Thiol changes during epididymal maturation: a link to flagellar angulation in mouse spermatozoa?

Caput epididymal wild-type spermatozoa and cauda epididymal spermatozoa from mice null for the adenylyl cyclase Adcy10 gene are immotile unless stimulated by a membrane-permeant cyclic AMP analogue. Both types of spermatozoa exhibit flagellar angulation where the head folds back under these conditions. As sperm proteins undergo oxidation of sulfhydryl groups and the flagellum becomes more stable to external forces during epididymal transit, we hypothesized that ADCY10 is involved in a mechanism regulating flagellar stabilization. Although no differences were observed in global sulfhydryl status between caput and cauda epididymal spermatozoa from wild-type or Adcy10-null mice, two-dimensional fluorescence difference gel electrophoresis was performed to identify specific mouse sperm proteins containing sulfhydryl groups that became oxidized during epididymal maturation. A-kinase anchor protein 4, fatty acid-binding protein 9 (FABP9), glutathione S-transferase mu 5 and voltage-dependent anion channel 2 exhibited changes in thiol status between caput and cauda epididymal spermatozoa. The level and thiol status of each of these proteins were quantified in wild-type and Adcy10-null cauda epididymal spermatozoa. No differences in the abundance of any protein were observed; however, FABP9 in Adcy10-null cauda epididymal spermatozoa contained fewer disulfide bonds than wild-type sperm cells. In caput epididymal spermatozoa, FABP9 was detected in the cytoplasmic droplet, principal piece, midpiece, and non-acrosomal area of the head. However, in cauda epididymal spermatozoa, this protein localized to the perforatorium, post-acrosomal region and principal piece. Together, these results suggest that thiol changes during epididymal maturation have a role in the stabilization of the sperm flagellum.

High adenylyl cyclase activity and in vivo cAMP fluctuations in corals suggest central physiological role.

Corals are an ecologically and evolutionarily significant group, providing the framework for coral reef biodiversity while representing one of the most basal of metazoan phyla. However, little is known about fundamental signaling pathways in corals. Here we investigate the dynamics of cAMP, a conserved signaling molecule that can regulate virtually every physiological process. Bioinformatics revealed corals have both transmembrane and soluble adenylyl cyclases (AC). Endogenous cAMP levels in live corals followed a potential diel cycle, as they were higher during the day compared to the middle of the night. Coral homogenates exhibited some of the highest cAMP production rates ever to be recorded in any organism; this activity was inhibited by calcium ions and stimulated by bicarbonate. In contrast, zooxanthellae or mucus had >1000-fold lower AC activity. These results suggest that cAMP is an important regulator of coral physiology, especially in response to light, acid/base disturbances and inorganic carbon levels.

CO(2)/HCO(3)(-)-responsive soluble adenylyl cyclase as a putative metabolic sensor.

Cyclic AMP (cAMP) is an evolutionarily conserved regulator of metabolism. Recently, we identified a novel mammalian source of cAMP - soluble adenylyl cyclase (sAC) - that is regulated directly by bicarbonate ions (HCO(3)(-)). As the concentration of HCO(3)(-) reflects cellular levels of carbon dioxide (CO(2)), energy-generating metabolic processes (which increase intracellular CO(2)) are poised to activate bicarbonate-responsive sAC. This direct link between metabolic activity, sAC and cAMP could represent an evolutionarily conserved mechanism of metabolic feedback regulation.

Bicarbonate-regulated soluble adenylyl cyclase.

Soluble adenylyl cyclase (sAC) represents a novel form of mammalian adenylyl cyclase structurally, molecularly, and biochemically distinct from the G protein-regulated, transmembrane adenylyl cyclases (tmACs). sAC possesses no transmembrane domains and is insensitive to classic modulators of tmACs, such as heterotrimeric G proteins and P site ligands. Thus, sAC defines an independently regulated cAMP signaling system within mammalian cells. sAC is directly stimulated by bicarbonate ion both in vivo in heterologously expressing cells and in vitro using purified protein. sAC appears to be the predominant form of adenylyl cyclase (AC) in mammalian sperm, and its direct activation by bicarbonate provides a mechanism for generating the cAMP required to complete the bicarbonate-induced processes necessary for fertilization, including hyperactivated motility, capacitation, and the acrosome reaction. Immunolocalization studies reveal sAC is also abundantly expressed in other tissues which respond to bicarbonate or carbon dioxide levels suggesting it may function as a general bicarbonate/CO(2) sensor throughout the body.

