Cellular migration and axonal outgrowth from adult mammalian peripheral nerves in vitro

Impaired axonal regeneration by isolectin B4-binding dorsal root ganglion neurons in vitro

The subpopulation of dorsal root ganglion (DRG) neurons recognized by Griffonia simplicifolia isolectin B4 (IB4) differ from other neurons by expressing receptors for glial cell line-derived neurotrophic factor (GDNF) rather than neurotrophins. Additionally, IB4-labeled neurons do not express the laminin receptor, alpha7-integrin (Gardiner et al., 2005), necessary for optimal axonal regeneration in the peripheral nervous system. In cultures of dissociated DRG neurons of adult mice on laminin, robust spontaneous neurite outgrowth from IB4-negative neurons occurs and is strongly enhanced by previous axotomy. In contrast, IB4-labeled neurons show little neurite outgrowth and do not express GAP 43, even after axotomy or culture with GDNF. Moreover, growth of their axons through collagen gels is impaired compared with other DRG neurons. To determine whether the sparse neurite outgrowth of IB4-labeled neurons is attributable to lack of integrin expression, DRG cultures were infected with a herpes simplex 1 vector encoding alpha7-integrin, but its forced expression failed to promote neurite outgrowth in either IB4-labeled or other DRG neurons or in cultured adult retinal ganglion cells. Forced coexpression of both alpha7-integrin and GAP 43 also failed to promote neurite outgrowth in IB4-labeled neurons. In addition, cultured sciatic nerve segments were found to release much lower levels of GDNF, demonstrated by ELISA, than nerve growth factor. These findings together with their impaired intrinsic axonal regeneration capacity may contribute to the known vulnerability of the IB4-labeled population of DRG neurons to peripheral nerve injury.

Microtubule-associated protein 1B controls directionality of growth cone migration and axonal branching in regeneration of adult dorsal root ganglia neurons

During development, microtubule-associated protein 1B (MAP1B) is one of the earliest MAPs, preferentially localized in axons and growth cones, and plays a role in axonal outgrowth. Although generally downregulated in the adult, we have shown that MAP1B is constitutively highly expressed in adult dorsal root ganglia (DRGs) and associated with central sprouting and peripheral regeneration of these neurons. Mutant mice with a complete MAP1B null allele that survive until adulthood exhibit a reduced myelin sheath diameter and conductance velocity of peripheral axons and lack of the corpus callosum. Here, to determine the function of MAP1B in axonal regeneration, we used cultures of adult DRG explants and/or dissociated neurons derived from this map1b-/- mouse line. Whereas the overall length of regenerating neurites lacking MAP1B was similar to wild-type controls, our analysis revealed two main defects. First, map1b-/- neurites exhibited significantly (twofold) higher terminal and collateral branching. Second, the turning capacity of growth cones (i.e., "choice" of a proper orientation) was impaired. In addition, lack of MAP1B may affect the post-translational modification of tubulin polymers: quantitative analysis showed a reduced amount of acetylated microtubules within growth cones, whereas the distribution of tyrosinated or detyrosinated microtubules was normal. Both growth cone turning and axonal branch formation are known to involve local regulation of the microtubule network. Our results demonstrate that MAP1B plays a role in these processes during plastic changes in the adult. In particular, the data suggest MAP1B implication in the locally coordinated assembly of cytoskeletal components required for branching and straight directional axon growth.

Multidimensional long-term time-lapse microscopy of in vitro peripheral nerve regeneration

In order to test the effectiveness of a new advanced time-lapse microscopy imaging and image processing and analysis system, and to do quantitative and qualitative temporal analyses of in vitro peripheral nerve regeneration, long-term time-lapse imaging of cultures of mouse dorsal root ganglia (DRGs) was performed. DRGs were placed in a Petri dish, covered with collagen gel, their attached peripheral nerves were cut in the middle, creating a gap, and the dish was filled with culture medium. Six preparations were kept on the time-lapse imaging system, which provides a suitable incubation environment and enables to capture images from multiple coordinates at x,y,z axes at desired time intervals for 13 days. In general, the time-lapse imaging system proved quite stable and efficient, although some improvements are certainly required. Two main components of peripheral nerve regeneration, outgrowth of axons and activities of resident cells, were examined. Axons started to grow during the first hour of incubation with a 16.5 microm/h rate and showed the slowest rates (0.7 microm/h) on days 8 and 9, after which they resumed higher speeds again. The first cell came out of the proximal end of the cut nerve on the second day and it was a Schwann cell (SC), which was the prominent cell type in the preparations throughout the experiment. SCs were higher in number (83.15% of all cells) but slower in migration (3.4 vs. 7.3 microm/h, P < 0.001) than other cells. Other observed characteristics of axonal outgrowth and cellular activity and interactions between axons and the cells are discussed.

