Jeong-Yoon Kim

Proteolytic stability of recombinant human serum albumin secreted in the yeast Saccharomyces cerevisiae.

Abstract In order to direct the persistent expression of recombinant human serum albumin (HSA) from the GAL10 promoter in the yeast Saccharomyces cerevisiae, we carried out periodic feeding of galactose during shake-flask cultures. Unexpectedly, the recombinant protein secreted was observed to undergo rapid degradation, which was apparently accelerated by carbon-source feeding. The extracellular degradation of HSA occurred even in the strain deficient in the major vacuolar proteases PrA and PrB, and in the strain lacking the acidic protease Yap3p (involved in the generation of HSA-truncated fragments). Interestingly, the degradation correlated closely with the acidification of extracellular pH and thus was significantly overcome either by buffering the culture medium above pH 5.0 or by adding amino acid-rich supplements to the culture medium, which could prevent the acidification of medium pH during cultivation. Addition of arginine or ammonium salt also substantially minimized the degradation of HSA, even without buffering. The extracellular degradation activity was not detected in the cell-free culture supernatant but was found to be associated with intact cells. The results of the present study strongly suggest that the HSA secreted in S. cerevisiae is highly susceptible to the pH-dependent proteolysis mediated by cell-bound protease(s) whose activity and expression are greatly affected by the composition of the medium.

Functional Characterization of the Hansenula polymorpha HOC1, OCH1, and OCR1 Genes as Members of the Yeast OCH1 Mannosyltransferase Family Involved in Protein Glycosylation

The α-1,6-mannosyltransferase encoded by Saccharomyces cerevisiae OCH1 (ScOCH1) is responsible for the outer chain initiation of N-linked oligosaccharides. To identify the genes involved in the first step of outer chain biosynthesis in the methylotrophic yeast Hansenula polymorpha, we undertook the functional analysis of three H. polymorpha genes, HpHOC1, HpOCH1, and HpOCR1, that belong to the OCH1 family containing seven members with significant sequence identities to ScOCH1. The deletions of these H. polymorpha genes individually resulted in several phenotypes suggestive of cell wall defects. Whereas the deletion of HpHOC1 (Hphoc1Δ) did not generate any detectable changes in N-glycosylation, the null mutant strains of HpOCH1 (Hpoch1Δ) and HpOCR1 (Hpocr1Δ) displayed a remarkable reduction in hypermannosylation. Although the apparent phenotypes of Hpocr1Δ were most similar to those of S. cerevisiae och1 mutants, the detailed structural analysis of N-glycans revealed that the major defect of Hpocr1Δ is not in the initiation step but rather in the subsequent step of outer chain elongation by α-1,2-mannose addition. Most interestingly, Hpocr1Δ showed a severe defect in the O-linked glycosylation of extracellular chitinase, representing HpOCR1 as a novel member of the OCH1 family implicated in both N- and O-linked glycosylation. In contrast, addition of the first α-1,6-mannose residue onto the core oligosaccharide Man8GlcNAc2 was completely blocked in Hpoch1Δ despite the comparable growth of its wild type under normal growth conditions. The complementation of the S. cerevisiae och1 null mutation by the expression of HpOCH1 and the lack of in vitro α-1,6-mannosyltransferase activity in Hpoch1Δ provided supportive evidence that HpOCH1 is the functional orthologue of ScOCH1. The engineered Hpoch1Δ strain with the targeted expression of Aspergillus saitoi α-1,2-mannosidase in the endoplasmic reticulum was shown to produce human-compatible high mannose-type Man5GlcNAc2 oligosaccharide as a major N-glycan.

EXPRESSION, SECRETION, AND PROCESSING OF RICE ALPHA -AMYLASE IN THE YEAST YARROWIA LIPOLYTICA

The gene encoding rice α-amylase in Oryza sativa was expressed in the yeast Yarrowia lipolytica, which is a potential host system for heterologous protein expression. For efficient secretion, the strong and inducible XPR2 promoter was used in the construction of four kinds of expression vectors with the following configurations between the XPR2 promoter and terminator: 1) XPR2 prepro-region-rice α-amylase coding sequence, 2) rice α-amylase signal peptide-rice α-amylase coding sequence, 3) XPR2 signal peptide-rice α-amylase coding sequence, and 4) XPR2 signal peptide-dipeptide stretch-rice α-amylase coding sequence. Secretion of active recombinant rice α-amylase into the culture medium was achieved only in the first two cases, demonstrating that the XPR2 signal peptide is not sufficient to direct the secretion of heterologous protein. Furthermore, our study shows that the XPR2 prepro-region causes imprecise processing (after Pro150-Ala151 or Val135-Leu136 instead of Lys156-Arg157) and leads to N-terminal amino acid sequences that differ from that of native rice α-amylase. Secondary structure analysis proposed that the structural form in the vicinity of the KEX2-like endopeptidase processing site in the XPR2 pro-region might play a critical role in the processing of heterologous proteins. These results suggest that the XPR2 pro-region is dispensable for obtaining the precise N-terminal amino acid in heterologous protein secretion. In contrast, utilizing the rice α-amylase signal peptide was sufficient in directing secretion of recombinant protein with the expected N-terminal sequence, indicating that the signal peptide of rice α-amylase was effectively recognized and processed by the Y. lipolytica secretory pathway.

