Calmodulin and HIV type 1: interactions with Gag and Gag products.

The level of calmodulin increases in cells expressing HIV-1 envelope glycoprotein. Although a calmodulin increase is bound to alter many cellular metabolic and signaling pathways, the benefits to the virus of these alterations must be indirect. However, the possibility exists that increased cellular calmodulin benefits the virus by directly associating with nonenvelope viral proteins. We have, therefore, investigated whether calmodulin can interact with HIV structural proteins Gag, p17, and p24. Calmodulin binds Gag and p17 but not p24 in (125)I-labeled calmodulin overlays of SDS-polyacrylamide gels. Removal of calcium by addition of EGTA eliminates this binding. A computer algorithm for predicting helical regions that should bind calmodulin predicts that there are two calmodulin-binding regions near the N terminus of p17. Intrinsic tryptophan fluorimetry shows that two peptides, each of which includes one of the predicted regions, bind calmodulin: p17(11-25) binds calmodulin with a 2-to-1 stoichiometry and dissociation constant of approximately 10(-9) M(2), and p17(31-46) also binds calmodulin with a dissociation constant of about 10(-9) M. These binding sites are nearly contiguous, forming an extended calmodulin-binding domain p17(11-46). In H-9 cells, Gag and calmodulin colocalize within the resolution of confocal light microscopy.

Protein-assisted pericyclic reactions: an alternate hypothesis for the action of quantal receptors.

The rules for allowable pericyclic reactions indicate that the photoisomerizations of retinals in rhodopsins can be formally analogous to thermally promoted Diels-Alder condensations of monoenes with retinols. With little change in the seven-transmembrane helical environment these latter reactions could mimic the retinal isomerization while providing highly sensitive chemical reception. In this way archaic progenitors of G-protein-coupled chemical quantal receptors such as those for pheromones might have been evolutionarily plagiarized from the photon quantal receptor, rhodopsin, or vice versa. We investigated whether the known structure of bacteriorhodopsin exhibited any similarity in its active site with those of the two known antibody catalysts of Diels-Alder reactions and that of the photoactive yellow protein. A remarkable three-dimensional motif of aromatic side chains emerged in all four proteins despite the drastic differences in backbone structure. Molecular orbital calculations supported the possibility of transient pericyclic reactions as part of the isomerization-signal transduction mechanisms in both bacteriorhodopsin and the photoactive yellow protein. It appears that reactions in all four of the proteins investigated may be biological analogs of the organic chemists' chiral auxiliary-aided Diels-Alder reactions. Thus the light receptor and the chemical receptor subfamilies of the heptahelical receptor family may have been unified at one time by underlying pericyclic chemistry.

Intracellular calcium puffs in osteoclasts.

We studied intracellular calcium ([Ca(2+)](i)) in acid-secreting bone-attached osteoclasts, which produce a high-calcium acidic extracellular compartment. Acid secretion and [Ca(2+)](i) were followed using H(+)-restricted dyes and fura-2 or fluo-3. Whole cell calcium of acid-secreting osteoclasts was approximately 100 nM, similar to cells on inert substrate that do not secrete acid. However, measurements in restricted areas of the cell showed [Ca(2+)](i) transients to 500-1000 nM consistent with calcium puffs, transient (millisecond) localized calcium elevations reported in other cells. Spot measurements at 50-ms intervals indicated that puffs were typically less than 400 ms. Transients did not propagate in waves across the cell in scanning confocal measurements. Calcium puffs occurred mainly over regions of acid secretion as determined using lysotracker red DND99 and occurred at irregular periods averaging 5-15 s in acid secreting cells, but were rare in lysotracker-negative nonsecretory cells. The calmodulin antagonist trifluoperazine, cell-surface calcium transport inhibitors lanthanum or barium, and the endoplasmic reticulum ATPase inhibitor thapsigargin had variable acute effects on the mean [Ca(2+)](i) and puff frequency. However, none of these agents prevented calcium puff activity, suggesting that the mechanism producing the puffs is independent of these processes. We conclude that [Ca(2+)](i) transients in osteoclasts are increased in acid-secreting osteoclasts, and that the puffs occur mainly near the acid-transporting membrane. Cell membrane acid transport requires calcium, suggesting that calcium puffs function to maintain acid secretion. However, membrane H(+)-ATPase activity was insensitive to calcium in the 100 nM-1 microM range. Thus, any effects of calcium puffs on osteoclastic acid transport must be indirect.

