Overexpression of the Saccharomyces cerevisiae mannosylphosphodolichol synthase-encoding gene in Trichoderma reesei results in an increased level of protein secretion and abnormal cell ultrastructure.

Production of extracellular proteins plays an important role in the physiology of Trichoderma reesei and has potential industrial application. To improve the efficiency of protein secretion, we overexpressed in T. reesei the DPM1 gene of Saccharomyces cerevisiae, encoding mannosylphosphodolichol (MPD) synthase, under homologous, constitutively acting expression signals. Four stable transformants, each with different copy numbers of tandemly integrated DPM1, exhibited roughly double the activity of MPD synthase in the respective endoplasmic reticulum membrane fraction. On a dry-weight basis, they secreted up to sevenfold-higher concentrations of extracellular proteins during growth on lactose, a carbon source promoting formation of cellulases. Northern blot analysis showed that the relative level of the transcript of cbh1, which encodes the major cellulase (cellobiohydrolase I [CBH I]), did not increase in the transformants. On the other hand, the amount of secreted CBH I and, in all but one of the transformants, intracellular CBH I was elevated. Our results suggest that posttranscriptional processes are responsible for the increase in CBH I production. The carbohydrate contents of the extracellular proteins were comparable in the wild type and in the transformants, and no hyperglycosylation was detected. Electron microscopy of the DPM1-amplified strains revealed amorphous structure of the cell wall and over three times as many mitochondria as in the control. Our data indicate that molecular manipulation of glycan biosynthesis in Trichoderma can result in improved protein secretion.

Phosphorylated carboxy terminal serine residues stabilize the mouse gap junction protein connexin45 against degradation.

Phosphoamino acid analysis of mouse connexin45 (Cx45) expressed in human HeLa cells revealed that phosphorylation occurred mainly at serine residues, but also on tyrosine and threonine residues. To characterize the role of Cx45 phosphorylation, different serine residues of the serine-rich carboxy terminal region were deleted or exchanged for other amino acids residues. Human HeLa cells deficient in gap junctional intercellular communication were stably transfected with appropriate constructs and analyzed for expression, localization, phosphorylation, formation of functional gap junction channels and degradation of mutant Cx45. fter exchange or deletion of nine carboxy terminal serine residues, phosphorylation was decreased by 90%, indicating that these serine residues represented main phosphorylation sites of mouse Cx45. The various serine residues of this region contributed differently to the phosphorylation of Cx45 suggesting a cooperative mechanism for phosphorylation. Substitution of different serine residues for other amino acids did not interfere with correct intracellular trafficking and assembly of functional gap junction channels, as shown by localization of mutant Cx45 at the plasma membrane and by dye transfer to neighboring cells. Truncated Cx45 was also weakly phosphorylated but was trapped in perinuclear locations. Dye transfer of these transfectants was similar as in nontransfected HeLa cells. The half-life of mouse Cx45 protein in HeLa cells was determined as 4.2 hr. Pulse-chase experiments with the different transfectants revealed an increased turnover of Cx45, when one or both of the serine residues at positions 381 and 382 or 384 and 385 were exchanged for other amino acids. The half-life of these mutants was diminished by 50% compared to wild type Cx45.

Expression of connexin31 and connexin43 genes in early rat embryos.

Gap junctions have been reported to play a pivotal role in coordinating embryonic development. Here we report the temporal and spatial pattern of connexin31 that has been found to be coexpressed with connexin43 in preimplantation rat embryos. Connexin31 and connexin43 transcripts are abundant in the zygote and degraded in the two- and four-cell stage to low levels for connexin31 and to undetectable ones for connexin43. The uncompacted eight-cell stage lacks the transcripts of both connexins. Reexpression of connexin43 and connexin31 mRNA is found from the compacted eight-cell stage onward. The connexin31 antigen, however, is already detected intracellularly at the uncompacted eight-cell stage. At the blastocyst stage, both connexins are coexpressed in the trophectoderm as well as in the inner cell mass. After implantation, compartmentalization of both connexins is observed. Connexin31 is now expressed exclusively by the cells of the ectoplacental cone and extraembryonic ectoderm, whereas connexin43 is restricted to the cells of the embryo proper. This compartmentalization in connexin expression between the derivatives of the inner cell mass and the trophectoderm may maintain the different developmental programs. THus, connexin31 seems not to be related to the first step in trophoblast lineage development and could serve as a compensatory channel during preimplantation development.

Connexins and E-cadherin are differentially expressed during trophoblast invasion and placenta differentiation in the rat.