Soluble adenylyl cyclase as an evolutionarily conserved bicarbonate sensor.

Spermatozoa undergo a poorly understood activation process induced by bicarbonate and mediated by cyclic adenosine 3',5'-monophosphate (cAMP). It has been assumed that bicarbonate mediates its effects through changes in intracellular pH or membrane potential; however, we demonstrate here that bicarbonate directly stimulates mammalian soluble adenylyl cyclase (sAC) activity in vivo and in vitro in a pH-independent manner. sAC is most similar to adenylyl cyclases from cyanobacteria, and bicarbonate regulation of cyclase activity is conserved in these early forms of life. sAC is also expressed in other bicarbonate-responsive tissues, which suggests that bicarbonate regulation of cAMP signaling plays a fundamental role in many biological systems.

Specific expression of soluble adenylyl cyclase in male germ cells.

The cAMP signaling pathway is an important mediator of extracellular signals in organisms from prokaryotes to higher eukaryotes. In mammals two types of adenylyl cyclase synthesize cAMP; a ubiquitous family of transmembrane isoforms regulated by G proteins in response to extracellular signals, and a recently isolated soluble enzyme insensitive to heterotrimeric G protein modulation. Using the very sensitive reverse transcription-polymerase chain reaction (RT-PCR), soluble adenylyl cyclase (sAC) expression is detectable in almost all tissues examined; however, Northern analysis and in situ hybridization indicate that high levels of sAC message are unique to male germ cells. Elevated levels of sAC mRNA are first observed in pachytene spermatocytes and expression increases through spermiogenesis. The accumulation of high levels of message in round spermatids suggests sAC protein plays an important role in the generation of cAMP in spermatozoa, implying possible roles in sperm maturation through the epididymis, capacitation, hypermotility, and/or the acrosome reaction.

A calcium-inhibited Drosophila adenylyl cyclase.

Mammals possess a family of transmembrane, G-protein-responsive adenylyl cyclase isoforms (tmACs) encoded by distinct genes differing in their patterns of expression and modes of biochemical regulation. Our previous work confirmed that Drosophila melanogaster also possesses a family of tmAC isoforms defining the fly as a suitable genetic model for discerning mammalian tmAC function. We now describe a Drosophila tmAC, DAC39E, which employs a novel means for regulating its expression; differential exon utilization results in a developmental switch in DAC39E protein. DAC39E protein sequence is most closely related to mammalian type III AC, and it is predominantly expressed in the central nervous system (CNS) and olfactory organs, suggesting a role in processing sensory signaling inputs. DAC39E catalytic activity is inhibited by micromolar concentrations of calcium; therefore, DAC39E is oppositely regulated by calcium compared to the only other tmAC shown to be expressed in the Drosophila CNS, Rutabaga AC. The presence of both positively and negatively regulated tmACs suggests a complex mode of cross-talk between cAMP and calcium signal transduction pathways in the fly CNS.

A new family of adenylyl cyclase genes in the male germline of Drosophila melanogaster.

We describe the cloning and characterization of a new gene family of adenylyl cyclase related genes in Drosophila. The five adenylyl cyclase-like genes that define this family are clearly distinct from previously known adenylyl cyclases. One member forms a unique locus on chromosome 3 whereas the other four members form a tightly clustered, tandemly repeated array on chromosome 2. The genes on chromosome 2 are transcribed in the male germline in a doublesex dependent manner and are expressed in postmitotic, meiotic, and early differentiating sperm. These genes therefore provide the first evidence for a role for the cAMP signaling pathway in Drosophila spermatogenesis. Expression from this locus is under the control of the always early, cannonball, meiosis arrest, and spermatocyte arrest genes that are required for the G2/M transition of meiosis I during spermatogenesis, implying a mechanism for the coordination of differentiation and proliferation. Evidence is also provided for positive selection at the locus on chromosome 2 which suggests this gene family is actively evolving and may play a novel role in spermatogenesis.

