Purification and molecular cloning of aspartic proteinases from the stomach of adult Japanese fire belly newts, Cynops pyrrhogaster.

Six aspartic proteinase precursors, a pro-cathepsin E (ProCatE) and five pepsinogens (Pgs), were purified from the stomach of adult newts (Cynops pyrrhogaster). On sodium dodecylsulfate-polyacrylamide gel electrophoresis, the molecular weights of the Pgs and active enzymes were 37-38 kDa and 31-34 kDa, respectively. The purified ProCatE was a dimer whose subunits were connected by a disulphide bond. cDNA cloning by polymerase chain reaction and subsequent phylogenetic analysis revealed that three of the purified Pgs were classified as PgA and the remaining two were classified as PgBC belonging to C-type Pg. Our results suggest that PgBC is one of the major constituents of acid protease in the urodele stomach. We hypothesize that PgBC is an amphibian-specific Pg that diverged during its evolutional lineage. PgBC was purified and characterized for the first time. The purified urodele pepsin A was completely inhibited by equal molar units of pepstatin A. Conversely, the urodele pepsin BC had low sensitivity to pepstatin A. In acidic condition, the activation rates of newt pepsin A and BC were similar to those of mammalian pepsin A and C1, respectively. Our results suggest that the enzymological characters that distinguish A- and C-type pepsins appear to be conserved in mammals and amphibians.

Expression, purification and auto-activation of cathepsin E from insect cells.

Cathepsin E is an aspartic protease that belongs to the pepsin family. This protease is similar to cathepsin D but differs in its tissue distribution and cell localization. Elevated levels of this enzyme are linked to several tumors, including devastating pancreatic ductal adenocarcinoma. In this manuscript, we present a new protocol for the high-yield purification of recombinant human cathepsin E in the baculovirus expression system. The recombinant protein was produced by the Sf9 insect cell line and secreted into the medium in the form of an inactive zymogen. Procathepsin E was purified using ion-exchange and size exclusion chromatographies followed by pepstatin- and heparin-affinity chromatography steps. The zymogen was activated at an acidic pH, resulting in a high yield of the activated intermediate of cathepsin E. The enzymatic activity, stability, and molecular weight corresponded to those of cathepsin E. The new purification procedure will promote further studies of this enzyme to improve the understanding of its structure-function relationship and consequently enable the development of better therapeutic approaches.

Cathepsin D, but not cathepsin E, degrades desmosomes during epidermal desquamation.

BACKGROUND: We previously reported that an ambient aspartic proteinase is crucial to desquamation of the stratum corneum at pH 5. Identification of this aspartic proteinase by using enzyme inhibitors suggested it to be cathepsin D, although we could not exclude cathepsin E. OBJECTIVES: To determine the identity of this aspartic proteinase and its distribution within the stratum corneum. METHODS: We measured enzyme activities of cathepsin D and cathepsin E in the salt and detergent extracts from callus stratum corneum, using a fluorogenic peptide as a substrate and comparing the effect of addition of Ascaris pepsin inhibitor (specific for cathepsin E) with that of pepstatin A (which inhibits both cathepsin D and cathepsin E). Both enzymes were then extracted and purified from plantar stratum corneum samples and identified by Western blotting. Immunofluorescence microscopy was used to investigate the localization of proteinases within human plantar stratum corneum sample sections. RESULTS: We found that 20% of total aspartic proteinase activity could be attributed to cathepsin E, the remainder to cathepsin D. Two subunits of cathepsin D were identified, a mature active form at 33 kDa and an intermediate active form at 48 kDa; cathepsin E was also identified at 48 kDa, although in a stained band 10-fold weaker in the immunoblot. Immunofluorescence microscopy showed the antibody to cathepsin D to be localized in the lipid envelopes of the stratum corneum, whereas that to cathepsin E stained the tissue diffusely. The labelling for cathepsin D was similar to that observed for desmosomes, and immunoelectron microscopy confirmed that cathepsin D was present on desmosomes. On the other hand, cathepsin E occurred intracellularly within the squames. CONCLUSIONS: We conclude that cathepsin D, and not cathepsin E, causes desquamation by degrading desmosomes.

Purification and characterization of recombinant human cathepsin E expressed in human kidney cell line 293.

A cDNA encoding human prepro-cathepsin E was introduced into the adenovirus-transformed HEK-293 (human embryonic kidney) cell line. The construct contained both a V5 peptide epitope and histidine tags at the carboxy terminus. Transfected cells efficiently secreted recombinant pro-cathepsin E into the culture medium. The secreted pro-cathepsin E was purified in a single step using Ni affinity chromatography yielding a protein of about 92 kDa under non-reducing conditions. The amino-terminal sequence of the purified protein began at Ser20, suggesting human cathepsin E accumulated in the culture supernatant as the pro-enzyme. The purified protein was rapidly and completely converted to the active form by treatment at pH 4.0 or below. Steady state kinetic parameters for hydrolysis of the fluorogenic peptide substrate MOCAc-Gly-Lys-Pro-Ile-Leu-Phe-Phe-Arg-Leu-Lys(Dnp)-d-Arg-NH2 (cleavage at the Phe-Phe bond) were consistent with previously reported values for purified human enzyme (kc/Ki= 53 x 10(6) M(-1) s(-1), Km= 6.3 microM, and kcat= 3 x 10(2) s(-1)). The activated protein was potently inhibited by pepstatin with Ki= 0.2 nM, as well as a reported beta secretase inhibitor. This work demonstrates the potential for producing large quantities of highly purified human cathepsin E from HEK-293 cells in quantities to support both biochemical and structural characterization of the enzyme.

Molecular cloning of preprocathepsin E cDNA from the stomach of bullfrog Rana catesbeiana.

A cDNA library was constructed from a poly(A)(+) RNA fraction of the gastric mucosa of bullfrog Rana catesbeiana. We cloned a cDNA encoding preprocathepsin E (Pre-Pro-CE) from the library. The present study is the first demonstration of the Pre-Pro-CE cDNA of lower vertebrate such as amphibian. Amino acid sequence deduced from the cDNA was compared with partial amino acid sequence determined by Edman degradation, suggesting that the cDNA comprises an open reading frame encoding a signal peptide (16 amino acids), a pro-sequence (33 amino acids) and a mature protein region (348 amino acids). Two consensus tri-peptide sequences (FDT and VDT) as active site and positions of seven cysteine residues were conserved in this amphibian CE. Although the bullfrog CE was deduced to contain one potential N-linked glycosylation site, its position (Asn(139)-Leu(140)-Thr(141)) was different from that of mammalian CEs. Molecular phylogenetic analysis showed that the bullfrog Pro-CE belongs to the typical Pro-CE group among various aspartic proteinases.