Calmodulin antagonists inhibit apoptosis of CD4+ T-cells from patients with AIDS.

Recent studies indicate that Fas and Fas ligand are involved in apoptosis of T-cells in HIV-infected patients. We have demonstrated that calcium/calmodulin is involved in Fas-mediated apoptosis in human T-cell lines transfected with HIV recombinant cDNA. In the present study, we examined spontaneous apoptosis of T-cells in vitro in peripheral blood obtained from 11 patients with AIDS and 8 HIV-seronegative normal donors and the effect of the calmodulin antagonists, trifluoperazine (TFP) or tamoxifen (TMX), on apoptosis. The results show that: (1) levels of spontaneous apoptosis were higher in PBMCs obtained from patients with AIDS than HIV-negative normal controls and the levels of apoptosis correlated with the severity of disease. (2) The accelerated apoptosis occurred predominantly in CD4+ cells in patients with AIDS. (3) Calmodulin antagonists inhibited the spontaneous apoptosis of CD4+ T-cells from patients with AIDS, which resulted in an increase in the ratio of CD4+ to CD8+ T-cells. (4) The inhibitory effect of calmodulin antagonists on apoptosis was more significant in patients with advanced disease (CDC category C) compared to less severe disease (CDC category B). These results indicate that calmodulin antagonists inhibit HIV-associated apoptosis of CD4+ T-cells, and imply that the calcium/calmodulin play important roles in mediating apoptosis of CD4+ T-cells induced by HIV infection.

Differential effects of tamoxifen-like compounds on osteoclastic bone degradation, H(+)-ATPase activity, calmodulin-dependent cyclic nucleotide phosphodiesterase activity, and calmodulin binding.

We studied effects of calmodulin antagonists on osteoclastic activity and calmodulin-dependent HCl transport. The results were compared to effects on the calmodulin-dependent phosphodiesterase and antagonist-calmodulin binding affinity. Avian osteoclast degradation of labeled bone was inhibited approximately 40% by trifluoperazine or tamoxifen with half-maximal effects at 1-3 microM. Four benzopyrans structurally resembling tamoxifen were compared: d-centchroman inhibited resorption 30%, with half-maximal effect at approximately 100 nM, cischroman and CDRI 85/287 gave 15-20% inhibition, and l-centchroman was ineffective. No benzopyran inhibited cell attachment or protein synthesis below 10 microM. However, ATP-dependent membrane vesicle acridine transport showed that H(+)-ATPase activity was abolished by all compounds with 50% effects at 0.25-1 microM. All compounds also inhibited calmodulin-dependent cyclic nucleotide phosphodiesterase at micromolar calcium. Relative potency varied with assay type, but d- and l-centchroman, surprisingly, inhibited both H(+)-ATPase and phosphodiesterase activity at similar concentrations. However, d- and l-centchroman effects in either assay diverged at nanomolar calcium. Of benzopyrans tested, only the d-centchroman effects were calcium-dependent. Interaction of compounds with calmodulin at similar concentrations were confirmed by displacement of labeled calmodulin from immobilized trifluoperazine. Thus, the compounds tested all interact with calmodulin directly to varying degrees, and the observed osteoclast inhibition is consistent with calmodulin-mediated effects. However, calmodulin antagonist activity varies between specific reactions, and free calcium regulates specificity of some interactions. Effects on whole cells probably also reflect other properties, including transport into cells.

Role of calmodulin in HIV-potentiated Fas-mediated apoptosis.