Restricted expression of a truncated adenylyl cyclase in the cephalic furrow of Drosophila melanogaster.

We have identified a novel isoform of adenylyl cyclase, DAC78C, in Drosophila melanogaster that encodes two structurally distinct proteins in a developmentally restricted manner. The protein corresponding to one transcript is potently activated by G protein and protein kinase C and is expressed ubiquitously. The protein corresponding to the second transcript is expressed in a dynamic pattern in gastrulation stage embryos; it is restricted to the cephalic furrow and dorsal transverse folds, active regions of cell movement of unknown function in the Drosophila embryo. We propose that DAC78C and the cAMP pathway play an important role in directing these morphogenetic movements, and that this gene may provide clues to the functional significance of these structures in gastrulation.

Cytosolic adenylyl cyclase defines a unique signaling molecule in mammals.

Mammals have nine differentially regulated isoforms of G protein-responsive transmembrane-spanning adenylyl cyclases. We now describe the existence of a distinct class of mammalian adenylyl cyclase that is soluble and insensitive to G protein or Forskolin regulation. Northern analysis indicates the gene encoding soluble adenylyl cyclase (sAC) is preferentially expressed in testis. As purified from rat testis cytosol, the active form of sAC appears to be a fragment derived from the full-length protein, suggesting a proteolytic mechanism for sAC activation. The two presumptive catalytic domains of sAC are closely related to cyanobacterial adenylyl cyclases, providing an evolutionary link between bacterial and mammalian signaling molecules.

Cloning and characterization of a Drosophila adenylyl cyclase homologous to mammalian type IX.

A novel Drosophila adenylyl cyclase (AC) was identified by PCR using degenerate primers specific for the known metazoan ACs. The full-length cDNA predicts a protein displaying significant sequence homology with mammalian Type IX AC (AC9). The abundance and size of the message for the Drosophila AC9 homolog (DAC9) changes through development. Biochemical analysis of DAC9 confirms it encodes a functional enzyme which can be activated by forskolin or G protein. Together with the Drosophila Type I AC homolog encoded by the learning and memory gene, rutabaga, the molecular identification of DAC9 demonstrates there is a family of Drosophila AC isoforms reflecting at least part of the diversity of mammalian AC isoforms.

Identification of functional domains of adenylyl cyclase using in vivo chimeras.

Adenylyl cyclase, the effector molecule of the cAMP signaling pathway, is composed of a family of isoforms that differ in their modes of regulation. Many of these modulatory interactions are dependent upon well characterized molecules from various second messenger pathways; however, very little is known about their mechanisms or sites of action on adenylyl cyclase. Chimeras were produced by a novel in vivo mechanism between two differentially modulated adenylyl cyclases to identify their regulatory domains. The basal activity of the type I adenylyl cyclase (AC1) is activated by calcium/calmodulin, inhibited by G protein beta gamma subunits, and insensitive to protein kinase C regulation. In contrast, type II adenylyl cyclase (AC2) is insensitive to calcium/calmodulin regulation and is activated by G protein beta gamma subunits as well as by activated protein kinase C. Expression and biochemical characterization of chimeras between AC1 and AC2 identified a single specific domain of AC1 responsible for calmodulin binding and a small, well defined region near the C terminus of AC2 required for protein kinase C activation.

CRAC, a cytosolic protein containing a pleckstrin homology domain, is required for receptor and G protein-mediated activation of adenylyl cyclase in Dictyostelium.

