The TSC1 tumour suppressor hamartin regulates cell adhesion through ERM proteins and the GTPase Rho.

Loss of the tumour-suppressor gene TSC1 is responsible for hamartoma development in tuberous sclerosis complex (TSC), which renders several organs susceptible to benign tumours. Hamartin, the protein encoded by TSC1, contains a coiled-coil domain and is expressed in most adult tissues, although its function is unknown. Here we show that hamartin interacts with the ezrin-radixin-moesin (ERM) family of actin-binding proteins. Inhibition of hamartin function in cells containing focal adhesions results in loss of adhesion to the cell substrate, whereas overexpression of hamartin in cells lacking focal adhesions results in activation of the small GTP-binding protein Rho, assembly of actin stress fibres and formation of focal adhesions. Interaction of endogenous hamartin with ERM-family proteins is required for activation of Rho by serum or by lysophosphatidic acid (LPA). Our data indicate that disruption of adhesion to the cell matrix through loss of hamartin may initiate the development of TSC hamartomas and that a Rho-mediated signalling pathway regulating cell adhesion may constitute a rate-limiting step in tumour formation.

A Src-astic response to mounting tension.

The nerve growth cone binds to a complex array of guidance cues in its local environment that influence cytoskeletal interactions to control the direction of subsequent axon outgrowth. How this occurs is a critical question and must certainly involve signal transduction pathways. The paper by Suter and Forscher (2001)(this issue) begins to address how one such pathway, an Src family tyrosine kinase, enhances cytoskeletal linkage to apCAM, a permissive extracellular cue for Aplysia growth cones. Interestingly, they show that applied tension increases this kinase's localized phosphorylation that in turn further strengthens linkage. This suggests a potential positive feedback mechanism for amplifying and discriminating guidance information to guide growth cone motility.

Talin and vinculin play distinct roles in filopodial motility in the neuronal growth cone.

Filopodial motility is critical for many biological processes, particularly for axon guidance. This motility is based on altering the F-actin-based cytoskeleton, but the mechanisms of how this occurs and the actin-associated proteins that function in this process remain unclear. We investigated two of these proteins found in filopodia, talin and vinculin, by inactivating them in subregions of chick dorsal root ganglia neuronal growth cones and by observing subsequent behavior by video-enhanced microscopy and quantitative morphometry. Microscale chromophore-assisted laser inactivation of talin resulted in the temporary cessation of filopodial extension and retraction. Inactivation of vinculin caused an increased incidence of filopodial bending and buckling within the laser spot but had no effect on extension or retraction. These findings show that talin acts in filopodial motility and may couple both extension and retraction to actin dynamics. They also suggest that vinculin is not required for filopodial extension and retraction but plays a role in the structural integrity of filopodia.

Function of myosin-V in filopodial extension of neuronal growth cones.

The molecular mechanisms underlying directed motility of growth cones have not been determined. The role of myosin-V, an unconventional myosin, in growth cone dynamics was examined by chromophore-assisted laser inactivation (CALI). CALI of purified chick brain myosin-V absorbed onto nitrocellulose-coated cover slips inhibited the ability of myosin-V to translocate actin filaments. CALI of myosin-V in growth cones of chick dorsal root ganglion neurons resulted in rapid filopodial retraction. The rate of filopodial extension was significantly decreased, whereas the rate of filopodial retraction was not affected, which suggests a specific role for myosin-V in filopodial extension.

Fasciclin I and II have distinct roles in the development of grasshopper pioneer neurons.

We have used a new technique, micro-CALI (chromophore-assisted laser inactivation), to investigate the function of the neural cell adhesion molecules fasciclin I and II in the development of the grasshopper Ti1 neurons. Micro-CALI of fasciclin I results in defasciculation of the Ti1 axons similar to that achieved using large scale CALI (Jay and Keshishian, 1990). The initial point of axon separation corresponds to the site of laser irradiation, and defasciculation always continues distal to this point. Micro-CALI of fasciclin II prevents the initiation of Ti1 axon outgrowth but has no effect on fasciculation. This effect is restricted to a 3 hr interval between cytokinesis and growth cone emergence.

Chromophore-assisted laser inactivation of a repulsive axonal guidance molecule.

