Localization of alpha integrin subunits in the neural retina of the tiger salamander.

BACKGROUND: Integrin receptors mediate cell-extracellular matrix interactions and regulate many events, including cell growth, proliferation, and differentiation. Retinal integrins are incompletely understood, although these receptors are potentially important factors in normal retinal function and pathology. METHODS: Immunocytochemistry was used to localize alpha integrin subunits 1-6 in the neural retina. RESULTS: Each alpha integrin subunit had a unique distribution in the retina, although there was considerable overlap among subunits. The alpha 1 subunit was broadly distributed throughout the retina, with some presumptive ganglion cells showing enriched labeling. The alpha 2 subunit was present on all retinal cell bodies, but was reduced in synaptic layers. The alpha 3 subunit was present in synaptic layers, Müller cells, and some cone and amacrine cells. The alpha 4 subunit was broadly distributed in the nuclear layers but was reduced in synaptic layers. The alpha 5 subunit was broadly expressed in the nuclear and synaptic layers with enriched labeling in the outer plexiform layer. Labeling for the alpha 6 subunit was restricted to the outer limiting membrane and some cone outer segments. Double-labeling studies indicated that photoreceptor terminals may exhibit alpha 1 and alpha 5 subunits, while processes from second-order neurons may exhibit alpha 1, alpha 3, and alpha 5 subunits. CONCLUSION: Integrin receptors containing the alpha 1, alpha 3, and alpha 5 subunits may have important functions at retinal synapses, in addition to roles in the nuclear layers. Integrin receptors containing alpha 2, alpha 4, and alpha 6 subunits probably serve non-synaptic functions.

The effect of N-bromosuccinimide on ferredoxin:NADP+ oxidoreductase.

Treatment of spinach leaf ferredoxin:NADP+ oxidoreductase (FNR) with N-bromosuccinimide (NBS), under conditions where approximately one tryptophan residue per enzyme was modified, resulted in a loss of between 80 and 85% of the activity of the enzyme when electron transfer from NADPH to either ferredoxin or 2,6-dichlorophenol-indophenol was measured. Amino acid analysis revealed no detectable modification by NBS of any FNR amino acids other than tryptophan. Complex formation with ferredoxin, but not with NADP+, prevented both the inhibition of activity and the modification of tryptophan caused by the treatment with NBS. Modification of one FNR tryptophan residue had no significant effect on the Km values of the enzyme for either ferredoxin or NADPH or on the binding constants for the FNR complexes with either ferredoxin or NADP+. NBS treatment had only very small effects on the absorbance and circular dichroism spectra of FNR and did not significantly affect either the oxidation-reduction midpoint potential of the FAD prosthetic group of the enzyme or inhibit the reduction of the FAD group by NADPH. These results raise the possibility that a tryptophan residue may play a role in the electron transfer between the FAD of FNR and the enzyme substrate, ferredoxin.