Adenylyl cyclase in Dictyostelium, as in higher eukaryotes, is activated through G protein-coupled receptors. Insertional mutagenesis into a gene designated dagA resulted in cells that cannot activate adenylyl cyclase, but have otherwise normal responses to exogenous cAMP. Neither cAMP treatment of intact cells nor GTP gamma S treatment of lysates stimulates adenylyl cyclase activity in dagA mutants. A cytosolic protein that activates adenylyl cyclase, CRAC, has been previously identified. We trace the signaling defect in dagA- cells to the absence of CRAC, and we demonstrate that dagA is the structural gene for CRAC. The 3.2-kb dagA mRNA encodes a predicted 78.5-kD product containing a pleckstrin homology domain, in agreement with the postulated interaction of CRAC with activated G proteins. Although dagA expression is tightly developmentally regulated, the cDNA restores normal development when constitutively expressed in transformed mutant cells. In addition, the megabase region surrounding the dagA locus was mapped. We hypothesize that CRAC acts to connect free G protein beta gamma subunits to adenylyl cyclase activation. If so, it may be the first member of an important class of coupling proteins.

Preferential expression of the Drosophila rutabaga gene in mushroom bodies, neural centers for learning in insects.

Seven lines were isolated with P element insertions in the cytogenetic vicinity of the learning and memory gene, rutabaga, from an enhancer detector screen designed to mark genes preferentially expressed in mushroom bodies. Six of these lines performed poorly in learning and memory tests, and several failed to complement an existing rutabaga allele. Molecular cloning revealed that the P elements were inserted in the putative promoter of the rutabaga gene. RNA in situ hybridization and immunohistochemistry demonstrated that the expression of the rutabaga gene, which encodes a Ca2+/calmodulin-responsive adenylyl cyclase, is markedly elevated in the mushroom bodies of normal flies and that the insertion elements compromised its expression in the new rutabaga mutants. The reisolation of a known learning and memory gene, but with a heretofore unknown expression pattern, strongly supports the postulate that mushroom bodies are principal sites mediating olfactory learning and memory.

Structural basis for the low affinities of yeast cAMP-dependent and mammalian cGMP-dependent protein kinases for protein kinase inhibitor peptides.

Affinities of the catalytic subunit (C1) of Saccharomyces cerevisiae cAMP-dependent protein kinase and of mammalian cGMP-dependent protein kinase were determined for the protein kinase inhibitor (PKI) peptide PKI(6-22)amide and seven analogues. These analogues contained structural alterations in the N-terminal alpha-helix, the C-terminal pseudosubstrate portion, or the central connecting region of the PKI peptide. In all cases, the PKI peptides were appreciably less active as inhibitors of yeast C1 than of mammalian C alpha subunit. Ki values ranged from 5- to 290-fold higher for the yeast enzyme than for its mammalian counterpart. Consistent with these results, yeast C1 exhibited a higher Km for the peptide substrate Kemptide. All of the PKI peptides were even less active against the mammalian cGMP-dependent protein kinase than toward yeast cAMP-dependent protein kinase, and Kemptide was a poorer substrate for the former enzyme. Alignment of amino acid sequences of these homologous protein kinases around residues in the active site of mammalian C alpha subunit known to interact with determinants in the PKI peptide [Knighton, D. R., Zheng, J., Ten Eyck, L. F., Xuong, N-h, Taylor, S. S., & Sowadski, J. M. (1991) Science 253, 414-420] provides a structural basis for the inherently lower affinities of yeast C1 and cGMP-dependent protein kinase for binding peptide inhibitors and substrates. Both yeast cAMP-dependent and mammalian cGMP-dependent protein kinases are missing two of the three acidic residues that interact with arginine-18 in the pseudosubstrate portion of PKI. Further, the cGMP-dependent protein kinase appears to completely lack the hydrophobic/aromatic pocket that recognizes the important phenylalanine-10 residue in the N-terminus of the PKI peptide, and binding of the inhibitor by the yeast protein kinase at this site appears to be partially compromised.

The Drosophila learning and memory gene rutabaga encodes a Ca2+/Calmodulin-responsive adenylyl cyclase.

