Biochemical characteristics of new thermosensitive secretory mutants of yeasts

New thermosensitive mutants of the yeast Saccharomyces cerevisiae which block the secretion of periplasmic enzymes at restriction temperature have been obtained. These mutants accumulate active low molecular weight and mature invertase species in the cell; the buoyant density of the cells in a Percoll gradient is higher than that in the wild strain cells. The mutant cells transferred to permissive temperature (25 degrees C) in the absence of protein synthesis can secrete some amount of accumulated invertase. It was found that the secretory defects of conditional mutants do not affect the activity of cytoplasmic enzymes (e.g., alcohol dehydrogenase) or the level of total protein synthesis and glycosylation and do not induce non-specific disturbances in energy metabolism and plasma membrane functions at restriction temperature. Some strains of new secretory mutants revealed uncoupled defective secretion of periplasmic enzymes and intrinsic membrane proteins (proline permease). The possibility of branching of the secretory pathway for periplasmic enzymes and cytoplasmic membrane proteins is discussed.     

Secretion and localization of invertase and inulinase in recombinant Saccharomyces cerevisiae

Summary Secretion of invertase and inulinase produced by recombinant Saccharomyces cerevisiae cells were investigated under derepression conditions of GALI promoter. Secreted invertase mainly localized in the periplasmic space, but most of inulinase was found in the extracellular culture medium. This high level of extracellular secretion of inulinase was not dependent on the growth phase in which derepression of GALI promoter occurs. Our results indicate that the inulinase polypeptide itself may have a function for the protein secretion into the culture medium.     

Phenotypic analysis of temperature-sensitive yeast actin mutants

The consequences of two different mutations in the single essential actin structural gene of yeast (Saccharomyces cerevisiae) were studied. Both conditional-lethal actin mutants exhibit six phenotypes at the restrictive temperature: disruption of the asymmetric staining pattern of actin assembly; delocalized deposition of chitin on the cell surface; partial inhibition of secretion of the periplasmic protein, invertase; an intracellular accumulation of secretory vesicles; death of cells in the budded portion of the cell cycle upon prolonged incubation at the restrictive condition; and osmotic sensitivity. These results implicate actin in the organization and polarized growth of the yeast cell surface.     

Incadronate disodium inhibits advanced glycation end products-induced angiogenesis in vitro

We report here a genetic assay suitable for detecting site-specific proteolysis in secretory pathways. The yeast enzyme invertase is linked to the truncated lumenal region of the yeast Golgi membrane protein STE13 via a protease substrate domain in a Saccharomyces cerevisiae strain lacking invertase. When the substrate is cleaved by a specific protease, the invertase moiety is released into the periplasmic space where it degrades sucrose to glucose and fructose. Therefore, site-specific proteolysis can be detected by monitoring the growth of yeast cells on selective media containing sucrose as the sole carbon source. We confirmed the validity of this assay with yeast Kex2 and human TMPRSS2 proteases. Our data suggest that this in vivo assay is an efficient method for the determination of substrate specificity and mutational analysis of secreted or membrane proteases.     

Structure, assembly, and secretion of octameric invertase

Yeast invertase forms a homo-octamer of core glycosylated subunits during assembly in the lumen of the endoplasmic reticulum. This form has been purified from mutant cells (sec18) in which transport of secreted proteins from the endoplasmic reticulum is blocked. No heterologous protein subunits are found in the purified material. Analysis of invertase derived from wild type cells or from mutant cells blocked at subsequent stages in secretion demonstrates that invertase remains a homo-octamer throughout the pathway even though the extent of subunit glycosylation increases. Purified octameric invertase is dissociated into dimer units that reassociate in the presence of polyethylene glycol. Negatively stained preparations show the dissociated enzyme as individual spheres, whereas octameric invertase appears as four associated spheres. Assembly of the octamer in vitro and in vivo is facilitated by the presence of N-linked carbohydrate. Selective release of dimeric glycosylated invertase from intact yeast cells suggests that oligomerization helps retain the enzyme in the periplasmic space.     

