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Query: EC:4.6.1.1 (
adenylate cyclase
)
19,190
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Several domains of guanine nucleotide-binding proteins are conserved and form the guanine nucleotide-binding pocket. Mutations in these domains in
EF-Tu
, ras, and Gas have been shown to result in informative phenotypes. We made several analogous changes in SCG1, which encodes the alpha subunit of the G protein involved in pheromone response in yeast. The scg1Lys388 and scg1Ala391 mutations resulted in severe growth and cell morphology defects; this phenotype is similar to the null phenotype and results from constitutive activation of the pheromone response pathway. On the basis of the model for the action of the yeast G protein, the effect of these mutations is consistent with the effect of analogous mutations in ras, which result in a transforming phenotype. The SCG1Ala322 mutation resulted in pheromone response and mating defects. This effect is similar to the effect of the analogous G alpha s mutation, which results in a defect in stimulation of
adenylate cyclase
. The scg1Val50 mutation, which is analogous to the transforming mutation rasVal12, resulted in multiple effects, including defects in growth, cell morphology, and mating. Some of our results and interpretations are different from previously published results of others for the same mutation in SCG1; specifically, our gene replacement of this mutation resulted in high basal activation of the pheromone response pathway, consistent with a GTPase defect, which was not seen previously with scg1Val50 on a low-copy plasmid. Implications of these phenotypes are discussed.
...
PMID:Mutations in the guanine nucleotide-binding domains of a yeast G alpha protein confer a constitutive or uninducible state to the pheromone response pathway. 190 Apr 95
Transducin, a GTP-binding protein involved in phototransduction in the vertebrate retina, belongs to a family of homologous coupling proteins that also includes Gs and Gi, the regulatory proteins of
adenylate cyclase
. Here we report the cDNA sequence and deduced amino acid sequence of transducin's alpha subunit (T alpha). The cDNA was isolated, by screening with an antibody probe, from a bovine retinal cDNA library in the expression vector lambda gt11. The 2.2-kilobase cDNA insert hybridized to a single 2.6-kilobase poly(A)+ RNA species present in extracts of bovine retina but not of bovine heart, liver, or brain. The nucleotide sequence of the cDNA revealed an open reading frame long enough to encode the entire 39-kDa T alpha polypeptide. The polypeptide sequence deduced from the cDNA would be composed of 350 amino acids and have a molecular weight of 39,971. Portions of the sequence matched reported amino acid sequences of T alpha tryptic fragments, including sites specifically ADP-ribosylated by cholera and pertussis toxins. The predicted sequence also includes four segments, ranging from 11 to 19 residues in length, that exhibit significant homology to sequences of GTP-binding proteins, including the ras proteins of man and yeast and the elongation factors of ribosomal protein synthesis in bacteria, EF-G and
EF-Tu
. In combination with previous functional studies of tryptic fragments of T alpha, the deduced amino acid sequence makes it possible to predict which portions of the polypeptide interact with other molecules involved in retinal phototransduction.
...
PMID:Amino acid sequence of the alpha subunit of transducin deduced from the cDNA sequence. 240 55
To identify the amino acid residues of the Harvey (Ha) ras-encoded protein that are involved in protein-protein interactions, we have created a series of mutant Ha-ras proteins. In particular, amino acid substitutions have been introduced within two regions, residues 32-42 and 61-80, that are conserved among ras proteins from different species. We observed that amino acid substitutions at positions 35, 36, 38, 40, and, to a lesser extent, 39 and 78 reduce the biological potency of Ha-ras protein in both mammalian and Saccharomyces cerevisiae cells, without noticeably affecting the known intrinsic biochemistry of these proteins. The reduction of in vivo activity for these mutant ras proteins correlates with their reduced ability to stimulate yeast
adenylate cyclase
. The ras-protein-neutralizing antibody Y13-259 binds to six residues: Glu-63, Ser-65, Ala-66, Met-67, Gln-70, and Arg-73. Single substitutions for these residues reduce Y13-259 antibody binding by at least a factor of 1000 but do not significantly affect biological activity. These data are discussed in terms of the model for Ha-ras protein based on the structure of the elongation factor
EF-Tu
-GDP complex.
...
PMID:Identification of effector residues and a neutralizing epitope of Ha-ras-encoded p21. 242 52
A unique feature of eucaryotic adenylate cyclases is their interaction with GTP-binding proteins that mediate hormonal responses. Until now, there has been no evidence for regulation of Escherichia coli
adenylate cyclase
by a GTP-binding protein. We describe here that the most abundant protein in E. coli, the GTP-binding protein
EF-Tu
, which is important as an elongation factor in protein synthesis, also serves as a stimulator of
adenylate cyclase
activity. Homogeneous
EF-Tu
specifically increased the activity of purified
adenylate cyclase
as much as 70%; other E. coli GTP-binding proteins had no effect on enzyme activity. A study of the guanine nucleotide specificity for
EF-Tu
-mediated stimulation of
adenylate cyclase
activity suggested that the preferred activator is
EF-Tu
X GDP. To account for the GTP-specific stimulation of
adenylate cyclase
activity observed in intact cells, we propose that the nucleotide specificity for
EF-Tu
-dependent activation of
adenylate cyclase
is governed by other factors in the cell.
...
PMID:Stimulation of Escherichia coli adenylate cyclase activity by elongation factor Tu, a GTP-binding protein essential for protein synthesis. 301 31
Cancer is a malfunction of cellular growth control. The discovery of oncogenes, first in transforming retroviruses, and later in human and animal tumors, may have uncovered the key to understanding one of the most elusive subjects of basic cell biology, namely, the controlling mechanisms of cell growth. The ras gene family encodes a group of closely related 21,000 dalton (p21) proteins with special affinity for guanine nucleotides. Other cellular proteins with similar biochemical properties, collectively known as G-proteins, include the regulatory G proteins of
adenylate cyclase
, the alpha subunit of transducin of retina rod outer segments, the recently identified rho gene proteins, and perhaps also the elongation factors,
EF-Tu
and EF-G, of the protein synthesis system. These G-proteins have roles in cellular signal transduction; by analogy p21 may have a similar cellular function in mediating the flow of growth control signals. Recent progress in the cloning and sequencing of these genes, overproduction of gene products in E. coli, protein engineering, detailed biochemical characterization, and the molecular structure determined by high resolution X-ray crystallography, have helped to elucidate in great detail the structure and function of p21 ras proteins. p21 appears to have a small membrane binding domain at the C-terminus, which contains a palmitylation site at cysteine-186, four amino acid residues from the end. Separated by a variable "hinge" region, most of the rest of ras amino acid sequences are highly conserved in nature. Four regions of extensive sequence homology among G-proteins constitute the GTP/GDP binding domain. In the crystal structure of
EF-Tu
, four peptide loops connecting beta sheets and alpha helices form the pocket for binding GDP. Studies using site-directed mutagenesis and immnochemical probes, indicate that the basic structure of the GDP binding site is conserved between p21 and
EF-Tu
. Furthermore, these studies also conclude that GTP binding is crucial for p21 ras cellular function. Although the precise target molecules for p21 are still unknown, the finding of the on/off switch function for ras genes have provided a better understanding of the mechanism of proto-oncogene activation, and may also provide further impetus to explore means of cancer intervention by interfering with the switch function.
...
PMID:Structure and function of p21 ras proteins. 333 61