BACKGROUND: The axons of retinal ganglion neurons from a precise topographic map in the optic tectum in the midbrain, and the guidance of retinal axons by directional cues in the tectum is crucial in this process. Several in vitro systems have been developed in order to identify the molecular basis of these directional cues. Temporal, but not nasal, retinal axons avoid posterior tectal membranes and grow on anterior membranes as a result of repellent guidance activities that are linked by glycosylphosphatidylinositol (GPI) anchors to the posterior membranes. A putative GPI-anchored repulsive guidance molecule with a molecular weight of 33 kDa has previously been characterized. Indirect results from experiments in vitro support the hypothesis that this 33 kDa molecule guides temporal retinal axons. RESULTS: To assess whether the 33 kDa protein is involved in axon guidance in vitro, we raised monoclonal antibodies against molecules that had been removed from tectal membranes by treatment with phosphatidylinositol-specific phospholipase C, which cleaves GPI anchors. A monoclonal immunoglobulin M, F3D4, recognized the 33 kDa molecule. In combination with chromophore-assisted laser inactivation, F3D4 caused a loss of the repellent activity from posterior tectal membranes in vitro. As a result, temporal retinal fibers were no longer repelled by posterior tectal membranes. This demonstrates that the F3D4 antigen, which we name RGM (repulsive guidance molecule) is involved in the guidance of retinal axons in an assay in vitro. In vivo, the expression of RGM increases from the anterior to the posterior pole of the optic tectum. CONCLUSIONS: These findings not only support the hypothesis that retinal axons are guided by gradients of repulsive guidance molecules but, in combination with earlier studies of receptor kinases and their ligands that act during guidance, argue for the presence of several repellent guidance molecules with similar functions in vitro and expression patterns in vivo.

Essential functions of ezrin in maintenance of cell shape and lamellipodial extension in normal and transformed fibroblasts.

BACKGROUND: Changes in cell shape and motility are important manifestations of oncogenic transformation, but the mechanisms underlying these changes and key effector molecules in the cytoskeleton remain unknown. The Fos oncogene induces expression of ezrin, the founder member of the ezrin/radixin/moesin (ERM) protein family, but not expression of the related ERM proteins, suggesting that ezrin has a distinct role in cell transformation. ERM proteins have been suggested to link the plasma membrane to the actin-based cytoskeleton and are substrates and anchoring sites for a variety of protein kinases. Here, we examined the role of ezrin in cellular transformation. RESULTS: Fos-mediated transformation of Rat-1 fibroblasts resulted in an increased expression and hyperphosphorylation of ezrin, and a concomitant increased association of ezrin with the cortical cytoskeleton. We tagged ezrin with green fluorescent protein and examined its distribution in normal and Fos-transformed fibroblasts: ezrin was concentrated at the leading edge of extending pseudopodia of Fos-transformed Rat-1 cells, and was mainly cytosolic in normal Rat-1 cells. Functional ablation of ezrin by micro-CALI (chromophore-assisted laser inactivation) blocked plasma-membrane ruffling and motility of Fos-transformed fibroblasts. Ablation of ezrin in normal Rat-1 cells caused a marked collapse of the leading edge of the cell. CONCLUSIONS: Ezrin plays an important role in pseudopodial extension in Fos-transformed Rat-1 fibroblasts, and maintains cell shape in normal Rat-1 cells. The increased expression, hyperphosphorylation and subcellular redistribution of ezrin upon fibroblast transformation coupled with its roles in cell shape and motility suggest a critical role for ezrin in oncogenic transformation.

Radixin is involved in lamellipodial stability during nerve growth cone motility.

Immunocytochemistry and in vitro studies have suggested that the ERM (ezrin-radixin-moesin) protein, radixin, may have a role in nerve growth cone motility. We tested the in situ role of radixin in chick dorsal root ganglion growth cones by observing the effects of its localized and acute inactivation. Microscale chromophore-assisted laser inactivation (micro-CALI) of radixin in growth cones causes a 30% reduction of lamellipodial area within the irradiated region whereas all control treatments did not affect lamellipodia. Micro-CALI of radixin targeted to the middle of the leading edge often split growth cones to form two smaller growth cones during continued forward movement (>80%). These findings suggest a critical role for radixin in growth cone lamellipodia that is similar to ezrin function in pseudopodia of transformed fibroblasts. They are consistent with radixin linking actin filaments to each other or to the membrane during motility.

Methods for ablating neurons.

This past year, laser ablation has been applied to investigations of neuromuscular connectivity in Drosophila, neuronal function in nematode, and mammalian central nervous system development. Ablation by targeted gene expression has been refined and applied to questions of neural development. Chromophore-assisted laser inactivation has been used to demonstrate distinct functions for two proteins during grasshopper neural development.

The neural cell adhesion molecules L1 and NCAM-180 act in different steps of neurite outgrowth.

