Synthesis of Sucrose-Mimicking Disaccharide by Intramolecular Aglycone Delivery.

Rare sugars are known for their ability to suppress postprandial blood glucose levels. Therefore, oligosaccharides and disaccharides derived from rare sugars could potentially serve as functional sweeteners. A disaccharide [α-d-allopyranosyl-(1→2)-ß-d-psicofuranoside] mimicking sucrose was synthesized from rare monosaccharides D-allose and D-psicose. Glycosylation using the intermolecular aglycon delivery (IAD) method was employed to selectively form 1,2-cis α-glycosidic linkages of the allopyranose residues. Moreover, ß-selective psicofuranosylation was performed using a psicofuranosyl acceptor with 1,3,4,6-tetra-O-benzoyl groups. This is the first report on the synthesis of non-reducing disaccharides comprising only rare d-sugars by IAD using protected ketose as a unique acceptor; additionally, this approach is expected to be applicable to the synthesis of functional sweeteners.

Synthesis of azide-modified glycerophospholipid precursor analogs for detection of enzymatic reactions.

Glycerophospholipids (GPLs) are major cell membrane components. Although various phosphorylated molecules are attached to lipid moieties as their headgroups, GPLs are biosynthesized from phosphatidic acid (PA) via its derivatives, diacylglycerol (DAG) or cytidine diphosphate diacylglycerol (CDP-DAG). A variety of molecular probes capable of introducing detection tags have been developed to investigate biological events involved in GPLs. In this study, we report the design, synthesis, and evaluation of novel analytical tools suitable to monitor the activity of GPL biosynthetic enzymes in vitro. Our synthetic targets, namely, azide-modified PA, azide-modified DAG, and azide-modified CDP-DAG, were successfully obtained from solketal as their common starting material. Moreover, using CDP-diacylglycerol-inositol 3-phosphatidyltransferase (CDIPT), an enzyme that catalyzed the final reaction step in synthesizing phosphatidylinositol, we demonstrated that azide-modified CDP-DAG worked as a substrate for CDIPT.

Squaryl group-modified UDP analogs as inhibitors of the endoplasmic reticulum-resident folding sensor enzyme UGGT.

UDP-Glc:glycoprotein glucosyltransferase (UGGT) has a central role to retain quality control of correctly folded N-glycoprotein in the endoplasmic reticulum (ER). A selective and potent inhibitor against UGGT could lead to elucidation of UGGT-related events, but such a molecule has not been identified so far. Examples of small molecules with UGGT inhibitory activity are scarce. Here, we report squaryl group-modified UDP analogs as a promising UGGT inhibitor. Among these, the compound possessing a 2'-amino group of the uridine moiety and hydroxyethyl-substituted squaramide exhibited the highest potency, suggesting its relevance as a molecule for further optimization.

AeiA is a novel autophagy-related protein that promotes peroxisome degradation by pexophagy in Aspergillus oryzae.

Autophagy is classified into nonselective and selective autophagy, depending on the specificity of substrate degradation. In the filamentous fungus Aspergillus oryzae, selective autophagy, which includes pexophagy and mitophagy, has been observed. However, the molecular mechanism underlying selective autophagy in filamentous fungi remains unclear. Here, we identified a novel protein that interacts with the autophagy-related protein Atg8 in A. oryzae, named AoAtg8-interacting protein A (AeiA). AeiA was localized to AoAtg8-positive autophagic membrane structures and peroxisomes. Moreover, peroxisomal trafficking into the vacuole was reduced in AeiA disruptants. Taken together, AeiA is a novel selective autophagy-related protein that contributes to pexophagy in A. oryzae.

Analysis of Selenoprotein F Binding to UDP-Glucose:Glycoprotein Glucosyltransferase (UGGT) by a Photoreactive Crosslinker.

