Functional divergence of the duplicated AtKIN14a and AtKIN14b genes: critical roles in Arabidopsis meiosis and gametophyte development

Gene duplication is important for gene family evolution, allowing for functional divergence and innovation. In flowering plants, duplicated genes are widely observed, and functional redundancy of closely related duplicates has been reported, but few cases of functional divergence of close duplicates have been described. Here, we show that the Arabidopsis AtKIN14a and AtKIN14b genes encoding highly similar kinesins are two of the most closely related Arabidopsis paralogs, which were formed by a duplication event that occurred after the split of Arabidopsis and poplar. In addition, AtKIN14a and AtKIN14b exhibit varying degrees of coding sequence divergence. Further genetic studies of plants carrying atkin14a and/or atkin14b mutations indicate that, although these two genes have similar functions, there is clear evidence for functional divergence. Although both genes are important for male and female meiosis, AtKIN14a plays a more critical role in male meiosis than AtKIN14b . Moreover, either one of these two genes is necessary and sufficient for gametophyte development, indicating that they are redundant for this function. Therefore, AtKIN14a and AtKIN14b together play important roles in controlling plant reproductive development. Our results suggest that the AtKIN14a and AtKIN14b genes have retained similar functions in gametophyte development and female meiosis, but have evolved partially distinct functions in male meiosis, with AtKIN14a playing a more substantive role.     

The yeast LATS/Ndr kinase Cbk1 regulates growth via Golgi-dependent glycosylation and secretion

Saccharomyces cerevisiae Cbk1 is a LATS/Ndr protein kinase and a downstream component of the regulation of Ace2 and morphogenesis (RAM) signaling network. Cbk1 and the RAM network are required for cellular morphogenesis, cell separation, and maintenance of cell integrity. Here, we examine the phenotypes of conditional cbk1 mutants to determine the essential function of Cbk1. Cbk1 inhibition severely disrupts growth and protein secretion, and triggers the Swe1-dependent morphogenesis checkpoint. Cbk1 inhibition also delays the polarity establishment of the exocytosis regulators Rab-GTPase Sec4 and its exchange factor Sec2, but it does not interfere with actin polarity establishment. Cbk1 binds to and phosphorylates Sec2, suggesting that it regulates Sec4-dependent exocytosis. Intriguingly, Cbk1 inhibition causes a >30% decrease in post-Golgi vesicle accumulation in late secretion mutants, indicating that Cbk1 also functions upstream of Sec2-Sec4, perhaps at the level of the Golgi. In agreement, conditional cbk1 mutants mislocalize the cis-Golgi mannosyltransferase Och1, are hypersensitive to the aminoglycoside hygromycin B, and exhibit diminished invertase and Sim1 glycosylation. Significantly, the conditional lethality and hygromycin B sensitivity of cbk1 mutants are suppressed by moderate overexpression of several Golgi mannosyltransferases. These data suggest that an important function for Cbk1 and the RAM signaling network is to regulate growth and secretion via Golgi and Sec2/Sec4-dependent processes.     

Rho of Plant GTPase Signaling Regulates the Behavior of Arabidopsis Kinesin-13A to Establish Secondary Cell Wall Patterns

Plant cortical microtubule arrays determine the cell wall deposition pattern and proper cell shape and function. Although various microtubule-associated proteins regulate the cortical microtubule array, the mechanisms underlying marked rearrangement of cortical microtubules during xylem differentiation are not fully understood. Here, we show that local Rho of Plant (ROP) GTPase signaling targets an Arabidopsis thaliana kinesin-13 protein, Kinesin-13A, to cortical microtubules to establish distinct patterns of secondary cell wall formation in xylem cells. Kinesin-13A was preferentially localized with cortical microtubules in secondary cell wall pits, areas where cortical microtubules are depolymerized to prevent cell wall deposition. This localization of Kinesin-13A required the presence of the activated ROP GTPase, MICROTUBULE DEPLETION DOMAIN1 (MIDD1) protein, and cortical microtubules. Knockdown of Kinesin-13A resulted in the formation of smaller secondary wall pits, while overexpression of Kinesin-13A enlarged their surface area. Kinesin-13A alone could depolymerize microtubules in vitro; however, both MIDD1 and Kinesin-13A were required for the depolymerization of cortical microtubules in vivo. These results indicate that Kinesin-13A regulates the formation of secondary wall pits by promoting cortical microtubule depolymerization via the ROP-MIDD1 pathway.     

