Inhibition of Human Pepsin and Gastricsin by α2-Macroglobulin

The inhibitory effects of human α₂-macroglobulin (α₂-M), a major plasma proteinase inhibitor, on human pepsin and gastricsin were investigated. The activities of pepsin and gastricsin towards a protein substrate (reduced and carboxymethylated ribonuclease A) were significantly inhibited by α₂-M at pH 5.5, whereas those towards a peptide substrate (oxidized insulin B-chain) were scarcely inhibited. Under these conditions at pH 5.5, pepsin and gastricsin cleaved α₂-M mainly at the His⁶⁹⁴-Ala⁶⁹⁵ bond and Leu⁶⁹⁷-Val⁶⁹⁸ bond, respectively, in the bait regions sequence of α₂-M. The conformation of α₂-M was also shown to be markedly altered upon inhibition of these enzymes as examined by native polyacrylamide gel electrophoresis and electron microscopy. These results show the entrapment and concomitant inhibition of those proteinases by α₂-M.     

Myofibril-Inducing RNA (MIR) is essential for tropomyosin expression and myofibrillogenesis in axolotl hearts

The Mexican axolotl, Ambystoma mexicanum, carries the naturally-occurring recessive mutant gene 'c' that results in a failure of homozygous (c/c) embryos to form hearts that beat because of an absence of organized myofibrils. Our previous studies have shown that a noncoding RNA, Myofibril-Inducing RNA (MIR), is capable of promoting myofibrillogenesis and heart beating in the mutant (c/c) axolotls. The present study demonstrates that the MIR gene is essential for tropomyosin (TM) expression in axolotl hearts during development. Gene expression studies show that mRNA expression of various tropomyosin isoforms in untreated mutant hearts and in normal hearts knocked down with double-stranded MIR (dsMIR) are similar to untreated normal. However, at the protein level, selected tropomyosin isoforms are significantly reduced in mutant and dsMIR treated normal hearts. These results suggest that MIR is involved in controlling the translation or post-translation of various TM isoforms and subsequently of regulating cardiac contractility.     

Distinct cleavage specificity of human cathepsin E at neutral pH with special preference for Arg-Arg bonds

In order to clarify the potential role of cathepsin E at neutral pH, the cleavage specificity of human cathepsin E was examined at pH 7.4 toward reduced-carboxymethylated(RCm-)ribonuclease A and various bioactive and related peptides. The specificity of the enzyme at pH 7.4 was found to be considerably different from that at acidic pH; preferential cleavages were observed with Arg-X and Glu-X bonds, which are not the major cleavage sites at acidic pH. Moreover, the Arg-Arg bond was found to be the most preferential site of cleavage. This unique specificity observed at pH 7.4 suggests the possibility that cathepsin E might be involved in processing and/or degradation of certain proteins and/or peptides at or near neutral pH in vivo.     

Stability profiles of nepenthesin in urea and guanidine hydrochloride: comparison with porcine pepsin A

Nepenthesin, an aspartic endopeptidase from the pitcher fluid of Nepenthes, was found to be markedly less stable than porcine pepsin A when treated with urea or guanidine hydrochloride. This is in sharp contrast with its remarkably high pH/temperature stability as compared with porcine pepsin A. No protein with such a stability profile has been reported to date.     

Gastric procathepsin E and progastricsin from guinea pig. Purification, molecular cloning of cDNAs, and characterization of enzymatic properties, with special reference to procathepsin E.

Procathepsin E and progastricsin were purified from the gastric mucosa of the guinea pig. They were converted to the active form autocatalytically under acidic conditions. Each active form hydrolyzed protein substrates maximally at around pH 2.5. Pepstatin inhibited cathepsin E very strongly at an equimolar concentration, whereas the inhibition was much weaker for gastricsin. Molecular cloning of the respective cDNAs permitted us to deduce the complete amino acid sequences of their pre-proforms; preprocathepsin E and preprogastricsin consisted of 391 and 394 residues, respectively. Procathepsin E has unique structural and enzymatic features among the aspartic proteinases. Lys at position 37, which is common to various aspartic proteinases and is thought to be important for stabilizing the activation segment, was absent at the corresponding position, as in human procathepsin E. The rate of activation of procathepsin E to cathepsin E is maximal at around pH 4.0. It is very different from the pepsinogens and may be correlated with the absence of Lys37. Native procathepsin E is a dimer, consisting of two monomers covalently bound by a disulfide bridge between 2 Cys37. Interconversion between the dimer and the monomer was reversible and regulated by low concentrations of a reducing reagent. Although the properties of the dimeric and monomeric cathepsins E are quite similar, a marked difference was found between them in terms of their stability in weakly alkaline solution: monomeric cathepsin E was unstable at weakly alkaline pH whereas the dimeric form was stable. The generation of the monomer was thought to be the process leading to inactivation, hence degradation of cathepsin E in vivo.     