In the endoplasmic reticulum glycoprotein quality control system, UDP-glucose : glycoprotein glucosyltransferase (UGGT) functions as a folding sensor. Although it is known to form a heterodimer with selenoprotein F (SelenoF), the details of the complex formation remain obscure. A pulldown assay using co-transfected SelenoF and truncated mutants of human UGGT1 (HUGT1) revealed that SelenoF binds to the TRXL2 domain of HUGT1. Additionally, a newly developed photoaffinity crosslinker was selectively introduced into cysteine residues of recombinant SelenoF to determine the spatial orientation of SelenoF to HUGT1. The crosslinking experiments showed that SelenoF formed a covalent bond with amino acids in the TRXL3 region and the interdomain between ßS2 and GT24 of HUGT1 via the synthetic crosslinker. SelenoF might play a role in assessing and refining the disulfide bonds of misfolded glycoproteins in the hydrophobic cavity of HUGT1 as it binds to the highly flexible region of HUGT1 to reach its long hydrophobic cavity. Clarification of the SelenoF-binding domain of UGGT and its relative position will help predict and reveal the function of SelenoF from a structural perspective.

Phenotypic analysis of α1,2-mannosidase-like protein deletion mutants in Saccharomyces cerevisiae.

α1,2­mannosidase-like proteins mediate quality control of glycoproteins in the endoplasmic reticulum. This study explored α1,2­mannosidase-like protein functions in Saccharomyces cerevisiae. Single disruptants in targeted protein-coding genes were found to be viable; however, deletion of MNL2 resulted in declined yeast growth at 37 °C. The normal growth rate was recovered in double-deletion strains where one of the deletions was in MNS1 . We also measured the mannosidase activity of microsomal fractions of deficient strains using artificial glycan. Increased mannose trimming activities were demonstrated by the microsomes of MNL2 -deletion strains compared to levels of activity exhibited by the microsomes of the control strain.

In vitro mannosidase activity of EDEM3 against asparagine-linked oligomannose-type glycans.

Oligomannose-type glycans on glycoproteins play an important role in the endoplasmic reticulum (ER)-protein quality control. Mannose trimming of the glycans triggers the ER-associated protein degradation pathway. In mammals, ER mannosyl-oligosaccharide 1,2-α-mannosidase 1 and three ER degradation -enhancing α-mannosidase-like proteins (EDEMs) are responsible for mannose trimming. However, the exact role of EDEMs as α-mannosidases in ERAD remains unclear. Here, we performed the biochemical characterization of EDEM3 using synthetic oligomannose-type glycan substrates. In vitro assays revealed that EDEM3 can convert an asparagine-linked M9 glycan to M8 and M7 glycans in contrast to glycine-linked M9 glycan, and the activity is enhanced in the presence of ERp46, a known partner protein of EDEM3. Our study provides novel insights into the enzymatic properties of EDEM3 and the use of artificial glycan substrates as tools to study ERAD mechanisms.

Analysis of an acyl-CoA binding protein in Aspergillus oryzae that undergoes unconventional secretion.

Acyl-CoA binding protein (ACBP) plays important roles in the metabolism of lipids in eukaryotic cells. In the industrially important filamentous fungus Aspergillus oryzae, although we have previously demonstrated that the A. oryzae ACBP (AoACBP) localizes to punctate structures and exhibits long-range motility, which is dependent on autophagy-related proteins, the physiological role of AoACBP remains elusive. Here, we describe identification and characterization of another ACBP from A. oryzae; we named this ACBP as AoAcb2 and accordingly renamed AoACBP as AoAcb1. The deduced amino acid sequence of AoAcb2 lacked a signal peptide. Phylogenetic analysis classified AoAcb2 into a clade that was same as the ACBP Acb1 of the model yeast Saccharomyces cerevisiae, but was different from that of AoAcb1. In contrast to punctate localization of AoAcb1, AoAcb2 was found to be dispersedly distributed in the cytoplasm, as was previously observed for the S. cerevisiae Acb1. Since we could not generate an Aoacb2 disruptant, we created an Aoacb2 conditional mutant that exhibited less growth under Aoacb2-repressed condition, suggesting that Aoacb2 is an essential gene for growth. Moreover, we observed that A. oryzae AoAcb2, but not A. oryzae AoAcb1, was secreted under carbon-starved condition, suggesting that AoAcb2 might be secreted via the unconventional protein secretion (UPS) pathway, just like S. cerevisiae Acb1. We also demonstrated that the unconventional secretion of AoAcb2 was dependent on the t-SNARE AoSso1, but was independent of the autophagy-related protein AoAtg1, suggesting that the unconventional secretion of AoAcb2, unlike that of S. cerevisiae Acb1, via the UPS pathway, is not regulated by the autophagy machinery. Thus, the filamentous fungus A. oryzae harbors two types of ACBPs, one of which appears to be essential for growth and undergoes unconventional secretion.