Syntaxin of plants31 (SYP31) and SYP32 is essential for Golgi morphology maintenance and pollen development

Pollen development is a key process for the sexual reproduction of angiosperms. The Golgi plays a critical role in pollen development via the synthesis and transport of cell wall materials. However, little is known about the molecular mechanisms underlying the maintenance of Golgi integrity in plants. In Arabidopsis thaliana, syntaxin of plants (SYP) 3 family proteins SYP31 and SYP32 are the only two Golgi-localized Qa-soluble N-ethylmaleimide sensitive factor attachment protein receptors (SNAREs) with unknown endogenous functions. Here, we demonstrate the roles of SYP31 and SYP32 in modulating Golgi morphology and pollen development. Two independent lines of syp31/+ syp32/+ double mutants were male gametophytic lethal; the zero transmission rate of syp31 syp32 mutations was restored to largely normal levels by pSYP32:SYP32 but not pSYP32:SYP31 transgenes, indicating their functional differences in pollen development. The initial arrest of syp31 syp32 pollen occurred during the transition from the microspore to the bicellular stage, where cell plate formation in pollen mitosis I (PMI) and deposition of intine were abnormal. In syp31 syp32 pollen, the number and length of Golgi cisterna were significantly reduced, accompanied by many surrounding vesicles, which could be largely attributed to defects in anterograde and retrograde trafficking routes. SYP31 and SYP32 directly interacted with COG3, a subunit of the conserved oligomeric Golgi (COG) complex and were responsible for its Golgi localization, providing an underlying mechanism for SYP31/32 function in intra-Golgi trafficking. We propose that SYP31 and SYP32 play partially redundant roles in pollen development by modulating protein trafficking and Golgi structure.     

Genetic Relationship Between Angustifolia3 and Extra-Small Sisters Highlights Novel Mechanisms Controlling Leaf Size

