Transient-state kinetics of phosphoenzyme transformation in the rabbit skeletal sarcoplasmic reticulum calcium-dependent adenosine triphosphatase reaction. Two distinct modes of ADP and K+ regulation

We have observed two modes each of ADP and K+ regulation of phosphoenzyme (EP) intermediates formed in the early phase of skeletal sarcoplasmic reticulum hydrolysis of ATP at 20 degrees C, using, for the first time, a five-syringe quench flow apparatus for transient-state kinetic measurements. The total acid-stable EP formed for 20.5 and 116 ms in the K+ medium appears to be composed of either two monomers in rapid equilibrium, E1P in equilibrium E'1P, or a dimer of the two subunits, PE1E'1P. The ADP-sensitive E1P may form an acid-labile ADP X E1P (or ATP X E1) complex rapidly, giving ATP as a consequence of acid quenching. The ADP may also induce decomposition of the ADP-reactive E'1P. Monomeric and dimeric mechanisms are introduced to account for the hyperbolic relation between the rate constant of the ADP-induced E'1P decomposition and [ADP], consistent with the fact that the E'1P may also give ATP in the presence of ADP. As to the K+ effects, the K+, which is bound to the unphosphorylated enzyme and possibly becomes occluded during EP formation, may either facilitate the one-to-one E1P in equilibrium E'1P equilibrium or maintain the dimeric functional unit. The subsequent forward transformation of the E'1P to the ADP-insensitive K+-sensitive E'2P, possibly the rate-determining step for the catalytic cycle, is found to be K+ independent. The major effect of the K+ in the medium is its catalytic cleavage of the E'2P, which is detected as the missing EP under these conditions. When K+ is not involved in the EP formation, the forward sequential transformation E1P----E'1P----E'2P----E2P or PE1E'1P----PE'2E2P is apparent in the time range from 20.5 to 116 ms after EP formation, and the E'2P may accumulate in the K+ devoid medium and be detected as the major component of the total acid-stable EP. The Mg2+-sensitive E2P represents the EP missing in the medium containing no ADP and K+.     

Reorganization of alpha-actinin and vinculin induced by a phorbol ester in living cells

We have used fluorescent analogue cytochemistry, image intensification, and digital image processing to examine the redistribution of alpha-actinin and vinculin in living cultured African green monkey kidney (BSC-1) cells treated with the phorbol ester 12-O-tetradecanoylphorbol-13-acetate (TPA). Before treatment, microinjected alpha-actinin shows characteristic distribution along stress fibers and at adhesion plaques; vinculin is localized predominantly at adhesion plaques. Soon after the addition of TPA, highly dynamic membrane ruffles begin to form. These incorporate a large amount of alpha-actinin but little vinculin. Alpha-actinin is subsequently depleted, more or less uniformly, from stress fibers. Disrupted stress fibers often fragment into aggregates and move into the perinuclear region. Careful analyses of fluorescence intensity distribution indicate that alpha-actinin is depleted more rapidly from adhesion plaques than from stress fibers. Furthermore, the depletion of alpha-actinin from adhesion plaques is also faster than either the depletion of vinculin or the disappearance of focal contacts. These observations indicate that TPA may initiate disruption of stress fibers by interfering with a link between alpha-actinin and vinculin, causing alpha-actinin to be preferentially depleted from adhesion plaques.     

Structural and enzymological characterization of immunoaffinity-purified DNA polymerase alpha.DNA primase complex from KB cells

We describe the polypeptide structure and some of the catalytic properties of a DNA polymerase alpha.DNA primase complex that can be prepared from KB cells by immunoaffinity purification. The procedure is based on monoclonal antibodies that were raised against a biochemically purified, catalytically active core protomer of the polymerase. In all respects tested, the basic mechanism of substrate recognition and binding by the immunoaffinity-purified polymerase is qualitatively identical to that of the core protomer. The immunoaffinity-purified KB cell polymerase alpha X DNA primase is structurally complex. On the basis of extensive immunochemical analyses with five independent monoclonal antibodies, three of which are potent neutralizers of polymerase alpha activity, peptide mapping studies, and the application of a sensitive immunoassay that permits detection of polymerase alpha antigens in crude cell lysates, we have established that the principal form of catalytically active DNA polymerase alpha in KB cells is a phosphoprotein with a molecular mass of 180 kilodaltons. This protein is stable in vivo, with an estimated half-life of greater than or equal to 15 h. In contrast, the polypeptide is extremely fragile in vitro and generates partial degradation products of p165, p140, and p125 that explain the "microheterogeneity" typically exhibited by polymerase alpha peptides in denaturing polyacrylamide gels. In addition to the catalytically active polymerase alpha polypeptide(s), the immunopurified enzyme fraction typically contains three other proteins, p77, p55, and p49, the functions of which have not yet been established. These proteins do not display polymerase alpha epitopes and have been shown by peptide mapping to be independent species that are unrelated either to the large polymerase peptides or to one another. The polypeptide p77 is also a phosphoprotein, and in both p180 and p77 the phosphorylated amino acids are exclusively serine and threonine.     