Carbon and nitrogen depletion-induced nucleophagy and selective autophagic sequestration of a whole nucleus in multinucleate cells of the filamentous fungus Aspergillus oryzae.

Autophagy is a conserved cellular degradation process in eukaryotes, in which cytoplasmic components and organelles are digested in vacuoles/lysosomes. Recently, autophagic degradation of nuclear materials, termed "nucleophagy", has been reported. In the multinucleate filamentous fungus Aspergillus oryzae, a whole nucleus is degraded by nucleophagy after prolonged culture. While developing an H2B-EGFP processing assay for the evaluation of nucleophagy in A. oryzae, we found that nucleophagy is efficiently induced by carbon or nitrogen depletion. Microscopic observations in a carbon depletion condition clearly demonstrated that autophagosomes selectively sequester a particular nucleus, despite the presence of multiple nuclei in the same cell. Furthermore, AoNsp1, the A. oryzae homolog of the yeast nucleoporin Nsp1p, mainly localized at the nuclear periphery, but its localization was restricted to the opposite side of the autophagosome being formed around a nucleus. In contrast, the perinuclear ER visualized with the calnexin AoClxA was not morphologically affected by nucleophagy. The findings of nucleophagy-inducing conditions enabled us to characterize the morphological process of autophagic degradation of a whole nucleus in multinucleate cells.

AoAtg26, a putative sterol glucosyltransferase, is required for autophagic degradation of peroxisomes, mitochondria, and nuclei in the filamentous fungus Aspergillus oryzae.

Autophagy is a conserved process in eukaryotic cells for degradation of cellular proteins and organelles. In filamentous fungi, autophagic degradation of organelles such as peroxisomes, mitochondria, and nuclei occurs in basal cells after the prolonged culture, but its mechanism is not well understood. Here, we functionally analyzed the filamentous fungus Aspergillus oryzae AoAtg26, an ortholog of the sterol glucosyltransferase PpAtg26 involved in pexophagy in the yeast Pichia pastoris. Deletion of Aoatg26 caused a severe decrease in conidiation and aerial hyphae formation, which is typically observed in the autophagy-deficient A. oryzae strains. In addition, cup-shaped AoAtg8-positive membrane structures were accumulated in the Aoatg26 deletion strain, indicating that autophagic process is impaired. Indeed, the Aoatg26 deletion strain was defective in the degradation of peroxisomes, mitochondria, and nuclei. Taken together, AoAtg26 plays an important role for autophagic degradation of organelles in A. oryzae, which may physiologically contribute to the differentiation in filamentous fungi.

Subcellular localization of acyl-CoA binding protein in Aspergillus oryzae is regulated by autophagy machinery.

In eukaryotic cells, acyl-CoA binding protein (ACBP) is important for cellular activities, such as in lipid metabolism. In the industrially important fungus Aspergillus oryzae, the ACBP, known as AoACBP, has been biochemically characterized, but its physiological function is not known. In the present study, although we could not find any phenotype of AoACBP disruptants in the normal growth conditions, we examined the subcellular localization of AoACBP to understand its physiological function. Using an enhanced green fluorescent protein (EGFP)-tagged AoACBP construct we showed that AoACBP localized to punctate structures in the cytoplasm, some of which moved inside the cells in a microtubule-dependent manner. Further microscopic analyses showed that AoACBP-EGFP co-localized with the autophagy marker protein AoAtg8 tagged with red fluorescent protein (mDsRed). Expression of AoACBP-EGFP in disruptants of autophagy-related genes revealed aggregation of AoACBP-EGFP fluorescence in the cytoplasm of Aoatg1, Aoatg4 and Aoatg8 disruptant cells. However, in cells harboring disruption of Aoatg15, which encodes a lipase for autophagic body, puncta of AoACBP-EGFP fluorescence accumulated in vacuoles, indicating that AoACBP is transported to vacuoles via the autophagy machinery. Collectively, these results suggest the existence of a regulatory mechanism between AoACBP localization and autophagy.

AoRim15 is involved in conidial stress tolerance, conidiation and sclerotia formation in the filamentous fungus Aspergillus oryzae.

