Microtubule-associated adenylate cyclase

Association of adenylate cyclase with an actin-like protein in the human myometrium

Regulation of muscle contraction by second messengers such as cAMP and regulation of the adenylate cyclase enzyme by the cytoskeleton have been previously described. However, the physical association of both effector and structural elements is still unknown. In this context, we have co-purified a human myometrial adenylate cyclase with an actin-like protein in a two-step purification protocol. The adenylate cyclase catalytic unit was solubilized with Lubrol-PX, submitted to anionic exchange chromatography and purified about 7-fold. The eluate was applied to a forskolin-agarose column obtaining an adenylate cyclase extract enriched 257-fold (enzymatic activity of 1390 pmol/30 min per mg protein) that co-eluted with a 74.6-kDa protein that possessed the 18-27 amino-acid fragment from the N-terminal region of human actin. Under non-reducing conditions, the apparent molecular weight of this protein decreased to 54 kDa, which has been previously described for arthrin. These results provide the first demonstration of the physical association of human myometrial adenylate cyclase with a cytoskeleton-related protein, supporting the hypothesis that adenylate cyclase is regulated by mechanical stimuli.

Adenylyl cyclase in the heart: an enzymocytochemical and immunocytochemical approach

This review provides a discussion of the localization of adenylyl cyclase (AC) in normal mammalian heart tissue employing enzymocytochemistry (detection of the catalytic activity of AC by a metal precipitation technique) and immunocytochemistry (immunolabeling of the enzyme protein with antibodies against AC subtypes). By the metal precipitation technique, AC activity was localized in adult guinea pig cardiomyocytes along the sarcolemma and the T-tubule membranes. This reaction can be enhanced by hormones and guanylyl imidodiphosphate, fluoride, and forskolin. With this technique, no precipitates were detected at the sarcoplasmic reticulum. However, under ischemic conditions, AC activity was also found in the junctional sarcoplasmic reticulum of rat cardiomyocytes. Immunocytochemistry revealed AC in the plasma membrane of rat cardiomyocytes. Detection of AC in the perinuclear space of cardiomyocytes might reflect initiation of synthesis and processing of the enzyme protein. Colocalization of AC with cytoskeleton fibers of non-cardiomyocytes emerging in the cell culture of neonatal rat cardiocytes imply a direct cytoskeletal-AC interaction. Finally, it can be stated that the immunolabeling pattern of AC in cryosections of adult and new-born rat hearts reveals a good correspondence with the localization of AC activity in cardiomyocytes demonstrated by enzymocytochemistry.

Is signal transduction modulated by an interaction between heterotrimeric G-proteins and tubulin?

Although it is generally accepted that tubulin plays an important role in G-protein-mediated signal transduction in a variety of systems, the mechanism of this phenomenon is not completely understood. G-protein-tubulin interaction at the cell membrane and the cytosol, and the influence of such an interaction on cellular signaling are discussed in this review article. Because the diameter of a microtubule is 25 nm and the plasma membrane is 9-11 nm thick, it is not possible for membrane-associated tubulin to assemble into a complete microtubule in the membrane environment. However, tubulin heterodimers may be able to function in the membrane environment as individual heterodimers or as polymers arranged into short protofilaments. At the cell membrane, membrane-associated tubulin may influence hormone-receptor interaction, receptor-G-protein coupling, and G-protein-effector coupling. Structural proteins, such as tubulin, can participate in cellular signaling by communicating through physical forces. By virtue of its interaction with the submembranous network of cytoskeletal proteins, tubulin, when perturbed in one locus, can transmit large changes in conformations to other points. Thus, GTP binding to membrane-associated tubulin might lead to a conformational change in either receptors or G proteins. This may, in turn, influence the binding of an agonist to its receptor. On the other hand, in the cell cytosol, subsequent to agonist-induced translocation of G-proteins from the membrane compartment to the cytosol, G-proteins may affect microtubule formation. In GH3 and AtT-20 cells (stably expressing TRH receptor), transiently transfected with Gq alpha cDNA, soluble tubulin levels decreased in Gq alpha-transfected GH3 and AtT-20 cells, by 33% and 52%, respectively. These results suggest that G-proteins may have a direct effect on the microtubule function in vivo. Because tubulin and G-protein families are ubiquitous and highly conserved, an interaction between these two protein families may occur in vivo, and this, in turn, can have an impact on signal transduction. However, the physiological significance of this interaction remains to be demonstrated.

