Quantitation and significance of 125I-calmodulin binding to myosin light chain kinase and phosphorylase distributed on polyacrylamide gels

Glycogen phosphorylase (a or b) binds 125I-calmodulin in a Ca2+-dependent manner, in the 125I-calmodulin overlay technique. This binding is quantitatively identical to 125I-calmodulin binding to myosin light chain kinase. In an in vitro assay, calmodulin stimulates phosphorylase activity at limiting concentrations of either glucose-1-phosphate or glycogen, but the Ka is 1000 fold higher than for the kinase, and is not Ca2+-dependent. Activation of phosphorylase, but not myosin light chain kinase, by calmodulin can be mimicked by troponin C or bovine serum albumin. These results demonstrate that the properties of calmodulin interaction with proteins can vary between the 125I-calmodulin technique and a functional assay of calmodulin effect on the same protein.     

Bacterial expression and characterization of proteins derived from the chicken calmodulin cDNA and a calmodulin processed gene

Both normal chicken calmodulin (CaM) and a CaM-like mutant protein have been expressed in bacteria, isolated and evaluated with respect to several physical and biological properties. The mutant CaM is derived from a CaM-like gene that lacks intervening sequences and probably evolved from a CaM-processed gene (Stein, J. P., Munjaal, R. P., Lagacé, L., Lai, E. C., O'Malley, B. W., and Means, A. R. (1983) Proc. Natl. Acad. Sci. U. S. A. 80, 6485-6489). The mutant CaM protein contains 16 of the 19 amino acids encoded by the CaM-like gene. Normal chicken CaM produced in bacteria is identical to rat CaM by all criteria tested except that it is not trimethylated. The protein product of the CaM-like gene has been termed CaML and exhibits properties which are very similar to CaM despite the presence of 16 amino acid substitutions. CaML binds Ca2+ as evidenced by Ca2+-dependent binding to phenothiazine- and phenyl-Sepharose affinity resins and a Ca2+-dependent electrophoretic mobility shift which is similar to but distinct from CaM. CaML cross-reacts with a monospecific CaM antibody and has an immunodilution curve which is identical to bacterially synthesized CaM. Finally, CaML can maximally activate rat brain phosphodiesterase but with altered kinetic parameters as compared to CaM. These data suggest that the nucleotide substitutions in the putative CaM processed gene are not random but are selected to retain CaM-like functions in the encoded protein. Such a mechanism may exist for other processed genes.     

Comparison of the Soluble and Membrane-Bound Forms of the Puromycin-Sensitive Enkephalin-Degrading Aminopeptidases from Rat

Enkephalin degradation in brain has been shown to be catalyzed, in part, by a membrane-bound puromycin-sensitive aminopeptidase. A cytosolic puromycin-sensitive aminopeptidase with similar properties also has been described. The relationship between the soluble and membrane forms of the rat brain enzyme is investigated here. Both of these aminopeptidase forms were purified from rat brain and an antiserum was generated to the soluble enzyme. Each of the aminopeptidases is composed of a single polypeptide of molecular mass 100 kilodaltons as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and size-exclusion chromatography. The antisoluble aminopeptidase antiserum reacts with both enzyme forms on immunoblots and inhibits both with nearly identical inhibition curves. The isoelectric points (pI = 5.0) of both forms were shown to be identical. N-terminal sequencing yielded a common sequence (P-E-K-R-P-F-E-R-L-P-T-E-V-S-P-I-N-Y) for both enzyme forms, and peptide mapping yielded 26 peptides that also appeared identical between the two enzyme forms. Studies on the nature of the association of the membrane enzyme form with the cell membrane suggest that this enzyme form does not represent the soluble form trapped during the enzyme preparation. It is suggested that the membrane form of the puromycin-sensitive aminopeptidase is identical to the soluble enzyme and that it associates with the membrane by interactions with other integral membrane proteins.     