The serine-threonine kinase Rim15p is a master regulator of stress signaling and is required for stress tolerance and sexual sporulation in the yeast Saccharomyces cerevisiae. However, in filamentous fungi that reproduce asexually via conidiation, the physiological function of Rim15p homologs has not been extensively analyzed. Here, we functionally characterized the protein homolog of Rim15p in the filamentous fungus Aspergillus oryzae, by deleting and overexpressing the corresponding Aorim15 gene and examining the role of this protein in stress tolerance and development. Deletion of Aorim15 resulted in an increase in the sensitivity of conidia to oxidative and heat stresses, whereas conidia of the Aorim15 overexpressing strain were more resistant to these stresses. These results indicated that AoRim15 functions in stress tolerance, similar to S. cerevisiae Rim15p. Phenotypic analysis revealed that conidiation was markedly reduced by overexpression of Aorim15 in A. oryzae, and was completely abolished in the deletion strain. In addition, the formation of sclerotia, which is another type of developmental structure in filamentous fungi, was decreased by the deletion of Aorim15, whereas Aorim15 overexpression increased the number of sclerotia. These results indicated that AoRim15 is a positive regulator of sclerotia formation and that overexpression of AoRim15 shifts the developmental balance from conidiation towards sclerotia formation. Collectively, we demonstrated that AoRim15 is involved in the stress tolerance of conidia and differentially regulates between the two developmental fates of conidiation and sclerotia formation.

Cooperative role of calnexin and TigA in Aspergillus oryzae glycoprotein folding.

Calnexin (CNX), known as a lectin chaperone located in the endoplasmic reticulum (ER), specifically recognizes G1M9GN2-proteins and facilitates their proper folding with the assistance of ERp57 in mammalian cells. However, it has been left unidentified how CNX works in Aspergillus oryzae, which is a filamentous fungus widely exploited in biotechnology. In this study, we found that a protein disulfide isomerase homolog TigA can bind with A. oryzae CNX (AoCNX), which was revealed to specifically recognize monoglucosylated glycans, similarly to CNX derived from other species, and accelerate the folding of G1M9GN2-ribonuclease (RNase) in vitro. For refolding experiments, a homogeneous monoglucosylated high-mannose-type glycoprotein G1M9GN2-RNase was chemoenzymatically synthesized from G1M9GN-oxazoline and GN-RNase. Denatured G1M9GN2-RNase was refolded with highest efficiency in the presence of both soluble form of AoCNX and TigA. TigA contains two thioredoxin domains with CGHC motif, mutation analysis of which revealed that the one in N-terminal regions is involved in binding to AoCNX, while the other in catalyzing protein refolding. The results suggested that in glycoprotein folding process of A. oryzae, TigA plays a similar role as ERp57 in mammalian cells, as a partner protein of AoCNX.

Functional analysis of AoAtg11 in selective autophagy in the filamentous fungus Aspergillus oryzae.

Autophagy is a highly conserved cellular degradation process in eukaryotes and consists of both non-selective and selective types. Selective autophagic processes include pexophagy, mitophagy, and the cytoplasm-to-vacuole targeting (Cvt) pathway of yeast, in which particular vacuolar proteins, such as aminopeptidase I (Ape1), are selectively transported to vacuoles. Although selective autophagy has been mainly studied in the yeasts Saccharomyces cerevisiae and Pichia pastoris, there is evidence for selective autophagy in filamentous fungi; however, the details are poorly understood. In S. cerevisiae, Atg11 is a selective autophagy-specific protein that recognizes and transports substrates to the pre-autophagosomal structure (PAS). Here, we first identified an ATG11 homologue in the filamentous fungus Aspergillus oryzae and analyzed the localization of the corresponding protein, designated AoAtg11, fused to enhanced green fluorescent protein (EGFP). Imaging analysis revealed that AoAtg11-EGFP was localized to PAS-like structures. We next constructed an Aoatg11 disruptant of A. oryzae and showed that AoAtg11 is involved in pexophagy and mitophagy. In addition, AoAtg11 was found to be dispensable for non-selective autophagy and for transporting AoApe1 to vacuoles. Taken together, these results suggest that AoAtg11 is a selective autophagy-specific protein in A. oryzae, and has distinct molecular functions from that of S. cerevisiae Atg11.

