CHL1 cooperates with PAK1-3 to regulate morphological differentiation of embryonic cortical neurons.

The cell adhesion molecule close homologue of L1 (CHL1) is important for apical dendritic projection and laminar positioning of pyramidal neurons in caudal regions of the cerebral cortex. The p21-activated kinase (PAK1-3) subfamily of serine/threonine kinases has also been implicated in regulating cell adhesion, migration, and morphology. Immunofluorescence staining in mouse embryonic brain showed that PAK1-3 was expressed in embryonic cortex and colocalized with CHL1 during neuronal migration and differentiation. To investigate a cooperative function for CHL1 and PAK in pyramidal cell differentiation or migration, a dominant-negative PAK mutant (PAK1 AID) that inhibits PAK1-3 kinase activity while coexpressing a green fluorescent protein (GFP) reporter was electroporated into the lateral ventricles of wild type (WT) and CHL1 null mutant mouse embryos (E14.5), then brain slices were cultured and neurons analyzed for laminar positioning and morphology by confocal microscopy after 3 days in vitro. Expression of PAK1 AID in CHL1 mutant cortex inactivated PAK and caused embryonic cortical neurons to branch profusely in the intermediate zone (IZ) and cortical plate (CP). The number of nodes, terminals and length of leading processes/apical dendrites of CHL1 mutant embryos expressing PAK1 AID increased dramatically, compared to CHL1 mutants without PAK1 AID, or WT embryos with or without PAK1 AID. These findings suggest that CHL1 and PAK1-3 kinase cooperate, most likely in independent pathways, in regulating morphological development of the leading process/apical dendrite of embryonic cortical neurons.

Developmental regulation of neural cell adhesion molecule in human prefrontal cortex.

Neural cell adhesion molecule (NCAM) is a membrane-bound cell recognition molecule that exerts important functions in normal neurodevelopment including cell migration, neurite outgrowth, axon fasciculation, and synaptic plasticity. Alternative splicing of NCAM mRNA generates three main protein isoforms: NCAM-180, -140, and -120. Ectodomain shedding of NCAM isoforms can produce an extracellular 105-115 kilodalton soluble neural cell adhesion molecule fragment (NCAM-EC) and a smaller intracellular cytoplasmic fragment (NCAM-IC). NCAM also undergoes a unique post-translational modification in brain by the addition of polysialic acid (PSA)-NCAM. Interestingly, both PSA-NCAM and NCAM-EC have been implicated in the pathophysiology of schizophrenia. The developmental expression patterns of the main NCAM isoforms and PSA-NCAM have been described in rodent brain, but no studies have examined NCAM expression across human cortical development. Western blotting was used to quantify NCAM in human postmortem prefrontal cortex in 42 individuals ranging in age from mid-gestation to early adulthood. Each NCAM isoform (NCAM-180, -140, and -120), post-translational modification (PSA-NCAM) and cleavage fragment (NCAM-EC and NCAM-IC) demonstrated developmental regulation in frontal cortex. NCAM-180, -140, and -120, as well as PSA-NCAM, and NCAM-IC all showed strong developmental regulation during fetal and early postnatal ages, consistent with their identified roles in axon growth and plasticity. NCAM-EC demonstrated a more gradual increase from the early postnatal period to reach a plateau by early adolescence, potentially implicating involvement in later developmental processes. In summary, this study implicates the major NCAM isoforms, PSA-NCAM and proteolytically cleaved NCAM in pre- and postnatal development of the human prefrontal cortex. These data provide new insights on human cortical development and also provide a basis for how altered NCAM signaling during specific developmental intervals could affect synaptic connectivity and circuit formation, and thereby contribute to neurodevelopmental disorders.

Approaches to developing biological H(2)-photoproducing organisms and processes.

The development of efficient biological systems for the direct photoproduction of H(2) gas from water faces several challenges, the more serious of which is the sensitivity of the H(2)-evolving enzymes (hydrogenases) to O(2), an obligatory by-product of photosynthesis. This high sensitivity is common to both FeFe and NiFe hydrogenases, and is caused by O(2) binding to their respective metallocatalytic sites. This overview describes approaches to (i) molecular engineering of algal FeFe-hydrogenase to prevent O(2) access to its catalytic site; (ii) transform a cyanobacterium with an O(2)-tolerant bacterial NiFe hydrogenase or (c) partially inactivate algal O(2)-evolution activity to create physiologically anaerobiosis and induce hydrogenase expression.

Altered distribution of dopaminergic neurons in the brain of L1 null mice.