The hydrolysis of endothelins by neutral endopeptidase 24.11 (enkephalinase)

Endothelins 1-3 are a family of 21-amino acid peptides whose structure consists of two rings formed by intra-chain disulfide bonds and a linear "COOH-terminal tail." These peptides were originally described on the basis of their potent vasoconstrictor activity. The hydrolytic inactivation of endothelin action has recently been implicated to be attributed, at least in part, to the enzyme neutral endopeptidase 24.11 (Scicli, A. G., Vijayaraghavan, J., Hersh, L., and Carretero, O. (1989) Hypertension 14, 353). The kinetic properties and mode of hydrolysis of the endothelins by this enzyme are reported in this study. The Km for endothelins 1 and 3 hydrolysis is approximately 2 microM while endothelin2 exhibits a 5-fold higher Km. Endothelins 1 and 2 exhibit similar Vmax values while endothelin3 is hydrolyzed considerably more slowly. The initial cleavage site in endothelin1 is at the Ser5-Leu6 bond located within one of the cyclic structures. Thermolysin, a bacterial neutral endopeptidase with a similar substrate specificity to neutral endopeptidase 24.11 initially cleaves endothelin1 between His16-Leu17 which lies within the COOH-terminal linear "tail" portion of the molecule. The cleavage of endothelins 2 and 3 by neutral endopeptidase 24.11 differs from that observed with endothelin1 in that cleavage of these endothelins occurs at Asp18-Ile19 within the linear COOH-terminal tail structure. These results demonstrate that the endothelins are good substrates for neutral endopeptidase 24.11 and suggest that their mode of cleavage is dependent upon both amino acid sequence as well as peptide conformation.     

Identification, purification, and characterization of a protein activator (PA28) of the 20 S proteasome (macropain).

A protein that greatly stimulates the multiple peptidase activities of the 20 S proteasome (also known as macropain, the multicatalytic protease complex, and 20 S protease) has been purified from bovine red blood cells and from bovine heart. The activator protein was a single polypeptide with an apparent molecular weight of 28,000, as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and had a native molecular weight of approximately 180,000. This protein, which we have termed PA28, regulated all three of the putatively distinct peptidase activities displayed by each of two functionally different forms of the proteasome. This regulation usually included both an increase in the maximal reaction velocity and a decrease in the concentration of substrate required for half-maximal velocity and indicated that PA28 acted as a positive allosteric effector of the proteasome. PA28 failed, however, to stimulate the hydrolysis of large protein substrates such as casein and lysozyme. These results suggested that the hydrolysis of protein substrates occurred at a site or sites distinct from those that hydrolyzed small peptides and that the regulation of the two processes could be uncoupled. Evidence for direct binding of PA28 to the proteasome was obtained by glycerol density gradient centrifugation. PA28 may play an important regulatory role in intracellular proteolytic pathways mediated by the proteasome.     

Purification of component A of Rab geranylgeranyl transferase: possible identity with the choroideremia gene product.

Rab geranylgeranyl transferase (GG transferase) from rat brain contains two components, A and B. Component B comprises polypeptides of 60 and 38 kd. Here we report the purification of component A, a single 95 kd polypeptide. The holoenzyme attaches 3H-geranylgeranyl to cysteines in two GTP-binding proteins, Rab3A and Rab1A. The reaction is abolished when both cysteines in the COOH-terminal CysCys sequence of Rab1A are mutated to serines. The mutant protein inhibits transfer of 3H-geranylgeranyl to wild-type Rab1A and Rab3A, suggesting that the enzyme recognizes conserved sequences distinct from the COOH-terminus. Six peptides from rat component A show striking similarity to the product of the defective gene in choroideremia, an X-linked retinal degeneration disease. The choroideremia protein resembles Rab3A GDI, which binds Rab3A. We hypothesize that component A binds conserved sequences in Rab and that component B transfers geranylgeranyl. A defect in this reaction may cause choroideremia.     

Expression and characterization of recombinant human acyloxyacyl hydrolase, a leukocyte enzyme that deacylates bacterial lipopolysaccharides

The molecular cloning and eukaryotic cell expression of the complementary DNA for human neutrophil acyloxyacyl hydrolase (AOAH) are described. AOAH is a leukocyte enzyme that selectively removes the secondary (acyloxyacyl-linked) fatty acyl chains from the lipid A region of bacterial lipopolysaccharides (endotoxins), thereby detoxifying the molecules. The two disulfide-linked subunits of the enzyme are encoded by a single mRNA. The amino acid sequence of the protein contains a lipase consensus sequence in the large subunit and a region in the small subunit that is similar to the saposins, cofactors for sphingolipid hydrolases. The recombinant enzyme, like native AOAH, hydrolyzes secondary acyl chains from more than one position on the lipopolysaccharide backbone. Acyloxyacyl hydrolase is a novel two-component lipase that, by deacylating lipopolysaccharides, may modulate host inflammatory responses to Gram-negative bacterial invasion.     