Role of the RAM Network in Cell Polarity and Hyphal Morphogenesis in Candida albicans

RAM (regulation of Ace2p transcription factor and polarized morphogenesis) is a conserved signaling network that regulates polarized morphogenesis in yeast, worms, flies, and humans. To investigate the role of the RAM network in cell polarity and hyphal morphogenesis of Candida albicans, each of the C. albicans RAM genes (CaCBK1, CaMOB2, CaKIC1, CaPAG1, CaHYM1, and CaSOG2) was deleted. All C. albicans RAM mutants exhibited hypersensitivity to cell-wall- or membrane-perturbing agents, exhibiting cell-separation defects, a multinucleate phenotype and loss of cell polarity. Yeast two-hybrid and in vivo functional analyses of CaCbk1p and its activator, CaMob2p, the key factors in the RAM network, demonstrated that the direct interaction between the SMA domain of CaCbk1p and the Mob1/phocein domain of CaMob2p was necessary for hyphal growth of C. albicans. Genome-wide transcription profiling of a Camob2 mutant suggested that the RAM network played a role in serum- and antifungal azoles-induced activation of ergosterol biosynthesis genes, especially those involved in the late steps of ergosterol biosynthesis, and might be associated, at least indirectly, with the Tup1p-Nrg1p pathway. Collectively, these results demonstrate that the RAM network is critically required for hyphal growth as well as normal vegetative growth in C. albicans.

High cell density culture of Yarrowia lipolytica using a one-step feeding process.

Yarrowia lipolytica is a potentially useful host for heterologous protein production. To develop an efficient culture method for high cell density cultivation and heterologous gene expression of Y. lipolytica, the effects of medium components and their concentrations on the growth of Y. lipolytica have been investigated. Addition of yeast extract to the culture media was found to significantly reduce the long lag phase encountered when Y. lipolyticawas cultivated in synthetic culture media containing high concentrations of glycerol. Therefore, by enriching with 0.3% yeast extract the synthetic culture medium containing 15% glycerol, we could cultivate Y. lipolyticaup to 83 g/L dry cell weight in a batch culture. Furthermore, over 100 g/L and 88 units/mL of rice α‐amylase activity were obtained in less than 50 h with a one‐step feeding process in which a recombinant Y. lipolytica expressing rice α‐amylase was cultivated in the 10% glycerol medium enriched with 0.3% yeast extract and fed only once with the concentrated feeding medium (60% glycerol). The easy cultivation of recombinant Y. lipolytica to a high cell density may strengthen its position as a host for heterologous protein production.

Engineering of the Yeast Yarrowia lipolytica for the Production of Glycoproteins Lacking the Outer-Chain Mannose Residues of N-Glycans

ABSTRACT In an attempt to engineer a Yarrowia lipolytica strain to produce glycoproteins lacking the outer-chain mannose residues of N-linked oligosaccharides, we investigated the functions of the OCH1 gene encoding a putative α-1,6-mannosyltransferase in Y. lipolytica. The complementation of the Saccharomyces cerevisiae och1 mutation by the expression of YlOCH1 and the lack of in vitro α-1,6-mannosyltransferase activity in the Yloch1 null mutant indicated that YlOCH1 is a functional ortholog of S. cerevisiae OCH1. The oligosaccharides assembled on two secretory glycoproteins, the Trichoderma reesei endoglucanase I and the endogenous Y. lipolytica lipase, from the Yloch1 null mutant contained a single predominant species, the core oligosaccharide Man8GlcNAc2, whereas those from the wild-type strain consisted of oligosaccharides with heterogeneous sizes, Man8GlcNAc2 to Man12GlcNAc2. Digestion with α-1,2- and α-1,6-mannosidase of the oligosaccharides from the wild-type and Yloch1 mutant strains strongly supported the possibility that the Yloch1 mutant strain has a defect in adding the first α-1,6-linked mannose to the core oligosaccharide. Taken together, these results indicate that YlOCH1 plays a key role in the outer-chain mannosylation of N-linked oligosaccharides in Y. lipolytica. Therefore, the Yloch1 mutant strain can be used as a host to produce glycoproteins lacking the outer-chain mannoses and further developed for the production of therapeutic glycoproteins containing human-compatible oligosaccharides.

