Apoptosis or programmed cell death is the major mechanism used by multicellular organisms to remove infected, excessive and potentially dangerous cells. Cysteine proteases from the caspase family play a crucial role in the process. However, there is increasing evidence that lysosomal proteases are also involved in apoptosis. In this review various lysosomal proteases and their potential contribution to propagation of apoptosis are discussed.
Ricin is a potent A-B toxin that is transported from the cell surface to the cytosol, where it inactivates ribosomes, leading to cell death. Ricin enters cells via endocytosis, where only a minute number of ricin molecules reach the endoplasmic reticulum (ER) lumen. Subsequently, the ricin A chain traverses the ER bilayer by a process referred to as dislocation or retrograde translocation to gain access to the cytosol. To study the molecular processes of ricin A chain dislocation, we have established, for the first time, a human cell system in which enzymatically attenuated ricin toxin A chains (RTA E177D and RTA ⌬177-181 ) are expressed in the cell and directed to the ER. Using this human cell-based system, we found that ricin A chains underwent a rapid dislocation event that was quite distinct from the dislocation of a canonical ER soluble misfolded protein, null Hong Kong variant of ␣ 1 -antitrypsin. Remarkably, ricin A chain dislocation occurred via a membrane-integrated intermediate and utilized the ER protein SEL1L for transport across the ER bilayer to inhibit protein synthesis. The data support a model in which ricin A chain dislocation occurs via a novel strategy of utilizing the hydrophobic nature of the ER membrane and selective ER components to gain access to the cytosol.
Human cytomegalovirus down-regulates cell surface class I major histocompatibility (MHC) molecules, thus allowing the virus to proliferate while avoiding detection by CD8 ؉ T lymphocytes. The unique short gene product US2 is a 199-amino acid type I endoplasmic reticulum glycoprotein that modulates surface expression of class I MHC products by targeting class I heavy chains for dislocation from the endoplasmic reticulum to the cytosol, where they undergo proteasomal degradation. Although the mechanism by which this viral protein targets class I heavy chains for destruction remains unclear, the putative US2 cytoplasmic tail comprised of only 14 residues is known to play a functional role. To determine the specific residues critical for mediating class I degradation, a mutagenesis analysis of the cytoplasmic tail of US2 was performed. Using truncation mutants, the removal of only 4 residues (mutant US2 195 ) from the US2 carboxyl terminus completely abolishes class I destruction. Furthermore, site-directed mutagenesis of the US2 cytoplasmic tail revealed that the most critical residues for class I-induced destruction, cysteine 187, serine 190, tryptophan 193, and phenylalanine 196, occurs every third residue. This experimental data supports a model that the US2 cytoplasmic tail is in a 3 10 helical configuration. Such a secondary structure would predict that one side of the 3 10 helical cytoplasmic tail would interact with the extraction apparatus to facilitate the dislocation and subsequent destruction of class I heavy chains.
The human cytomegalovirus proteins US2 and US11 have coopted endoplasmic reticulum (ER) quality control to facilitate the destruction of major histocompatibility complex class I heavy chains. The class I heavy chains are dislocated from the ER to the cytosol, where they are deglycosylated and subsequently degraded by the proteasome. We examined the role of TRAM1 (translocating chain-associated membrane protein-1) in the dislocation of class I molecules using US2-and US11-expressing cells. TRAM1 is an ER protein initially characterized for its role in processing nascent polypeptides. Co-immunoprecipitation studies demonstrated that TRAM1 can complex with the wild type US2 and US11 proteins as well as deglycosylated and polyubiquitinated class I degradation intermediates. In studies using US2-and US11-TRAM1 knockdown cells, we observed an increase in levels of class I heavy chains. Strikingly, increased levels of glycosylated heavy chains were observed in TRAM1 knockdown cells when compared with control cells in a pulse-chase experiment. In fact, US11-mediated class I dislocation was more sensitive to the lack of TRAM1 than US2. These results provide further evidence that these viral proteins may utilize distinct complexes to facilitate class I dislocation. For example, US11-mediated class I heavy chain degradation requires Derlin-1 and SEL1L, whereas signal peptide peptidase is critical for US2-induced class I destabilization. In addition, TRAM1 can complex with the dislocation factors Derlin-1 and signal peptide peptidase. Collectively, the data support a model in which TRAM1 functions as a cofactor to promote efficient US2-and US11-dependent dislocation of major histocompatibility complex class I heavy chains. HCMV2 can down-regulate cell surface expression of the immunologically important molecule major histocompatibility complex class I to avoid immune detection by cytotoxic T cells (1, 2). More specifically, the HCMV US2 and US11 gene products alone can target the ER-localized major histocompatibility complex class I heavy chains for extraction across the ER membrane by a process referred to as dislocation or retrograde translocation. The N-linked glycan is then removed upon exposure to the cytosol by N-glycanase (3), followed by proteasomal destruction (4, 5). The HCMV US2 and US11 proteins utilize the ER quality control process to eliminate class I heavy cells in a similar manner as misfolded or damaged ER proteins (e.g. genetic mutants of ␣ 1 -antitrypsin (6) and the cystic fibrosis transmembrane conductance regulator protein (7)) are targeted for degradation (8). Hence, analysis of US2-and US11-mediated destruction of class I heavy chains provides an excellent system to delineate viral protein function as well as the ER quality control process.ER and cytosolic proteins are required for US2-and US11-mediated dislocation/degradation of class I heavy chains. Some of these proteins have also been identified in the processing of aberrant ER polypeptides. The ER chaperones calnexin, calreticulin, and BiP have ...
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