Dopaminergic neurons of the mouse mesencephalon originate in the ventricular zone and migrate radially along radial glia then tangentially along nerve fibers that express the neural cell adhesion molecule L1 to form the substantia nigra (A9 group) and ventral tegmental area (VTA) (A10 group). The role of L1 in migration of dopaminergic neuronal precursors was investigated in L1 knockout mice by tyrosine hydroxylase (TH) immunostaining. An altered rostrocaudal distribution of dopaminergic neurons was observed within the substantia nigra and VTA of L1-minus mice. In L1-minus mice at postnatal day 0, TH-positive cells were present abnormally in the dorsomedial mesencephalon, suggesting impaired migration. Axons projecting from the substantia nigra to the caudate putamen also exhibited an abnormal targeting pattern. There was no evidence of dopaminergic cell loss in the mutant SN. Abnormal localization of dopaminergic neurons in L1-minus mice was also evident in the zona incerta of the thalamus (A13 group), and the arcuate (A12) and periventricular nucleus (A14) of the hypothalamus. Cell bodies and axons in the substantia nigra, VTA, and hypothalamus of wild type mouse embryos expressed L1. These results suggested that L1 plays an important developmental role in the organization of dopaminergic neuronal cell groups in the mesencephalon and diencephalon.

Cytoplasmic domain mutations of the L1 cell adhesion molecule reduce L1-ankyrin interactions.

The neural adhesion molecule L1 mediates the axon outgrowth, adhesion, and fasciculation that are necessary for proper development of synaptic connections. L1 gene mutations are present in humans with the X-linked mental retardation syndrome CRASH (corpus callosum hypoplasia, retardation, aphasia, spastic paraplegia, hydrocephalus). Three missense mutations associated with CRASH syndrome reside in the cytoplasmic domain of L1, which contains a highly conserved binding region for the cytoskeletal protein ankyrin. In a cellular ankyrin recruitment assay that uses transfected human embryonic kidney (HEK) 293 cells, two of the pathologic mutations located within the conserved SFIGQY sequence (S1224L and Y1229H) strikingly reduced the ability of L1 to recruit 270 kDa ankyrinG protein that was tagged with green fluorescent protein (ankyrin-GFP) to the plasma membrane. In contrast, the L1 missense mutation S1194L and an L1 isoform lacking the neuron-specific sequence RSLE in the cytoplasmic domain were as effective as RSLE-containing neuronal L1 in the recruitment of ankyrin-GFP. Ankyrin binding by L1 was independent of cell-cell interactions. Receptor-mediated endocytosis of L1 regulates intracellular signal transduction, which is necessary for neurite outgrowth. In rat B35 neuroblastoma cell lines stably expressing L1 missense mutants, antibody-induced endocytosis was unaffected by S1224L or S1194L mutations but appeared to be enhanced by the Y1229H mutation. These results suggested a critical role for tyrosine residue 1229 in the regulation of L1 endocytosis. In conclusion, specific mutations within key residues of the cytoplasmic domain of L1 (Ser(1224), Tyr(1229)) destabilize normal L1-ankyrin interactions and may influence L1 endocytosis to contribute to the mechanism of neuronal dysfunction in human X-linked mental retardation.

Evidence for three distinct hydrogenase activities in Rhodospirillum rubrum.

Inducer, inhibitor, and mutant studies on three hydrogenase activities of Rhodospirillum rubrum indicate that they are mediated by three distinct hydrogenase enzymes. Uptake hydrogenase mediates H2 uptake to an unknown physiological acceptor or methylene blue and is maximally synthesized during autotrophic growth in light. Formate-linked hydrogenase is synthesized primarily during growth in darkness or when light becomes limiting, and links formate oxidation to H2 production. Carbon-monoxide-linked hydrogenase is induced whenever CO is present and couples CO oxidation to H2 evolution. The enzymes can be expressed singly or conjointly depending on growth conditions, and the inhibitor or inducer added. All three hydrogenases can use methyl viologen as the mediator for both the H2 evolution and H2 uptake reactions while displaying distinct pH optima, reversibility, and sensitivity to C2H2 gas. Yet, we present evidence that the CO-linked hydrogenase, unlike the uptake hydrogenase, does not link to methylene blue as the electron acceptor. These differences allow conditions to be established to quantitatively assay each hydrogenase independently of the others both in vivo and in vitro.

A MAP kinase-signaling pathway mediates neurite outgrowth on L1 and requires Src-dependent endocytosis.