Photoconstructs of nerve guidance prosthesis using photoreactive gelatin as a scaffold

We devised a novel nerve prosthesis composed of an elastomeric gelatinous tube and multifilament gelatinous fibers, both of which were prepared from styrene-derivatized gelatin, which allows in situ formation of a bioactive substance-incorporated gel. An in vitro study showed that the axonal regeneration potential of a photocured gelatin layer impregnated with laminin, fibronectin, and NGF was almost comparable with that of coated Matrigel. A nerve conduit and fibers prepared from photoreactive gelatin was subjected to visible-light irradiation with rotation in the presence of camphorquinone as a photoinitiator using a custom-designed apparatus. A sample of transparent gelatinous conduit with an inner diameter of 1.2 mm and a wall thickness of 0.6 mm and gelatin fibers ranging from 10 to 100 pm in diameter were produced. The photocured elastomeric gelatinous tube was flexible and had structural integrity that allowed mechanical handling without breaking. A novel nerve guidance prosthesis composed of tubes packed with fibers was assembled. This photofabrication technology may enable the design of a tailor-made shape and rapid morphogenesis and functional recovery of damaged nerve tissue.

Contraction of collagen-glycosaminoglycan matrices by peripheral nerve cells in vitro

The objective of this study was to investigate the contractile behavior of peripheral nerve support cells in collagen-glycosaminoglycan (GAG) matrices in vitro. Contractile fibroblasts (myofibroblasts) are known to participate in wound contraction during healing of selected connective tissues (viz., dermis), but little is known about the activity of non-muscle contractile cells during healing of peripheral nerves. Explants from adult rat sciatic nerves were placed onto collagen-GAG matrix disks and maintained in culture for up to 30 days. Groups of collagen-GAG matrices were tested that differed in average pore diameter and in degree of cross-linking. Cell migration from nerve explants into the matrices was examined, and immunohistochemical staining was used to identify cells expressing a contractile actin isoform (alpha-smooth muscle actin; alpha-SMA) and Schwann cells (S-100). Geometric contraction of matrix disks was quantified every five days as the percent reduction in disk diameter. The amount of contraction of matrix disks was significantly affected by the degree of cross-linking. Cell migration into the matrices and the distribution of cells staining for alpha-SMA or S-100 was not affected by matrix parameters. These studies demonstrate that cells from peripheral nerve explants were capable of adopting a contractile phenotype and causing geometric contraction of matrices in vitro and suggest that contractile processes may be important during nerve wound healing in vivo.

Effects of Leukemia Inhibitory Factor on Galanin Expression and on Axonal Growth in Adult Dorsal Root Ganglion Neurons in Vitro

Synthesis of leukemia inhibitory factor (LIF) is increased in lesioned peripheral nerves and it is thought that this may cause increased expression of galanin (GAL) in axotomized dorsal root ganglia (DRG) neurons and also to promote axonal regeneration. We therefore compared effects of LIF and nerve growth factor (NGF) on galanin expression and axonal growth using cultured intact DRGs of adult mice. In control lumbar DRGs cultured for 3 days, only 16% of neurons were immunoreactive for GAL, but this was increased to 38% in preparations cultured with LIF. NGF by itself had no effect on GAL expression, but the proportion of GAL-positive neurons in cultures incubated with LIF and NGF together (22%) was less than that observed in DRGs cultured with LIF alone. Similar results were obtained using thoracic DRGs. In collagen gels, NGF caused marked increases in the numbers and lengths of outgrowing axons as observed in previous studies. In contrast, LIF did not stimulate axonal outgrowth but increased the proportions of axons which were immunoreactive for GAL. The results indicate that expression of LIF in lesioned nerves may affect expression of neuropeptides such GAL rather than stimulating axonal regeneration.

