A single expression site with a conserved leader sequence regulates variation of expression of the Pneumocystis carinii family of major surface glycoprotein genes.

The major surface glycoprotein (MSG) of Pneumocystis carinii is encoded by a family of related but distinct genes distributed throughout the P. carinii genome. Previous reports of the genomic and mRNA MSG structure suggested that there was a highly conserved 5'-untranslated region and a highly variable translated region. In the current study, we demonstrate that there is a single expression site for MSG expression and that different MSG genes are located downstream of this expression site. Isolation of a genomic clone containing the putative 5'-untranslated region has demonstrated that there was a single base sequencing error in what was considered to be the untranslated region. The corrected sequence reveals an extended open reading frame encoding a constant amino-terminal leader domain, with a typical signal peptide, for the MSG protein family. Since this constant amino-terminal domain is encoded by a single copy genomic sequence, a recombination/gene conversion-mediated antigenic switching event is required to effect the known variability in expressed MSG sequences. Therefore, like some bacterial and protozoan pathogens, the opportunistic fungal pathogen P. carinii contains a constant genomic site dedicated to MSG expression and a switchable downstream region for the variable part of the MSG gene family.

Human growth hormone induces and maintains c-myc gene expression in Nb2 lymphoma cells.

The effect of human GH (hGH) on c-myc gene expression and cell proliferation in the Nb2 lymphoma cell line was examined. The addition of hormone to stationary cultures of Nb2 cells resulted in an increased accumulation of c-myc transcripts that was detectable within 15 min, reached a maximum induction of 25-fold in 3 h, and then gradually declined. Although maximal accumulation of c-myc transcripts occurred within 3 h after hGH addition, removal of the hormone even after 4 h of treatment resulted in a failure of the cells to proliferate. This loss of proliferative capacity following hormone removal was accompanied by a 20-fold reduction in the level of c-myc transcripts. These results indicate that hGH induced proliferation of Nb2 cells is associated with the induction and maintenance of c-myc gene expression.

Biosynthesis of glucagon (IRG3500) in canine gastric mucosa.

The canine gastric mucosa has previously been shown to contain considerable amounts of a polypeptide with the immunologic and physicochemical characteristics and biologic activity of glucagon (IRG3500). Using mucosal pieces that remained viable for at least 8 h, we have demonstrated that IRG3500 is synthesized in this extrapancreatic tissue. Gel filtration and electrophoresis of extracts of mucosal pieces incubated with 3H-tryptophan, 3H-leucine, or 35S-methionine revealed small amounts of labeled, newly synthesized gastric IRG3500. No labeling of gastric IRG3500 was observed when the mucosa was incubated with 3H-proline, an amino acid not found in glucagon, in the presence of cycloheximide, or in isolated rat hepatocytes. Small amounts of newly synthesized IRG3500 were specifically immunoprecipitated by C-terminally directed glucagon antiserum gamma globulins. The rate of gastric IRG3500 biosynthesis in vitro was apparently unchanged in mucosal pieces from pancreatectomized dogs and unaffected by increased glucose or glucose lack during incubations. Thus we have provided evidence that a hormone of the endocrine pancreas can be synthesized in extrapancreatic tissues.

Chromatographic pattern of extrapancreatic glucagon and glucagon-like immunoreactivity before and during stimulation by epinephrine and participation of glucagon in epinephrine-induced hepatic glucose overproduction.

To characterize the glucagon released in response to epineephrine in depancreatized dogs, plasma samples before and during epinephrine infusion were subjected to molecular-sieve chromatography on Bio-Gel P-30 columns. The chromatographic profile for extrapancreatic immunoreactive glucagon (eIRG) revealed two glucagon moieties of molecular weight 9,000 to 12,000. GLI of this molecular weight was released in response to epinephrine only under conditions of prevailing hyperglycemia. To determine if glucagon's participation in epinephrine-induced hepatic glucose overproduction in diabetes was dependent upon the degree of metabolic control, six conscious depancreatized dogs were infused with epinephrine or epinphrine plus somatostatin, under conditions of prevailing hyperglycemia or normoglycemia. Under normoglycemic conditions, epinephrine stimulated eIRG release, but there was a similar rise in hepatic glucose production (Ra) with or without glucagon suppression by somatostatin. Under hyperglycemic conditions, epinephrine stimulated eIRG and GLI release, and the rise in Ra was significantly greater with epinephrine than with epinephrine plus somatostatin infusion. Thus, under conditions of good metabolic control, epinephrine increased hepatic glucose production independently of glucagon, whereas with poor metabolic control, glucagon contributed to hepatic overproduction of glucose.