The active site titration of proteinases by using alpha 2-macroglobulin and high-performance liquid chromatography.

The active site titration for various proteinases relies on the development of optimal enzyme titrants for each proteinase, but these titrants are only available for a limited number of proteinases. We have described a new active site titration method applicable to various kinds of endoproteinases using small quantities of the enzymes. This method was carried out by using alpha 2-macroglobulin (alpha 2M) as a titrant and a high-performance liquid chromatography (HPLC) system. When the proteinase solution was treated with alpha 2M, the active proteinase was trapped by alpha 2M. In this reaction alpha 2M does not usually complex with inactive proteinase. After the reaction of proteinase with an excess of alpha 2M, the reaction mixture is applied to an HPLC gel column to separate the uncomplexed enzyme from the one complexed with alpha 2M. The active proteinase is complexed and eluted with alpha 2M, but the inactive proteinase is eluted at the original elution volume. The same amount of the enzyme was also applied to the column. From the decrease of the peak height at the elution position of the uncomplexed proteinase, we can estimate the ratio between enzymatically active proteinases and total proteinases. To test the usefulness of this method, we applied this method to chymotrypsin and trypsin whose activities were predetermined by conventional active site titration, and there was good agreement between both results. With this new method, we can estimate a proteinase activity with as little as 200 ng of the enzyme, a very small amount compared with those required in conventional methods.(ABSTRACT TRUNCATED AT 250 WORDS)     

Protein kinase A-mediated gating of neuregulin-dependent ErbB2-ErbB3 activation underlies the synergistic action of cAMP on Schwann cell proliferation

In Schwann cells (SCs), cyclic adenosine monophosphate (cAMP) enhances the action of neuregulin, the most potent known mitogen for SCs, by synergistically increasing the activation of two crucial signaling pathways: ERK and Akt. However, the underlying mechanism of cross-talk between neuregulin and cAMP signaling remains mostly undefined. Here, we report that the activation of protein kinase A (PKA), but not that of exchange protein activated by cAMP (EPAC), enhances S-phase entry of SCs by synergistically enhancing the ligand-dependent tyrosine phosphorylation/activation of the neuregulin co-receptor, ErbB2-ErbB3. The role of PKA in neuregulin-ErbB signaling was confirmed using PKA inhibitors, pathway-selective cAMP analogs, and natural ligands stimulating PKA activity in SCs, such as adenosine and epinephrine. Two basic observations defined the synergistic action of PKA as "gating" for neuregulin-ErbB signaling: 1) the activation of PKA was not sufficient to induce S-phase entry or the activation of either ErbB2 or ErbB3; and 2) the presence of neuregulin was strictly required to ignite ErbB activation and thereby ERK and Akt signaling. However, PKA directly phosphorylated ErbB2 on Thr-686, a highly conserved intracellular regulatory site that was required for the PKA-mediated synergistic enhancement of neuregulin-induced ErbB2-ErbB3 activation and proliferation in SCs. The gating action of PKA on neuregulin-induced ErbB2-ErbB3 activation has important biological significance, because it insures signal amplification into the ERK and Akt pathways without compromising either the neuregulin dependence or the high specificity of ErbB signaling pathways.     

Inhibition of human pepsin and gastricsin by alpha2-macroglobulin

The inhibitory effects of human alpha2-macroglobulin (alpha2-M), a major plasma proteinase inhibitor, on human pepsin and gastricsin were investigated. The activities of pepsin and gastricsin towards a protein substrate (reduced and carboxymethylated ribonuclease A) were significantly inhibited by alpha2-M at pH 5.5, whereas those towards a peptide substrate (oxidized insulin B-chain) were scarcely inhibited. Under these conditions at pH 5.5, pepsin and gastricsin cleaved alpha2-M mainly at the His694-Ala695 bond and Leu697-Val698 bond, respectively, in the bait regions sequence of alpha2-M. The conformation of alpha2-M was also shown to be markedly altered upon inhibition of these enzymes as examined by native polyacrylamide gel electrophoresis and electron microscopy. These results show the entrapment and concomitant inhibition of those proteinases by alpha2-M.