Coordination between cell proliferation and cell expansion is pivotal in leaf size determination. A group of mutants that are impaired in cell proliferation such as the angustifolia3 (an3) has provided a clue to understanding how these cellular processes are coordinated. In these mutants, impaired cell proliferation is accompanied by enhanced cell enlargement. We propose to call this phenomenon “compensated cell enlargement.” Previously, we isolated ten extra-small sisters (xs) mutants that are specifically impaired in post-mitotic cell expansion and found that several xs mutations are able to suppress compensated cell enlargement in an3. Thus, the enhanced cell expansion observed in an3 results from the hyperactivation of post-mitotic cell expansion involving specific members of the XS gene family. These results suggested that cell proliferation process(es) and post-mitotic cell expansion process(es) are somehow linked in an as yet unknown fashion in leaf primordia. In this addendum, we propose possible models for the linking mechanisms that coordinate AN3-dependent cell proliferation and XS-dependent cell expansion in leaf development.Key Words: Arabidopsis, cell expansion, cell proliferation, extra-small sisters (xs), angustifolia3 (an3), compensated cell enlargement, leaf, organ size controlMature leaf size is determined by the final number and size of cells within a leaf. Thus, the spatial and temporal regulation of cell proliferation and cell expansion plays pivotal roles in establishing developmentally programmed leaf size in a reproducible fashion. During leaf development, cell proliferation is maintained in the basal part of the leaf primordium and terminates basipetally.^1,2 Cells that exit cell cycling undergo differentiation and expand enormously.¹ Although many studies have revealed the molecular mechanisms underlying the above processes, the coordination of cell proliferation and cell expansion in the context of organogenesis is not yet understood.In recent years, an interesting phenomenon has been reported in leaves of several mutants or transgenic plants with impaired cell proliferation. These mutants not only have a defect in cell proliferation, but have larger cells than does the wild type, suggesting that the cell proliferation process interacts with the cell expansion process during leaf organogenesis.^3–8 This phenomenon, called “compensation,” has highlighted the existence of a coordination system between cell proliferation and cell expansion in leaf development.^9–13Conceptually, this compensation can be dissected into two processes: the induction process involves the reduction of cell proliferation and the response process directs the enhancement of cell expansion and “compensated cell enlargement.” Recently, we showed that, in the typical compensation-exhibiting mutant angustifolia3 (an3), the expansion of post-mitotic, but not mitotic, cells is specifically enhanced.⁸ Thus, the induction and the response processes should take place separately in proliferating and differentiating cells, respectively. To dissect compensation genetically, with an emphasis on the response process, we isolated 10 mutants, named extra-small sisters (xs), that are specifically impaired in post-mitotic cell expansion.^14–16 We classified xs mutants into three classes based on the effect of each xs mutation on compensated cell enlargement, using an3 as a representative of compensation-exhibiting mutants.¹⁴ As expected, a group of xs mutants (xs1, xs2, xs4 and xs5) completely suppressed compensated cell enlargement in an3 mutants (named the “small-cell” class), whereas the other two classes had either no suppressive or additive effects on cell enlargement.¹⁴ This finding demonstrated that these XS genes act downstream of cell expansion pathways that are regulated by compensation and triggered in an3. How is this relationship established in the context of leaf organogenesis? When considering the above result, one might speculate that, in addition to a promotive role in cell proliferation, AN3 has a role in cell expansion post-mitotic cells. However, AN3 is hardly expressed in differentiating cells, and the overexpression of AN3 has no effects on post-mitotic cell expansion,⁶ suggesting that this possibility is unlikely. Taken together, these results indicate that the AN3-dependent cell proliferation pathway is somehow linked by an intermediary process to post-mitotic cell expansion pathway(s) involving the small-cell class XS.Based on these data, we propose two possible scenarios for the intermediary process, categorized in terms of cell autonomy (Fig. 1). In the non-cell-autonomous case, proliferating cells located in the basal region of the developing leaf may regulate the expansion of differentiating cells located in the upper region of the leaf via unknown cell-cell communications (Fig. 1A and B). In the cell-autonomous case, the activity involved in cell proliferation may be memorized in each cell, and, depending on this memory, each post-mitotic cell determines its own final size (Fig. 1C). Whatever the mechanism, we can assume that regulatory signal(s) would be affected by cell proliferation. Irrespective of cell autonomy, this putative signal acts either positively or negatively on cell expansion. When cell proliferation is impaired by the an3 mutation, the strength of the negative signal would be reduced and become insufficient to prevent differentiating cells from excessive cell expansion. Conversely, if this signal plays a positive role in cell expansion, the signal may be insufficient to positively control cell expansion in the wild type. However, when the cell number is significantly reduced by the an3 mutation, this positive signal(s) would hyperactivate cell expansion pathways. Further analyses of the factors involved in the intermediary process should provide an important insight into signaling mechanisms that control leaf size.Open in a separate windowFigure 1Proposed models for the leaf size control inferred from the analysis of compensated cell enlargement. (A and B) Non-cell-autonomous model. Cells located in the basal part of a leaf primordium would produce signal(s) that inhibit (A) or promote (B) cell expansion of post-mitotic cells present in the apical part of the leaf primordium. (A) If a significant reduction in cell number occurs in an3, the strength of the inhibitory signal would be reduced and cell expansion would be de-repressed, resulting in the abnormal enlargement of leaf cells. (B) When we assume a cell expansion-promoting signal(s), its strength may be insufficient to enhance cell expansion in the wild type. When a significant reduction in cell number occurs in an3, the promoting signal(s) would increase sufficiently to cause compensation. (C) “Cell memory” model. A specific signal reflecting cell proliferation activity in proliferating cells is retained during cell differentiation and affects the magnitude of cell expansion. Inhibitory and stimulatory signal examples are shown in the upper and lower panels, respectively. The relationship between the strength of the signals and the induction of compensation is the same as that described in the non-cell-autonomous model.Before our reports on the actions of an3, fugu and xs mutants,^8,14 compensated cell enlargement was considered to be caused by the uncoupling of cell division and growth. Now, this possibility is clearly ruled out. Cell proliferation and post-mitotic cell expansion are the most basic cellular processes and are each supported by different regulatory networks. The putative signaling systems discussed here provide a new perspective on how developmental programs integrate these networks into a super-network to control organ size.     