Directed axonal growth towards axolotl limb blastemas in vitro

Limb amputation in urodele amphibia is followed by formation of a blastema, which subsequently develops into a complete limb with normal pattern of innervation. In this study, we investigated the effects of axolotl limb blastemas on axonal growth in gels of collagen and extracellular matrix (matrigel). When peripheral nerves with attached dorsal root ganglia were cultured in collagen gels together with blastemas, axonal outgrowth was markedly increased compared with control preparations. Blastemas contain fibroblast growth factors, and may also contain neurotrophic factors such as nerve growth factor, brain-derived neurotrophic factor, neurotrophin 3, neurotrophin 4, glial cell line-derived neurotrophic factor and hepatocyte growth factor/scatter factor, since these factors are expressed in developing limbs in other vertebrates. In collagen gels the neurotrophins and glial cell line-derived neurotrophic factor stimulated axonal growth, but outgrowing axons were shorter than in co-cultures with blastemas. The tyrosine kinase inhibitor K252a blocked the stimulatory effects of the neurotrophins on axonal growth but had relatively little effect on axonal growth in co-cultures with blastemas. In experiments in which peripheral nerves, with attached dorsal root ganglia, were cultured in matrigel, axons grew towards blastemas over distances of about 1mm. Directed axonal growth even occurred in these co-cultures after addition of high concentrations of all the above neurotrophic factors, suggesting that blastemas may release a different factor which stimulates axonal growth. The results indicate that during early stages of limb regeneration in amphibia, factor(s) are released which are capable of attracting the growth of peripheral nerves and may play an important role in the development of innervation of regenerated limbs. The identity of the factor(s) remains to be determined.

The role of endogenous growth factors to support corneal endothelial migration after wounding in vitro

Previous studies have shown that corneal endothelial cells contain mRNA and protein of various growth factors. However, the role of these endogenous growth factors in corneal endothelial wound healing is not fully elucidated. In the present study, we investigated the role of endogenous factors and several growth factor inhibitors on migration of corneal endothelial cells in an in vitro model of wound healing. Bovine corneal endothelial cells (BCEC) were grown to confluency and experiments performed at passage 2 under serum reduced [2% fetal calf serum (FCS)] conditions. A central circular 'wound' (5 mm diameter) was made with an especially designed trephine. In different experiments, cells were incubated over different time periods (1-72 hr) either with the cellular debris produced by the wounding procedure or with previously prepared endothelial cell lysates (protein content 50-500 microg ml(-1)). Additionally, purified bovine polyclonal anti-BFGF antibodies (Ab) (4.5-27 microg ml(-1)), suramin (0.5 m M) or anti-FGF receptor-Ab (1 microg ml(-1)) were added to both experimental approaches, respectively. Migration was quantitated by counting the cells inside the denuded area in four different sections from the wound edge after 5 days. Cellular migration of cells adjacent to the wound was significantly stimulated by factors released during wounding or by endothelial cell lysates at protein concentrations >100 microg ml(-1). This increase in migrating cells was partially inhibited when the anti-bFGF antibody was incubated with the cell debris or the lysates. The addition of suramin at 0.5 m M almost completely blocked the migration activity. Incubation of the anti-FGF-receptor antibody prior to and >5 hr after wounding significantly reduced migration to nearly 50% of the rate in control cultures (P<0.001). In the present study, we demonstrate that intracellular growth factors released from corneal endothelial cells enhance the migration of surviving cells in vitro. The strong inhibitory effect of suramin indicates a major role of heparin-binding growth factors for cellular migration. bFGF and the regulation of bFGF-receptor expression on cells at the wound margin seem to be of crucial importance for the wound healing process.

A two-dimensional gel electrophoretic study of proteins synthesized and released by degenerating adult mouse sciatic nerve

Previous two-dimensional (2-D) gel electrophoretic studies of proteins secreted by degenerating mammalian peripheral nerves (Ignatius et al., 1986, Proc. Natl. Acad. Sci. USA 83: 1125-1129; Muller et al., 1986, J. Cell Biol. 102: 393-402) detected the up-regulation of two proteins of 67-70 and 34-37 kDa, although they failed to resolve proteins smaller than about 15 kDa or with isoelectric points greater than 8. In the present study, we have used 2-D gels that can resolve proteins in the molecular mass range 3.6-200 kDa and isoelectric point range 2.4-10.6. This revealed that the incorporation of radiolabel by three diffusible proteins with apparent molecular mass/isoelectric point values of 38/5-6, 27-31/4-5, and 8/>10 was increased in the distal stumps of sciatic nerves 4 days after lesion, while the radiolabel incorporation by a further two proteins (15/5.3 and 12.5-17.5/6.8-7.5) was increased in the distal nerve stump 15 days after lesion. The possible cellular sources of these proteins were assessed by comparing protein secretion from unoperated nerves with nerve segments maintained in culture for 4 days (in which the contribution from recruited macrophages would be expected to be minimal) and segments of nerve that had been frozen and then replaced in situ for 4 days (in which the contribution from nerve sheath cells would be expected to be minimal). This revealed that three of the proteins up-regulated in lesioned nerves (27-31/4-5, 15/5.3, and 12.5-17.5/6.8-7.5) are probably sheath cell products, while the other two (38/5-6 and 8/>10) may be secreted mainly by macrophages (or other cells) that infiltrate the frozen nerve segments. The identity of these proteins and their possible involvement in axonal regeneration remain to be determined.

