Coupling between the N- and C-terminal domains influences transducin-alpha intrinsic GDP/GTP exchange

The N-terminal regions of the heterotrimeric G-protein alpha-subunits represent one of the major Gbetagamma contact sites and have been implicated in an interaction with G-protein-coupled receptors. To probe the role of the N-terminal domain of transducin-alpha in G-protein function, a chimeric Gtialpha subunit with the 31 N-terminal Gtalpha residues replaced by the corresponding 42 residues of Gsalpha (Ns-Gtialpha) has been examined for the interaction with light-activated rhodopsin (R). Gtialpha displayed a somewhat higher R-stimulated rate of GTPgammaS binding relative to Ns-Gtialpha, suggesting modest involvement of the Gtalpha N-terminal sequence in recognition of the receptor. However, the intrinsic rate of nucleotide exchange in Ns-Gtialpha was significantly faster (k(app) = 0.014 min(-)(1)) than that in Gtialpha (k(app) = 0.0013 min(-1)) as judged by the GTPgammaS binding rates. Substitution of 42 N-terminal residues of Gsalpha by the Gtalpha residues in a reciprocal chimera, Nt-Gsalpha, had an opposite effect-notable reduction in the intrinsic GTPgammaS-binding rate (k(app) = 0.0075 min(-)(1)) in comparison with Gsalpha (k(app) = 0.028 min(-)(1)). Residue Val30 (His41 in Gsalpha) within the N-terminal region of Gtalpha interacts with the C-terminal residue, Ile339. To test the hypothesis that observed changes in the intrinsic nucleotide exchange rate in chimeric Galpha subunits might be attributed to this interaction, GtialphaVal30His, GtialphaIle339Ala, and Ns-GtialphaHis41Val mutants have been made and analyzed for basal GTPgammaS binding. GtialphaVal30His and GtialphaIle339Ala had increased GTPgammaS binding rates (k(app) = 0. 010 and 0.009 min(-)(1), respectively), whereas Ns-GtialphaHis41Val had a decreased GTPgammaS binding rate (k(app) = 0.0011 min(-)(1)) relative to their parent proteins. These results suggest that the coupling between the N-terminal and C-terminal domains of Gtalpha is important for maintaining a low nucleotide exchange rate in unstimulated transducin.     

Beta-subunit of bovine rod photoreceptor cGMP phosphodiesterase. Comparison with the phosphodiesterase family

A group of cDNA clones encoding the beta-subunit of bovine rod photoreceptor cGMP phosphodiesterase were isolated for structural analysis. The encoded polypeptide has 853 residues with a calculated molecular mass of 98 kDa. The beta-subunit is 72% identical to the rod cGMP phosphodiesterase alpha-subunit. Like the alpha-subunit and the cone alpha'-subunit, the beta-subunit belongs to the family of phosphodiesterase genes. The beta- and alpha-subunits are more similar to each other than either is to the cone alpha'-subunit, suggesting either that the beta- and alpha-subunits diverged more recently or that their divergence was restrained by the rod functional environment.     

Cyclic GMP phosphodiesterase from bovine retina. Amino acid sequence of beta-subunit and nucleotide sequence of corresponding cDNA

Primary structure of beta-subunit of the cyclic GMP phosphodiesterase has been determined by the parallel analysis of the protein amino acid sequence and the corresponding cDNA nucleotide sequence. The beta-subunit contains 852 amino acid residues, its molecular mass is 98291 Da. A significant homology is found between beta- and alpha-subunit of the cGMP phosphodiesterase.     

The Insecticidal Activity of Bacillus thuringiensisCells

The effects of sixteen different nutrient media on the entomopathogenic activity of three Bacillus thuringiensisstrains was studied. The medium composition based on potato, yeast extract, and molasses was optimized. B. thuringiensisno. 1 grown on the media nos. 7 and 9 displayed the highest entomopathogenic activity (94.3 and 90.6%, respectively).     

Biosynthesis of Pectinase by Fungi of the Genera Bjerkanderaand Coriolusduring Solid-Phase Fermentation

Production of an extracellular pectinase by wood-rot fungi of the genus Bjerkanderaand Corioluswas studied. The active producersB. adusta40 and C. versicolor24 were selected. The dynamics of production of pectinase and effects of temperature, initial pH, humidity of the medium, and addition of nitrogen sources on the biosynthesis of pectinase were studied.     

The inhibitory gamma subunit of the rod cGMP phosphodiesterase binds the catalytic subunits in an extended linear structure

The unique feature of rod photoreceptor cGMP phosphodiesterase (PDE6) is the presence of inhibitory subunits (Pgamma), which interact with the catalytic heterodimer (Palphabeta) to regulate its activity. This uniqueness results in an extremely high sensitivity and sophisticated modulations of rod visual signaling where the Pgamma/Palphabeta interactions play a critical role. The quaternary organization of the alphabetagammagamma heterotetramer is poorly understood and contradictory patterns of interaction have been previously suggested. Here we provide evidence that supports a specific interaction, by systematically and differentially analyzing the Pgamma-binding regions on Palpha and Pbeta through photolabel transfer from various Pgamma positions throughout the entire molecule. The Pgamma N-terminal Val16-Phe30 region was found to interact with the Palphabeta GAFa domain, whereas its C terminus (Phe73-Ile87) interacted with the Palphabeta catalytic domain. The interactions of Pgamma with these two domains were bridged by its central Ser40-Phe50 region through interactions with GAFb and the linker between GAFb and the catalytic domain, indicating a linear and extended interaction between Pgamma and Palphabeta. Furthermore, a photocross-linked product alphabetagamma(gamma) was specifically generated by the double derivatized Pgamma, in which one photoprobe was located in the polycationic region and the other in the C terminus. Taken together the evidence supports the conclusion that each Pgamma molecule binds Palphabeta in an extended linear interaction and may even interact with both Palpha and Pbeta simultaneously.     

Loss of the effector function in a transducin-alpha mutant associated with Nougaret night blindness

A missense mutation, G38D, was found in the rod transducin alpha subunit (Galpha(t)) in individuals with the Nougaret form of dominant stationary night blindness. To elucidate the mechanism of Nougaret night blindness, we have examined the key functional properties of the mutant transducin. Our data show that the G38D mutation does not alter the interaction between Galpha(t) and Gbetagamma(t) or activation of transducin by photoexcited rhodopsin (R*). The mutant Galpha(t) has only a modestly (approximately 2.5-fold) reduced k(cat) value for GTP hydrolysis. The GTPase activity of Galpha(t)G38D can be accelerated by photoreceptor regulator of G protein signaling, RGS9. Analysis of the Galpha(t)G38D interaction with cGMP phosphodiesterase revealed marked impairment of the mutant effector function. Galpha(t)G38D completely fails to bind the inhibitory PDE gamma subunit and activate the enzyme. Altogether, our results demonstrate a novel molecular mechanism in dominant stationary night blindness. In contrast to known forms of the disease caused by constitutive activation of the visual cascade, the Nougaret form has its origin in attenuated visual signaling due to loss of effector function by transducin G38D mutant.