Mutations of the a Mating-Type Gene in NEUROSPORA CRASSA

In Neurospora, the mating-type locus controls both mating ( A + a is fertile) and heterokaryosis (A + a is incompatible). The two alleles appear stable: no novel fertility reactions have ever been reported, and attempts to separate fertility and heterokaryon incompatibility functions by recombination have been unsuccessful. In the present approach the locus was studied through a mutational analysis of heterokaryon incompatibility function. A selection system was used that detects vigorous (A + a) heterokaryotic colonies against a background of inhibited growth. Twenty-five mutants of an a strain were produced following mutagenic treatment with UV and NG: 15 were viable as homokaryons and 10 were not. All but one were infertile, but most showed an abortive mating reaction involving the production of barren, well-developed perithecia with A and (surprisingly) a testers. None of the mutants complement each other to restore fertility. Seven mutants have been mapped to the mating-type locus region of chromosome 1. Restoration of fertility was used to detect revertants, and these were found in five out of the eight mutants tested. (A dose response was observed). In four cases incompatibility was fully restored and in one case it was not.—The results suggest two positive actions of the locus when in heterozygous (A/a) combination (the stimulation of some stage of ascus production and the inhibition of vegetative heterokaryosis), and one positive action in homozygous combination (the production of a perithecial inhibitor).     

Mutations in SNF1 complex genes affect yeast cell wall strength

The trimeric SNF1 complex from Saccharomyces cerevisiae, a homolog of mammalian AMP-activated kinase, has been primarily implicated in signaling for the utilization of alternative carbon sources to glucose. We here find that snf1 deletion mutants are hypersensitive to different cell wall stresses, such as the presence of Calcofluor white, Congo red, Zymolyase or the glucan synthase inhibitor Caspofungin in the growth medium. They also have a thinner cell wall. Caspofungin treatment triggers the phosphorylation of the catalytic Snf1 kinase subunit at Thr210 and removal of this phosphorylation site by mutagenesis (Snf1-T210A) abolishes the function of Snf1 in cell wall integrity. Deletion of the PFK1 gene encoding the α-subunit of the heterooctameric yeast phosphofructokinase suppresses the cell wall phenotypes of a snf1 deletion, which suggests a compensatory effect of central carbohydrate metabolism. Epistasis analyses with mutants in cell wall integrity (CWI) signaling confirm that the SNF1 complex and the CWI pathway independently affect yeast cell integrity.     

Pattern Recognition Receptors Require N-Glycosylation to Mediate Plant Immunity

N-Glycans attached to the ectodomains of plasma membrane pattern recognition receptors constitute likely initial contact sites between plant cells and invading pathogens. To assess the role of N-glycans in receptor-mediated immune responses, we investigated the functionality of Arabidopsis receptor kinases EFR and FLS2, sensing bacterial translation elongation factor Tu (elf18) and flagellin (flg22), respectively, in N-glycosylation mutants. As revealed by binding and responses to elf18 or flg22, both receptors tolerated immature N-glycans induced by mutations in various Golgi modification steps. EFR was specifically impaired by loss-of-function mutations in STT3A, a subunit of the endoplasmic reticulum resident oligosaccharyltransferase complex. FLS2 tolerated mild underglycosylation occurring in stt3a but was sensitive to severe underglycosylation induced by tunicamycin treatment. EFR accumulation was significantly reduced when synthesized without N-glycans but to lesser extent when underglycosylated in stt3a or mutated in single amino acid positions. Interestingly, EFR^N143Q lacking a single conserved N-glycosylation site from the EFR ectodomain accumulated to reduced levels and lost the ability to bind its ligand and to mediate elf18-elicited oxidative burst. However, EFR-YFP protein localization and peptide:N-glycosidase F digestion assays support that both EFR produced in stt3a and EFR^N143Q in wild type cells correctly targeted to the plasma membrane via the Golgi apparatus. These results indicate that a single N-glycan plays a critical role for receptor abundance and ligand recognition during plant-pathogen interactions at the cell surface.     

Biosynthesis of the Fungal Cell Wall Polysaccharide Galactomannan Requires Intraluminal GDP-mannose

Fungal cell walls frequently contain a polymer of mannose and galactose called galactomannan. In the pathogenic filamentous fungus Aspergillus fumigatus, this polysaccharide is made of a linear mannan backbone with side chains of galactofuran and is anchored to the plasma membrane via a glycosylphosphatidylinositol or is covalently linked to the cell wall. To date, the biosynthesis and significance of this polysaccharide are unknown. The present data demonstrate that deletion of the Golgi UDP-galactofuranose transporter GlfB or the GDP-mannose transporter GmtA leads to the absence of galactofuran or galactomannan, respectively. This indicates that the biosynthesis of galactomannan probably occurs in the lumen of the Golgi apparatus and thus contrasts with the biosynthesis of other fungal cell wall polysaccharides studied to date that takes place at the plasma membrane. Transglycosylation of galactomannan from the membrane to the cell wall is hypothesized because both the cell wall-bound and membrane-bound polysaccharide forms are affected in the generated mutants. Considering the severe growth defect of the A. fumigatus GmtA-deficient mutant, proving this paradigm might provide new targets for antifungal therapy.     