The recently demonstrated extraordinary rate of turnover of T cells in human immunodeficiency virus (HIV)-1-infected patients and the apparently concomitant high rate of viral production and death are consistent with a large amount of cell death directly due to infection. Apoptosis may be one of the major forms of T cell death in HIV-1 infection. Many apoptotic pathways depend on calcium and therefore would be expected to involve calmodulin. As the HIV-1 envelope glycoprotein, gp160, contains two known calmodulin-binding domains, we investigated the possibility that the cytoplasmic domain of the HIV-1 envelope protein gp160 could enhance Fas-mediated apoptosis, the major form of apoptosis in lymphocytes. Our studies have shown that 1) transfection of H9 and MOLT-4 cells with a non-infectious HIV proviral clone, pFN, which expresses wild-type gp160, leads to enhanced Fas-mediated apoptosis, 2) transfection of MOLT-4 cells with a pFN construct pFN delta 147, which expresses a carboxyl-terminally truncated gp160 lacking the calmodulin-binding domains, produces less Fas-mediated apoptosis than transfection with pFN, and 3) the calmodulin antagonists trifluoperazine and tamoxifen completely inhibit the pFN enhancement of Fas-mediated apoptosis in MOLT-4 cells. We have replicated all of these results using the vectors pSRHS and pSRHS delta 147, which express wild-type gp160 and truncated gp160, respectively, in the absence of other viral proteins. These investigations provide a mechanism by which HIV-1 may induce apoptosis and a possible intracellular target for future therapeutics.

Expression of HIV-1 envelope glycoprotein alters cellular calmodulin.

Removal of parts of a known calmodulin binding site at the C-terminus of HIV-1 envelope glycoprotein, gp160, can result in diminished infectivity. We investigated whether expression of full length gp160 would result in changes in intracellular calmodulin compared to expression of gp160 truncated to remove both known calmodulin binding sites. Both Western and Northern blots demonstrated that expression of gp160 led to increased calmodulin when compared to expression of truncated gp160. The induced calmodulin was associated preferentially with a particulate subcellular fraction. Confocal immunomicroscopy confirmed the increase in calmodulin and also showed that there was enhanced colocalization of calmodulin with gp160. Understanding of the role of calmodulin in the viral life-cycle may lead to new therapeutics.

Tyrosine-phosphorylated calmodulin has reduced biological activity.

Calmodulin is phosphorylated by the purified insulin receptor on tyrosine residues with a maximum stoichiometry of 1 mol phosphate/mol of calmodulin. Isolated tryptic phosphopeptides were sequenced by manual Edman degradation and demonstrated that calmodulin is equally phosphorylated on tyrosine 99 and tyrosine 138. Phosphorylated calmodulin has a decreased affinity (K0.5 = 4.2 nM) for the 63-kDa isozyme of cyclic nucleotide phosphodiesterase compared to nonphosphorylated calmodulin (K0.5 = 2.1 nM). The K0.5 for Ca2+ is marginally increased from 2.8 to 3.2 microM in the presence of phosphotyrosyl calmodulin. The effect of the calmodulin antagonist, mastoparan, was investigated to determine whether mastoparan would differentially inhibit calmodulin- or phosphocalmodulin-dependent enzyme activity. The IC50 of mastoparan is fourfold lower for phosphotyrosyl calmodulin compared to nonphosphorylated calmodulin. Phosphorylation of calmodulin may provide a mechanism for the differential regulation of calmodulin-dependent enzymes. These observations further support a potentially important regulatory function of calmodulin phosphorylation in signal transduction.

Regulation of osteoclastic acid secretion by cGMP-dependent protein kinase.

Nitric oxide (NO) down-regulates osteoclastic activity. The mechanism is unknown, although, in some cells NO acts by stimulating guanylate cyclase which activates cGMP-dependent proteins. We demonstrated cGMP-dependent protein kinase in osteoclasts by immunofluorescence microscopy. Specificity was confirmed by Western blot analysis showing a single 78 kDa band, the size of the Type I isoform, in isolated avian osteoclasts. Osteoclast function centers on HCl secretion at a specialized membrane organelle. We found that purified cGMP-dependent protein kinase inhibits ATP-dependent acid transport in reconstituted osteoclast membrane vesicles >90%, while cAMP-dependent kinase catalytic subunit, calmodulin kinase II, or cGMP alone were ineffective. This novel, direct modulation of acid transport by cGMP-dependent kinase and the occurrence of the enzyme in osteoclasts suggest that a mechanism of NO-regulation of bone turnover is via cGMP and cGMP-dependent protein kinase inhibition of HCl transport.