The neural cell adhesion molecule L1 mediates the axon outgrowth, adhesion, and fasciculation necessary for proper development of synaptic connections. Mutations of human L1 cause an X-linked mental retardation syndrome termed CRASH (corpus callosum hypoplasia, retardation, aphasia, spastic paraplegia, and hydrocephalus), and L1 knock-out mice display defects in neuronal process extension resembling the CRASH phenotype. Little is known about the biochemical or cellular mechanism by which L1 performs neuronal functions. Here it is demonstrated that clustering of L1 with antibodies or L1 protein in rodent B35 neuroblastoma and cerebellar neuron cultures induced the phosphorylation/activation of the mitogen-activated protein kinases (MAPKs) and extracellular signal-regulated kinases 1 and 2. MAPK activation was essential for L1-dependent neurite outgrowth, because chemical inhibitors [2-(2'-amino-3'-methoxyphenyl)-oxanaphthalen-4-one and 1,4-diamino-2, 3-dicyano-1,4-bis(2-aminophenylthio)butadiene] of the MAPK kinase MEK strongly suppressed neurite outgrowth by cerebellar neurons on L1. The nonreceptor tyrosine kinase pp60(c-src) was required for L1-triggered MAPK phosphorylation, as shown in src-minus cerebellar neurons and by expression of the kinase-inactive mutant Src(K295M) in B35 neuroblastoma cells. Phosphatidylinositol 3-kinase (PI3-kinase) and the small GTPase p21(rac) were identified as signaling intermediates to MAPK by phosphoinositide and Rac-GTP assays and expression of inhibitory mutants. Antibody-induced endocytosis of L1, visualized by immunofluorescence staining and confocal microscopy of B35 cells, was blocked by expression of kinase-inactive Src(K295M) and dominant-negative dynamin(K44A) but not by inhibitors of MEK or PI3-kinase. Dynamin(K44A) also inhibited L1 antibody-triggered MAPK phosphorylation. This study supports a model in which pp60(c-src) regulates dynamin-mediated endocytosis of L1 as an essential step in MAPK-dependent neurite outgrowth on an L1 substrate.

Long-term potentiation in mice lacking the neural cell adhesion molecule L1.

Genetic evidence indicates that cell adhesion molecules of the immunoglobulin superfamily (IgCAMs) are critical for activity-dependent synapse formation at the neuromuscular junction in Drosophila and have also been implicated in synaptic remodelling during learning in Aplysia (see [1] for review). In mammals, a widely adopted model for the process of learning at the cellular level is long-term potentiation (LTP) in the hippocampal formation. Studies in vitro have shown that antibodies to the IgCAMs L1 and NCAM reduce LTP in CA1 neurons of rat hippocampus, suggesting a role for these molecules in the modulation of synaptic efficacy, perhaps by regulating synaptic remodelling [2]. A role for NCAM in LTP has been confirmed in mice lacking NCAM [3] (but see [4]), but similar studies have not been reported for L1. Here we examine LTP in the hippocampus of mice lacking L1 [5,6], using different experimental protocols in three different laboratories. In tests of LTP in vitro and in vivo we found no significant differences between mutant animals and controls. Thus, contrary to expectation, our data suggest that L1 function is not necessary for the establishment or maintenance of LTP in the hippocampus. Impaired performance in spatial learning exhibited by L1 mutants may therefore not be due to hippocampal dysfunction [6].

Bactericidal activity of photocatalytic TiO(2) reaction: toward an understanding of its killing mechanism.

When titanium dioxide (TiO(2)) is irradiated with near-UV light, this semiconductor exhibits strong bactericidal activity. In this paper, we present the first evidence that the lipid peroxidation reaction is the underlying mechanism of death of Escherichia coli K-12 cells that are irradiated in the presence of the TiO(2) photocatalyst. Using production of malondialdehyde (MDA) as an index to assess cell membrane damage by lipid peroxidation, we observed that there was an exponential increase in the production of MDA, whose concentration reached 1.1 to 2.4 nmol. mg (dry weight) of cells(-1) after 30 min of illumination, and that the kinetics of this process paralleled cell death. Under these conditions, concomitant losses of 77 to 93% of the cell respiratory activity were also detected, as measured by both oxygen uptake and reduction of 2,3,5-triphenyltetrazolium chloride from succinate as the electron donor. The occurrence of lipid peroxidation and the simultaneous losses of both membrane-dependent respiratory activity and cell viability depended strictly on the presence of both light and TiO(2). We concluded that TiO(2) photocatalysis promoted peroxidation of the polyunsaturated phospholipid component of the lipid membrane initially and induced major disorder in the E. coli cell membrane. Subsequently, essential functions that rely on intact cell membrane architecture, such as respiratory activity, were lost, and cell death was inevitable.

