deficient weaver mouse cerebellum in vivo and in primary cultures of the vermal weaver granule neurons with or without a rescue by verapamil. We found that both NMDAR1(zeta1) message and protein were expressed by the weaver granule neurons in situ. Immunocytochemical and biochemical analyses indicated that granule neurons of the weaver cerebellum expressed R1(zeta1) and R2A(epsilon1) subunits but showed little expression of the R2B(epsilon2) subunit. In weaver cerebellum, the R2B(epsilon2) subunit was primarily expressed in nerve fibers of the internal granule cell layer and white matter. Reverse-transcriptase-polymerase chain reaction followed by sequence analysis of the R1(zeta1) subunit indicated that the zeta1 subunit amplicons of both normal and weaver cerebella were identical, and that splice variants with exon 22 (1-2) and with or without exon 5 (a/b) or exon 21 (1-4) were detectable. The R2A(epsilon1), and R2B(epsilon2) subunits of the normal and weaver mouse cerebellum revealed no primary structural differences between the normal and weaver NMDA receptor subunits or the cloned mouse NMDA receptor subunits. In vermal cultures, normal granule neurons expressed all three NMDA receptor subunits (zeta1, epsilon1, and epsilon2), whereas the weaver neurons failed to express the epsilon2 subunit. Rescue of the weaver neurons by verapamil induced expression of the epsilon2 protein along the granule neuronal surfaces. The present results suggest that lack of the epsilon2 subunit in the weaver cerebellum may relate to the lack of functional NMDA receptors and/or to the migratory failure of the weaver granule neurons. Our data further suggest that NMDA receptor-mediated neurotoxicity is an unlikely mediator of neuronal death of the weaver granule neurons. In fact, down-regulation of the NMDA receptor expression and function may be a protective measure of the weaver granule neurons to reduce calcium entry via these receptors.

Molecular gradient along the axon pathway is not required for directional axon growth.

We show that axon guidance of embryonic hippocampal neurons is promoted by pathways of a decapeptide (RDIAEIIKDI) derived from a neurite outgrowth domain of the gamma1 chain of laminin-1. This guidance is directly dependent on: (1) a concentration difference of the decapeptide between the peptide pathway and its surrounding areas, and (2) the optimal surface geometry of the decapeptide pathway. These results indicate that axon guidance of central neurons may proceed along a preferred substratum pathway without a concentration gradient of the guiding molecule along this pathway, or without a repulsive molecule next to the axon pathway.

Use of paper for treatment of a peripheral nerve trauma in the rat.

Reinnervation of the muscles and skin in the rat hindpaw was studied after transection and attempted repair of the sciatic nerve. Reconnecting the transected nerve with lens cleaning paper was at least as effective in rejoining the transected nerves as traditional microsurgical neurorraphy. Paper induced a slightly bigger fibrous scar around the site of transection than neurorraphy, but this scar did not cause impairment of functional recovery or excessive signs of neuropathic pain. We conclude that a paper graft can be used in restorative surgery of severed peripheral nerves.

BAPTA-AM and ethanol protect cerebellar granule neurons from the destructive effect of the weaver gene.

The mechanisms by which the weaver gene (Reeves et al., 1989; Patil et al., 1995) inhibits neurite extension and/or induces death of the granule neurons in homozygous weaver mouse cerebellum are not presently understood. Here we show that BAPTA-AM and ethanol, which either reduce cytosolic levels of free calcium or prevent calcium entry, promote neurite outgrowth of the weaver neurons similar to the L-type calcium channel blocker verapamil (Liesi and Wright, 1996). Importantly, BAPTA-AM, ethanol, and verapamil not only restore neurite outgrowth of the weaver neurons but adjust their depolarized resting membrane potentials to the levels of normal neurons. These results indicate that calcium-dependent mechanisms mediate the action of the weaver gene and that the weaver neurons can be normalized by blocking this calcium effect. We further report that BAPTA-AM and verapamil also have a neuroprotective effect on normal neurons exposed to high concentrations of ethanol. We suggest that verapamil should be evaluated as a drug for treatment of alcohol-induced brain damage and neurodegenerative disorders.

