Sukkid Yasothornsrikul scite author profile

Multistep proteolytic mechanisms are essential for converting proprotein precursors into active peptide neurotransmitters and hormones. Cysteine proteases have been implicated in the processing of proenkephalin and other neuropeptide precursors. Although the papain family of cysteine proteases has been considered the primary proteases of the lysosomal degradation pathway, more recent studies indicate that functions of these enzymes are linked to specific biological processes. However, few protein substrates have been described for members of this family. We show here that secretory vesicle cathepsin L is the responsible cysteine protease of chromaffin granules for converting proenkephalin to the active enkephalin peptide neurotransmitter. The cysteine protease activity was identified as cathepsin L by affinity labeling with an activity-based probe for cysteine proteases followed by mass spectrometry for peptide sequencing. Production of T he biosynthesis of enkephalin opioid peptides as well as numerous peptide neurotransmitters and hormones requires proteolytic processing of respective proprotein precursors within regulated secretory vesicles (1-4). The mature, processed enkephalin peptide is stored within these vesicles and undergoes stimulated secretion to mediate neurotransmission and cell-cell communication in the regulation of analgesia, behavior, and immune-cell functions. Secretory vesicles of neuroendocrine chromaffin cells (also known as chromaffin granules) contain enkephalin and its precursor proenkephalin (PE) (5, 6), with relevant prohormone convertases for converting PE into active enkephalin.The primary PE-cleaving activity in chromaffin granules has been characterized as a cysteine protease complex known as ''prohormone thiol protease'' (PTP) (7-10). The cysteine protease activity cleaves PE and enkephalin-containing peptide substrates at paired basic residues, as well as at certain monobasic residues, to generate appropriate enkephalin-related peptide products. Cellular inhibition of PTP by a cysteine protease inhibitor results in reduced production of enkephalin (11). Molecular identification of the protease component responsible for this cysteine protease activity will facilitate our understanding of multiple proteolytic enzymes that produce active peptides including the opioid [Met]enkephalin (ME) (12,13).In this study the protease responsible for PE-cleaving activity in chromaffin granules was identified by using an activity-based probe for cysteine proteases (14, 15) combined with mass spectrometry (MS) for peptide sequencing. Results identified secretory vesicle cathepsin L as the enzyme responsible for the previously described PTP cysteine protease activity involved in enkephalin and neuropeptide production (7-10). Cathepsin L generated the active peptide ME by cleaving enkephalin-containing peptide substrates at native dibasic and monobasic sites. Notably, cathepsin L colocalized with ME in the regulated secretory pathway of chromaffin cells. In cathepsin L gene knockout (KO) mice (16-1...

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Molecular Cloning of Endopin 1, a Novel Serpin Localized to Neurosecretory Vesicles of Chromaffin Cells

Hwang

Steineckert

Yasothornsrikul

et al. 1999

Journal of Biological Chemistry

100

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β‐Amyloid peptide in regulated secretory vesicles of chromaffin cells: evidence for multiple cysteine proteolytic activities in distinct pathways for β‐secretase activity in chromaffin vesicles

Hook

Toneff

Aaron

et al. 2002

Journal of Neurochemistry

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A key factor in Alzheimer's disease (AD) is the beta-secretase activity that is required for the production of beta-amyloid (Abeta) peptide from its amyloid precursor protein (APP) precursor. In this study, the majority of Abeta secretion from neuronal chromaffin cells was found to occur via the regulated secretory pathway, compared with the constitutive secretory pathway; therefore, beta-secretase activity in the regulated secretory pathway was examined for the production and secretion of Abeta in chromaffin cells obtained from in vivo adrenal medullary tissue. The presence of Abeta(1-40) in APP-containing chromaffin vesicles, which represent regulated secretory vesicles, was demonstrated by radioimmunoassay (RIA) and reverse-phase high-performance liquid chromatography. These vesicles also contain Abeta(1-42), measured by RIA. Significantly, regulated secretion of Abeta(1-40) from chromaffin cells represented the majority of secreted Abeta (> 95% of total secreted Abeta), compared with low levels of constitutively secreted Abeta(1-40). These results indicate the importance of Abeta production and secretion in the regulated secretory pathway as a major source of extracellular Abeta. Beta-secretase activity in isolated chromaffin vesicles was detected with the substrate Z-Val-Lys-Met-/MCA (methylcoumarinamide) that contains the beta-secretase cleavage site. Optimum beta-secretase activity in these vesicles required reducing conditions and acidic pH (pH 5-6), consistent with the in vivo intravesicular environment. Evidence for cysteine protease activity was shown by E64c inhibition of Z-Val-Lys-Met-MCA-cleaving activity, and E64c inhibition of Abeta(1-40) production in isolated chromaffin vesicles. Chromatography resolved the beta-secretase activity into two distinct proteolytic pathways consisting of: (i) direct cleavage of the beta-secretase site at Met-/Asp by two cysteine proteolytic activities represented by peaks Il-A and Il-B, and (ii) an aminopeptidase-dependent pathway represented by peak I cysteine protease activity that cleaves between Lys-/Met, followed by Met-aminopeptidase that would generate the beta-secretase cleavage site. Treatment of chromaffin cells in primary culture with the cysteine protease inhibitor E64d reduced the production of the beta-secretase product, a 12-14 kDa C-terminal APP fragment. In addition, BACE 1 and BACE 2 were detected in chromaffin vesicles; BACE 1 represented a small fraction of total beta-secretase activity in these vesicles. These results illustrate that multiple cysteine proteases, in combination with BACE 1, contribute to beta-secretase activity in the regulated secretory pathway. These results complement earlier findings for BACE 1 as beta3-secretase for Abeta production in the constitutive secretory pathway that provides basal secretion of Abeta into conditioned media. These findings suggest that drug inhibition of several proteases may be required for reducing Abeta levels as a potential therapeutic approach for AD.

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