Abnormalities in neuronal process extension, hippocampal development, and the ventricular system of L1 knockout mice.

In humans, mutations in the L1 cell adhesion molecule are associated with a neurological syndrome termed CRASH, which includes corpus callosum agenesis, mental retardation, adducted thumbs, spasticity, and hydrocephalus. A mouse model with a null mutation in the L1 gene (Cohen et al., 1997) was analyzed for brain abnormalities by Nissl and Golgi staining and immunocytochemistry. In the motor, somatosensory, and visual cortex, many pyramidal neurons in layer V exhibited undulating apical dendrites that did not reach layer I. The hippocampus of L1 mutant mice was smaller than normal, with fewer pyramidal and granule cells. The corpus callosum of L1-minus mice was reduced in size because of the failure of many callosal axons to cross the midline. Enlarged ventricles and septal abnormalities were also features of the mutant mouse brain. Immunoperoxidase staining showed that L1 was abundant in developing neurons at embryonic day 18 (E18) in wild-type cerebral cortex, hippocampus, and corpus callosum and then declined to low levels with maturation. In the E18 cortex, L1 colocalized with microtubule-associated protein 2, a marker of dendrites and somata. These new findings suggest new roles for L1 in the mechanism of cortical dendrite differentiation, as well as in guidance of callosal axons and regulation of hippocampal development. The phenotype of the L1 mutant mouse indicates that it is a potentially valuable model for the human CRASH syndrome.

NCAM stimulates the Ras-MAPK pathway and CREB phosphorylation in neuronal cells.

The neural cell adhesion molecule NCAM plays an important role in axonal growth, learning, and memory. A signaling pathway has been elucidated in which clustering of the NCAM140 isoform in the neural plasma membrane stimulated the activating phosphorylation of mitogen-activated protein kinases (MAPKs) and the transcription factor cyclic AMP response-element binding protein (CREB). NCAM clustering transiently induced dual phosphorylation (activation) of the MAPKs ERK1 and ERK2 (extracellular signal-regulated kinases) by a pathway regulated by the focal adhesion kinase p125fak, p59fyn, Ras, and MAPK kinase. CREB phosphorylation at serine 133 induced by NCAM was dependent in part on an intact MAPK pathway. c-Jun N-terminal kinase, which is associated with apoptosis and cellular stress, was not activated by NCAM. Inhibition of the MAPK pathway in rat cerebellar neuron cultures selectively reduced NCAM-stimulated neurite outgrowth. These results define an NCAM signal transduction mechanism with the potential for modulating the expression of genes needed for axonal growth, survival, and synaptic plasticity.

Rek, an Axl/Tyro3-related receptor-class tyrosine kinase, is expressed in Müller glia and differentiating neural subpopulations in the avian retina.

Rek is a receptor-class tyrosine kinase of the Axl/Tyro3 family that has transforming capability and is expressed in the avian nervous system. To gain insight into its normal cellular function, the spatial and temporal expression of Rek was analyzed in the developing chick retina by immunoperoxidase staining and Western blotting using Rek-specific antibodies. Rek was developmentally regulated in the retina with maximal expression of the 140 kD full-length kinase at embryonic stage 34 (E8), when retinal glia and neurons begin to differentiate. Rek immunoreactivity was most prominent in the processes of developing and mature retinal Müller glia, and appeared transiently in the bodies of differentiating ganglion and amacrine neurons. In the developing optic tract Rek was found in oligodendroglial-type cells but not in ganglion cell axons. Rek antibodies also stained brain ependymal cells and some cerebellar neuronal cell types (Purkinje, basket and stellate cells). This expression pattern suggests that the Rek tyrosine kinase participates in an aspect of Müller glial function, and may also contribute to the development of restricted populations of glia and neurons in the brain and retina.

p59fyn and pp60c-src modulate axonal guidance in the developing mouse olfactory pathway.