Ethanol-exposed central neurons fail to migrate and undergo apoptosis.

Prenatal exposure of human brain to ethanol impairs neuronal migration and differentiation and causes mental retardation. The present results indicate that the adverse effects of ethanol on brain development may be partly due to the ethanol-induced disturbance of neuronal interaction with laminin, a protein involved in neuronal migration and axon guidance. This report shows that physiological concentrations (IC50 = 28 mM) of ethanol inhibit neurite outgrowth and neuronal migration of the rat cerebellar granule neurons on a laminin substratum. The ethanol-treated granule neurons undergo apoptosis, degrade their laminin substratum, and appear to release and bind increased amounts of the B2-chain-derived peptides along their surfaces. A protease inhibitor aprotinin, and the NMDA receptor channel, and voltage-gated calcium channel antagonist MK801 partially protect cerebellar granule neurons from ethanol-induced neurotoxicity. These results imply that ethanol-treated granule neurons resemble the granule neurons of the homozygous weaver mouse cerebellum with respect to their apoptosis, laminin expression, and partial rescue by approtinin and MK-801. Thus, ethanol may influence neuronal survival and neurite outgrowth via molecular pathways similar to those involved in neuronal death in other neurodegenerative processes of the central nervous system.

Chemically modifying glass surfaces to study substratum-guided neurite outgrowth in culture.

We describe here a modification procedure for chemically fabricating neuron adhesive substrates to study the substratum-guided neurite outgrowth in culture. These substrates were fabricated by chemically attaching a synthetic peptide derived from a neurite-out-growth-promoting domain of the B2 chain of laminin. The attachment was carried out by coupling the peptide to an amine-derived glass surface using a heterobifunctional crosslinker. Hippocampal neurons were dissociated from embryonic rats and placed on the substrate at low-density in a chemically defined medium to examine the direct effect of the modified surface on their outgrowth. We observed that the neurons developed a morphology typical to that of hippocampal neurons having multiple short and single long processes within 24 h in culture. The chemical modification procedure was then combined with a UV-photo-masking technique to fabricate patterns of peptide surface on glass substrates. By culturing the hippocampal neurons on substates having alternate stripes of peptide surface and non-adhesive surface, we demonstrated substratum-controlled changes in the neuronal morphology. The modification procedure presented here can be easily achieved in the standard culture facility and should be useful in fabricating an in vitro tool for studying substratum-guided neurite outgrowth.

Weaver granule neurons are rescued by calcium channel antagonists and antibodies against a neurite outgrowth domain of the B2 chain of laminin.

The weaver mutation impairs migration of the cerebellar granular neurons and induces neuronal death during the first two weeks of postnatal life. To elucidate the molecular mechanisms for the impaired neuronal migration, we investigated the rescue mechanisms of the weaver (wv/wv) granule neurons in vitro. We found that Fab2 fragments of antibodies against a neurite outgrowth domain of the B2 chain of laminin enhanced neurite outgrowth and neuronal migration of the weaver granule neurons on a laminin substratum and in the established cable culture system. The rescue of the weaver granule neurons by antibodies against the B2 chain of laminin may result from the neutralizing effect of these antibodies against the elevated B2 chain levels of the weaver brain. The L-type calcium channel blocker, verapamil (1-5 microM), also rescued the weaver granule neurons. High concentrations of MK-801 (10-20 microM), a glutamate receptor antagonist and voltage-gated calcium channel blocker, rescued the weaver granule neurons similar to verapamil, but low concentrations of MK-801 (1 microM) had no rescue effect. Simultaneous patch-clamp studies indicated that the weaver granule neurons did not express functional N-methyl-D-aspartate receptors further indicating that the rescue of the weaver granule neurons by MK-801 resulted from its known inhibition of voltage-gated calcium channels. The present results indicate that antibodies against the B2 chain of laminin, verapamil, and high concentrations of MK-801 protect the weaver granule neurons from the otherwise destructive action of the weaver gene. Thus, both the laminin system and calcium channel function contribute to the migration deficiency of the weaver granule neurons.

