Mutant and misfolded human growth hormone is rapidly degraded through the proteasomal degradation pathway in a cellular model for isolated growth hormone deficiency type II.

Autosomal dominant isolated growth hormone deficiency type II (IGHD II) is mainly caused by splice site mutations of the GH-1 gene, leading to deletion of amino acids 32-71 of the human growth hormone (hGH). The severe hGH deficit in IGHD II suggests a dominant negative effect of the partially deleted del(32-71)-hGH on the production, storage or secretion of normal wild-type (wt)-hGH in somatotrophic cells of the pituitary. To shed more light on the cellular and molecular basis of IGHD II, we established and analysed diverse clones of the rat somatotrophic cell line GH(4)C(1) stably expressing either wt-hGH, del(32-71)-hGH, or both proteins concomitantly. The cellular morphology of all transfected GH(4)C(1) cell clones showed moderate differences to untransfected GH(4)C(1) cells. On the molecular level, both cDNA-constructs induced transcription but, under normal culture conditions, only wt-hGH protein was found to be synthesised and secreted in readily detectable amounts. By contrast, only after inhibition of proteasomes did high amounts of del(32-71)-hGH show up. The solubility of del(32-71)-hGH in nondenaturing buffer was poor compared to wt-hGH, hinting at molecular aggregation, and several epitopes recognised by monoclonal hGH antibodies were not present on del(32-71)-hGH, confirming the assumption that del(32-71)-hGH must be severely misfolded. Expression of both proteins in Escherichia coli mirrored the findings from the GH(4)C(1) cell clones in terms of solubility and immunological reactivity. The results of the present study indicate that, in IGHD II, somatotrophs continuously have to remove misfolded del(32-71)-hGH via the proteasomal degradation pathway, suggesting a mechanism that may result in chronic cellular stress.

Activation of c-myc promoter P1 by immunoglobulin kappa gene enhancers in Burkitt lymphoma: functional characterization of the intron enhancer motifs kappaB, E box 1 and E box 2, and of the 3' enhancer motif PU.

Deregulated expression of the proto-oncogene c- myc in Burkitt lymphoma (BL) cells carrying a t(2;8) translocation is mediated by a synergistic interaction of the translocated immunoglobulin (Ig) kappa gene intron (kappaEi) and 3' (kappaE3') enhancers and characterized by a strong activation of the promoter P1. We have investigated the functional role of distinct kappa enhancer sequence motifs in P1 activation on both mini-chromosomes and reporter gene constructs. Stable and transient transfections of BL cells revealed critical roles of the kappaEi and kappaE3' elements kappaB and PU, respectively. Joint mutation of kappaB and PU completely abolished P1 activity, implying that an interaction of kappaB- and PU-binding factors is essential for the enhancer synergism. Mutation of the E box 1 and E box 2 motifs markedly decreased P1 activity in transient but not in stable transfection experiments. Co-expression of the NF-kappaB subunit p65(RelA) and Sp1, an essential factor for P1 transcription, in Drosophila melanogaster SL2 cells synergistically enhanced promoter activity. Our results support a model which proposes cross-talk between promoter and enhancer binding factors as the basic mechanism for kappa enhancer-mediated c- myc activation in BL cells.

Targeting of heterologous membrane proteins into proliferated internal membranes in Saccharomyces cerevisiae.

Overproduction of chimeric proteins containing the HMG2/1 peptide, which comprises the seven transmembrane domains of Saccharomyces cerevisiae 3-hydroxy-3-methylglutaryl-CoA reductase isozymes 1 and 2, has previously been observed to induce the proliferation of internal endoplasmic reticulum-like membranes. In order to exploit this amplified membrane surface area for the accommodation of heterologous microsomal proteins, we fused sequences coding for human cytochrome P4501A1 (CYP1A1) to sequences encoding the HMG2/1 peptide and expressed the hybrid genes in yeast. The heterologous hybrid proteins were targeted into strongly proliferated membranes, as shown by electron microscopic and immunofluorescent analysis. Fusion proteins comprising the whole CYP1A1 polypeptide (HMG2/1-CYP1A1) exhibited 7-ethoxyresorufin-O-deethylase activity, whereas fusion proteins lacking the N-terminal 56 amino acids of CYP1A1 (HMG2/1-delta CYP1A1) were inactive and appeared to be unable to incorporate protoheme. Similar amounts of heterologous protein were detected in cells expressing HMG2/1-CYP1A1, HMG2/1-delta CYP1A1 and CYP1A1, respectively. Replacement of the N-terminal membrane anchor domain of human NADPH-cytochrome P450 oxidoreductase by the HMG2/1 peptide also resulted in a functional fusion enzyme, which was able to interact with HMG2/1-CYP1A1 and the yeast endogenous P450 enzyme lanosterol-14 alpha-demethylase.