The Src-family tyrosine kinases p59fyn and pp60c-src are localized on axons of the mouse olfactory nerve during the initial stages of axonal growth, but their functional roles remain to be defined. To study the role of these kinases, we analyzed the trajectory of the olfactory nerve in E11.5 homozygous null mutant mice lacking single src or fyn gens and double mutants lacking both genes. Primary olfactory axons of single and double mutants exited the olfactory epithelium and projected toward the telencephalon, but displayed differences in fasciculation. The fyn-minus olfactory nerve had significantly more fascicles than than src-minus nerve. Most strikingly, the primary olfactory nerve of src/fyn double mutants showed the greatest degree of defasciculation. These defects, identified by NCAM labeling, were not due to apparent changes in the size of the olfactory epithelium. With the exception of the src-minus mice, which had fever fascicles than the wild type, no obvious differences were observed in coalescence of vomeronasal axons from mutant mice. The mesenchyme of the double and single mutants exhibited only subtle changes in laminin and fibronectin staining, indicating that the adhesive environment of the mesenchyme may contribute in part to defects in fasciculation. The results suggest that signaling pathways mediated by p59fyn and pp60c-src contribute to the appropriate fasciculation of axons in the nascent olfactory system, and comprise partially compensatory mechanisms for axonal adhesion and guidance.

Microtubule dynamics in a cytosolic extract of fetal rat brain.

Brain microtubule dynamics were studied by video-enhanced differential interference contrast microscopy in a cytosolic extract from fetal rat brain, prepared under conditions designed to produce minimal alterations in microtubule stability. With urchin sperm axoneme fragments as nucleation seeds, the extract was shown to support cellular-like microtubule dynamics. Microtubules elongated from one end of the axonemes, and did not spontaneously self-assemble in the absence of axonemes. The following microtubule kinetic parameters were measured in the extract: velocity of elongation (8.1 mm/min), velocity of rapid shortening (5.8 mm/min), catastrophe frequency (0.17 min(-1)), and rescue frequency (1 min(-1)). These parameters were in close agreement with reported values for growth cones of living neurons. Microtubule properties in the fetal brain extract were shown to be affected by agents with known effects on the cytoskeleton. pp60c-src, a tyrosine kinase important in cell adhesion molecule-dependent axon growth, caused small increases in the frequency of microtubule catastrophe (0.31 min(-1)) and rescue (2 min(-1)) without changing the velocities of elongation or rapid-shortening. Although pp60c-src phosphorylated purified porcine brain tubulin in vitro, it did not elicit significant changes in its polymerization properties, suggesting that other cytoskeletal proteins in the brain extract are involved in modulating microtubule dynamics. The cytosolic extract of fetal rat brain provides a useful system for studying regulation of microtubule assembly in neuronal growth cones.

Why do neurotransmitters act like growth factors?

It is now well established that neurotransmitters act as growth-regulatory signals for neuronal and non-neuronal cells of both primitive and higher organisms, where they control cell proliferation, motility, survival, growth, differentiation, and gene expression. Many of these actions are reminiscent of the actions of other growth-regulatory signals such as growth factors, neurotrophins, and proto-oncogenes. How, then, do neurotransmitters exert these effects? Although some information is available concerning second messengers activated by these neurotransmitters in developing cells, little is known about subsequent steps involving signal transduction cascades leading to their final outcomes. This review attempts to provide testable hypotheses regarding possible cellular and molecular mechanisms downstream of second messengers activated by neurotransmitters, based on recent insights into signal transduction cascades activated by classical growth-regulatory signals. In many cases, there are clear points of convergence between these pathways, raising the interesting possibility that neurotransmitters and other growth-regulatory signals may cooperate to regulate developmental functions of cells and tissues.

NIEHS/EPA Workshops. Growth and differentiation factors.

The work group identified a number of research areas where they felt there were significant data gaps where additional research was critical to better under standing of the origins of birth defects and to developing ways for their prevention. These included: 1. Studies designed to determine the role of growth and differentiation factors during pre- and postimplantation stages of development. These investigations could include descriptive studies involving the localization and timing of genes expressed and their products, but must also emphasize and include studies involving the function of these molecules and their interactions in normal and abnormal development. 2. Studies designed to develop and utilize models for investigating normal and abnormal development. These approaches could include in vivo and in vitro techniques, such as creation of genetically defined systems and cell, organ, and whole embryo cultures. These technologies should emphasize ways to study the functions of growth and differentiation factors and the effects of environmental factors. 3. Studies designed to identify environmental agents and their targets in embryonic, extraembryonic, and maternal tissues that may play a role in producing developmental abnormalities through peturbations of growth and differentiation factors. 4. Studies designed to determine cellular and molecular mechanisms for protection and recovery from environmental insults.

NCAM140 interacts with the focal adhesion kinase p125(fak) and the SRC-related tyrosine kinase p59(fyn).