Secretion of human superoxide dismutase in Escherichia coli using the condensed single-protein-production system

A secretion vector, pColdV for the Single-Protein-Production (SPP) system was constructed using the E. coli OmpA signal peptide. Using this vector, human superoxide dismutase (hSOD) was co-expressed with MazF, an ACA-specific mRNA interferase, allowing E. coli cells to produce only hSOD, which was secreted into the periplasmic space with a yield of ～20% of total cellular proteins. The signal peptide was properly cleaved. Using cells overproducing DsbA protein, two S-S bridges were also properly formed to yield enzymatically active SOD. A well resolved heteronuclear single quantum coherence (HSQC) spectrum of hSOD isotope-labeled in the condensed SPP (cSPP) system was obtained by simply isolating the periplasmic fraction. These results indicate that human secretory proteins can be expressed well in the cSPP system using pColdV.     

Coincident localization of secretory and plasma membrane proteins in organelles of the yeast secretory pathway.

Immunoelectron microscopy of Saccharomyces cerevisiae cells embedded in Lowicryl K4M has been used to localize invertase and plasma membrane (PM) ATPase in secretory organelles. sec mutant cells incubated at 37 degrees C were prepared for electron microscopy, and thin sections were incubated with polyclonal antibodies, followed by decoration with protein A-gold. Specific labeling of invertase was seen in the lumen of the endoplasmic reticulum, Golgi apparatus, and secretory vesicles in mutant cells that exaggerate these organelles. PM ATPase accumulated within the same organelles. Double-immune labeling revealed that invertase and PM ATPase colocalized in secretory vesicles. These results strengthen the view that secretion and plasma membrane assembly are biosynthetically coupled in yeast.     

Hypoglycosylation in the alg12delta yeast mutant destabilizes protease A and causes proteolytic loss of external invertase

The Saccharomyces cerevisiae alg12delta mutant accumulates oligosaccharide lipid with a Man(7)GlcNAc(2) oligosaccharide. To determine the N-glycan structures present on S. cerevisiae glycoproteins in the alg12delta strain, we made attempts to purify external invertase, a highly glycosylated secreted protein. These efforts revealed that, in the alg12delta background, external invertase was mildly hypoglycosylated and rapidly destroyed proteolytically. Although secreted alg9delta invertase was more severely hypoglycosylated than the alg12delta form, it was paradoxically stable during purification. The loss of periplasmic invertase was prevented by addition of pepstatin A to the cell cultures, suggesting that aspartyl proteases were active. We found that during overexpression of invertase in alg12delta yeast, sufficient protease A was mistargeted to the periplasmic space, where it hydrolyzed the invertase. Even though alg9delta invertase is underglycosylated in comparison to the alg12delta form, it is more stable because in this genetic background much less protease A is secreted compared to alg12delta cells. These observations may be relevant to studies using other extracellular proteins (e.g., mating factors, alpha-glucosidase) as probes when characterizing glycosylation defects in yeast.     

Post-translational modifications in mitotic yeast cells

We have recently shown that secretion of invertase is not inhibited in the yeast Saccharomyces cerevisiae during mitosis, but continues, as during interphase. This is in contrast with the mammalian cell, where membrane traffic stops at the onset of prometaphase. Here we extend our findings by showing that the bulk of the cell surface glycoproteins and mannans, as well as the yeast pheromone alpha-factor, traverse the secretory pathway during mitosis. We show that the mitotic cells are able to carry out several types of post-translational modification of secretory proteins. (a) The secretory protein invertase was oligomerized and extensively glycosylated, (b) the N-glycan cores of bulk-cell surface mannans were extended with outer chains, (c) some N-glycans were phosphorylated, (d) the protein-bound O-glycans were extended up to tetramannosides, (e) prepro-ka-factor was proteolytically processed to alpha-factor molecules. We conclude that the secretory pathway in yeast remains fully functional throughout the cell cycle.     

Optimal chemostat cascades for periplasmic protein production.