Cooperative Regulation of Cellular Proliferation by Intercellular Diffusion

A theoretical model for the cooperative control of cellular kinetics is investigated. A critical substance A is produced by the cells whose concentration in a given cell determines whether that cell can divide. The substance A can leak out of the cells into the surrounding medium as well as be reabsorbed by the cells. This feature then implies communication between the cells since all concentrations will be functions of the population density. The substance A also has a lifetime, i.e. decays, for example, by denaturation. This system can be described by three coupled nonlinear differential equations which can be solved analytically in certain limiting cases and can, of course, be studied in detail by computer techniques. Our investigations have shown that (a) there is a critical initial cell population density below which cell proliferation will not occur, (b) cell proliferation can be stimulated by supplying substance A to the medium and there is a critical initial concentration in the medium for initiating proliferation when the cell population density is subcritical, and (c) a well-defined induction period prior to exponential growth may exist whose length depends on the system parameters and initial conditions.     

Identification of a Site in Sar1 Involved in the Interaction with the Cytoplasmic Tail of Glycolipid Glycosyltransferases

Glycolipid glycosyltransferases (GGT) are transported from the endoplasmic reticulum (ER) to the Golgi, their site of residence, via COPII vesicles. An interaction of a (R/K)X(R/K) motif at their cytoplasmic tail (CT) with Sar1 is critical for the selective concentration in the transport vesicles. In this work using computational docking, we identify three putative binding pockets in Sar1 (sites A, B, and C) involved in the interaction with the (R/K)X(R/K) motif. Sar1 mutants with alanine replacement of amino acids in site A were tested in vitro and in cells. In vitro, mutant versions showed a reduced ability to bind immobilized peptides with the CT sequence of GalT2. In cells, Sar1 mutants (Sar1^D198A) specifically affect the exiting of GGT from the ER, resulting in an ER/Golgi concentration ratio favoring the ER. Neither the typical Golgi localization of GM130 nor the exiting and transport of the G protein of the vesicular stomatitis virus were affected. The protein kinase inhibitor H89 produced accumulation of Sec23, Sar1, and GalT2 at the ER exit sites; Sar1^D189A also accumulated at these sites, but in this case GalT2 remained disperse along ER membranes. The results indicate that amino acids in site A of Sar1 are involved in the interaction with the CT of GGT for concentration at ER exiting sites.     

THESEUS 1, FERONIA and relatives: a family of cell wall-sensing receptor kinases?

The plant cell wall provides form and integrity to the cell as well as a dynamic interface between a cell and its environment. Therefore mechanisms capable of policing changes in the cell wall, signaling cellular responses including those that would feedback regulate cell wall properties are expected to play important roles in facilitating growth and ensuring survival. Discoveries in the last few years that the Arabidopsis THESEUS 1 receptor-like kinase (RLK) may function as a sensor for cell wall defects to regulate growth and that its relatives FERONIA and ANXURs regulate pollen tube integrity imply strongly that they play key roles in cell wall-related processes. Furthermore, FERONIA acts as a cell surface regulator for RAC/ROP GTPases and activates production of reactive oxygen species which are, respectively, important molecular switches and mediators for diverse processes. These findings position the THESEUS 1/FERONIA family RLKs as surface regulators and potential cell wall sensors capable of broadly and profoundly impacting cellular pathways in response to diverse signals.     

Role of the Guanine Nucleotide Exchange Factor Rom2 in Cell Wall Integrity Maintenance of Aspergillus fumigatus

Aspergillus fumigatus is a mold and the causal agent of invasive aspergillosis, a systemic disease with high lethality. Recently, we identified and functionally characterized three stress sensors implicated in the cell wall integrity (CWI) signaling of this pathogen, namely, Wsc1, Wsc3, and MidA. Here, we functionally characterize Rom2, a guanine nucleotide exchange factor with essential function for the cell wall integrity of A. fumigatus. A conditional rom2 mutant has severe growth defects under repressive conditions and incorporates all phenotypes of the three cell wall integrity sensor mutants, e.g., the echinocandin sensitivity of the Δwsc1 mutant and the Congo red, calcofluor white, and heat sensitivity of the ΔmidA mutant. Rom2 interacts with Rho1 and shows a similar intracellular distribution focused at the hyphal tips. Our results place Rom2 between the cell surface stress sensors Wsc1, Wsc3, MidA, and Rho1 and their downstream effector mitogen-activated protein (MAP) kinase module Bck1-Mkk2-MpkA.     