Calmodulin concentrated at the osteoclast ruffled border modulates acid secretion.

Osteoclasts mediate acid dissolution of bone for maintenance of serum [Ca2+] and for replacement of old bone in terrestrial vertebrates. Recent findings point to the importance of intracellular signals, particularly Ca2+, in osteoclast regulation. However, acid degradation of bone mineral subjects the osteoclast to uniquely high extracellular [Ca2+]. We hypothesized that this high calcium environment would affect calcium signalling mechanisms, and studied the calcium binding regulatory protein, calmodulin, in the osteoclast. Avian osteoclast bone resorption was inhibited 30% at 1 microM and 90% at 7 microM by the calmodulin antagonist trifluoperazine. Osteoclast bone attachment was not affected by 10 microM trifluoperazine. Quantitative immunofluorescence using fluorescein-labelled calmodulin monoclonal antibody showed a severalfold increase of calmodulin concentration in bone attached relative to plastic attached osteoclasts. Western blots confirmed this, showing two to threefold increased osteoclast calmodulin per milligram of cell protein in 3-day bone-attached vs. nonattached cells. Scanning confocal microscopy showed calmodulin polarization to areas of bone attachment. Electron micrographs with 9 nm colloidal gold labelling showed calmodulin in the acid secreting ruffled membrane. ATP-dependent acid transport in osteoclast membrane vesicles was inhibited by the calmodulin antagonist calmidazolium. This effect was reversed by addition of excess calmodulin, showing that the inhibition is specific. Vesicle acid transport inhibition reflects an approximately fourfold shift in the apparent Km for ATP of vesicular acid transport in the presence of the calmodulin antagonist. We conclude that calmodulin concentration and distribution is modified by bone attachment, and that osteoclastic acid secretion is calmodulin regulated.

An insulin receptor peptide (1135-1156) stimulates guanosine 5'-[gamma-thio]triphosphate binding to the 67 kDa G-protein associated with the insulin receptor.

Peptides representing two putative G-protein-binding motifs (GPBP1 and GPBP2) derived from insulin-receptor sequences were tested for their ability to stimulate guanosine 5'-[gamma-thio]-triphosphate (GTP[S]; 'GTP gamma S') binding to a preparation containing the 41 and 67 kDa G-proteins that are associated with the insulin receptor [Jo, Cha, Davis and McDonald (1992) Endocrinology (Baltimore) 131, 2855-2861]. GPBP2 (residues 1135-1156) specifically stimulated GTP[S] binding, whereas GPBP1 (1319-1333) did not. Substitution of Arg-1152 with Gln in GPBP2 corresponding to a mutation site in insulin-resistant patients [Cocozza, Porcellini, Riccardi, Monticelli, Condorelli, Ferrera, Pianese, Miele, Capaldo, Beguinot and Varrone (1992) Diabetes 41, 521-526] attenuated the stimulatory potency of GPBP2. Size-exclusion chromatography and studies with purified 67 kDa G-protein revealed that GPBP2 stimulated GTP[S] binding only to the 67 kDa G-protein. These studies provide evidence for a potential regulatory site for G-protein interaction with the insulin receptor in the tyrosine kinase domain.

A novel acetylcholine receptor-related peptide blocks canine cardiac ganglia and inhibits the nicotinic receptor of PC-12 cells.

A 13 amino acid peptide from the calf muscle acetylcholine receptor has been previously shown to bind both snake neurotoxins and acetylcholine. In the experiments reported here a modified complementary peptide (cAChR) derived from that acetylcholine receptor peptide was tested for biological activity in a canine heart preparation. It was expected that the modified complementary peptide would exhibit either acetylcholine-like effects or acetylcholine inhibiting effects, since, as a complementary peptide to the receptor, it should resemble acetylcholine. In these studies cAChR was administered via the sinus node artery of dog hearts in intact animals which were anesthetized with pentobarbital, intubated, and prepared with local cardiac electrograms and force gauges. cAChR was also injected directly into thoracic sympathetic ganglia. Both approaches demonstrated cAChR inhibition of neural transmission, cAChR was added to the medium of carbachol stimulated PC-12 cells. In these cells, derived from a rat pheochromocytoma, sodium flux is controlled by neural nicotinic receptors. With or without preincubation cAChR inhibited carbachol stimulation of sodium flux, exhibiting a Ki of approximately 9 x 10(-5) (similar to that of hexamethonium). Thus cAChR appears to be a novel synthetic peptide which interrupts nicotinic cholinergic neural transmission by acting as an antagonist of the neural nicotinic receptor.