Vesicle trafficking, organelle functions, and unconventional secretion in fungal physiology and pathogenicity.

Specific localization of appropriate sets of proteins and lipids is central to functions and integrity of organelles, which in turn underlie cellular activities of eukaryotes. Vesicle trafficking is a conserved mechanism of intracellular transport, which ensures such a specific localization to a subset of organelles. In this review article, we summarize recent advances in our understanding of how vesicle trafficking and related organelles support physiology and pathogenicity of filamentous fungi. Examples include a link between Golgi organization and polarity maintenance during hyphal tip growth, a new role of early endosomes in transport of translational machinery, involvement of endosomal/vacuolar compartments in secondary metabolite synthesis, and functions of vacuoles and autophagy in fungal development, nutrient recycling and allocation. Accumulating evidence showing the importance of unconventional secretion in fungal pathogenicity is also summarized.

Enhanced production of bovine chymosin by autophagy deficiency in the filamentous fungus Aspergillus oryzae.

Aspergillus oryzae has been utilized as a host for heterologous protein production because of its high protein secretory capacity and food-safety properties. However, A. oryzae often produces lower-than-expected yields of target heterologous proteins due to various underlying mechanisms, including degradation processes such as autophagy, which may be a significant bottleneck for protein production. In the present study, we examined the production of heterologous protein in several autophagy (Aoatg) gene disruptants of A. oryzae. We transformed A. oryzae gene disruptants of Aoatg1, Aoatg13, Aoatg4, Aoatg8, or Aoatg15, with a bovine chymosin (CHY) expression construct and found that the production levels of CHY increased up to three fold compared to the control strain. Notably, however, conidia formation by the Aoatg gene disruptants was significantly reduced. As large amounts of conidia are necessary for inoculating large-scale cultures, we also constructed Aoatg gene-conditional expression strains in which the promoter region of the Aoatg gene was replaced with the thiamine-controllable thiA promoter. Conidiation by the resultant transformants was clearly enhanced in the absence of thiamine, while autophagy remained repressed in the presence of thiamine. Moreover, these transformants displayed increased CHY productivity, which was comparable to that of the Aoatg gene disruptants. Consequently, we succeeded in the construction of A. oryzae strains capable of producing high levels of CHY due to defects in autophagy. Our finding suggests that the conditional regulation of autophagy is an effective method for increasing heterologous protein production in A. oryzae.

Functional analysis of Abp1p-interacting proteins involved in endocytosis of the MCC component in Aspergillus oryzae.

We have investigated the functions of three endocytosis-related proteins in the filamentous fungus Aspergillus oryzae. Yeast two-hybrid screening using the endocytic marker protein AoAbp1 (A.oryzae homolog of Saccharomyces cerevisiae Abp1p) as a bait identified four interacting proteins named Aip (AoAbp1 interacting proteins). In mature hyphae, EGFP (enhanced green fluorescent protein) fused to Aips colocalized with AoAbp1 at the hyphal tip region and the plasma membrane, suggesting that Aips function in endocytosis. aipA is a putative AAA ATPase and its function has been dissected (Higuchi et al., 2011). aipB, the homolog of A. nidulans myoA, encodes an essential class I myosin and its conditional mutant showed a germination defect. aipC and aipD do not contain any recognizable domains except some proline-rich regions which may interact with two SH3 (Src homology 3) domains of AoAbp1. Neither aipC nor aipD disruptants showed any defects in their growth, but the aipC disruptant formed less conidia compared with the control strain. In addition, the aipC disruptant was resistant to the triazole antifungal drugs that inhibit ergosterol biosynthesis. Although no aip disruptants showed any defects in the uptake of the fluorescent dye FM4-64, the endocytosis of the arginine permease AoCan1, one of the MCC (membrane compartment of Can1p) components, was delayed in both aipC and aipD disruptants. In A. oryzae, AoCan1 localized mainly at the plasma membrane in the basal region of hyphae, suggesting that different endocytic mechanisms exist in apical and basal regions of highly polarized cells.

Functional analysis of Aoatg1 and detection of the Cvt pathway in Aspergillus oryzae.