Four putative adenylyl cyclase genes from Drosophila melanogaster were identified by virtue of their extensive sequence homology with mammalian cyclases. One corresponds to the learning and memory gene rutabaga and is most similar to the mammalian brain Ca2+/calmodulin (CaM)-responsive cyclase. In a mammalian expression system, rutabaga cyclase activity was stimulated approximately 5-fold by the presence of Ca2+/CaM. A point mutation, identified at this locus in rut1 mutant flies, resulted in loss of detectable adenylyl cyclase activity. New P element insertion-induced rutabaga mutations mapped to within 200 nucleotides of the 5' end of the rutabaga cDNA. These data confirm the identity of the rutabaga locus as the structural gene for the Ca2+/CaM-responsive adenylyl cyclase and show that the inactivation of this cyclase leads to a learning and memory defect.

Association of catalytic and regulatory subunits of cyclic AMP-dependent protein kinase requires a negatively charged side group at a conserved threonine.

In Saccharomyces cerevisiae, as in higher eucaryotes, cyclic AMP (cAMP)-dependent protein kinase is a tetramer composed of two catalytic (C) subunits and two regulatory (R) subunits. In the absence of cAMP, the phosphotransferase activity of the C subunit is inhibited by the tight association with R. Mutation of Thr-241 to Ala in the C1 subunit of S. cerevisiae reduces the affinity of this subunit for the R subunit approximately 30-fold and results in a monomeric cAMP-independent C subunit. The analogous residue in the mammalian C subunit is known to be phosphorylated. Peptide maps of in vivo 32P-labeled wild-type C1 and mutant C1(Ala241) suggest that Thr-241 is phosphorylated in yeast cells. Substituting Thr-241 with either aspartate or glutamate partially restored affinity for the R subunit. Uncharged and positively charged residues substituted at this site resulted in C subunits that failed to associate with the R subunit. Replacement with the phosphorylatable residue serine resulted in a C subunit with wild-type affinity for the R subunit. Analysis of this protein revealed that it appears to be phosphorylated on Ser-241 in vivo. These data suggest that the interaction between R and C involves a negatively charged phosphothreonine at position 241 of yeast C1, which can be mimicked by either aspartate, glutamate, or phosphoserine.

A mutation in the catalytic subunit of cAMP-dependent protein kinase that disrupts regulation.

A mutant catalytic subunit of adenosine 3',5'-monophosphate (cAMP)-dependent protein kinase has been isolated from Saccharomyces cerevisiae that is no longer subject to regulation yet retains its catalytic activity. Biochemical analysis of the mutant subunit indicates a 100-fold decreased affinity for the regulatory subunit. The mutant catalytic subunit exhibits approximately a threefold increase in Michaelis constant for adenosine triphosphate and peptide cosubstrates, and is essentially unchanged in its catalytic rate. The nucleotide sequence of the mutant gene contains a single nucleotide change resulting in a threonine-to-alanine substitution at amino acid 241. This residue is conserved in other serine-threonine protein kinases. These results identify this threonine as an important contact between catalytic and regulatory subunits but only a minor contact in substrate recognition.

Repeat colonoscopy after endoscopic polypectomy.

The records of all patients undergoing endoscopic polypectomy between December 1979 and December 1982 were reviewed. One hundred seventy-two patients underwent colonoscopic polypectomy in the absence of carcinoma or inflammatory bowel disease. Of these, the polyp could not be retrieved in 4, and 19 were lost to follow-up. One hundred forty-nine patients underwent subsequent endoscopy from one to four years after the initial polypectomy. Seventy-five (50.3 percent) of the patients developed new polyps. Although 61 of the 75 patients with new polyps were identified in the first two years, new polyps were noted throughout all four years. The presence of multiple polyps on the initial examination was statistically significant in predicting new polyps. The age and sex of the patients, size of the polyps, and the presence of atypia did not identify patients at higher risk for new polyps. The data indicate that new polyps are more likely to develop in patients who had a previous polyp. It would appear that annual examinations should be performed until two successive examinations are negative. Following a second negative examination, reexamination at two- or three-year intervals, unless symptomatic, would appear to be adequate.