Absolute quantitation of low abundance plasma APL1ß peptides at sub-fmol/mL Level by SRM/MRM without immunoaffinity enrichment.

Selected/multiple reaction monitoring (SRM/MRM) has been widely used for the quantification of specific proteins/peptides, although it is still challenging to quantitate low abundant proteins/peptides in complex samples such as plasma/serum. To overcome this problem, enrichment of target proteins/peptides is needed, such as immunoprecipitation; however, this is labor-intense and generation of antibodies is highly expensive. In this study, we attempted to quantify plasma low abundant APLP1-derived Aß-like peptides (APL1ß), a surrogate marker for Alzheimer's disease, by SRM/MRM using stable isotope-labeled reference peptides without immunoaffinity enrichment. A combination of Cibacron Blue dye mediated albumin removal and acetonitrile extraction followed by C18-strong cation exchange multi-StageTip purification was used to deplete plasma proteins and unnecessary peptides. Optimal and validated precursor ions to fragment ion transitions of APL1ß were developed on a triple quadruple mass spectrometer, and the nanoliquid chromatography gradient for peptide separation was optimized to minimize the biological interference of plasma. Using the stable isotope-labeled (SI) peptide as an internal control, absolute concentrations of plasma APL1ß peptide could be quantified as several hundred amol/mL. To our knowledge, this is the lowest detection level of endogenous plasma peptide quantified by SRM/MRM.

Identification of the recognition sequence and target proteins for DJ-1 protease.

DJ-1, the product of familial Parkinson's disease gene and an oncogene, is a cysteine protease which plays a role in anti-oxidative stress reaction. In this study, we identified the recognition sequence for DJ-1 protease by using recombinant DJ-1 and a peptide library. Protease activity of DJ-1 lacking C-terminal α-helix (DJ-1ΔH9) was stronger than that of full-sized DJ-1, and the most susceptible sequence digested by DJ-1ΔH9 was valine-lysine-valine-alanine (VKVA) under the optimal conditions of pH 5.5 and 0 mM NaCl. Divalent ions, especially Cu²âº, were inhibitory to DJ-1's protease activity. c-abl oncogene 1 product (ABL1) and kinesin family member 1B (KIF1B) containing VKVA were digested by DJ-1ΔH9.

A halophilic serine proteinase from Halobacillus sp. SR5-3 isolated from fish sauce: purification and characterization.

A halophilic bacterium was isolated from fish sauce, classified, and named Halobacillus sp. SR5-3. A purified 43-kDa proteinase produced by this bacterium showed optimal activity at 50 degrees C and pH 9-10 in 20% NaCl. The activity of the enzyme was enhanced about 2.5-fold by the addition of 20-35% NaCl, and the enzyme was highly stabilized by NaCl. It was found to be a serine proteinase related to either chymotrypsin or subtilisin. It absolutely preferred Ile at the P(2) position of substrates. Thus, the enzyme was found to be a halophilic serine proteinase with unique substrate specificity.

Exploring the subsite-structure of vimelysin and thermolysin using FRETS-libraries.

Vimelysin is a metalloproteinase with high activity at low temperature and an unusual resistance to organic solvents. Substrate specificities of vimelysin and thermolysin were examined using FRETS-libraries, revealing a significant difference at the P3' position: vimelysin preferred acidic amino acid residues, whereas thermolysin preferred basic residues. Homology modeling of vimelysin suggests that oppositely charged residues in the S3' subsites (R215 in vimelysin and D213 in thermolysin) may be responsible for this specificity difference. This hypothesis was confirmed by examining the R215D mutant of vimelysin, which showed a substrate specificity profile intermediate between thermolysin and vimelysin.

Catalytic residues and substrate specificity of scytalidoglutamic peptidase, the first member of the eqolisin in family (G1) of peptidases.

Scytalidoglutamic peptidase (SGP) is the first-discovered member of the eqolisin family of peptidases with a unique structure and a presumed novel catalytic dyad (E136 and Q53) [Fujinaga et al., PNAS 101 (2004) 3364-3369]. Mutants of SGP, E136A, Q53A, and Q53E lost both the autoprocessing and enzymatic activities of the wild-type enzyme. Coupled with the results from the structural analysis of SGP, Glu136 and Gln53 were identified as the catalytic residues. The substrate specificity of SGP is unique, particularly, in the preference at the P3 (basic amino acid), P1' (small a.a.), and P3' (basic a.a.) positions. Superior substrates and inhibitors have been synthesized for kinetic studies based on the results reported here. kcat, Km, and kcat/Km of SGP for D-Dap(MeNHBz)-GFKFF*ALRK(Dnp)-D-R-D-R were 34.8 s-1, 0.065 microM, and 535 microM-1 s-1, respectively. Ki of Ac-FKF-(3S,4S)-phenylstatinyl-LR-NH2 for SGP was 1.2x10(-10) M. Taken together, we can conclude that SGP has not only structural and catalytic novelties but also a unique subsite structure.

Mammalian D-aspartyl endopeptidase: a scavenger for noxious racemized proteins in aging.

The accumulation of D-isomers of aspartic acid (D-Asp) in proteins during aging has been implicated in the pathogenesis of Alzheimer's disease, cataracts, and arteriosclerosis. Here, we identified a specific lactacystin-sensitive endopeptidase that cleaves the D-Asp-containing protein and named it D-aspartyl endopeptidase (DAEP). DAEP has a multi-complex structure (MW: 600kDa) and is localized in the inner mitochondrial membrane of mouse and rabbit, but DAEP activity was not detected in Escherichia coli, Saccharomyces cerevisiae, and Caenorhabditis elegans. A specific inhibitor for DAEP was newly synthesized, and inhibited DAEP activity (IC(50), 3microM), a factor of 10 greater than lactacystin on DAEP. On the other hand, the inhibitor did not inhibit either the 20S or 26S proteasome.

Substrate specificity of alkaline serine proteinase isolated from photosynthetic bacterium, Rubrivivax gelatinosus KDDS1.

A novel type of fluorescence resonance energy transfer (FRET) combinatorial libraries were used for the characterization of alkaline serine proteinase produced from Rubrivivax gelatinosus KDDS1. This enzyme was the first serine proteinase characterized from photosynthetic bacteria. The proteinase was found to prefer Met and Phe at the P1 position, Ile and Lys at the P2 position, and Arg and Phe at the P3 position. To date, no serine proteinase has exhibited a preference for Met at the P1 position. Thus, the alkaline serine proteinase from R. gelatinosus KDDS1 is very unique in terms of substrate specificity. A highly sensitive substrate, Boc-Arg-Ile-Met-MCA, was synthesized for kinetic study based on the results reported here. The optimum pH of the enzyme for this substrate was pH 10.7, and the values of kcat, Km, and kcat/Km were 23.7 s(-1), 15.4 microM, and 1.54 microM(-1) s(-1), respectively.