Degradation of oxidized insulin B chain by the multiproteinase complex macropain (proteasome)

The peptides generated from the degradation of the oxidized B chain of bovine insulin by the multiproteinase complex macropain (proteasome) have been analyzed by reverse-phase peptide mapping and identified by N-terminal amino acid sequencing and composition analysis. Six of the 29 peptide bonds in the insulin B chain were found to be rapidly cleaved by macropain. The catalytic center that cleaves the Gln4-His5 bond could be distinguished from the center or centers that cleave the other preferred bonds by its specific susceptibility to inhibition by leupeptin, antipain, chymostatin, and pentamidine, suggesting that macropain utilizes at least two distinct catalytic centers for the degradation of this model polypeptide. The same effectors simultaneously enhance the rate of cleavage at the other susceptible sites in insulin B. The quantitative characteristics of this effect indicate that different catalytic centers of the complex may be functionally coupled, possibly by an allosteric mechanism or possibly by a mechanism in which binding to the catalytic centers is preceded by a rate-limiting binding of the substrate to a site or sites on the enzyme distinct from the catalytic centers. The kinetics of insulin B chain degradation indicate that macropain can catalyze sequential hydrolysis of peptide bonds in a single substrate molecule via a reaction pathway that involves channeling of peptide intermediates between different catalytic centers within the multienzyme complex. This capacity for channeling may confer potential physiological advantages of increasing the efficiency of amino acid recycling and reducing the pool sizes of peptide intermediates that are generated during the degradation of polypeptides in the intracellular milieu.     

How do children with and without ADHD talk about frustration?: Use of a novel emotion narrative recall task

Children with attention-deficit/hyperactivity disorder (ADHD) experience difficulties related to emotional reactivity and regulation. The current study examines differences in the emotional reactivity and regulation of children with and without ADHD in the context of their real-life experiences of negative emotion using a novel ecologically valid methodology. Eighty-three 8–12-year-old children (46 ADHD, 38 non-ADHD) participated in the study. Children completed the negative emotion narrative recall task, a novel task whereby children provided a narrative recall of a real-life event where they experienced negative emotion. ANCOVA indicated children with ADHD recalled significantly more overall frustration and intense frustration than children without ADHD. Children with ADHD exhibiting more negative emotional reactivity while recalling negative emotions than children without ADHD. The current study suggests that children with ADHD are uniquely impacted by negative emotional experiences and represents an important step in understanding the emotional reactivity and regulation of children with ADHD.     

ERK phosphorylation potentiates Elk-1-mediated ternary complex formation and transactivation.

Induction of the human c-fos proto-oncogene by mitogens depends on the formation of a ternary complex by p62TCF with the serum response factor (SRF) and the serum response element (SRE). We demonstrate that Elk-1, a protein closely related to p62TCF in function, is a nuclear target of two members of the MAP kinase family, ERK1 and ERK2. Phosphorylation of Elk-1 increases the yield of ternary complex in vitro. At least five residues in the C-terminal domain of Elk-1 are phosphorylated upon growth factor stimulation of NIH3T3 cells. These residues are also phosphorylated by purified ERK1 in vitro, as determined by a combination of phosphopeptide sequencing and 2-D peptide mapping. Conversion of two of these phospho-acceptor sites to alanine impairs the formation of ternary complexes by the resulting Elk-1 proteins. Removal of these serine residues also drastically diminishes activation of the c-fos promoter in epidermal growth factor-treated cells. Analogous mutations at other sites impair activation to a lesser extent without affecting ternary complex formation in vitro. Our results indicate that phosphorylation regulates ternary complex formation by Elk-1, which is a prerequisite for the manifestation of its transactivation potential at the c-fos SRE.