This theoretical work predicts the optimal system design for the steady-state production of secreted protein in a chemostat cascade, using bakers' yeast (Saccharomyces cerevisiae) as the host organism. The protein of interest, mutant invertase, is secreted to the periplasmic space instead of the culture medium on account of its large size. This work uses the secretion model developed and tested by Park and Ramirez (1988). It is shown that the highest productivity is achieved when the chemostat cascade contains two stages, although the improvement over the single-stage productivity is small. When no recycle is used, the advantage of two stages results from the tradeoff between maximizing the cell concentration and maximizing the rate of protein production per cell. When recycle is used, the cell concentration and protein productivity are increased, and the advantage of two stages results from the tradeoff between maximizing the specific protein production rate and maximizing the specific protein secretion rate. Cascades with three stages were also investigated, but these were found to have no improvement over the corresponding two-stage cascades.     

Synthesis and biological roles of O-glycans in insects

Protein O-glycosylation is the attachment of carbohydrate structures to the oxygen atom in the hydroxyl group of Serine and Threonine residues. This post-translational modification is commonly found on the majority of proteins trafficking through the secretory pathway and is reported to influence protein characteristics such as folding, secretion, stability, solubility, oligomerization and intracellular localization. In addition, O-glycosylation is essential for cell-cell interactions, protein-protein interactions and many biological processes, such as stress response, immunization, phosphorylation, ubiquitination, cell division, metabolism and cell signaling. The availability of sequenced genomes and genetic tools to create mutants with clear phenotypes makes insects an interesting model system to study O-glycosylation. In this review, we provide an overview of the current knowledge of O-glycosylation, mainly obtained from the model organism Drosophila melanogaster, with a focus on the synthesis and biological roles of the common O-glycans in insects.     

Protein secretion from Saccharomyces cerevisiae directed by the prepro-alpha-factor leader region

The Saccharomyces cerevisiae secretory process was studied by evaluating secretion efficiency, processing efficiency, and the efficiency of protein folding for hybrid proteins containing the yeast prepro-alpha-factor leader region. Secretion of three proteins, beta-endorphin, calcitonin, and a consensus alpha-interferon (IFN-Con1), were compared in terms of secretion efficiency into the culture medium, beta-Endorphin and calcitonin, both small proteins, were found to be efficiently secreted from logarithmically grown cells. In contrast, the larger IFN-Con1 accumulated in the periplasmic space and cell wall. The glycosylated, unprocessed prepro-alpha-factor/IFN-Con1 fusion protein was also found to be secreted into the culture medium. The presence of (Glu-Ala) dipeptides in the alpha-factor spacer peptide increased the efficiency of cleavage at Lys-Arg in the prepro-alpha-factor/IFN-Con1 protein fusion. Purified secreted IFN-Con1 was structurally characterized to determine the effect of passage through the yeast secretory pathway on the fidelity and efficiency of protein folding. The disulfide structure of the secreted protein was found to be identical with that reported for the native human alpha-interferons.     

Recombinant protein secretion in Escherichia coli

The secretory production of recombinant proteins by the Gram-negative bacterium Escherichia coli has several advantages over intracellular production as inclusion bodies. In most cases, targeting protein to the periplasmic space or to the culture medium facilitates downstream processing, folding, and in vivo stability, enabling the production of soluble and biologically active proteins at a reduced process cost. This review presents several strategies that can be used for recombinant protein secretion in E. coli and discusses their advantages and limitations depending on the characteristics of the target protein to be produced.     

Improved protein synthesis and secretion through medium enrichment in a stable recombinant yeast strain

Two Saccharomyces cerevisiae strains were employed to investigate the effects of medium enrichment on the expression and secretion of a recombinant protein. One was a stable autoselection strain with mutations in the ura3, fur1, and urid-k genes. The combination of these three mutations blocks both the pyrimidine nucleotide biosynthetic and salvage pathways and is lethal to the cells. Retention of the plasmid, which carries a URA3 gene, was essential for cell viability. Therefore, all media were selective, allowing cultivation of the strain in complex medium. The second strain was a nonautoselection (control) strain and is isogenic to the first except for the fur1 and urid-k mutations. The plasmid utilized contains the yeast invertase gene under the control of the MFalpha1 promoter and leader sequence. The expression and secretion of invertase for the autoselection strain were examined in batch culture for three media: a minimal medium (SD), a semidefined medium (SDC), and a rich complex medium (YPD). Biomass yields and invertase productivity (volumetric activity) increased with the complexity of the medium; total invertase volumetric activity in YPD was 100% higher than in SDC and 180% higher than in SD. Specific activity, however, was lowest in the SDC medium. Secretion efficiency was extremely high in all three media; for the majority of the culture, 80-90% of the invertase was secreted into the periplasmic space and/or culture medium. A glucose pulse at the end of batch culture in YPD facilitated the transport of residual cytoplasmic invertase. For the nonautoselection strain, invertase productivity did not improve as the medium was enriched from SDC to YPD, and plasmid stability in the complex YPD medium dropped from 54% to 34% during one batch fermentation. During long-term sequential batch culture in YPD, invertase activity decreased by 90% and the plasmid-containing fraction dropped from 56% to 8.8% over 44 generations of growth. The expression level for the autoselection strain, however, remained high and constant over this time period, and no reversion at the fur1 or urid-k locus was observed. (c) 1993 John Wiley & Sons, Inc.     

