Expression of protein kinase C beta1 confers resistance to TNFalpha- and paclitaxel-induced apoptosis in HT-29 colon carcinoma cells.

The expression of different protein kinase C (PKC) isoenzymes has been shown to vary with proliferation rates, differentiation or apoptosis in normal colon crypts. In addition, the activity of some PKC isoenzymes appears to be reduced in colorectal cancer. The aim of the present work was to determine whether modulation of PKC expression would affect the susceptibility of a p53-defective colon carcinoma cell line to different apoptotic treatments. HT-29 cells exhibited sensitivity to paclitaxel (Taxol) and tumor necrosis factor alpha (TNFalpha) in a dose- and time-dependent manner but were relatively resistant to etoposide. Inhibition of PKC activity augmented the susceptibility of HT-29 cells to apoptosis, and phorbol ester induction of PKC reduced such susceptibility. Transfected HT-29(PKC) cells, hyper-expressing the beta1 isoform of PKC, were less sensitive to TNFalpha and paclitaxel than the normal counterpart. The present data 1) indicate that the expression of PKC influences the susceptibility of HT-29 colon cancer cells to apoptotic drugs apparently regardless of their mechanism of action, and 2) suggest paclitaxel as a potential candidate for the treatment of colon cancer, possibly in association with inhibitors of PKC (alpha and beta) at doses not cytotoxic per se.

The lysosomal protease cathepsin D is efficiently sorted to and secreted from regulated secretory compartments in the rat basophilic/mast cell line RBL.

Basophils and mast cells contain a peculiar class of inflammatory granules that discharge their content upon antigen-mediated crosslinking of IgE-membrane receptors. The pathways for granule biogenesis and exocytosis in these cells are still largely obscure. In this study we employed the rat basophilic leukemia (RBL)/mast cell line to verify the hypothesis that inflammatory granules share common bioactive molecules and functional properties with lysosomes. We demonstrate that inflammatory granules, as identified by the monoclonal 5G10 antibody (which recognises an integral membrane protein) or by Toluidine Blue staining, have an intralumenal acidic pH, possess lysosomal enzymes and are accessible by fluid-phase and membrane endocytosis markers. In addition, we studied the targeting, subcellular localisation and regulated secretion of the lysosomal aspartic protease cathepsin D (CD) as affected by IgE receptor stimulation in order to obtain information on the pathways for granule biogenesis and exocytosis. Stimulation with DNP-BSA of specific IgE-primed RBL cells led to a prompt release of processed forms of CD, along with other mature lysosomal hydrolases. This release could be prevented by addition of EGTA, indicating that it was dependent on extracellular calcium influx. Antigen stimulation also induced exocytosis of immature CD forms accumulated by ammonium chloride, suggesting the existence of an intermediate station in the pathway for granule biogenesis still sensitive to regulated exocytosis. The targeting of molecules to secretory granules may occur via either a mannose-6-phosphate-dependent or mannose-6-phosphate-independent pathway. We conclude that endosomes and lysosomes in basophils/mast cells can act as regulated secretory granules or actually identify with them.

Transformation by oncogenic ras-p21 alters the processing and subcellular localization of the lysosomal protease cathepsin D.

The expression, processing, and intracellular localization of cathepsin D (CD), an endosomal-lysosomal protease involved in malignancy, were studied in rat embryo fibroblasts transformed with an active mutant of c-Ha-ras oncogene. The pattern of the processed molecular forms of CD, comprising two single-chain mature forms of 45 and 43 kDa and two double-chain mature forms of 34 + 9 kDa and 30 + 14 kDa, expressed by the parental cell line was similar to that found in normal rat liver cells. By contrast, in the ras-transfected counterpart this pattern was profoundly altered in that the 45 kDa species was much less represented and the 30 + 14 kDa species virtually absent. In both untransformed and ras-transformed cells the conversion of proCD into mature forms was not inhibited by ammonium chloride, which is known to increase the intravacuolar pH of post-Golgi compartments. Yet, this drug induced the accumulation of the 43 and 45 kDa molecular forms of mature CD in ras-transformed cells and of the 34 kDa molecule in untransformed cells. As compared to controls, in ras-transformed fibroblasts vacuolar compartments containing CD were reduced in number and mostly located toward the periphery of the cell. This contrasted with the perinuclear distribution of CD-positive granules in untransformed cells. Serum deprivation did not affect the growth, nor the intra- and extracellular accumulation of CD activity in ras-transformed cultures, while it blocked the growth and strongly stimulated the accumulation of CD in the medium in cultures of control fibroblasts. Altogether these data are indicative for a crucial role of ras GTPase in the regulation of the transport between post-Golgi organelles.

Expression and posttranslational fate of cathepsin D in HT-29 tumor cells depend on their enterocytic differentiation state.