We have characterized the spatial and temporal expression pattern of six different connexin genes and E-cadherin during trophectoderm development in the rat. During the initial phase of trophoblast invasion at 6 days postcoitum (dpc), the trophoblast expressed E-cadherin but no connexin expression could be observed. With progressing invasion of the polar trophoblast into the maternal decidua, from 7 dpc onwards E-cadherin expression in the ectoplacental cone cells was lost and was now restricted to the extraembryonic ectoderm. In the ectoplacental cone and extraembryonic ectoderm instead connexin31 mRNA and protein could be found. This pattern was maintained up to day 10 postcoitum. The start of labyrinthine trophoblast differentiation from day 11 postcoitum onwards was characterized by persisting expression of E-cadherin in the extraembryonic ectoderm and its derivative, the chorionic plate. In addition to E-cadherin, from 10 dpc onwards, connexin26 started to be expressed in the chorionic plate, and both molecules remained coexpressed in the labyrinthine trophoblast of the mature placenta. During this differentiation process connexin31 remained expressed mainly in the proliferating spongiotrophoblast. From day 14 postcoitum onwards, the expression of connexin31 in the spongiotrophoblastic cells decreased, and in parallel they started to express connexin43. The trophoblastic giant cells, first characterized by connexin31, lost all of the investigated connexins during midgestation on day 12 postcoitum but started to express connexin43 from day 18 postcoitum onwards. Our studies suggest that loss of E-cadherin and induction of connexin31 expression is correlated with the proliferative and invasive stages of the ectoplacental cone, whereas appearance of connexin26, E-cadherin and connexin43 reflects the switch to the differentiated phenotypes of the mature placenta.

Expression of the gap junction proteins connexin31 and connexin43 correlates with communication compartments in extraembryonic tissues and in the gastrulating mouse embryo, respectively.

We have characterized the pattern of connexin expression in embryonic and extraembryonic tissues during early mouse development. In the preimplantation blastocyst, at 3.5 days post coitum (dpc), immunofluorescent signals specific for connexin31 and connexin43 proteins were present in both the inner cell mass and the trophectoderm, as shown by confocal laser scan microscopy. Immediately after implantation at 6.5 dpc, however, we find complete compartmentation of these two connexins: connexin31 mRNA and protein are expressed exclusively in cells derived from the trophectoderm lineage, whereas connexin43 mRNA and protein are detected in cells derived from the inner cell mass. This expression pattern of connexin31 and connexin43 is maintained at 7.5 dpc when the axial polarity of the mouse embryo is established. It correlates with the communication compartments in extraembryonic tissues and the gastrulating mouse embryo, respectively. The communication boundary between those compartments may be due to incompatibility of connexin31 and connexin43 hemichannels, which do not communicate with each other in cell culture.

Specific permeability and selective formation of gap junction channels in connexin-transfected HeLa cells.

DNAs coding for seven murine connexins (Cx) (Cx26, Cx31, Cx32, Cx37, Cx40, Cx43, and Cx45) are functionally expressed in human HeLa cells that were deficient in gap junctional communication. We compare the permeabilities of gap junctions comprised of different connexins to iontophoretically injected tracer molecules. Our results show that Lucifer yellow can pass through all connexin channels analyzed. On the other hand, propidium iodide and ethidium bromide penetrate very poorly or not at all through Cx31 and Cx32 channels, respectively, but pass through channels of other connexins. 4,6 Diamidino-2-phenylindole (DAPI) dihydrochloride shows less transfer among Cx31 or Cx43 transfectants. Neurobiotin is weakly transferred among Cx31 transfectants. Total junctional conductance in Cx31 or Cx45 transfected cells is only about half as high as in other connexin transfectants analyzed and does not correlate exactly with any of the tracer permeabilities. Permeability through different connexin channels appears to be dependent on the molecular structure of each tracer, i.e. size, charge and possibly rigidity. This supports the hypothesis that different connexin channels show different permeabilities to second messenger molecules as well as metabolites and may fulfill in this way their specific role in growth control and differentiation of cell types. In addition, we have investigated the function of heterotypic gap junctions after co-cultivation of two different connexin transfectants, one of which had been prelabeled with fluorescent dextran beads. Analysis of Lucifer yellow transfer reveals that HeLa cells expressing Cx31 (beta-type connexin) do not communicate with any other connexin transfectant tested but only with themselves. Two other beta-type connexin transfectants, HeLa-Cx26 and -Cx32, do not transmit Lucifer yellow to any of the alpha-type connexins analyzed. Among alpha-type connexins, Cx40 does not communicate with Cx43. Thus, connexins differ in their ability to form functional heterotypic gap junctions among mammalian cells.

Differential expression of the gap junction proteins connexin45, -43, -40, -31, and -26 in mouse skin.