Low cytoplasmic pH reduces ER-Golgi trafficking and induces disassembly of the Golgi apparatus

The Golgi apparatus was dramatically disassembled when cells were incubated in a low pH medium. The cis-Golgi disassembled quickly, extended tubules and spread to the periphery of cells within 30 min. In contrast, medial- and trans-Golgi were fragmented in significantly larger structures of smaller numbers at a slower rate and remained largely in structures distinct from the cis-Golgi. Electron microscopy revealed the complete disassembly of the Golgi stack in low pH treated cells. The effect of low pH was reversible; the Golgi apparatus reassembled to form a normal ribbon-like structure within 1–2 h after the addition of a control medium. The anterograde ER to Golgi transport and retrograde Golgi to ER transport were both reduced under low pH. Phospholipase A₂ inhibitors (ONO, BEL) effectively suppressed the Golgi disassembly, suggesting that the phospholipase A₂ was involved in the Golgi disassembly. Over-expression of Rab1, 2, 30, 33 and 41 also suppressed the Golgi disassembly under low pH, suggesting that they have protective role against Golgi disassembly. Low pH treatment reduced cytoplasmic pH, but not the luminal pH of the Golgi apparatus, strongly suggesting that reduction of the cytoplasmic pH triggered the Golgi disassembly. Because a lower cytoplasmic pH is induced in physiological or pathological conditions, disassembly of the Golgi apparatus and reduction of vesicular transport through the Golgi apparatus may play important roles in cell physiology and pathology. Furthermore, our findings indicated that low pH treatment can serve as an important tool to analyze the molecular mechanisms that support the structure and function of the Golgi apparatus.     

Rapid depletion of mutant eukaryotic initiation factor 5A at restrictive temperature reveals connections to actin cytoskeleton and cell cycle progression

Eukaryotic initiation factor 5A (eIF5A) is the only protein in nature that contains hypusine, an unusual amino acid derived from the modification of lysine by spermidine. Two genes, TIF51A and TIF51B, encode eIF5A in the yeast Saccharomyces cerevisiae. In an effort to understand the structure–function relationship of eIF5A, we have generated yeast mutants by introducing plasmid-borne tif51A into a double null strain where both TIF51A and TIF51B have been disrupted. One of the mutants, tsL102A strain (tif51A L102A tif51aΔ tif51bΔ) exhibits a strong temperature-sensitive growth phenotype. At the restrictive temperature, tsL102A strain also exhibits a cell shape change, a lack of volume change in response to temperature increase and becomes more sensitive to ethanol, a hallmark of defects in the PKC/WSC cell wall integrity pathway. In addition, a striking change in actin dynamics and a complete cell cycle arrest at G1 phase occur in tsL102A cells at restrictive temperature. The temperature-sensitivity of tsL102A strain is due to a rapid loss of mutant eIF5A with the half-life reduced from 6 h at permissive temperature to 20 min at restrictive temperature. Phenylmethyl sulfonylfluoride (PMSF), an irreversible inhibitor of serine protease, inhibited the degradation of mutant eIF5A and suppressed the temperature-sensitive growth arrest. Sorbitol, an osmotic stabilizer that complement defects in PKC/WSC pathways, stabilizes the mutant eIF5A and suppresses all the observed temperature-sensitive phenotypes.     