The RhoG/ELMO1/Dock180 Signaling Module Is Required for Spine Morphogenesis in Hippocampal Neurons

Background: Dendritic spines are actin-rich structures that receive most of the excitatory synaptic inputs in the brain. Results: ELMO1/Dock180 regulates spine morphogenesis through activating Rac, and RhoG functions upstream of this process. Conclusion: A RhoG/ELMO1/Dock180 signaling module is important for spine morphogenesis in hippocampal neurons. Significance: Our data reveal a novel role for RhoG/ELMO1/Dock180 and provide insight into the molecular mechanisms of spine morphogenesis. Dendritic spines are actin-rich structures, the formation and plasticity of which are regulated by the Rho GTPases in response to synaptic input. Although several guanine nucleotide exchange factors (GEFs) have been implicated in spine development and plasticity in hippocampal neurons, it is not known how many different Rho GEFs contribute to spine morphogenesis or how they coordinate the initiation, establishment, and maintenance of spines. In this study, we screened 70 rat Rho GEFs in cultured hippocampal neurons by RNA interference and identified a number of candidates that affected spine morphogenesis. Of these, Dock180, which plays a pivotal role in a variety of cellular processes including cell migration and phagocytosis, was further investigated. We show that depletion of Dock180 inhibits spine morphogenesis, whereas overexpression of Dock180 promotes spine morphogenesis. ELMO1, a protein necessary for in vivo functions of Dock180, functions in a complex with Dock180 in spine morphogenesis through activating the Rac GTPase. Moreover, RhoG, which functions upstream of the ELMO1/Dock180 complex, is also important for spine formation. Together, our findings uncover a role for the RhoG/ELMO1/Dock180 signaling module in spine morphogenesis in hippocampal neurons.

Essential Role of YlMPO1, a Novel Yarrowia lipolytica Homologue of Saccharomyces cerevisiae MNN4, in Mannosylphosphorylation of N- and O-Linked Glycans

ABSTRACT Mannosylphosphorylation of N- and O-glycans, which confers negative charges on the surfaces of cells, requires the functions of both MNN4 and MNN6 in Saccharomyces cerevisiae. To identify genes relevant to mannosylphosphorylation in the dimorphic yeast Yarrowia lipolytica, the molecular functions of five Y. lipolytica genes showing significant sequence homology with S. cerevisiae MNN4 and MNN6 were investigated. A set of mutant strains in which Y. lipolytica MNN4 and MNN6 homologues were deleted underwent glycan structure analysis. In contrast to S. cerevisiae MNN4 (ScMNN4), the Y. lipolytica MNN4 homologue, MPO1 (YlMPO1), encodes a protein that lacks the long KKKKEEEE repeat domain at its C terminus. Moreover, just a single disruption of YlMPO1 resulted in complete disappearance of the acidic sugar moiety in both the N- and O-linked glycan profiles. In contrast, even quadruple disruption of all ScMNN6 homologues, designated YlKTR1, YlKTR2, YlKTR3, and YlKTR4, resulted in no apparent reduction in acidic sugar moieties. These findings strongly indicate that YlMpo1p performs a significant role in mannosylphosphorylation in Y. lipolytica with no involvement of the Mnn6p homologues. Mutant strains harboring the YlMPO1 gene disruption may serve as useful platforms for engineering Y. lipolytica glycosylation pathways for humanized glycans without any yeast-specific acidic modifications.

Improvement of heterologous protein productivity using recombinant Yarrowia lipolytica and cyclic fed‐batch process strategy

A cyclic fed-batch bioprocess is designed and a significant improvement of rice alpha-amylase productivity of recombinant Yarrowia lipolytica is illustrated. A bioprocess control strategy developed and reported here entails use of a genetically stable recombinant cloned for heterologous protein, use of optimized media for cell growth and enzyme production phases, and process control strategy enabling high cell-density culture and high alpha-amylase productivity. This process control can be achieved through maintaining a constant optimal specific cell growth rate at a predetermined value (i.e., 0.1 h-1), controlling medium feed rate commensurate with the cell growth rate, and maintaining a high cell-density culture (i.e., 60-70 g/L) for high productivity of cloned heterologous protein. The volumetric enzyme productivity (1, 960 units/L. h) achieved from the cyclic fed-batch process was about 3-fold higher than that of the fed-batch culture process (630 units/L. h).

Molecular cloning of YlPMR1, a S. cerevisiae PMR1 homologue encoding a novel P-type secretory pathway Ca2+ -ATPase, in the yeast Yarrowia lipolytica.

A novel P-type ATPase gene, Saccharomyces cerevisiae PMR1 homologue (YlPMR1), has been cloned and sequenced in the yeast, Yarrowia lipolytica. The putative gene product has 928 amino acids with a calculated molecular mass of 100050 Da and a pI of 5.15. The deduced amino-acid sequence analysis demonstrated that the cloned gene product contains all 10 of the conserved regions in P-type ATPases and exhibits 55% amino-acid identity to the S. cerevisiae PMR1 gene product; however, it shows a relatively lower homology to PMCA (24%) and SERCA (33%), confirming the presence of a third class of Ca2+-ATPase (secretory pathway Ca2+-ATPase, SPCA). The YlPMR1-disrupted strain shows defective growth in low Ca2+ or EGTA-containing medium. In fact, a longer lag time (60 h) was observed in YlPMR1-defective mutant cells during cultivation in EGTA-containing YPD medium. These growth defects were overcome by adding Ca2+ and Mn2+ into the medium. Interestingly, whereas Mn2+ inhibits growth of the control strain, it significantly improves the growth of YlPMR1-disrupted cells. These results suggest an involvement of the YlPMR1 gene product in Ca2+ and Mn2+ ion homeostasis in Y. lipolytica.