Glycolytic enzymes and assembly of microtubule networks

The ability of glycolytic enzymes, glyceraldehyde-3-phosphate dehydrogenase (GAPDH), aldolase, pyruvate kinase (PK), and lactate dehydrogenase muscle-type (LDH(M)), to generate interactive microtubule networks was investigated. Bundles have previously been defined as the parallel alignment of several microtubules and are one form of microtubule networks. Utilizing transmission electron microscopy, interactive networks of microtubules as well as bundles were readily observed in the presence of GAPDH, aldolase, or PK. These networks appear morphologically as cross-linked microtubules, oriented in many different ways. Light scattering indicated that the muscle forms of GAPDH, aldolase, PK and LDH(m) caused formation of the microtubule networks. Triose phosphate isomerase (TPI) and lactate dehydrogenase heart-type (LDH(H)), glycolytic enzymes which do not interact with tubulin or microtubules, did not produce bundles, or interactive networks. Sedimentation experiments confirmed that the enzymes that cross-link also co-pellet with the microtubules. Such cross-linking of microtubules indicate that the enzymes are multivalent with the capability of simultaneous binding to more than one microtubule.

Cytochemical localization of adenylate cyclase activity in rat olfactory cells

Adenylate cyclase activity was demonstrated in the cilia, dendritic knob and axon of rat olfactory cells by using a strontium-based cytochemical method. The activity in the cilia and the dendritic knob was enhanced by non-hydrolyzable GTP (guanosine triphosphate) analogues and forskolin, and inhibited by Ca2+, all in agreement with biochemical reports of the odorant-sensitive adenylate cyclase. The results support the hypothesis of cyclic AMP working as a second messenger in olfactory transduction and imply that the transduction sites exist not only in the olfactory cilia but also in the dendritic knob. Enzymatic activity was also observed in the olfactory dendritic shaft by treating the tissue with 0.0002% Triton X-100, although the properties and role of the enzyme in this region are uncertain. The detergent inhibited the enzymatic activity in the cilia and the dendritic knob.

Effects of two microtubule-depolymerizing drugs, vincristine and vinblastine, on porphyrin production by primary neural tissue cultures

A porphyrinogenic effect of 10(-5) to 10(-7) M Vincristine (VC) and Vinblastine (VB) was observed on primary neural tissue cultures prepared from chicken embryo brain in the presence of 10(-3) M delta-aminolevulinic acid. This effect is very pronounced in neurocyte cultures, in contrast with the documented neurite elongation defect. The microtubule disassembly by VC and VB changed the quantity of the porphyrins in the cells and medium of glial cell cultures. The correlation was studied between the depolymerization of the microtubules by VC and VB and the porphyrin overproduction of primary neural tissue cultures, the investigation also extending to 10(-7) M taxol. The direct mediation of nucleotide binding proteins of the adenyl-cyclase complex by GTP liberated from beta-tubulin during the disassembly of the microtubules is presumed.

Glyceraldehyde-3-phosphate dehydrogenase is a microtubule binding protein in a human colon tumor cell line

A protein which binds to tubulin polymer was isolated from a human colonic tumor cell line. This protein has a molecular mass of 35 kDa, as determined by polyacrylamide slab gel electrophoresis. The protein was purified by affinity chromatography on taxol-stabilized microtubules, and it did not cross-react with anti-MAP2 or anti-tau antibodies. This protein was identified as glyceraldehyde-3-phosphate dehydrogenase by its enzyme activity and immunoblotting experiments. The purified protein caused a pronounced enhancement in the turbidity increase produced by in vitro tubulin polymerization, and electron microscopic observations revealed the presence of bundles of microtubules.

