Expression of mouse cathepsin L cDNA in Saccharomyces cerevisiae: evidence that cathepsin L is sorted for targeting to yeast vacuole.

To investigate the intracellular transport mechanism of lysosomal cathepsin L in yeast cells, we attempted to produce mouse cathepsin L in Saccharomyces cerevisiae by placing the coding region under the control of the promoter of the yeast glyceraldehyde 3-phosphate dehydrogenase (GAPDH) gene. Immunoblotting analysis by the use of an antibody specific for rat cathepsin L revealed that the yeast cells carrying the cathepsin L coding sequence produced 39- and 30-kDa products, which correspond to the rat procathepsin L and the single-chain form of mature cathepsin L, respectively. The precursor polypeptide showed sensitivity toward endoglycosidase H treatment. Cell fractionation experiments demonstrated that the processed form of 30-kDa cathepsin L was found to be colocalized to the yeast vacuole with the marker enzyme carboxypeptidase Y in a Ficoll step gradient. In the prepared vacuolar fraction, a considerable amount of cathepsin L was revealed to be cofractionated with the vacuolar membranes. Furthermore, the phase separation experiments with Triton X-114 provide the first evidence showing that the mature form of cathepsin L polypeptide is strongly associated with the vacuolar membranes. Therefore, the present results suggest that the mouse cathepsin L precursor polypeptide is initially synthesized as the proenzyme in the yeast cells and then correctly delivered to the vacuole. During the intracellular sorting pathway, the procathepsin L would undergo the post-translational proteolytic processing step to generate the mature enzyme. Based on these lines of evidence, we propose that cathepsin L is recognized by mechanisms similar to those for the intracellular sorting and processing of vacuolar proteins in the yeast cells.     

Characterization of the insulin resistance in liver cirrhosis: a comparison with non-insulin dependent diabetes mellitus.

To characterize the mechanisms of insulin resistance in liver cirrhosis (LC), we estimated the peripheral tissue sensitivity and responsiveness to insulin using the euglycemic clamp technique and determined the insulin binding to erythrocytes in patients with compensated LC as well as in patients with non-insulin dependent diabetes mellitus (NIDDM). The insulin dose-response curves of the glucose metabolic clearance rates (MCR) were shifted to the right and downward both in patients with LC and NIDDM, indicating a reduced sensitivity and responsiveness to insulin. In the cirrhotics, MCR at the maximally effective insulin level, an index of insulin responsiveness, was correlated with fasting insulin levels (r = -0.57, P < 0.01) and sigma BG in 75 gOGTT (r = -0.43, P < 0.05), but no correlations were found between them and the diabetics. Although specific insulin bindings to erythrocytes were significantly lower in patients both with LC and NIDDM, Scatchard analysis revealed a significant decrease in the number of insulin receptors in the cirrhotics, and a decrease in the empty-site affinity in the diabetics. These findings suggest that insulin resistance in LC consists of a combination of binding and postbinding defects. The latter defect may be caused by basal hyperinsulinemia and contribute to the development of glucose intolerance. Although binding and postbinding abnormalities are also found in NIDDM, the mechanisms of insulin resistance in LC and NIDDM may be different.     

Specific phosphorylation of the acidic central region of the N-myc protein by casein kinase II.

The central region of the N-myc protein has a characteristic amino acid sequence EDTLSDSDDEDD, which is very similar to those of particular domains of adenovirus E1A, human papilloma virus E7, Simian virus 40 large T, c-myc and L-myc proteins. Domains of these three viral oncoproteins have recently been shown to be specific binding sites for the tumor-suppressor gene retinoblastoma protein. We have noted that the sequence of serine followed by a cluster of acidic amino acids is exactly the same as that of a typical substrate of casein kinase II (CKII). Therefore, we investigated whether these nuclear oncoproteins are phosphorylated by CKII. For this purpose, we fused the beta-galactosidase and N-myc genes including this domain and expressed it in Escherichia coli cells. Several mutant N-myc genes, containing single amino acid substitutions in this domain, were also used to produce fused proteins. Strong phosphorylation by CKII was detected with the fused protein of wild-type N-myc. However, no phosphorylation of beta-galactosidase itself was observed and the phosphorylations of fused mutant proteins were low. Another fused N-myc protein containing most of the C-terminal region downstream of this acidic region was not phosphorylated by CKII. Analysis of phosphorylation sites in synthetic peptides of this acidic region identified the major sites phosphorylated by CKII as Ser261 and Ser263. On two-dimensional tryptic mapping of phosphorylated N-myc proteins, major spots of in vitro-labeled and in-vivo-labeled N-myc proteins were detected in the same positions. These results suggest that two serine residues of the acidic central region of the N-myc protein are phosphorylated by CKII in vivo as well as in vitro. The functional significance of this acidic domain is discussed.     