The expression of five different members of the gap junction multigene family, connexin (Cx)45, -43, -40, -31, and -26 was investigated in embryonic and adult mouse skin. For this purpose, polyclonal antibodies to Cx31 and Cx45 were raised by immunizing rabbits with fusion proteins of glutathione S-transferase and carboxy-terminal peptides including 65 amino acids of Cx31 or 138 c-terminal amino acids of Cx45, respectively. Here we describe characterization of the affinity-purified Cx31 antibodies in human HeLa cells, transfected with mouse Cx31 coding DNA, and in mouse keratinocyte-derived cell lines. In the epidermis of embryonic mice at day 19 of gestation Cx43 and -45 were detected in the basal layer, while the stratum spinosum showed expression of Cx43, -31 and -26. In the stratum granulosum we found expression of Cx31 and -26. In the epidermis of adult mice Cx43 and -31 were located similarly as in embryonic tissue, but Cx45 as well as Cx26 were not detected and in addition Cx40 was weakly expressed in the stratum basale. Furthermore, during hair development, Cx31 was detected in the inner epithelial root sheath and sebaceous glands of hair follicle. Cx43 and -40 were found in the outer epithelial root sheath and to a lesser extent in sebaceous glands. Cx31 was also demonstrated in Hel-37 and Hel-30, i.e. two related cell lines derived from mouse keratinocytes. Our results show that epidermal and follicular differentiation coincides with differential expression of five different connexin proteins, suggesting specific and coordinated function(s) of gap junctional communication during skin and hair development.

Immunochemical characterization of the gap junction protein connexin45 in mouse kidney and transfected human HeLa cells.

Antibodies to the gap junction protein connexin45 (Cx45) were obtained by immunizing rabbits with fusion protein consisting of glutathione S-transferase and 138 carboxy-terminal amino acids of mouse Cx45. As shown by immunoblotting and immunofluorescence, the affinity-purified antibodies recognized Cx45 protein in transfected human HeLa cells as well as in the kidney-derived human and hamster cell lines 293 and BHK21, respectively. In Cx45-transfected HeLa cells, this protein is phosphorylated as demonstrated by immunoprecipitation after metabolic labeling. The phosphate label could be removed by treatment with alkaline phosphatase. A weak phosphorylation of Cx45 protein was also detected in the cell lines 293 and BHK21. Treatment with dibutyryl cyclic adenosine- or guanosine monophosphate (cAMP, cGMP) did not alter the level of Cx45 phosphorylation, in either Cx45 transfectants or in 293 or BHK21 cells. The addition of the tumor-promoting agent phorbol 12-myristate 13-acetate (TPA) led to an increased 32P phosphate incorporation into the Cx45 protein in transfected cells. The Cx45 protein was found in homogenates of embryonic brain, kidney, and skin, as well as of adult lung. In kidney of four-day-old mice, Cx45 was detected in glomeruli and distal tubules, whereas connexin32 and -26 were coexpressed in proximal tubules. No connexin43 protein was detected in proximal tubules. No connexin43 protein was detected in renal tubules and glomeruli at this stage of development. Our results suggest that cells in proximal and distal tubules are interconnected by gap junction channels made of different connexin proteins. The Cx45 antibodies characterized in this paper should be useful for investigations of Cx45 in renal gap junctional communication.

Structural requirements of the cytoplasmic domains of the human macrophage Fc gamma receptor IIa and B cell Fc gamma receptor IIb2 for the endocytosis of immune complexes.

Two isotypes of the monocyte/macrophage as well as B cell Fc gamma receptor type II (FcRIIa and FcRIIb2, respectively) mainly differ in the length (76 vs. 44 amino acids) and amino acid sequence of their cytoplasmic domains. Only the eight amino acids just behind the putative transmembrane region are identical. Despite this marked difference, both FcRII mediate endocytosis of immune complexes. To determine the functional significance of the cytoplasmic domains, we expressed truncated FcRIIa and FcRIIb2 in FcR- BHK-21 cells. Mutants of both receptors containing only one amino acid (tail-minus) of the cytoplasmic domain failed to mediate immune complex uptake. The significance of the cytoplasmic domain of the receptors could be further demonstrated using a chimeric FcRIII-FcRIIa construct. Therefore we expressed an FcRIII lacking the hydrophobic carboxyl terminus (containing the putative phosphatidyl - inositol - glycan anchor site) fused inframe to the transmembrane and cytoplasmic domain of the FcRIIa in BHK-21 cells. In contrast to the wild type FcRIII, this chimeric receptor mediated immune complex uptake indistinguishable from that mediated by the FcRIIa. Receptor mutants with relatively short cytoplasmic domains (FcRIIb2: 13, and FcRIIa: 16 amino acids) revealed, that these short amino acid stretches are sufficient to allow reduced receptor-mediated endocytosis of bound ligand. Furthermore, using FcRIIa deletion mutants with a cytoplasmic domain consisting of 62, 46, and 28 amino acids, respectively, we found that the capability of these mutants to mediate immune complex uptake decreased gradually with the truncation of the cytoplasmic tails. Thus, only short amino acid sequences of the cytoplasmic domain are sufficient to enable an, albeit reduced, receptor-mediated endocytosis.