Axonal growth cones respond to adhesion molecules and extracellular matrix components by rapid morphological changes and growth rate modification. Neurite outgrowth mediated by the neural cell adhesion molecule (NCAM) requires the src family tyrosine kinase p59(fyn) in nerve growth cones, but the molecular basis for this interaction has not been defined. The NCAM140 isoform, which is found in migrating growth cones, selectively co-immunoprecipitated with p59(fyn) from nonionic detergent (Brij 96) extracts of early postnatal mouse cerebellum and transfected rat B35 neuroblastoma and COS-7 cells. p59(fyn) did not associate significantly with the NCAM180 isoform, which is found at sites of stable neural cell contacts, or with the glycophosphatidylinositol-linked NCAM120 isoform. pp60(c-)src, a tyrosine kinase that promotes neurite growth on the neuronal cell adhesion molecule L1, did not interact with any NCAM isoform. Whereas p59(fyn) was constitutively associated with NCAM140, the focal adhesion kinase p125(fak), a nonreceptor tyrosine kinase known to mediate integrin-dependent signaling, became recruited to the NCAM140-p59(fyn) complex when cells were reacted with antibodies against the extracellular region of NCAM. Treatment of cells with a soluble NCAM fusion protein or with NCAM antibodies caused a rapid and transient increase in tyrosine phosphorylation of p125(fak) and p59(fyn). These results suggest that NCAM140 binding interactions at the cell surface induce the assembly of a molecular complex of NCAM140, p125(fak), and p59(fyn) and activate the catalytic function of these tyrosine kinases, initiating a signaling cascade that may modulate growth cone migration.

Rek, a gene expressed in retina and brain, encodes a receptor tyrosine kinase of the Axl/Tyro3 family.

Rek (retina-expressed kinase) has been identified as a putative novel receptor-type tyrosine kinase of the Axl/Tyro3 family with a potential role in neural cell development. rek clones were isolated from a chick embryonic brain cDNA library with a DNA probe obtained by reverse transcriptase-polymerase chain reaction of mRNA from Müller glia-like cells cultured from chick embryonic retina. Sequence analysis indicated that Rek is a protein of 873 amino acids with an extracellular region composed of two immunoglobulin-like domains followed by two fibronectin type III domains with eight predicted N-glycosylation sites. Two consensus src homology 2 domain binding sites are present in the cytoplasmic domain, suggesting that Rek activates several signal transduction pathways. Northern analysis of rek mRNA revealed a 5.5-kilobase transcript in chick brain, retina, and kidney and in primary cultures of retinal Müller glia-like cells. Rek protein was identified by immunoprecipitation and immunoblotting as a 140-kDa protein expressed in the chick retina at embryonic days 6-13, which corresponded to the major period of neuronal and glial differentiation. Transfection of rek cDNA into COS cells resulted in transient expression of a putative precursor of 106 kDa that autophosphorylated in immune complex protein kinase assays. Overexpression of rek cDNA in mouse NIH3T3 fibroblasts resulted in activation of the 140-kDa rek kinase and induction of morphologically transformed foci. These properties indicated that Rek has oncogenic potential when overexpressed, but its normal function is likely to be related to cell-cell recognition events governing the differentiation or proliferation of neural cells.

Selective neural cell adhesion molecule signaling by Src family tyrosine kinases and tyrosine phosphatases.

Nerve growth cone guidance is a highly complex feat, involving coordination of cell adhesion molecules, trophic factor gradients, and extracellular matrix proteins. While navigating through the developing nervous system, the growth cone must integrate diverse environmental signals into a singular response. The repertoire of growth cone responses to these extracellular cues includes axonal growth, fasciculation, and synaptic stabilization, which are achieved through dynamic changes in the cytoskeleton and modulation of gene expression. It has become evident that interactions between cell adhesion molecules can activate intracellular signaling pathways in neurons. Such signaling pathways are just beginning to be defined for the axonal growth promoting molecules L1 and NCAM which are members of the immunoglobulin (Ig) superfamily. Recent findings have revealed that L1 and NCAM induce neurite outgrowth by activating intracellular signaling pathways in the growth cone mediated by two different members of the src family of nonreceptor protein tyrosine kinases (PTKs), pp60(c-src) and p59(fyn5,6). Growth cones display diverse morphologies and variable motility on these different cell adhesion molecules, which are likely to be generated by src kinases. In this review we will address novel features of nonreceptor PTKs of the src family which dictate their distinctive molecular interactions with cell adhesion molecules and signaling components.