Directional neurite outgrowth and axonal differentiation of embryonic hippocampal neurons are promoted by a neurite outgrowth domain of the B2-chain of laminin.

Molecular cues involved in directional neurite outgrowth and axonal differentiation of embryonic hippocampal neurons were studied on substrates coated in a striped 5 microns pattern with synthetic peptides from a neurite outgrowth (RDIAEIIKDI, P1543) and cell attachment (CDPGYIGSR, P364) domain of the B2- and B1-chains of laminin, respectively. Both peptides supported neuronal attachment, but only the B2-chain-derived P1543 promoted expression of a mature neuronal phenotype. Directional neurite outgrowth and axonal differentiation of embryonic hippocampal neurons were selectively induced by striped substrates of the B2-chain-derived P1543. Axonal differentiation was determined by expression of a phosphorylated epitope of the 200 kDa neurofilament protein in the longer "axonal" neurite of the bipolar embryonic hippocampal neurons. Ethanol (100 mM), a neuroactive compound known to delay neuronal development, impaired both directional neurite outgrowth and expression of a phosphorylated epitope of the 200 kDa neurofilament protein on a patterned P1543 substratum. The present results provide direct evidence that a 10 amino acid peptide (P1543), derived from a neurite outgrowth domain of the B2-chain of laminin, may be an axonal guidance and differentiation factor for embryonic hippocampal neurons in vitro.

Increased proteolytic activity of the granule neurons may contribute to neuronal death in the weaver mouse cerebellum.

The weaver mouse mutation is a genetic defect of unknown origin that leads to impairment of cerebellar granule neuronal migration and to neuronal cell death. We investigated laminin expression and proteolytic enzyme activity in this migration-deficient mouse mutant in vivo and in vitro to search for a molecular basis for the weaver defect. The weaver cerebellum showed a general increase in immunoreactivity for laminin, for a neurite outgrowth domain of the B2 chain of laminin, and for tissue plasminogen activator compared to the normal animals. Zymographic assays and immunocytochemistry confirmed that tissue plasminogen activator was the proteolytic enzyme synthesized in excess in the weaver mouse cerebellum in vivo. When placed in culture, the weaver granule neurons survived poorly on a laminin substratum, and failed to extend long neurites, unlike the normal cerebellar granule neurons. The cultured weaver granule neurons were proteolytically overactive and secreted excessive amounts of tissue plasminogen activator, which was likely to interfere with their neurite outgrowth potential on a laminin substratum. Indeed, the weaver granule neurons but not the normal neurons degraded laminin from their culture substratum and deposited a neurite outgrowth domain of the B2 chain of laminin onto their surfaces. Electrophysiology showed that the weaver granule neurons had poor resting membrane potentials (-38 V), whereas the normal neurons had normal resting membrane potentials of (-61 V). The resting membrane potentials of the weaver granule neurons were restored to near normal (-59 V) by a protease inhibitor, aprotinin. Aprotinin also rescued the weaver granule neurons from death on a laminin substratum and promoted their neurite outgrowth to the level of the normal animals. These results indicate that increased proteolytic activity accompanied with increased synthesis of laminin, and its B2 chain, distinguish the weaver mutation from the normal animals. These molecular changes may contribute to the impairment of granule neuronal migration and to the neuronal death, characteristic of the weaver mutation.

Domain-specific antibodies against the B2 chain of laminin inhibit neuronal migration in the neonatal rat cerebellum.