Golgi-localized UDP-glucose transporter is required for cell wall integrity in rice

Cell wall-related nucleotide sugar transporters (NSTs) theoretically supply the cytosolic nucleotide sugars for glycosyltransferases (GTs) to carry out ploysaccharide synthesis and modification in the Golgi apparatus. However, the regulation of cell wall synthesis by NSTs remains undescribed. Recently, we have reported the functional characterization of Oryza sativa nucleotide sugar transport (Osnst1) mutant and its corresponding gene. OsNST1/BC14 is localized in the Golgi apparatus and transports UDP-glucose. This mutant provides us with a unique opportunity for evaluation of its broad impacts on cell wall structure and components. We previously examined cell wall composition of bc14 and wild type plants. Here, the spatial distribution of these cell wall alterations was analyzed by immunolabeling approach. Analysis of the sugar yield in different cell wall fractions indicated that this mutation improves the extractability of cell wall components. Field emission scanning electron microscopy further showed that the orientation of microfibrils in bc14 is irregular when compared to that in wild type. Therefore, this UDP-glucose transporter, making substrates available for polysaccharide biosynthesis, plays a critical role in maintaining cell wall integrity.Key words: UDP-glucose transporter, Golgi apparatus, cell wall polysaccharides, xylan, riceNucleotide sugars mainly generated in cytosol are the substrates for the synthesis of cell wall polysaccharides. Supply of nucleotide sugars is thus a key level for regulation of cell wall components and structure. Mutation in MUR1, an isoform of GDP-D-mannose-4,6-dehydratase, causes reduced amount of GDP-fucose and abnormal xyloglucan structure.^1,2 Disturbance of UDP-rhamnose synthesis via the mutation in RHM2/MUM4 decreases the rhamnogalacturonan I contents in Arabidopsis seeds. Cellulose synthase catalytic subunits (CESAs) generally use cytosolic UDP-glucoses to synthesize cellulose on the plasma membrane. UDP-glucose can be produced either via the catalysis of sucrose by sucrose synthase (SuSy) or through the phosphorylation of glucose-1-phosphate by UDP-glucose pyrophosphorylase (UGPase).³ Suppression of SuSy function in cotton inhibited fiber initiation and elongation.⁴ For the synthesis of noncellulosic polysaccharides occurring inside the Golgi lumen, the cytosolic nucleotide sugars should be translocated inwards by Golgi nucleotide sugar transporters (NSTs).⁵ However, this hypothesis remains to be confirmed, although transport activities have been identified in some plant NSTs.^6–10 Altering the precursor supply may also affect the overall carbon allocation in plants. It is reasonable that substrate regulation often causes pleiotropic effects on cell wall biosynthesis and plant growth. Without genetic resources or mutants on cell wall related NST, the exact evaluation of NSTs'' impacts on cell wall structure and composition is largely delayed. Until recently, we identified a Golgi-localized transporter OsNST1 mutant in rice. This transporter has been found to supply UDP-glucose for the formation of matrix polysaccharides, thereby modulating cellulose biosynthesis.¹¹ Here, we examine these alterations of cell wall polymers at the cellular level. The orientation of cellulose microfibrils and extractability of wall polysaccharides were also compared between the mutant and wild type. All those further our understandings of the functions of NSTs and the synergetic synthesis of different polymers.     

Endoplasmic reticulum alpha-glycosidases of Candida albicans are required for N glycosylation, cell wall integrity, and normal host-fungus interaction

The cell surface of Candida albicans is enriched in highly glycosylated mannoproteins that are involved in the interaction with the host tissues. N glycosylation is a posttranslational modification that is initiated in the endoplasmic reticulum (ER), where the Glc₃Man₉GlcNAc₂ N-glycan is processed by α-glucosidases I and II and α1,2-mannosidase to generate Man₈GlcNAc₂. This N-oligosaccharide is then elaborated in the Golgi to form N-glycans with highly branched outer chains rich in mannose. In Saccharomyces cerevisiae, CWH41, ROT2, and MNS1 encode for α-glucosidase I, α-glucosidase II catalytic subunit, and α1,2-mannosidase, respectively. We disrupted the C. albicans CWH41, ROT2, and MNS1 homologs to determine the importance of N-oligosaccharide processing on the N-glycan outer-chain elongation and the host-fungus interaction. Yeast cells of Cacwh41Δ, Carot2Δ, and Camns1Δ null mutants tended to aggregate, displayed reduced growth rates, had a lower content of cell wall phosphomannan and other changes in cell wall composition, underglycosylated β-N-acetylhexosaminidase, and had a constitutively activated PKC-Mkc1 cell wall integrity pathway. They were also attenuated in virulence in a murine model of systemic infection and stimulated an altered pro- and anti-inflammatory cytokine profile from human monocytes. Therefore, N-oligosaccharide processing by ER glycosidases is required for cell wall integrity and for host-fungus interactions.