A nuclear ligand MRG15 involved in the proapoptotic activity of medicinal fungal galectin AAL (Agrocybe aegerita lectin)

Background

We have previously reported a novel fungal galectin Agrocybe aegerita lectin (AAL) with apoptosis-induced activity and nuclear migration activity. The importance of nuclear localization for AAL's apoptosis-induced activity has been established by mutant study. However, the mechanism remains unclear.

Methods

We further investigated the mechanism using a previously reported carbohydrate recognition domain (CRD) mutant protein H59Q, which retained its nuclear localization activity but lost most of its apoptotic activity. The cell membrane-binding ability of recombinant AAL (rAAL) and H59Q was analyzed by FACS, and their cellular partners were identified by affinity chromatography and mass spectroscopy. Furthermore, the interaction of AAL and ligand was proved by mammalian two-hybrid and pull down assays. A knockdown assay was used to confirm the role of the ligand.

Results

The apoptotic activity of AAL could be blocked by lactose. Mutant H59Q retained comparable cell membrane-binding ability to rAAL. Four cellular binding partners of AAL in HeLa cells were identified: glucose-regulated protein 78 (GRP78); mortality factor 4-like protein 1 (MRG15); elongation factor 2 (EEF2); and heat shock protein 70 (Hsp70). CRD region of AAL was required for the interaction between AAL/mutant AAL and MRG15. MRG15 knockdown increased the cells' resistance to AAL treatment.

Conclusion

MRG15 was a nuclear ligand for AAL in HeLa cells. These data implied the existence of a novel nuclear pathway for the antitumor activity of fungal galectin AAL.

General significance

These findings provide a novel explanation of AAL bioactivity and contribute to the understanding of mushroom lectins' antitumor activity.     

Structural Basis of Specific Recognition of Non-Reducing Terminal N-Acetylglucosamine by an Agrocybe aegerita Lectin

O-linked N-acetylglucosaminylation (O-GlcNAcylation) is a reversible post-translational modification that plays essential roles in many cellular pathways. Research in this field, however, is hampered by the lack of suitable probes to identify, accumulate, and purify the O-GlcNAcylated proteins. We have previously reported the identification of a lectin from the mushroom Agrocybe aegerita, i.e., Agrocybe aegerita lectin 2, or AAL2, that could bind terminal N-acetylglucosamine with higher affinities and specificity than other currently used probes. In this paper, we report the crystal structures of AAL2 and its complexes with GlcNAc and GlcNAcβ1-3Galβ1-4GlcNAc and reveal the structural basis of GlcNAc recognition by AAL2 and residues essential for the binding of terminal N-acetylglucosamine. Study on AAL2 may enable us to design a protein probe that can be used to identify and purify O-GlcNAcylated proteins more efficiently.     

Theoretical investigation on the glycan‐binding specificity of Agrocybe cylindracea galectin using molecular modeling and molecular dynamics simulation studies

Galectins are β‐galactoside binding proteins which have the ability to serve as potent antitumor, cancer biomarker, and induce tumor cell apoptosis. Agrocybe cylindracea galectin (ACG) is a fungal galectin which specifically recognizes α(2,3)‐linked sialyllactose at the cell surface that plays extensive roles in the biological recognition processes. To investigate the change in glycan‐binding specificity upon mutations, single point and double point site‐directed in silico mutations are performed at the binding pocket of ACG. Molecular dynamics (MD) simulation studies are carried out for the wild‐type (ACG) and single point (ACG1) and double point (ACG2) mutated ACGs to investigate the dynamics of substituted mutants and their interactions with the receptor sialyllactose. Plausible binding modes are proposed for galectin–sialylglycan complexes based on the analysis of hydrogen bonding interactions, total pair‐wise interaction energy between the interacting binding site residues and sialyllactose and binding free energy of the complexes using molecular mechanics–Poisson–Boltzmann surface area. Our result shows that high contribution to the binding in different modes is due to the direct and water‐mediated hydrogen bonds. The binding specificity of double point mutant Y59R/N140Q of ACG2 is found to be high, and it has 26 direct and water‐mediated hydrogen bonds with a relatively low‐binding free energy of −47.52 ± 5.2 kcal/mol. We also observe that the substituted mutant Arg59 is crucial for glycan‐binding and for the preference of α(2,3)‐linked sialyllactose at the binding pocket of ACG2 galectin. When compared with the wild‐type and single point mutant, the double point mutant exhibits enhanced affinity towards α(2,3)‐linked sialyllactose, which can be effectively used as a model for biological cell marker in cancer therapeutics. Copyright © 2015 John Wiley & Sons, Ltd.     