Although the spatial and temporal patterns of neuronal migration have been analyzed in great detail, little direct evidence is available as to what extracellular matrix molecules are involved. Because there is indirect evidence implicating the extracellular matrix protein laminin in neuronal migration, we investigated the effects of antibodies against a synthetic peptide derived from a neurite outgrowth domain of the B2 chain of laminin on neuronal migration in living cerebellar slices. We show by using infrared video microscopy that divalent Fab2 fragments of these antibodies inhibit granule neuronal movement in living slices of (P8) rat cerebellum. This inhibition of neuronal movement manifests itself by cessation of both radial and horizontal translocations of nuclei inside the granule neuronal processes. Fab2 fragments of antibodies against the intact (native) laminin molecule or Fab2 fragments from the preimmune serum do not affect nuclear translocation. Immunocytochemistry shows binding of the divalent Fab2 fragments of the B2 chain-specific antibodies to the Purkinje and Bergmann glial cell areas, and as punctate deposits in between the cells of the external granule cell layer. Native laminin antibodies bind to the basement membranes, and binding of the Fab2 fragments from the preimmune sera cannot be demonstrated. These results indicate that neuronal migration in the postnatal rat cerebellum in vivo involves nuclear translocation that can be inhibited by antibodies against a neurite outgrowth domain of the B2 chain of laminin. Thus, migration of cerebellar granule neurons may depend on the interaction between a neurite outgrowth domain of the B2 chain of laminin and neuronal cytoskeleton involved in nuclear movement.

Novel forms of neuronal migration in the rat cerebellum.

Infrared video microscopy of neonatal rat cerebellum (P0-P14) was used to directly visualize migrating granule neurons in relation to other cerebellar cells in a brain slice for up to 24 hr. Initially (P0-P5), granule neurons move along radial migration pathways of other neuronal fibers. These pathways are probably established by the bipolar granule neurons that attach to the external basement membrane via one process and extend another process toward the Purkinje cell layer. At P5-P8, a substantial number of granule neurons move horizontally and extend long parallel fibers. Both radially and horizontally migrating granule neurons move by nuclear translocation inside their preformed processes with a speed that varies between 6 and 120 microns/hr. In P10-P12 animals, the horizontally oriented granule neurons start to migrate radially. They move into the internal granule cell layer either along the radial pathways of other neuronal fibers or in contact with the matured glial processes. The radial neuronal migration pathways disappear by P14 whereas the glial cell processes are maintained and reach the basal lamina. These results describe novel radial and horizontal modes of neuronal migration that proceed independently of the physical glial guidance.

Neural elements in the normal and experimentally injured porcine intervertebral disk.

There is increasing evidence that-back pain may originate from degenerated or damaged disks, even in the absence of disk herniation. For a study of the pattern of innervation in injured disks, the anterior part of the annulus fibrosus of a lumbar disk in 11 domestic pigs was incised with a scalpel through a retroperitoneal approach. The animals were killed 2 weeks, 1, 2, 3, and 5 months postoperatively, and the whole anterior annulus of each injured disk and corresponding tissue from intact animals were excised. Cryostat sections 20 microns thick were cut from the surface downward, fixed, and stained with different antisera. Antisera to neurofilament triplet protein (R39), protein gene product (PGP) 9.5 and synaptophysin were used as general neural markers. Antiserum to substance P (SP) and calcitonin gene-related peptide (CGRP) were used to localize nerves mainly of the sensory type, and C flanking peptide of neuropeptide Y (CPON) to visualize nerve fibers of the sympathetic type. It was observed that in the intact porcine disk, the outer and middle parts of the anterior annulus were innervated to a depth of 7 mm from the annular surface, but the innermost annular layers showed no immunoreactivity to any of the neural antibodies. Disk injury did not cause any major changes in the nerve topography of the wound area, even though there were granulation tissue and neovascularization in this area.

A laminin graft replaces neurorrhaphy in the restorative surgery of the rat sciatic nerve.