Proposed partial beta-structures for lac permease and the Na+/H+ antiporter which use similar transport and H+ coupling mechanisms.

Most antiporters, symporters, and transporters have been represented as containing ten to 14 transmembrane helices, primarily on the basis of hydropathy plots. However, multihelix systems provide no obvious mechanism of transport and no simple way of distinguishing substrates. The models of lac permease and the Na+/H+ antiporter presented here postulate that beta-structures are involved in the transport of substrate, and in following this postulate arrive at readily understandable mechanisms for transport and for substrate specificity. The percentage of beta-structures necessary for these models is low enough that it is not in conflict with prior physical evidence for secondary structures. Immunological data also cannot rule these beta-structure mechanisms invalid. In lac permease the new model is obtained by formal representation of the C-terminal amino acids 243-405 as beta-strands. This formal representation nets two interchangeable beta-barrels which provide a simple mechanism for sugar transport. The alternating barrel system may comprise as little as 1/5 the entire permease. In one configuration the barrel forms a pocket with hydrogen bonding residues oriented to the outside of the cell. In the other configuration the barrel forms an analogous pocket oriented towards the inside. Six particular amino acids participate in the substrate hydrogen bonding schemes of both forms, providing a mechanism to shuttle lactose from the outside to the inside or vice versa. A trigger for change of forms which could couple the beta-barrel to H(+)-transport is easily devised, and it involves the apparently critical His322-Glu325 charge relay system. The Na+/H+ antiporter can be organized similarly with an interchanging beta-barrel-beta-clamshell structure attached to 7-transmembrane helices. Charged amino acid sidechains form the basis of an ionic shuttle which is analogous to the lactose shuttle. In this case, too, coupling of Na+ transport to H+ transport may be accomplished by a histidine-glutamate charge relay system.

Water molecules can control the side-chain rotamer distribution of an aryl peptide in a nonpolar environment.

With computer-controlled circular dichroism (CD) spectrophotometry it is possible to obtain difference CD spectra which result from small perturbations to the environment of a chiral molecule. In the experiments described here a dry iso-octane solution of cyclobis-N-methyl-L-phenylalanine (c-(NMe-L-Phe)2) has been perturbed by exposure to water vapor. The resulting difference spectrum shows that water coordination to c-(NMe-L-Phe)2 eliminates negative ellipticity in the 244 nm region, while it simultaneously creates positive CD intensity in the 212 nm region. These two features of the difference spectrum plus related features of other direct spectra imply that water coordinated with p-orbital unpaired electrons of the carbonyl interferes sterically with the chi = 180 degrees side-chain rotamer. It can be expected that in this way hydrogen bonding of any species to backbone carbonyls can control the rotamer distribution of aromatic side-chains, if one of the rotamers occludes unpaired electrons of the carbonyl. Such control may offer an on-off switch for electron transport through proteins.

Alpha-toxin binding to acetylcholine receptor alpha 179-191 peptides: intrinsic fluorescence studies.

Interactions between two alpha-toxins and the synthetic peptides alpha 179-191 from both calf and human acetylcholine receptor alpha-subunit sequences have been studied by measurements of quenching of intrinsic fluorescence after toxin addition. Dissociation constants of approx. 5 x 10(-8) M for binding of calf peptide by both alpha-cobratoxin and erabutoxin a have been estimated. The binding of alpha-cobratoxin to calf peptide, which leads to marked quenching of fluorescence intensity, is inhibited by a 10(4) molar excess of acetylcholine. The human alpha 179-191 peptide binds to alpha-cobratoxin, but not, under comparable conditions, to erabutoxin a.