The formation of neurocircuitry depends on the control of neurite outgrowth that, in turn, can be divided into two processes: nerve growth cone protrusion and neurite extension. It has long been known that the neural cell adhesion molecules L1 and NCAM-180 promote neurite outgrowth, but how they function in growth cones is unclear. We addressed the roles of L1 and NCAM-180 in neurite outgrowth by using microscale chromophore-assisted laser inactivation (micro-CALI) of these proteins to perturb their functions at precise times in single growth cones of embryonic chick dorsal root ganglion neurons grown in culture. Micro-CALI of L1 causes neurite retraction after a 10 min lag period but does not affect growth cone protrusion. In contrast, micro-CALI of NCAM-180 causes rapid growth cone retraction but does not affect neurite extension. The simultaneous inactivation of both these molecules resulted in both distinct effects that were segregated in time. The behavior of growth cones after these micro-CALI treatments resemble the drug-induced perturbation of microtubules for L1 and F-actin for NCAM-180. These findings suggest distinct roles in the growth cone for L1 and NCAM-180 in different steps of neurite outgrowth: L1 functions in neurite extension,whereas NCAM-180 functions in growth cone protrusion.

Chromophore-assisted laser inactivation (CALI) to elucidate cellular mechanisms of cancer.

Chromophore-assisted laser inactivation (CALI) is a new technology for acute protein inactivation in living cells. It targets laser energy to specific proteins via non-function-blocking antibodies that are labeled with the dye malachite green. Excitation of the dye generates short-lived free radicals that damage the bound protein without affecting other cellular components. The wavelength of laser light used (620 nm) is not readily absorbed by cells such that non-specific light damage does not occur. CALI provides an alternative to other inactivation strategies and has the advantages of high spatial and temporal resolution. The ultimate value of this technology for cancer research will be assessed by how effective CALI is in ascribing in situ function during cancer-relevant processes and in identifying and validating protein targets for drug discovery. Recent work using CALI on ezrin and pp60-c-src, two proteins that may be involved in cancer, suggests its potential. Further application of CALI will likely be of utility for understanding cellular mechanisms of cancer and developing cancer therapeutics.

Elimination of EVE protein by CALI in the short germ band insect Tribolium suggests a conserved pair-rule function for even skipped.

The question of the degree of evolutionary conservation of the pair-rule patterning mechanism known from Drosophila is still contentious. We have employed chromophore-assisted laser inactivation (CALI) to inactivate the function of the pair-rule gene even skipped (eve) in the short germ embryo of the flour beetle Tribolium. We show that it is possible to generate pair-rule type phenocopies with defects in alternating segments. Interestingly, we find the defects in odd numbered segments and not in even numbered ones as in Drosophila. However, this apparent discrepancy can be explained if one takes into account that the primary action of eve is at the level of parasegments and that different cuticular markers are used for defining the segment borders in the two species. In this light, we find that eve appears to be required for the formation of the anterior borders of the same odd numbered parasegments in both species. We conclude that the primary function of eve as a pair rule gene is conserved between the two species.

Laminin-induced PC-12 cell differentiation is inhibited following laser inactivation of cellular prion protein.

Prions, the etiological agents for infectious degenerative encephalopathies, act by inducing structural modifications in the cellular prion protein (PrPc). Recently, we demonstrated that PrPc binds laminin (LN) and that this interaction is important for the neuritogenesis of cultured hippocampal neurons. Here we have used the PC-12 cell model to explore the biological role of LN-PrPc interaction. Antibodies against PrPc inhibit cell adhesion to LN-coated culture plaques. Furthermore, chromophore-assisted laser inactivation of cell surface PrPc perturbs LN-induced differentiation and promotes retraction of mature neurites. These results point out to the importance of PrPc as a cell surface ligand for LN.

Micro-scale chromophore-assisted laser inactivation of nerve growth cone proteins.

Directed growth cone movement is crucial for the correct wiring of the nervous system. This movement is governed by the concerted actions of cell surface receptors, signaling proteins, cytoskeleton-associated molecules, and molecular motors. In order to investigate the molecular basis of growth cone motility, we applied a new technique to functionally inactivate proteins: micro-scale Chromophore-Assisted Laser Inactivation [Diamond et al. (1993) Neuron 11:409-421]. Micro-CALI uses laser light of 620 nm, focused through microscope optics into a 10-microm spot. The laser energy is targeted via specific Malachite green-labeled, non-function-blocking antibodies, that generate short-lived protein-damaging hydroxyl radicals [Liao et al. (1994) Proc Natl Acad Sci USA 91:2659-2663]. Micro-CALI mediates specific loss of protein function with unachieved spatial and temporal resolution. Combined with time-lapse video microscopy, it offers the possibility to induce and observe changes in growth cone dynamics on a real time base. We present here the effects of the acute and localized inactivation of selected growth cone molecules on growth cone behavior and morphology. Based on our observations, we propose specific roles for these proteins in growth cone motility and neurite outgrowth.