In the present work, we analyzed the variations in the expression and trafficking of cathepsin D (CD), a lysosomal endopeptidase, associated with the enterocytic differentiation of the human colon carcinoma HT-29 cell line. In spite of the fact that the abundance of CD mRNA was severalfold higher in undifferentiated HT-29 cells than in their enterocyte-like differentiated counterparts, the intracellular levels of CD activity and protein were found to be much higher in the latter. The kinetic of transport of newly synthesized proCD was different in the two cell populations: (a) full conversion of proCD into the lysosomal mature form required more than 24 h in differentiated cells, whereas it was almost complete within 8 h in undifferentiated HT-29 cells; and (b) the extracellular release of proCD was shown to occur more rapidly and to a higher degree in undifferentiated than in differentiated cells. Most of the secreted proCD contained phosphomannoses. Secretion of beta-hexosaminidase activity doubled, whereas that of CD activity was unchanged, upon vacuolar alkalinization with ammonium chloride or chloroquine. Inhibition of the lysosomal-autophagic degradative pathway resulted in the accumulation of proCD molecules in undifferentiated HT-29 cells. Altogether these data suggest that: (a) the expression and the posttranslational fate of CD in HT-29 colon cancer cells are largely affected by the state of their enterocytic differentiation; and (b) in this cell line the acid-dependent mannose 6-phosphate receptor pathway is, at best, little involved in the trafficking of CD.

Differentiation-induced changes in the content, secretion, and subcellular distribution of lysosomal cathepsins in the human colon cancer HT-29 cell line.

Enterocyte-like differentiated HT-29 colon carcinoma cells were shown to contain far higher intracellular levels of activity of lysosomal cathepsins B, D, and L than their undifferentiated counterparts. In the latter, inhibition of lysosomal functions by leupeptin or ammonium chloride led to a marked increase in the cell-associated activity of the three cathepsins. High levels of pro-cathepsins B, D, and L were found in the culture media of both HT-29 cell populations. Ammonium chloride and chloroquine, which are known to impair the mannose-6-phosphate-dependent trafficking of lysosomal-targeted proteins, did not increase the secretion of the three cathepsins in either undifferentiated or differentiated cultures of HT-29 cells. Analyses by cell fractionation revealed heterogeneities with regard to the density and the content of lysosomal cathepsins between the two cell populations. Leupeptin induced the accumulation of mature lysosomal cathepsins B and L in light density organelles in undifferentiated HT-29 cells. Altogether, these data demonstrate that (1) the expression and subcellular distribution of cathepsins B, D, and L in HT-29 cells are influenced by their state of enterocytic differentiation, (2) the segregation of lysosomal cathepsins is largely inefficient in this tumor cell line and does not increase upon differentiation, and (3) the mannose-6-phosphate-receptor-dependent pathway plays a minor role in the sorting of the three cathepsins, both in undifferentiated and enterocytic-differentiated HT-29 cells.

Differential targeting and processing of procathepsin D in normal and transformed murine 3T3 fibroblasts.

The kinetics of transport and the processing of procathepsin D (proCD), the precursor of a lysosomal aspartyl protease involved in tumor-cell proliferation and metastasis, were compared in normal and SV-40- or benzo[a]pyrene-transformed 3T3 mouse fibroblasts. Sorting of newly synthesized proCD in normal cells was almost complete within 3 hr, while in transformed cells a fraction of the precursor survives a long time. In both normal and transformed 3T3 cultures, secretion of proCD started at 3 hr of chase. However, in normal cells secretion of proCD remained constant between 3 and 24 hr of chase, while in transformed cells it increased along with the chase incubation. The efficiency of formation of the mannose-6-phosphate group on proCD varied among the 3 cell types, being minimal in benzo[a]pyrene-transformed 3T3 cells. Ammonium chloride, a drug known to disrupt the segregation and to enhance the secretion of lysosomal proenzymes, was 2-fold more effective in normal than in transformed 3T3 cells. Despite vacuolar alkalinization, about one third of proCD was segregated into the endosomal-lysosomal pathway in normal and in transformed 3T3 fibroblasts, indicating the existence in these cells of alternative, mannose-6-phosphate receptor-independent mechanisms for targeting proCD. Thus, while hypersecretion of proCD and reduced sensitivity to vacuolar alkalinization are common features of both transformed cell types, the mechanisms responsible for inefficient segregation of proCD may differ between virally and chemically transformed 3T3 cells.

Exposed thiols confer localization in the endoplasmic reticulum by retention rather than retrieval.