Connective tissue response to tubular implants for peripheral nerve regeneration: the role of myofibroblasts

The presence of contractile cells, their organization around regenerating nerve trunks, and the hypothetical effect of these organized structures on the extent of regeneration across a tubulated 10-mm gap in the rat sciatic nerve were investigated. Collagen and silicone tubes were implanted both empty and filled with a collagen-glycosaminoglycan (GAG) matrix. Nerves were retrieved at 6, 30, and 60 weeks postoperatively and time-dependent values of the nerve trunk diameter along the tubulated length were recorded. The presence of myofibroblasts was identified immunohistochemically using a monoclonal antibody to alpha-smooth muscle actin. Myofibroblasts were circumferentially arranged around the perimeter of regenerated nerve trunks, forming a capsule which was about 10 times thicker in silicone tubes than in collagen tubes. The nerve trunk diameter that formed inside collagen tubes was twice as large as that inside silicone tubes. In contrast, the collagen-GAG matrix had a relatively small effect on capsule thickness or diameter of regenerate. It was hypothesized that the frequency of successful bridging by axons depends on the balance between two competitive forces: the axial forces generated by the outgrowth of axons and nonneuronal cells from the proximal stump and the constrictive, circumferential forces imposed by the contractile tissue capsule that promote closure of the wounded stumps and prevent axon elongation. Because the presence of the collagen-GAG matrix has enhanced greatly the recovery of normal function of regenerates in silicone tubes, it was hypothesized that it accelerated axonal elongation sufficiently before the hypothetical forces constricting the nerve trunk in silicone tubes became sufficiently large. The combined data suggest a new mechanism for peripheral nerve regeneration along a tubulated gap.

Stimulation of axon growth from the spinal cord by a regenerating limb blastema in newts

The effects of limb blastemas of Pleurodeles waltl on axon growth from fragments of spinal cord were studied in vitro. Cultured in a defined medium, spinal cord fragments regenerated sparse, short axons. The culture of spinal fragments in the presence of blastemas greatly enhanced the length, number and survival of axons. Testing separately each of the two components of the blastema showed that only the mesenchyme exerts a neurotropic effect on the spinal fragments. Other tissues such as muscle or skin had a limited neurotrophic effect. Additionally, the neurotrophic activity of blastemas seems to be dependent of its proliferation status. Compared with blastemas of regenerating limbs from young animals, irradiated blastemas (devoid of mitotic activity) and blastemas of regenerating limbs from old animals or differentiated blastemas (both characterized by a low mitotic activity), exhibited a weaker neurotrophic influence. The blastema neurotrophic factor is not an attachment molecule but a soluble one and cannot be nerve growth factor (NGF) or fibroblast growth factor (FGF). It has a relatively low molecular weight (less than 15 kDa) and its protein nature was ascertained by its sensitivity to heating and proteases. As the production of this mesenchyme-derived neurotrophic factor depends upon mesenchymal cell proliferation of the blastema, we suggest that there is loop of positive regulation between spinal nerves and blastema. Blastema tissues may stimulate nerve regeneration allowing the stimulation of proliferation of blastema cells by regenerating nerve fibers. Alternatively, blastema cells may produce a neurotrophic factor whose secretion might be dependent on cell proliferation.