We investigated the role of laminin in functional recovery of a peripheral nerve injury using electrophysiological and behavioral approaches on the rat sciatic nerve in vivo. These studies were complemented by neurofilament protein immunocytochemistry on the sciatic nerve 20 days after an operation, in which an 8-mm piece of the nerve was removed and replaced by a graft of laminin, its neurite outgrowth-promoting peptide, a control peptide, collagen, or by resuturing of the removed piece of the nerve. Electrophysiological measurements of muscle strength 4 months after the sciatic nerve transection showed that a laminin graft was as effective as neurorrhaphy in supporting functional recovery of an injured peripheral nerve. A laminin graft also significantly reduced autotomy in the operated animals. Immunocytochemistry confirmed that both a laminin graft and resuturing supported growth of the 200-kDa neurofilament-positive axons into the distal stump of the nerve within 20 days of operation. A graft with a neurite outgrowth-promoting peptide of the B2 chain of laminin supported similar axon growth, whereas another peptide graft also derived from laminin or a collagen graft did not support axon growth. All grafts allowed Schwann cell growth into the distal stumps of the nerves, but neurites accompanied them only in the regeneration-supporting grafts and in the resutured nerves. The Schwann cells of the regenerating nerves expressed high levels of the neurite outgrowth-promoting domain of the B2 chain of laminin, whereas the Schwann cells of the degenerating nerves failed to express this domain in the distal stumps of the degenerating nerves. These results provide the first in vivo evidence for the functional role of laminin in peripheral nerve regeneration. As the neurite outgrowth-promoting domain of the B2 chain of laminin is as efficient as laminin or resuturing in supporting a short-term recovery of an injured sciatic nerve, this area may be a regeneration-promoting domain of this glycoprotein. More importantly, as grafting significantly reduces post-traumatic pain behavior in the operated animals, the laminin graft surgery may provide a useful method for clinical restoration of the injured peripheral nerves.

Neuronal migration in cerebellar microcultures is inhibited by antibodies against a neurite outgrowth domain of laminin.

The functional role of laminin in neuronal migration was investigated by using polyclonal antibodies or their divalent (Fab')2 fragments to a neurite outgrowth promoting domain of the B2 chain of laminin in a cerebellar microculture system widely recognized as a model for neuronal migration. We show here that these antibodies or their (Fab')2 fragments totally inhibit migration of the mouse cerebellar granule cells along the glial and other neuronal cell processes. Antibodies to native laminin or other control antibodies have no inhibitory effect. Immunocytochemical analysis of the cerebellar microcultures indicates that the functional role of these antibodies may relate to the fact that the punctate deposits of laminin and its neurite outgrowth promoting domain accumulate in between the migrating neurons and the glial cells. These data provide the first direct evidence for the functional role of laminin and its neurite outgrowth domain in neuronal migration in the mammals. They further suggest that a neuronal cell surface contact with the extracellular deposits of a neurite outgrowth domain of the B2 chain of laminin may mediate neuronal-glial interactions.

Neuronal migration on laminin involves neuronal contact formation followed by nuclear movement inside a preformed process.

Neuronal migration was investigated in rodent cerebellum in vitro and in vivo. Time-lapse video recording showed that cultured neurons migrated on laminin by first extending neurites that formed contacts with other neurons. This was followed by movement of the cell nucleus inside the preformed process. No guidance cues other than laminin were required. When the rodent premigratory (E18-P0) cerebellum was examined by immunocytochemistry, the radial glial cells were found to have extracellular punctate deposits of laminin along their fibers. Such punctate deposits of laminin were more numerous in the premigratory cerebellum than during the peak of neuronal migration (e.g., at 7-10 days postnatally). At the same time (E18-P0) L1 antigen- and neurofilament-positive, presumably granule cell processes extend radially from the external granule cell layer (EGL). These results imply that neuronal migration on laminin in vitro involves neuronal contact formation followed by nuclear movement inside a preformed process. That this mode of neuronal migration may occur in vivo is indicated by the fact that L1 antigen- and neurofilament-positive "pioneer neurites" colocalize with the punctate deposits of laminin deposited along the radial glial processes in the premigratory EGL. Taken together these results imply that the established glial dependency of the granule cell migration may in fact be dependency of the granule cells and their pioneer neurites on the punctate deposits of laminin produced and laid down by the glial cells.