Increased 5-Hydroxytryptamine and Norepinephrine Release from Rat Brain Slices by the Red Sea Flatfish

The effect of the Red Sea flatfish toxin pardaxin was examined on K+-evoked and on basal release of either [3H]norepinephrine or [3H]5-hydroxytryptamine from preloaded rat cortical slices. The K+-induced release of the neurotransmitters was stimulated in a dose-related manner at concentrations ranging from 0.5 to 4 micrograms/ml. Basal release of the two transmitters was elevated to a lesser extent. Although the stimulation of evoked release was approximately equivalent for the two neurotransmitters, the response to 5-hydroxytryptamine was reversible whereas that of norepinephrine was not washed by 20 min of superfusion. The mechanisms involved in producing these actions of pardaxin are not known; however, they may be mediated by changes in electrolyte fluxes across the neuronal membranes.     

梭曼等胆碱酯酶抑制剂对猫膈神经单纤维电活动的影响

在麻醉猫,经推动脉注入梭曼、VX,沙林及乙酰甲胆碱引起呼吸中枢严重抑制的剂量分别为0.5—1、3、15、2001μg/头;但在无麻醉、箭毒麻痹、人工呼吸并用药物保护循环的清醒猫,VX用量要增加十多倍,沙林用量增加2～8倍,棱曼用量不变。在严重抑制剂量的给药早期,梭曼使34.8％动物较早地出现膈神经单纤维放电加强,其每次吸气放电的冲动频率由20～30Hz增至50～80Hz,冲动个数由15～25个/每次放电增至40～60个/每次放电,兴奋持续短、迅速转入抑制且不易自动恢复;VX和乙酰甲胆碱使100％动物出现显著的放电加强,其冲动频率由20～30Hz增至70～130Hz、冲动个数由15～25个/每次放电增至60～80个/第次放电,兴奋持续时间较长、转入抑制慢但自动恢复较快;沙林使76.9％动物出现放电加强,其他表现类似VX。三种胆碱酯酶抑制剂和乙酰甲胆碱共使33/52根单纤维放电发生时相变化。结果表明:梭曼对呼吸中枢作用最强、沙林次之、VX最弱且更似乙酰甲胆碱。     

An equilibrium between distorted and undistorted DNA in the adult chicken beta A-globin gene

We have used single strand specific nucleases to map DNA distortion in the adult chicken beta A-globin gene. We have detected two structures of that kind and have mapped nuclease-cutting sites at one base resolution. One prominent site is centered at -190 relative to the RNA capping site and is positioned at the center of a stretch of contiguous C residues. The second site is near the first intron/exon junction (+620) and appears as a series of discrete 1-base-long enzyme-cutting sites. Based upon the pattern of nuclease cutting and the kinetics of nuclease cutting we conclude that the "poly(C)" stretch may assume a looped geometry in supertwisted DNA molecules which is similar to that proposed by Felsenfeld (Nickol, J. M., and Felsenfeld, G. (1983) Cell 35, 467-477). We show that S1 nuclease cuts within the intron occur mainly at the end points of polypurine segments and suggest that such end points may assume a distorted transitional geometry. We find that Neurospora crassa endonuclease cuts both the promotor and intron sites in linear DNA molecules but that in linear DNA the cutting process is limited by a first order conformation change of the DNA substrate. Based upon those kinetics we propose that in unstressed DNA, each of the two sites can convert between a distorted and undistorted geometry. In the enzyme assay buffer at 37 degrees C, the time constant for the equilibrium is nearly 10 h for the promotor site and 7 h for the intron.     

Localization of tyrosine kinase-coding region in v-abl oncogene by the expression of v-abl-encoded proteins in bacteria

A series of plasmids containing different segments of the v-abl oncogene have been constructed to express different portions of the v-abl protein in bacteria. The tyrosine kinase activity of these proteins was determined by an in vitro assay employing histones or angiotensin II as substrates for the v-abl-encoded tyrosine kinase. These experiments show that the 5'-1.2 kilobases of v-abl is necessary and sufficient to produce an active tyrosine kinase which is functional as a monomeric soluble protein. The kinase-coding region corresponds to the minimal region of v-abl required for the transformation of fibroblasts. The kinase-coding region also coincides with the conserved protein sequences which are found in other tyrosine kinases. A compact domain of the v-abl protein including this kinase-coding region can accumulate to high levels in bacteria. The C-terminal region of the v-abl protein is not needed for the kinase activity and is rapidly degraded in bacteria.     

Use of fluorinated tyrosine phosphates to probe the substrate specificity of the low molecular weight phosphatase activity of calcineurin

Calcineurin, a calmodulin-activated protein phosphatase, is known to dephosphorylate certain low molecular weight phosphate esters. The low molecular weight phosphatase activity of calcineurin has been studied by utilizing tyrosine phosphate derivatives. Kinetic studies suggest that the substrate specificity is dependent upon the electronic nature of the substrate in contrast to results obtained with alkaline phosphatase from Escherichia coli. Comparison of calcineurin and acid-catalyzed hydrolyses indicates a 1:1 correlation between the rate constants for the two processes. This correlation and other model studies have been utilized to provide insight into the chemical mechanism of calcineurin. Possible chemical mechanisms for calcineurin are discussed.