Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:4.6.1.2 (guanylate cyclase)
 8,497 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Several mechanisms are used to control the behaviour of sea urchin spermatozoa while fertilizing eggs. These include discrete regulatory steps that modulate the sperm activation sequence from spawning to gamete membrane fusion. After release from the testis, sperm motility is instantaneously activated, by using intracellular pH as a throttle mechanism to control the rate of the dynein motor that catalyses axonemal bending. To support motility, energy is transported from the mitochondrion to the tail, by using a shuttle mechanism involving phosphocreatine diffusion. This shuttle employs a novel, endotriplicated, creatine kinase of Mr 140,000 in the flagellar axoneme as its terminus. The steering mechanism that determines where the spermatozoon swims is unknown, but may involve an egg peptide-induced guanylate cyclase activation, mediated by a cGMP-dependent Ca2+ channel, and attenuated by a plasma membrane cGMP phosphodiesterase. Upon arriving at the egg, which is identified by virtue of its proteoglycan coat (egg jelly), the spermatozoon undergoes a univesicular secretion that prepares it to fuse with the egg. This acrosome reaction involves several altered ionic fluxes in its mechanism, terminating in a massive Ca2+ uptake. If the spermatozoon is fortunate enough to fuse with an egg, a new member of the species is generated; if the acrosome reaction occurs without gamete fusion, the spermatozoon rapidly dies. All of these activation processes involve changes in the intracellular ionic milieu that are co-ordinated with altered enzyme activities, often in a causal fashion. Even with our current imperfect understanding of the process, a few of the steps in sperm activation may be defined by biochemical pathways that include specific modulatory control points.
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PMID:Molecular mechanisms of sea-urchin sperm activation before fertilization. 196

Freeze-dried sections were prepared from retinas of frogs which were dark-adapted or exposed to varying periods of light. Samples of the discrete layers were dissected, weighed, and analyzed for energy metabolites, guanylate compounds, and the enzyme guanylate cyclase. ATP and P-creatine were measured in both dark- and light-adapted retinas. There was a gradient in ATP and P-creatine levels in dark-adapted retinas, with the lower concentrations in the photoreceptors, and increasing concentrations in the inner retina. After light adaptation, concentrations increased, an observation which supports the concept that transmitter release occurs in the dark and ceases in the light. The sum of GTP plus GDP, GDP, and cyclic GMP were analyzed in dark-adapted retinas and after exposure to 2 min or 2 h of room light. GDP was rather uniformly distributed in the retinal layers, was increased by 2 min of light in all layers but the outer nuclear, and remained elevated at 2 h in the inner retina. GTP values showed a marked localization in the outer nuclear layer, which increased after 2 min or 2 h of illumination; in all other layers GTP was decreased by light. Cyclic GMP in the dark was highest in the photoreceptor cells, decreasing to one-third after 2 min of light; there were significant increases in the outer plexiform and inner nuclear layers at this time. Cyclic GMP remained low in the photoreceptor cells even after 2 h of light, while the inner layers returned to dark values. Guanylate cyclase, like cyclic GMP, was largely confined to the photoreceptor cells and showed a maximal increase after 2 min of light exposure.
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PMID:Light-induced changes in energy metabolites, guanine nucleotides, and guanylate cyclase within frog retinal layers. 611 Jun 61