Kwang Ho Pyun

MOLECULAR CLONING AND CHROMOSOMAL LOCALIZATION OF A HUMAN GENE HOMOLOGOUS TO THE MURINE R-PTP-KAPPA , A RECEPTOR-TYPE PROTEIN TYROSINE PHOSPHATASE

Tyrosine phosphorylation of proteins plays an important role in cellular signaling and many cellular activities. The levels of cellular phosphorylation are reversibly controlled by protein tyrosine kinases and protein tyrosine phosphatases. The murine R-PTP-kappa, a receptor-type protein tyrosine phosphatase, has recently been cloned (Jiang et al. (1993) Mol. Cell. Biol. 13, 2942-2951). In order to identify the protein tyrosine phosphatases critical to the cellular signal transduction in human keratinocytes, a polymerase chain reaction (PCR)-based strategy was employed, and we have cloned a human homologue of the murine R-PTP-kappa. Here, we report the isolation of a complementary DNA encoding a human R-PTP-kappa. Of the several overlapping cDNA clones, one clone, which we originally termed p55-7, was found to encode a transmembrane protein of 1440 amino acids and was highly conserved with murine R-PTP-kappa with 98% identity at the amino-acid levels. The human R-PTP-kappa gene was localized to chromosome 6 by southern hybridization of DNA from a rodent/human somatic cell mapping panel. Northern blot analysis of RNA from several human tissues revealed, like the murine R-PTP-kappa, the presence of a major mRNA of approx. 7.0 kb and a minor mRNA of approx. 5.3 kb. In contrast to the expression of murine R-PTP-kappa which was highly expressed in liver and kidney, the human R-PTP-kappa was predominantly expressed in spleen, prostate, and ovary. However, the transcripts were detectable at various levels in all examined tissues (thymus, testis, small intestine, and colon) except for PBL (peripheral blood leukocytes). In addition, human R-PTP-kappa displayed a restricted pattern of expression among a series of cell lines, and was apparently expressed in an epidermal cells and cell lines (human normal keratinocytes, HaCaT, and A431), but was not detectable in other cell lines tested after longer exposure.

IL-6 undergoes transition from in vitro autocrine growth factor to in vivo growth inhibitor of B lymphoma cells

IL-6 is a multifunctional cytokine involved in differentiation and proliferation of immune cells. Moreover, it has diverse effects on the proliferation of tumor cells in vivo and in vitro. Although stimulating cell growth of multiple myeloma cells, it inhibits the proliferation of B16 melanoma cells and lung cancer cells. B9.55 cells, B-cell lymphoma, are IL-6-dependent cells, definitely requiring exogenous IL-6 for growth. When the cDNA for IL-6 was transfected into B9.55 cells, they began growing in an autocrine pattern without exogenous IL-6. To investigate the effects of IL-6 on B9.55 lymphoma in vivo, IL-6-transfected B9.55 cells (B9.G7) or neotransfected B9.55 cells (B9.vec) were injected subcutaneously into syngeneic mice. Initially, B9.G7 outgrew B9.vec, but after 3 weeks, B9.G7 grew slower than B9.vec. In addition, 5 micro g of recombinant human IL-6 was injected daily into the tumor site. Reduced tumor sizes of IL-6-treated rats, similar to those observed in mice which received B9.G7, indicated that IL-6 itself is the mediator of tumor regression. When B9.G7 cells were injected into the irradiated normal mice, tumor regression was released compared with the untreated normal control, suggesting that radiosensitive host components were involved in the regression of B9.G7 cell growth. However, the tumor regression of B9.G7 cells was not released in SCID mice. Histologically, B9.G7 tumor demonstrated severe necrosis and apoptotic cells with infiltration of host inflammatory cells. Above data indicate that IL-6 functions as an autocrine growth factor for B9.G7 cells in vitro, but behaves as an autocrine inhibiting factor in vivo. These contrasting effects of IL-6 on tumor cells in vitro and in vivo will be facilitative in understanding the interaction of cytokines and host immune systems.

Expression of recombinant human interleukin 6 ( rhIL6) in Saccharomyces cerevisiae by the modified phosphoglycerate kinase and chelatin promoter

Using the modified yeast expression vectors that contained phosphoglycerate kinase or chelatin promoter with the adenine (A) base at –3 position from the ATG coding sequences and the leu-2 gene, recombinant human inter-leukin-6 ( rhIL-6) was produced as a b-galactosidase ( lacZ) fusion protein in Saccharomyces cerevisiae. Expression level of the IL-6-lacZ was 12 times higher than that from the unmodified wild type plasmids and IL-6 activity was 9–9.8 x 10 5 unit/mg yeast total protein. Thus these modified yeast vectors are useful for high expression of foreign genes in yeast