Chromophore-assisted laser inactivation of subunits of the T-cell receptor in living cells is spatially restricted.

Chromophore-assisted laser inactivation (CALI) is a molecular photoablation technique that has been used to elucidate the in vivo roles of specific proteins in neural development. The interpretation of its effects on proteins in living cells relies on knowing how spatially restricted the CALI-induced damage is in vivo. To determine the spatial specificity of CALI in living cells, we have applied CALI to individual subunits of the T-cell receptor (TCR) complex on the surface of 2B4 hybridoma cells in culture and have examined the consequent structural and functional integrity of the TCR-alpha, TCR-beta and CD3-epsilon. The CALI of TCR-beta resulted in the disruption of the beta subunit and also resulted in a small effect on antibody binding alone to the neighboring TCR-alpha but caused no effect on another subunit, CD3-epsilon. Reciprocal experiments directing CALI to TCR-alpha and CD3-epsilon gave consistent results. No effects other than a simple loss of function were observed for any of these CALI experiments. These data demonstrate the extent of CALI-induced damage within a multisubunit complex in living cells and provide greater confidence for the future application of this technique to understanding in vivo function of proteins during complex cellular processes.

Autocrine semaphorin 3A signaling promotes glioblastoma dispersal.

Glioblastoma multiforme (GBM) is the most malignant glioma type with diffuse borders due to extensive tumor cell infiltration. Therefore, understanding the mechanism of GBM cell dispersal is critical for developing effective therapies to limit infiltration. We identified neuropilin-1 as a mediator of cancer cell invasion by a functional proteomic screen and showed its role in GBM cells. Neuropilin-1 is a receptor for semaphorin3A (Sema3A), a secreted chemorepellent that facilitates axon guidance during neural development. Although neuropilin-1 expression in GBMs was previously shown, its role as a Sema3A receptor remained elusive. Using fluorophore-assisted light inactivation and RNA interference , we showed that neuropilin-1 is required for GBM cell migration. We also showed that GBM cells secrete Sema3A endogenously, and RNA interference-mediated downregulation of Sema3A inhibits migration and alters cell morphology that is dependent on Rac1 activity. Sema3A depletion also reduces dispersal, which is recovered by supplying Sema3A exogenously. Extracellular application of Sema3A decreases cell-substrate adhesion in a neuropilin-1-dependent manner. Using immunohistochemistry, we showed that Sema3A is overexpressed in a subset of human GBMs compared with the non-neoplastic brain. Together, these findings implicate Sema3A as an autocrine signal for neuropilin-1 to promote GBM dispersal by modulating substrate adhesion and suggest that targeting Sema3A-neuropilin-1 signaling may limit GBM infiltration.

Selective destruction of protein function by chromophore-assisted laser inactivation.

Chromophore-assisted laser inactivation of protein function has been achieved. After a protein binds a specific ligand or antibody conjugated with malachite green (C.I. 42,000), it is selectively inactivated by laser irradiation at a wavelength of light absorbed by the dye but not significantly absorbed by cellular components. Ligand-bound proteins in solution and on the surfaces of cells can be denatured without other proteins in the same samples being affected. Chromophore-assisted laser inactivation can be used to study cell surface phenomena by inactivating the functions of single proteins on living cells, a molecular extension of cellular laser ablation. It has an advantage over genetics and the use of specific inhibitors in that the protein function of a single cell within the organism can be inactivated by focusing the laser beam.

Glycosylation site of band 3, the human erythrocyte anion-exchange protein.

The band 3 protein has a single glycosylation site on the carboxy-terminal 55 000-dalton tryptic fragment that defines a sequence of the polypeptide on the extracytoplasmic surface of the cell. To locate this site, a novel procedure involving end labeling of the 55 000-dalton tryptic fragment was used. Peptides resulting from partial proteolysis of the end radiolabeled glycoprotein were separated by lectin-Sepharose chromatography and analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography. The smallest fragment observed defined the distance between the glycosylation site and the amino terminus. The procedure was first tested on a protein for which the location of the glycosylation site is known, HLA-B7 antigen. It was then used to show that the glycosylation site of human band 3 is 28 000 +/- 3000 daltons from the carboxy terminus of the protein.