Exchange of guanine nucleotides between tubulin and GTP-binding proteins that regulate adenylate cyclase: cytoskeletal modification of neuronal signal transduction

Tubulin, the primary constituent of microtubules, is a GTP-binding proteins with structural similarities to other GTP-binding proteins. Whereas microtubules have been implicated as modulators of the adenylate cyclase system, the mechanism of this regulation has been elusive. Tubulin, polymerized with the hydrolysis-resistant GTP analog, 5'-guanylylimidodiphosphate [Gpp(NH)p], can promote inhibition of synaptic membrane adenylate cyclase which persists subsequent to washing. Tubulin with Gpp(NH)p bound was slightly less potent than free Gpp(NH)p in the inhibition of adenylate cyclase, but tubulin without nucleotide bound had no effect on the enzyme. A GTP-binding protein from the rod outer segment (transducin), with Gpp(NH)p bound, was also without effect on adenylate cyclase. Tubulin (regardless of the nucleotide bound to it) did not alter the activity of the adenylate cyclase catalytic unit directly. When tubulin was polymerized with the hydrolysis-resistant photoaffinity GTP analog, [32P]P3(4-azidoanilido)-P1-5'-GTP ([32P]AAGTP), and this protein was added to synaptic membranes, AAGTP was transferred from tubulin to the inhibitory GTP-binding protein, Gi. This transfer was blocked by prior incubation of the membranes with Gpp(NH)p or covalent binding of AAGTP to tubulin prior to exposure of that tubulin to membranes. Incubation of membranes with Gpp(NH)p subsequent to incubation with tubulin-AAGTP results in a decrease in AAGTP bound to Gi and a compensatory increase in AAGTP bound to the stimulatory GTP-binding protein, Gs. Likewise, persistent inhibition of adenylate cyclase by tubulin-Gpp(NH)p could be overridden by the inclusion of 100 microM Gpp(NH)p in the assay inhibition. Whereas Gpp(NH)p promotes persistent inhibition of synaptic membrane adenylate cyclase without incubation at elevated temperatures, tubulin [with AAGTP or Gpp(NH)p bound] requires 30 s incubation at 23 degrees C to effect adenylate cyclase inhibition. Photoaffinity experiments yield parallel results. These data are consistent with synaptic membrane tubulin regulating neuronal adenylate cyclase by transferring GTP to Gi and, subsequently, to Gs.

Microtubules bind glyceraldehyde 3-phosphate dehydrogenase and modulate its enzyme activity and quaternary structure

Glyceraldehyde 3-phosphate dehydrogenase, a tetramer of 140,000 Da, interacts with in vitro reconstituted microtubules. It results in a partial inhibition of the activity of the microtubule-bound enzyme. After cold depolymerization of the microtubule-glyceraldehyde 3-phosphate dehydrogenase complexes, a fraction of the enzyme is recovered in an active form in the disassembly supernatant; the other fraction devoid of activity, identified by polyacrylamide gel electrophoresis, remains associated with the undepolymerizable microtubule protein pellet. The inactivation of the microtubule-bound enzyme is related to the concentration of microtubule protein. Higher the concentration of microtubule protein, lower the fraction of inactivated enzyme; consequently, glyceraldehyde 3-phosphate dehydrogenase is able to copolymerize quantitatively with microtubule protein through one assembly-disassembly cycle, provided that the concentration of microtubule protein is high. Monomeric glyceraldehyde 3-phosphate dehydrogenase (molecular weight: 35,000) devoid of enzyme activity, prepared by reversible dissociation of the tetrameric enzyme, also binds to microtubules and is quantitatively recovered in the undepolymerizable microtubule protein fraction after cold treatment. These results indicate that interacting with microtubules, glyceraldehyde 3-phosphate dehydrogenase partly dissociates into inactive monomers, this process is regulated by the concentration of assembled microtubule protein, and active and inactive glyceraldehyde 3-phosphate dehydrogenase bound to microtubules have different fate at the step of microtubule disassembly. These data suggest that an association of glyceraldehyde 3-phosphate dehydrogenase to microtubules could play a role in modulating the activity of the glycolytic enzyme in intact cells.