HLA-DQ-restricted CD4+ T cells specific to streptococcal antigen present in low but not in high responders.

We have found that the low immune response to streptococcal cell wall Ag (SCW) was inherited as a dominant trait and was linked to HLA, as deduced from family analysis. In the present report, HLA class II alleles of healthy donors were determined by serology and DNA typing to identify the HLA alleles controlling low or high immune responses to SCW. HLA-DR2-DQA1*0102-DQB1*0602(DQw6)-Dw2 haplotype or HLA-DR2-DQA1*0103-DQB1*0601(DQw6)-DW12 haplotype was increased in frequency in the low responders and the frequency of HLA-DR4-DRw53-DQA1*0301-DQB1*0401(DQw4)-Dw15 haplotype or HLA-DR9-DRw53-DQA1*0301-DQB1*0303(DQw3)-Dw23 haplotype was increased in the high responders to SCW. Homozygotes of either DQA1*0102 or DQA1*0103 exhibited a low responsiveness to SCW and those of DQA1*0301 were high responders. The heterozygotes of DQA1*0102 or 0103 and DQA1*0301 showed a low response to SCW, thereby confirming that the HLA-linked gene controls the low response to SCW, as a dominant trait. Using mouse L cell transfectants expressing a single class II molecule as the APC, we found that DQw6(DQA1*0103 DQB1*0601) from the low responder haplotype (DR2-DQA1*0103-DQB1*0601(DQw6)-Dw12) activated SCW-specific T cell lines whereas DQw4(DQA1*0301 DQB1*0401) from the high responder haplotype (DR4-DRw53-DQA1*0301-DQB1*0401(DQw4)-Dw15) did not activate T cell lines specific to SCW. However, DR4 and DR2 presented SCW to CD4+ T cells in both the high and low responders to SCW, hence the DR molecule even from the low responder haplotype functions as an restriction molecule in the low responders. Putative mechanisms linked to the association between the existence of DQ-restricted CD4+ T cells specific to SCW, and low responsiveness to SCW are discussed.     

The Q7 alpha 3 domain alters T cell recognition of class I antigens.

In this study we have analyzed the role of the alpha 3 domain of class I molecules in T cell recognition. Using the laboratory engineered molecules LLQQ (alpha 1/alpha 2 from Ld, alpha 3, and phosphatidyl inositol (PI) linked C terminus from Q7) and LLQL (alpha 1/alpha 2 from Ld, alpha 3 from Q7, transmembrane (TM) and cytoplasmic domains from Ld) we show that these molecules are not recognized by primary Ld-specific CTL. The cell membrane expression of both Ld and LLQL are upregulated by co-culture with an exogenously supplied murine cytomegalovirus-derived peptide indicating that the Q7 alpha 3 domain does not interfere with binding of Ag to alpha 1/alpha 2. However, only peptide pulsed Ld but not LLQL target cells are recognized by Ld-restricted-peptide specific CTL. In contrast to the above results, LLQL and LLQQ molecules can be recognized by bulk alloreactive anti-Ld CTL and 2/3 of CTL clones derived from in vivo primed mice. The fact that these secondary CTL recognize LLQQ indicates that a PI linkage is permissive for presentation of class I epitopes to alloreactive CTL. These secondary CTL are resistant to blocking at the effector stage by mAb against CD8 and express relatively low levels of membrane CD8 molecules compared to CTL from unprimed mice. Further, culture of unprimed CTL precursors in the presence of CD8 mAb also allows for the generation of CD8-independent CTL that recognize LLQL. Taken together, these data indicate that the alpha 3 domain of Q7 (Qa-2) prevents CD8-dependent CTL from recognizing Ld, regardless of whether the class I molecule is attached to the cell surface by a PI moiety or as a membrane spanning protein domain. We hypothesize that this defect in recognition is most likely due to an inability of CD8 to interact efficiently with the Q7 alpha 3 domain and could account for why Q7 molecules do not serve as restricting elements for virus and minor H-Ag-specific CTL.