Low temperature blocks transport and sorting of cathepsin D in fibroblasts

Long-Peptide Cross-Presentation by Human Dendritic Cells Occurs in Vacuoles by Peptide Exchange on Nascent MHC Class I Molecules

Cross-presentation enables dendritic cells to present on their MHC class I molecules antigenic peptides derived from exogenous material, through a mechanism that remains partly unclear. It is particularly efficient with long peptides, which are used in cancer vaccines. We studied the mechanism of long-peptide cross-presentation using human dendritic cells and specific CTL clones against melanoma Ags gp100 and Melan-A/MART1. We found that cross-presentation of those long peptides does not depend on the proteasome or the transporter associated with Ag processing, and therefore follows a vacuolar pathway. We also observed that it makes use of newly synthesized MHC class I molecules, through peptide exchange in vesicles distinct from the endoplasmic reticulum and classical secretory pathway, in an SEC22b- and CD74-independent manner. Our results indicate a nonclassical secretion pathway followed by nascent HLA-I molecules that are used for cross-presentation of those long melanoma peptides in the vacuolar pathway. Our results may have implications for the development of vaccines based on long peptides.

Increase in ceramide level alters the lysosomal targeting of cathepsin D prior to onset of apoptosis in HT-29 colon cancer cells

Ceramide has been suggested as an important mediator of apoptosis. In HT-29 colorectal cancer cells increased ceramide levels, induced by exogenous N-acetylsphingosine (NAS, also known as C2-ceramide) or by 1-phenyl-2-(decanoylamino)-3-morpholino-1-propanol (PDMP), inhibited the transport and processing of cathepsin D (CD), a lysosomal protease implicated in apoptosis of tumour cells. C2-dihydroceramide (DH-C2), an inactive analogue of NAS, had no effect on CD transport and maturation. The treatment with either NAS or PDMP was revealed to be cytotoxic for HT-29 cells and led to cell death with classical features of apoptosis. Morphological signs of apoptosis and DNA fragmentation became apparent only between 24 and 48 h of incubation and poly(ADP ribose)-polymerase cleavage, a hallmark of caspase 3 activity, occurred no earlier than 8 h from incubation. Secretion of proCD was almost abolished and the formation of double-chain mature CD was reduced and delayed by NAS, whereas PDMP largely inhibited the lysosomal targeting and maturation of proCD. NAS- and PDMP-induced alteration of proCD transport and maturation were apparent already 2 h after incubation with the drugs, which is much earlier than when classical biochemical and morphological evidence of apoptosis could be detected. These data indicate that alteration of CD (and possibly of other glycoproteins) transport along the secretory pathway due to increased levels of cell-associated ceramide is an early event in cells undergoing apoptosis.

Accumulation of sialic acid in endocytic compartments interferes with the formation of mature lysosomes. Impaired proteolytic processing of cathepsin B in fibroblasts of patients with lysosomal sialic acid storage disease

The impact of an altered endocytic environment on the biogenesis of lysosomes was studied in fibroblasts of patients suffering from sialic acid storage disease (SASD). This inherited disorder is characterized by the accumulation of acidic monosaccharides in lysosomal compartments and a concomitant decrease of their buoyant density. We demonstrate that C-terminal trimming of the lysosomal cysteine proteinase cathepsin B is inhibited in SASD fibroblasts. This late event in the biosynthesis of cathepsin B normally takes place in mature lysosomes, suggesting an impaired biogenesis of these organelles in SASD cells. When normal fibroblasts are loaded with sucrose, which inhibits transport from late endosomes to lysosomes, C-terminal cathepsin B processing is prevented to the same extent. Further characterization of the terminal endocytic compartments of SASD cells revealed properties usually associated with late endosomes/prelysosomes. In addition to a decreased buoyant density, SASD "lysosomes" show a reduced acidification capacity and appear smaller than their normal counterparts. We conclude that the accumulation of small non-diffusible compounds within endocytic compartments interferes with the formation of mature lysosomes and that the acidic environment of the latter organelles is a prerequisite for C-terminal processing of lysosomal hydrolases.

Stabilization of mutant 46-kDa mannose 6-phosphate receptors by proteasomal inhibitor lactacystin

Palmitoylation of cysteine residue 34 within the 67-amino acid cytoplasmic domain of the 46-kDa mannose 6-phosphate receptor (MPR 46), which may be anchored to the lipid bilayer, prevents the receptor from entering lysosomes (Schweizer, A., Kornfeld, S., and Rohrer, J. (1996) J. Cell Biol. 132, 577-584). In the present study, we examined the importance of the spacing between the transmembrane domain and the palmitoylation anchor site in the cytoplasmic domain for stability and trafficking of MPR 46. MPR 46 mutants with deletions of residues 20-23 and 24-29 expressed in baby hamster kidney cells were rapidly degraded with half-lives of less than 10 h. The replacement of residues 24-29 by alanine resulted in prolongation of receptor stability (t(1)/(2) approximately 20 h). Whereas mutant MPR 46 could not be detected in lysosomal fractions and inhibitors of lysosomal proteases failed to prevent degradation, treatment with the proteasome inhibitor lactacystin resulted in increased stability of mutant MPR 46. Pulse-chase experiments at low temperature and the acquirement of endoglucosaminidase H-resistant oligosaccharides indicate that the majority of mutant MPR 46 is degraded after leaving the Golgi compartment. Altered trafficking of mutant MPR 46 may be the result of decreased palmitoylation reaching 40% of wild type receptors. The data suggest that the spacing between the transmembrane domain and the proposed palmitoylation anchor site in the cytoplasmic domain of MPR 46 is important for a post Golgi sorting step preventing receptor degradation by multiple proteolytic systems including the proteasome.