The cysteine present in the Ig micro chain tailpiece (microtp) prevents the secretion of unpolymerized IgM intermediates and causes their accumulation in the endoplasmic reticulum (ER). In principle, this can be the consequence of actual retention in this organelle or of retrieval from the Golgi. To determine which of the two mechanisms underlies the cysteine-dependent ER localization, we analyze here the post-translational modifications of suitably engineered cathepsin D (CD) molecules. The glycans of this protease are phosphorylated by post-ER phosphotransferases and further modified in the trans-Golgi to generate a mannose 6-phosphate lysosome targeting signal. Only trace amounts of the mutp-tagged CD (CDM&mutpCys) are phosphorylated, unless retention is reversed by exogenous reducing agents or the critical cysteine mutated (CDMmutpSer). In contrast, a KDEL-tagged CD, that is retrieved from the Golgi into the ER, acquires phosphates, though mainly resistant to alkaline phosphatase. Similarly to CDMmutpSer, the few CDMmutpCys molecules that escape retention and acquire phosphates in the cis-Golgi are transported beyond the KDEL retrieval compartment, as indicated by their sensitivity to alkaline phosphatase. These results demonstrate that the thiol-dependent ER localization arises primarily from true retention, without recycling through the Golgi.

Synthesis, maturation and extracellular release of procathepsin D as influenced by cell proliferation or transformation.

The relationship between cell growth and intra- and extracellular accumulation of cathepsin D (CD), a lysosomal endopeptidase involved in cell protein breakdown, was examined in cultures of normal and transformed BALB/c mouse 3T3 fibroblasts grown at various cell densities. In crowded cultures of normal 3T3 cells (doubling time, Td, 53 hr) intracellular CD activity was 2-fold higher than in sparse, rapidly-growing (Td, 27 hr) cultures. In uncrowded (Td, 18 hr) and crowded (Td, 32 hr) cultures of benzo[a]pyrene-transformed cells intracellular CD levels were one third and two thirds, respectively, of those measured in hyperconfluent 3T3 cultures. Regardless of cell density, SV-40-virus-transformed cells (Td, 12 hr) contained one third of CD levels found in hyperconfluent 3T3 cells. Both transformed cell lines released into the medium a higher proportion of CD, compared with their untransformed counterpart, yet the amount secreted was not sufficient to account for the reduced intracellular level of the enzyme. Serum withdrawal induced a marked increase of both intra- and extracellular levels of CD activity. In both normal and virally or chemically transformed 3T3 cells CD comprised a precursor (52 kDa) and processed mature polypeptides; the latter were mostly represented by a 48-kDa peptide, but a minor part was in a double-chain form (31 and 16 kDa respectively). The proportion of mature enzyme vs. precursor was much higher in confluent, slowly-growing cells than in fast-growing cells, whether normal or transformed. In the latter, conversion of mature 48-kDa peptide into the double-chain form occurred more efficiently.

Altered intracellular processing and enhanced secretion of procathepsin D in a highly deviated rat hepatoma.

Both freshly-isolated rat hepatocytes and Morris hepatoma 7777 cells synthesized cathepsin D as a precursor that was either processed intracellular to smaller mature forms or secreted into the medium. The pattern of mature enzyme forms was different in the 2 cell types. In addition, the relative amount of precursor secreted was much higher for hepatoma cells. Monensin strongly enhanced the secretion and also impaired the intracellular transport-linked maturation of procathepsin D in hepatocytes, while it markedly inhibited intracellular maturation and only slightly increased secretion of the pro-enzyme in hepatoma cells. Ammonium chloride influenced the intralysosomal segregation and maturation of procathepsin D in hepatocytes but not in hepatoma cells. Our observations indicate that (i) the lysosomal segregation of cathepsin D was less efficient and its fractional secretion higher in hepatoma cells than in hepatocytes; (ii) in the 2 cell types, delivery to lysosomes and processing of procathepsin D were differently sensitive to increases in the vacuolar pH.

High levels of proteolytic enzymes in the ascitic fluid and plasma of rats bearing the Yoshida AH-130 hepatoma.

Plasma and ascitic fluid of rats bearing the Yoshida ascites hepatoma AH-130 were shown to contain high levels of proteolytic enzymes belonging to different classes active at neutral and acidic pH. Relative to those measured in control rat plasma, in tumor-bearing animals, the activity levels of lysosomal cathepsins B and L, in their latent, acidic-activatable form, were approximately 5-fold higher in plasma and 9-fold higher in ascitic fluid, and cathepsin D activity was about 5-fold higher in both plasma and ascitic fluid. Plasma and ascitic fluid of tumor-bearing rats also contained novel neutral and acidic gelatinolytic activities. The latter, as revealed by zymographic analysis conducted at pH 6.0, in the presence of dithiothreitol and in the absence of divalent metal ions, was sensitive to iodoacetamide inhibition but not to EDTA, showed a molecular mass of approximately 90 kD on SDS-PAGE, and was lost upon limited proteolysis with pepsin. Therefore, this enzyme is not identifiable as cathepsin B or L or their related latent forms and may represent a novel, so far undescribed, gelatinase. Its presence exclusively in the body fluids of AH-130-bearing rats suggests its possible use as a tumor marker.