Secretory and extracellular production of recombinant proteins using<Emphasis Type="Italic"> Escherichia coli</Emphasis>

Escherichia coli is one of the most widely used hosts for the production of recombinant proteins. However, there are often problems in recovering substantial yields of correctly folded proteins. One approach to solve these problems is to have recombinant proteins secreted into the periplasmic space or culture medium. The secretory production of recombinant proteins has several advantages, such as simplicity of purification, avoidance of protease attack and N-terminal Met extension, and a better chance of correct protein folding. In addition to the well-established Sec system, the twin-arginine translocation (TAT) system has recently been employed for the efficient secretion of folded proteins. Various strategies for the extracellular production of recombinant proteins have also been developed. For the secretory production of complex proteins, periplasmic chaperones and protease can be manipulated to improve the yields of secreted proteins. This review discusses recent advances in secretory and extracellular production of recombinant proteins using E. coli.     

Delivery of a Secreted Soluble Protein to the Vacuole via a Membrane Anchor

To further understand how membrane proteins are sorted in the secretory system, we devised a strategy that involves the expression of a membrane-anchored yeast invertase in transgenic plants. The construct consisted of a signal peptide followed by the coding region of yeast invertase and the transmembrane domain and cytoplasmic tail of calnexin. The substitution of a lysine near the C terminus of calnexin with a glutamic acid residue ensured progression through the secretory system rather than retention in or return to the endoplasmic reticulum. In the transformed plants, invertase activity and a 70-kD cross-reacting protein were found in the vacuoles. This yeast invertase had plant-specific complex glycans, indicating that transport to the vacuole was mediated by the Golgi apparatus. The microsomal fraction contained a membrane-anchored 90-kD cross-reacting polypeptide, but was devoid of invertase activity. Our results indicate that this membrane-anchored protein proceeds in the secretory system beyond the point where soluble proteins are sorted for secretion, and is detached from its membrane anchor either just before or just after delivery to the vacuole.     

Rerouting of fibroblast growth factor 2 to the classical secretory pathway results in post-translational modifications that block binding to heparan sulfate proteoglycans

FGF-2 is a proangiogenic growth factor secreted by unconventional means. It is unknown why FGF-2 takes an ER/Golgi-independent secretory route. We find that secretion of FGF-2 via the ER/Golgi system causes post-translational modifications that prevent binding to heparan sulfate proteoglycans (HSPGs), an interaction that is critically important for both FGF-2 storage and signal transduction. This loss of function is due to artificial O-glycosylation mainly resulting in the addition of glycosaminoglycan chains of the chrondroitin sulfate type. Our findings suggest that the unconventional mechanism of FGF-2 export is an ancient pathway of protein secretion that, in the course of evolution, has been kept due to the inability of the classical secretory pathway to export FGF-2 in a functional form.     