Effect of carbohydrate position on lysosomal transport of procathepsin L

To study the role of carbohydrate in lysosomal protein transport, we engineered two novel glycosylation signals (Asn-X-Ser/Thr) into the cDNA of human procathepsin L, a lysosomal acid protease. We constructed six mutant cDNAs encoding glycosylation signals at mutant sites Asn-138, Asn-175, or both sites together, in the presence or absence of the wild-type Asn-204 site. We stably transfected wild-type and mutant cDNAs into NIH3T3 mouse fibroblasts and then used species-specific antibodies to determine the glycosylation status, phosphorylation, localization, and transport kinetics of recombinant human procathepsin L containing one, two, or three glycosylation sites. Both novel glycosylation sites were capable of being glycosylated, although Asn-175 was utilized only 30-50% of the time. Like the wild-type glycosylation at Asn-204, carbohydrates at Asn-138 and Asn-175 were completely sensitive to endoglycosidase H, and they were phosphorylated. Mutant proteins containing two carbohydrates were capable of being delivered to lysosomes, but there was not a consistent relationship between the efficiency of lysosomal delivery and carbohydrate content of the protein. Pulse-chase labeling revealed a unique biosynthetic pattern for proteins carrying the Asn-175 glycosylation sequence. Whereas wild-type procathepsin L and mutants bearing carbohydrate at Asn-138 appeared in lysosomes by about 60 min, proteins with carbohydrate at Asn-175 were processed to a lysosome-like polypeptide within 15 min. Temperature shift, brefeldin A, and NH4Cl experiments suggested that the rapid processing did not occur in the endoplasmic reticulum and that Asn-175 mutants could interact with the mannose 6-phosphate receptor. Taken together, our results are consistent with the interpretation that Asn-175 carbohydrate confers rapid transport to lysosomes. We may have identified a recognition domain in procathepsin L that is important for its interactions with the cellular transport machinery.

Mannose 6-phosphate-independent targeting of lysosomal enzymes in I-cell disease B lymphoblasts

B lymphocytes from patients with I-cell disease (ICD) maintain normal cellular levels of lysosomal enzymes despite a deficiency of the enzyme UDP-N-acetylglucosamine: lysosomal enzyme N-acetylglucosamine-1-phosphotransferase. We find that an ICD B lymphoblastoid cell line targets about 45% of the lysosomal protease cathepsin D to dense lysosomes. This targeting occurs in the absence of detectable mannose 6-phosphate residues on the cathepsin D and is not observed in ICD fibroblasts. The secretory protein pepsinogen, which is closely related to cathepsin D in both amino acid sequence and three-dimensional structure, is mostly excluded from dense lysosomes, indicating that the lymphoblast targeting pathway is specific. Carbohydrate residues are not required for lysosomal targeting, since a non-glycosylated mutant cathepsin D is sorted with comparable efficiency to the wild type protein. Analysis of a number of cathepsin D/pepsinogen chimeric proteins indicates that an extensive polypeptide determinant in the cathepsin D carboxyl lobe can confer efficient lysosomal sorting when introduced into the pepsinogen sequence. This determinant overlaps but is not identical to the recognition marker for phosphotransferase. These results indicate that a specific protein recognition event underlies Man-6-P-independent lysosomal sorting in ICD lymphoblasts.

The early and late processing of lysosomal enzymes: proteolysis and compartmentation

Lysosomal enzymes are subjected to a number of modifications including carbohydrate restructuring and proteolytic maturation. Some of these reactions support lysosomal targeting, others are necessary for activation or keeping the enzyme inactive before being segregated, while still others may be adventitious. The non-segregated fraction of the enzyme is secreted and can be isolated from the medium. It is considered that the secreted lysosomal enzymes fulfill certain physiological and pathophysiological roles. By comparing the secreted and the intracellular enzymes it is possible to distinguish between the reactions that occur before and after the segregation. In this review the reactions that may influence the segregation are referred to as the early processing and those characteristic for the enzymes isolated from lysosomal compartments as the late processing. The early processing is characterized mainly by modifications of carbohydrate side chains. In the late processing, proteolytic fragmentation represents the most conspicuous changes. The review focuses on the compartmentation of the reactions and the proteolytic fragmentation of lysosomal enzyme precursors. While a plethora of proteolytic reactions are involved, our knowledge of the proteinases responsible for the particular maturation reactions remains very limited. The review points also to work with cells from patients affected with lysosomal storage disorders, which contributed to our understanding of the lysosomal apparatus.

Reduced temperature does not prevent transport of lysosomal integral membrane proteins from endoplasmic reticulum and through the Golgi system to lysosomes

The effect of low temperature on the transport of three lysosomal integral membrane proteins (I, II and III) from endoplasmic reticulum to lysosomes has been studied in normal rat kidney cells. At 15 degrees C and 18 degrees C, though slowly, the proteins could leave the endoplasmic reticulum, move through the Golgi system from the cis to the trans side, and accumulate in lysosomes. Transport of these proteins at low temperature occurred slower than at 37 degrees C. Both at low temperature and 37 degrees C, the proteins were transported between the endoplasmic reticulum and Golgi (III greater than I and II) and from Golgi to lysosomes (II greater than III much greater than I) with different rates.