Collagen-GAG substrate enhances the quality of nerve regeneration through collagen tubes up to level of autograft

Peripheral nerve regeneration was studied across a tubulated 10-mm gap in the rat sciatic nerve using histomorphometry and electrophysiological measurements of A-fiber, B-fiber, and C-fiber peaks of the evoked action potentials. Tubes fabricated from large-pore collagen (max. pore diameter, 22 nm), small-pore collagen (max. pore diameter, 4 nm), and silicone were implanted either saline-filled or filled with a highly porous, collagen-glycosaminoglycan (CG) matrix. The CG matrix was deliberately synthesized, based on a previous optimization study, to degrade with a half-life of about 6 weeks and to have a very high specific surface through a combination of high pore volume fraction (0.95) and relatively small average pore diameter (35 microm). Nerves regenerated through tubes fabricated from large-pore collagen and filled with the CG matrix had significantly more large-diameter axons, more total axons, and significantly higher A-fiber conduction velocities than any other tubulated group; and, although lower than normal, their histomorphometric and electrophysiological properties were statistically indistinguishable from those of the autograft control. Although the total number of myelinated axons in nerves regenerated by tubulation had reached a plateau by 30 weeks, the number of axons with diameter larger than 6 microm, which have been uniquely associated with the A-fiber peak of the action potential, continued to increase at substantial rates through the completion of the study (60 weeks). The kinetic data strongly suggest that a nerve trunk maturation process, not previously reported in studies of the tubulated 10-mm gap in the rat sciatic nerve, and consisting in increase of axonal tissue area with decrease in total tissue area, continues beyond 60 weeks after injury, resulting in a nerve trunk which increasingly approaches the structure of the normal control.

Use of explant cultures of peripheral nerves of adult vertebrates to study axonal regeneration in vitro

Explanted preparations of peripheral nerves with attached dorsal root ganglia of adult mammals and amphibia survive for several days in serum-free medium and can be used to study axonal regeneration in vitro. This review outlines the methods which we routinely use and how they may be applied to study different aspects of axonal regeneration. When the peripheral nerves are crushed in vitro, axons regenerate through the crush site into the distal stump within 1 day (mouse) or 3 days (frog). The outgrowth distance of the leading sensory axons can be determined with the use of a simple method based on axonal transport of labelled proteins. A compartmentalised system permits selective application of drugs and other agents to either ganglia or peripheral nerve containing the regenerating axons and has been used to study selected aspects of regeneration including influence of non-neuronal cells, retrograde signalling, axonal release of proteins during regeneration and the role of phospholipase A2 activity. Explanted preparations may also be cultured in a layer of extracellular matrix material (matrigel), in which spontaneous outgrowth of a large number of naked axons from the cut ends of nerves starts within 1 day and continues for several days. This provides an opportunity to study the direct effects of different agents on axonal elongation. Preparations cultured in collagen gels show sparse spontaneous axonal growth, but this can be increased by addition of certain growth factors. The phenotype of the regenerating axons can be studied using immunohistochemical methods.

Effects of glial cell line-derived neurotrophic factor on axonal growth and apoptosis in adult mammalian sensory neurons in vitro

The effects of glial cell line-derived neurotrophic factor on axonal outgrowth and apoptosis were studied in vitro using explanted dorsal root ganglia-peripheral nerve preparations of adult mice. In gels of matrigel or collagen type 1, glial cell line-derived neurotrophic factor increased both the numbers and lengths of axons growing out of explanted preparations, although less effectively than nerve growth factor. Stimulation of axonal outgrowth by glial cell line-derived neurotrophic factor was unaffected by K252a, a protein kinase inhibitor which blocks the effects of nerve growth factor and other neurotrophins acting through trk receptors. To determine the phenotype of the axons responding to glial cell line-derived neurotrophic factor, preparations were stained using antibodies to trkA, calcitonin gene-related peptide, 200,000 mol. wt phosphorylated neurofilaments (monoclonal antibody RT97) and the lectin Bandeiraea simplicifolia 1B4. RT97 recognizes large diameter neurons whilst 1B4 labels small diameter neurons which broadly do not express neurotrophin receptors. In preparations cultured with glial cell line-derived neurotrophic factor, significant increases in the numbers of outgrowing axons labelled with RT97 and 1B4 were observed but the numbers of calcitonin gene-related peptide-positive axons were not significantly increased and their staining intensity was generally faint. In separate preparations it was found that in the presence of glial cell line-derived neurotrophic factor, the majority of the 1B4 labelled axons were trkA negative, indicating that this factor can stimulate axonal growth in this population of neurons which do not respond to the neurotrophins. Spontaneous apoptosis in neurons and satellite cells occurs in explanted preparations of the type used in the present investigations, but in cryostat sections of preparations cultured in the presence of glial cell line-derived neurotrophic factor, the incidence of apoptosis was lower than in control preparations which had been cultured in the absence of this factor. This suggests that glial cell line-derived neurotrophic factor may promote survival of some adult sensory neurons in vitro.

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.