Engineering of vesicle trafficking improves heterologous protein secretion in Saccharomyces cerevisiae

The yeast Saccharomyces cerevisiae is a widely used platform for the production of heterologous proteins of medical or industrial interest. However, heterologous protein productivity is often restricted due to the limitations of the host strain. In the protein secretory pathway, the protein trafficking between different organelles is catalyzed by the soluble NSF (N-ethylmaleimide-sensitive factor) receptor (SNARE) complex and regulated by the Sec1/Munc18 (SM) proteins. In this study, we report that over-expression of the SM protein encoding genes SEC1 and SLY1, improves the protein secretion in S. cerevisiae. Engineering Sec1p, the SM protein that is involved in vesicle trafficking from Golgi to cell membrane, improves the secretion of heterologous proteins human insulin precursor and α-amylase, and also the secretion of an endogenous protein invertase. Enhancing Sly1p, the SM protein regulating the vesicle fusion from endoplasmic reticulum (ER) to Golgi, increases α-amylase production only. Our study demonstrates that strengthening the protein trafficking in ER-to-Golgi and Golgi-to-plasma membrane process is a novel secretory engineering strategy for improving heterologous protein production in S. cerevisiae.     

Evidence that a globular conformation is not compatible with FhaC-mediated secretion of the Bordetella pertussis filamentous haemagglutinin

The 220 kDa Bordetella pertussis filamentous haemagglutinin (FHA) is the major extracellular protein of this organism. It is exported using a signal peptide-dependent pathway, and its secretion depends on one specific outer membrane accessory protein, FhaC. In this work, we have investigated the influence of conformation on the FhaC-mediated secretion of FHA using an 80 kDa N-terminal FHA derivative, Fha44. In contrast to many signal peptide-dependent secretory proteins, no soluble periplasmic intermediate of Fha44 could be isolated. In addition, cell-associated Fha44 synthesized in the absence of FhaC did not remain competent for extracellular secretion upon delayed expression of FhaC, indicating that the translocation steps across the cytoplasmic and the outer membrane might be coupled. A chimeric protein, in which the globular B subunit of the cholera toxin, CtxB, was fused at the C-terminus of Fha44, was not secreted in B. pertussis or in Escherichia coli expressing FhaC. The hybrid protein was only secreted when both disulphide bond-forming cysteines of CtxB were replaced by serines or when it was produced in DsbA^?E. coli. The Fha44 portion of the secretion-incompetent hybrid protein was partly exposed on the cell surface. These results argue that the Fha44–CtxB hybrid protein transited through the periplasmic space, where disulphide bond formation is specifically catalysed, and that secretion across the outer membrane was initiated. The folded CtxB portion prevented extracellular release of the hybrid, in contrast to the more flexible CtxB domain devoid of cysteines. We propose a secretion model whereby Fha44 transits through the periplasmic space on its way to the cell surface and initiates its translocation through the outer membrane before being released from the cytoplasmic membrane. Coupling of Fha44 translocation across both membranes would delay the acquisition of its folded structure until the protein emerges from the outer membrane. Such a model would be consistent with the extensive intracellular proteolysis of FHA derivatives in B. pertussis.     

The yeast SEC20 gene is required for N- and O-glycosylation in the Golgi. Evidence that impaired glycosylation does not correlate with the secretory defect

The Golgi plays a fundamental role in posttranslational glycosylation, transport, and sorting of proteins. The mechanism of protein transport through the Golgi has been seen as controversial in recent years. During the characterization of N-glycosylation-defective mutants (ngd) previously isolated by this laboratory, it was found that ngd20 is allelic to sec20. SEC20 was reported to be required for transport from endoplasmic reticulum to Golgi, but its precise function remains to be determined. We show now that SEC20 is also required for N- and O-glycosylation in the Golgi but not in the ER, in a cargo-specific manner, and that the glycosylation defect does not correlate with the secretory defect. By pulse-chase labeling experiments in combination with mannose linkage-specific antibodies, invertase and carboxypeptidase were found to be efficiently secreted to their final compartment, even upon shift to the nonpermissive temperature, while glycosylation in the Golgi was severely impaired. Using microsomal membranes isolated from ngd20, we found that mannosyl transfer from GDP-Man to various mannose-oligosaccharides, indicative for Golgi mannosylation, was strongly diminished. Analysis of the carbohydrate component of chitinase, an exclusively O-mannosylated protein, or of the bulk mannoprotein indicates that O-mannosylation is also reduced. The results demonstrate that in addition to secretion SEC20 also affects glycosylation in the Golgi, presumably because it exerts a more general role in maintenance and function of the Golgi compartments.