Autophagy is a degradation system in which cellular components are digested via vacuoles/lysosomes. In the budding yeast Saccharomyces cerevisiae, the induction of autophagy results from inactivation of target of rapamycin complex 1 (TORC1), promoting formation of the serine/threonine kinase Atg1, which is one of the key autophagy-related (Atg) proteins required for both nonselective and selective autophagy such as the cytoplasm-to-vacuole targeting (Cvt) pathway. Here, to understand the induction mechanism of autophagy in filamentous fungi, we first identified the ATG1 homolog Aoatg1 in Aspergillus oryzae and then analyzed the localization of an enhanced green fluorescent protein (EGFP)-AoAtg1 fusion protein. AoAtg1-EGFP localized to pre-autophagosomal structure (PAS)-like structures, similar to Atg1 localization in S. cerevisiae. The function of AoAtg1 was evaluated by constructing an Aoatg1 disruptant, ΔAoatg1. Conidiation and development of aerial hyphae were scarcely observed in ΔAoatg1. Moreover, autophagy in the disruptant was examined by observation of the localization of EGFP-AoAtg8 and AoApe1-EGFP, with the results indicating that AoAtg1 is essential for nonselective autophagy and the Cvt pathway. Furthermore, we demonstrated that the overexpression of Aoatg1 results in decreased conidiation and the excessive development of aerial hyphae and sclerotia. Taken together, our findings provide evidence for the existence of the Cvt pathway in A. oryzae.

Autophagy delivers misfolded secretory proteins accumulated in endoplasmic reticulum to vacuoles in the filamentous fungus Aspergillus oryzae.

Autophagy is a conserved intracellular degradation process of eukaryotic cells. In filamentous fungi, although autophagy has been reported to have multiple physiological roles, it is not clear whether autophagy is involved in the degradation of misfolded proteins. Here, we investigated the role of autophagy in the degradation of misfolded secretory proteins accumulated in endoplasmic reticulum (ER) in the filamentous fungus Aspergillus oryzae. In late-phase cultures, a disulfide bond-deleted mutant of the secretory protein α-amylase AmyB fused with mDsRed that had accumulated in the ER was subsequently delivered to vacuoles, whereas wild-type AmyB-mDsRed was predominantly located at cell walls and septa. To examine the involvement of autophagy in the delivery of mutant AmyB to vacuoles, mutant AmyB-EGFP was expressed in an A. oryzae autophagy-deficient strain (ΔAoatg8). Microscopic examination revealed that the protein delivery to vacuoles did not occur in the absence of autophagic activity, with mutant AmyB-mDsRed forming large spherical structures surrounded by ER membrane. Hence, we conclude that autophagy is responsible for the delivery of misfolded secretory proteins accumulated in the ER to vacuoles for degradation during late-growth phase in A. oryzae. This is the first study to provide evidence that autophagy plays a role in the degradation of misfolded secretory proteins in filamentous fungi.

Analysis of autophagy in Aspergillus oryzae by disruption of Aoatg13, Aoatg4, and Aoatg15 genes.

Autophagy is a degradation system in which cellular components are digested via vacuoles/lysosomes, and involved in differentiation in addition to helping cells to survive starvation. The autophagic process is composed of several steps: induction of autophagy, formation of autophagosomes, transportation to vacuoles, and degradation of autophagic bodies. To further understand autophagy in the filamentous fungus Aspergillus oryzae, we first constructed A. oryzae mutants defective for the Aoatg13, Aoatg4, and Aoatg15 genes and examined the resulting phenotypes. The ΔAoatg13 mutant developed conidiophores and conidia, although the number of conidia was decreased compared with the wild-type strain, while conidiation in the ΔAoatg4 and ΔAoatg15 mutants was not detected. The ΔAoatg15 mutants displayed a marked reduction of development of aerial hyphae. Moreover, autophagy in these mutants was examined by observation of the behavior of enhanced green fluorescent protein (EGFP)-AoAtg8. In the ΔAoatg13 mutant, the slight accumulation of EGFP-AoAtg8 in vacuoles, preautophagosomal structures (PAS), and autophagosomes was observed, whereas only PAS-like structures were detected in the ΔAoatg4 mutant. In the ΔAoatg15 mutant, autophagic bodies accumulated in vacuoles, suggesting that the uptake process proceeded. We therefore propose that the level of autophagy is closely correlated with the degree of differentiation in A. oryzae.