Protein tyrosine phosphatase alpha (PTPalpha) and contactin form a novel neuronal receptor complex linked to the intracellular tyrosine kinase fyn.

Glycosyl phosphatidylinositol (GPI)-linked receptors and receptor protein tyrosine phosphatases (RPTPs), both play key roles in nervous system development, although the molecular mechanisms are largely unknown. Despite lacking a transmembrane domain, GPI receptors can recruit intracellular src family tyrosine kinases to receptor complexes. Few ligands for the extracellular regions of RPTPs are known, relegating most to the status of orphan receptors. We demonstrate that PTPalpha, an RPTP that dephosphorylates and activates src family kinases, forms a novel membrane-spanning complex with the neuronal GPI-anchored receptor contactin. PTPalpha and contactin associate in a lateral (cis) complex mediated through the extracellular region of PTPalpha. This complex is stable to isolation from brain lysates or transfected cells through immunoprecipitation and to antibody-induced coclustering of PTPalpha and contactin within cells. This is the first demonstration of a receptor PTP in a cis configuration with another cell surface receptor, suggesting an additional mode for regulation of a PTP. The transmembrane and catalytic nature of PTPalpha indicate that it likely forms the transducing element of the complex, and we postulate that the role of contactin is to assemble a phosphorylation-competent system at the cell surface, conferring a dynamic signal transduction capability to the recognition element.

Neuronal cell adhesion molecule contactin/F11 binds to tenascin via its immunoglobulin-like domains.

Adhesive interactions between neurons and extracellular matrix (ECM) play a key role in neuronal pattern formation. The prominent role played by the extracellular matrix protein tenascin/cytotactin in the development of the nervous system, tied to its abundance, led us to speculate that brain may contain yet unidentified tenascin receptors. Here we show that the neuronal cell adhesion molecule contactin/F11, a member of the immunoglobulin(Ig)-superfamily, is a cell surface ligand for tenascin in the nervous system. Through affinity chromatography of membrane glycoproteins from chick brain on tenascin-Sepharose, we isolated a major cell surface ligand of 135 kD which we identified as contactin/F11 by NH2-terminal sequencing. The binding specificity between contactin/F11 and tenascin was demonstrated in solid-phase assays. Binding of immunopurified 125I-labeled contactin/F11 to immobilized tenascin is completely inhibited by the addition of soluble tenascin or contactin/F11, but not by fibronectin. When the fractionated isoforms of tenascin were used as substrates, contactin/F11 bound preferentially to the 190-kD isoform. This isoform differs in having no alternatively spliced fibronectin type III domains. Our results imply that the introduction of these additional domains in some way disrupts the contactin/F11 binding site on tenascin. To localize the binding site on contactin/F11, proteolytic fragments were generated and characterized by NH2-terminal sequencing. The smallest contactin/F11 fragment which binds tenascin is 45 kD and also begins with the contactin/F11 NH2-terminal sequence. This implies that contactin/F11 binds to tenascin through a site within the first three Ig-domains.

Contactin/F11 and tenascin-C co-expression in the chick retina correlates with formation of the synaptic plexiform layers.

The neural immunoglobulin-like cell adhesion molecule contactin/F11 and the extracellular matrix glycoprotein tenascin-C are prominent molecules in the developing nervous system which interact in in vitro assays (Zisch et al., J. Cell Biol. 119, 203-213). To determine their potential role in neural development, the distribution of tenascin-C and contactin/F11 was examined in the developing chick retina. The onset of both tenascin-C and contactin/F11 expression coincides with the appearance of ganglion cell dendrides and neurites from bipolar and amacrine cells in the inner layer (IPL) at E8, and the extension of bipolar and horizontal cell processes in the outer plexiform layer (OPL) at E9. Contactin/F11 expression is co-ordinately upregulated with the TN190 and TN200 tenascin-C isoforms between embryonic day 8 (E8) and E17, while little, if any, of the TN220 isoform, which does not bind contactin/F11, is detected. In situ hybridization reveals that tenascin-C and contactin/F11 mRNAs are synthesized by different neuronal types. Tenascin-C mRNA probes hybridize to amacrine and displaced amacrine neurons, and horizontal neurons. In cultured retinal cells, tenascin-C is also present on process-bearing neurofilament-positive cells. Contactin/F11 mRNA is detected in bipolar cells or their precursors from E8-9, and later in horizontal and ganglion neurons. The highest levels and greatest overlap in the synaptic IPL and OPL are reached at E17, when the stratification of the retina is nearly complete. These results are consistent with a putative role for contactin/F11-tenascin-C interactions in the establishment of synaptic layers in the retina.

Eventual error caused by dehydration with pachometry.

Among the possible variables responsible for systemic errors in the acquisition of pachometric measurements, the corneal hydration condition plays a determinant role. In the present study, the authors have investigated the importance of this condition with two different pachometers (Storz Corneoscan II and Allergan Humphrey), reproducing an experimental dehydrated condition. The main datum arising from the comparison of the measurements obtained is represented by the different time course of the value of the measurement in the two groups. In fact, confronting the medium initial superimposed thickness value in the two tables (521 vs. 520 microm) there is a substantial difference in the final examination. For the first group of 60 corneas, the thickness values appear almost identical in the different intervals of time (medium initial thickness 521 vs. 512 microm final thickness). For the group examined with the solid-point machine, a decreasing thickness equal to 7% was evidenced (520 vs. 482 microm) with a significant decrease in the corneal thickness after only 45 s.

Tenascin-contactin/F11 interactions: a clue for a developmental role?

To understand how the extracellular matrix glycoprotein tenascin modifies cell adhesion and neurite outgrowth, we sought to isolate cellular receptors for tenascin. So far, two completely different cell surface ligands for tenascin have been detected. This we achieved by affinity chromatography of tissue extracts and of isolated proteins over tenascin-Sepharose and by solid-phase assays using the individual proteins. The first receptor, the neuronal cell adhesion molecule contactin/F11, a member of the immunoglobulin superfamily, binds to tenascin via a site in the N-terminal immunoglobulin-like domains. The binding site is within the fibronectin type III homology region at the boundary of the alternatively spliced region of tenascin, requiring that fibronectin type III homology domains 5 and 9 be adjacent, as they are in the 190 kD tenascin isoform. The close similarity in tertiary structure between type III domains and immunoglobulin-like repeats raises the possibility that we are observing a side-by-side interaction between the two molecules in a manner closely analogous to that between paired immunoglobulin domains. The second receptor is the heparan sulfate proteoglycan, glypican, which, similarly to contactin/F11, is anchored to the membrane via glycosylphosphatidylinositol. Glypican bound to a column of tenascin-Sepharose cannot be dissociated by chondroitin sulfate or dermatan sulfate, but elutes in a broad peak with a gradient of heparan sulfate and in a sharper peak with heparin. By means of fusion proteins, we have identified a potential binding site on the fifth fibronectin type III homology domain of tenascin. We are trying to define these sites more closely by means of site-directed mutagenesis. It will be interesting to see whether the interaction between tenascin and cell surface contactin/F11, and possibly cellular heparan sulfate proteoglycans, contributes to the prominent role played by tenascin in pattern formation during development of the nervous system. In a first step, we have examined the distribution of tenascin isoforms and contactin/F11 during retinal development by means of immunohistochemistry and in situ hybridization with tenascin isoform-specific probes. Tenascin isoforms 190/200 along with contactin/F11 are particularly prominent in the inner and outer plexiform layers of embryonic day 8 retina in the chick. This coordinate up-regulation was confirmed both by immunoblots and Northern blots of retinal extracts. A speculative model is presented to suggest how the unique hexabrachion may signal the cell via contactin/F11.

Stimulation of the electron transport chain in mitochondria isolated from rats treated with mannoheptulose or glucagon.

We investigated the kinetics of the mitochondrial respiratory chain, proton leak, and phosphorylating subsystems of liver mitochondria from mannoheptulose-treated and control rats. Mannoheptulose treatment raises glucagon and lowers insulin; it had no effect on the kinetics of the mitochondrial proton leak or phosphorylating subsystems, but the respiratory chain from succinate to oxygen was stimulated. Previous attempts to detect any stimulation of cytochrome c oxidase by glucagon are shown by flux control analysis to have used inappropriate assay conditions. To investigate the site of stimulation of the respiratory chain we measured the relationship between the thermodynamic driving force and respiration rate for the span succinate to coenzyme Q, the cytochrome bc1 complex and cytochrome c oxidase. Hormone treatment of rats altered the kinetics of electron transport from succinate to coenzyme Q in subsequently isolated mitochondria and activated succinate dehydrogenase. The kinetics of electron transport through the cytochrome bc1 complex were not affected. Effects on cytochrome c oxidase were small or nonexistent.

The glypiated neuronal cell adhesion molecule contactin/F11 complexes with src-family protein tyrosine kinase Fyn.

Glycosyl phosphatidylinositol-anchored glycoproteins of the immunoglobulin superfamily play an important role in the formation of neuronal networks during development. The mechanism whereby neuronal GPI-linked molecules transduce recognition signals remains to be established. Analysis of detergent-resistant immune-complexes reveals that the glypiated neuronal cell adhesion molecule contactin/F11 specifically complexes with the cytoplasmic, nonreceptor type src-family tyrosine kinase Fyn. Antibody-mediated cross-linking of contactin/F11 on embryonic chick neuronal cells leads to an increase of the Fyn-activity coprecipitated with contactin/F11, and elevates phosphorylation of an additional 75/80 K component within the contactin/F11-immune-complex. Additionally, binding of ligands, i.e., contactin/F11-specific antibody or tenascin-R, a natural ligand of contactin/F11, to the surface of HeLa transfectants expressing contactin/F11, causes capping of contactin/F11 and a concomitant change in the distribution of the intracellular kinase Fyn, thus confirming their physical association. This indicates that contactin/F11-mediated signaling requires Fyn.