Regulation of RNF144A E3 Ubiquitin Ligase Activity by Self-association through Its Transmembrane Domain

RNF144A, an E3 ubiquitin ligase for DNA-dependent protein kinase catalytic subunit (DNA-PKcs), can promote DNA damage-induced cell apoptosis. Here we characterize an important regulation of RNF144A through its transmembrane (TM) domain. The TM domain of RNF144A is highly conserved among species. Deletion of the TM domain abolishes its membrane localization and also significantly reduces its ubiquitin ligase activity. Further evidence shows that the TM domain is required for RNF144A self-association and that the self-association may be partially mediated through a classic GXXXG interaction motif. A mutant RNF144A-G252L/G256L (in the G²⁵²XXXG²⁵⁶ motif) preserves membrane localization but is defective in self-association and ubiquitin ligase activity. On the other hand, a membrane localization loss mutant of RNF144A still retains self-association and E3 ligase activity, which can be blocked by additional G252L/G256L mutations. Therefore, our data demonstrate that the TM domain of RNF144A has at least two independent roles, membrane localization and E3 ligase activation, to regulate its physiological function. This regulatory mechanism may be applicable to other RBR (RING1-IBR-RING2) E3 ubiquitin ligases because, first, RNF144B also self-associates. Second, all five TM-containing RBR E3 ligases, including RNF144A and RNF144B, RNF19A/Dorfin, RNF19B, and RNF217, have the RBR-TM(GXXXG) superstructure. Mutations of the GXXXG motifs in RNF144A and RNF217 have also be found in human cancers, including a G252D mutation of RNF144A. Interestingly, RNF144A-G252D still preserves self-association and ubiquitin ligase activity but loses membrane localization and is turned over rapidly. In conclusion, both proper membrane localization and self-association are important for RNF144A function.     

Subcellular Localization of Matrin 3 Containing Mutations Associated with ALS and Distal Myopathy

Background

Mutations in Matrin 3 [MATR3], an RNA- and DNA-binding protein normally localized to the nucleus, have been linked to amyotrophic lateral sclerosis (ALS) and distal myopathies. In the present study, we have used transient transfection of cultured cell lines to examine the impact of different disease-causing mutations on the localization of Matrin 3 within cells.

Results

Using CHO and human H4 neuroglioma cell models, we find that ALS/myopathy mutations do not produce profound changes in the localization of the protein. Although we did observe variable levels of Matrin 3 in the cytoplasm either by immunostaining or visualization of fluorescently-tagged protein, the majority of cells expressing either wild-type (WT) or mutant Matrin 3 showed nuclear localization of the protein. When cytoplasmic immunostaining, or fusion protein fluorescence, was seen in the cytoplasm, the stronger intensity of staining or fluorescence was usually evident in the nucleus. In ~80% of cells treated with sodium arsenite (Ars) to induce cytoplasmic stress granules, the nuclear localization of WT and F115C mutant Matrin 3 was not disturbed. Notably, over-expression of mutant Matrin 3 did not induce the formation of obvious large inclusion-like structures in either the cytoplasm or nucleus.

Conclusions

Our findings indicate that mutations in Matrin 3 that are associated with ALS and myopathy do not dramatically alter the normal localization of the protein or readily induce inclusion formation.     

Impaired Iron Transport Activity of Ferroportin 1 in Hereditary Iron Overload

To investigate the functional significance of mutations in Ferroportin that cause hereditary iron overload, we directly measured the iron efflux activity of the proteins expressed in Xenopus oocytes. We found that wild type and mutant Ferroportin molecules (A77D, N144H, Q248H and V162Δ) were all expressed at the plasma membrane at similar levels. All mutations caused significant reductions in ⁵⁹Fe efflux compared to wild type but all retained some residual transport activity. A77D had the strongest effect on ⁵⁹Fe efflux (remaining activity 9% of wild-type control), whereas the N144H mutation retained the highest efflux activity (42% of control). The Q248H and V162Δ mutations were intermediate between these values. Co-injection of mutant and wild-type mRNAs revealed that the A77D and N144H mutations had a dominant negative effect on the function of the WT protein.     

对92株茶树菇菌株的遗传多样性分析和农艺性状的评价

为了解茶树菇（Agrocybe aegerita）种质资源的遗传多样性和筛选优良的茶树菇新品种,采用菌株拮抗试验方法观察了92株茶树菇菌株间拮抗反应及其类型,ISSR-PCR（inter-simple sequence repeat-PCR）分子标记方法对92株茶树菇菌株的遗传多样性进行了综合分析。拮抗试验将92株茶树菇菌株分为27组;筛选出的20条ISSR引物共扩增出317条清晰条带,多态性条带平均比率为82.60%;在遗传相似系数为0.742时,ISSR分子标记分析可将92株茶树菇划分为6大类群,拮抗试验和ISSR分子标记分析的结果基本一致。通过对比农艺性状分析,初步筛选出滇农5、滇农14、茶5-800、白茶、闽农5及滇农8作为工厂化生产茶树菇菌种。结果表明茶树菇的遗传多样性丰富,结合栽培出菇试验可为茶树菇品种选育和杂交育种的亲本选择提供参考。     

Stepwise oxygenations of toluene and 4-nitrotoluene by a fungal peroxygenase

Fungal peroxygenases have recently been shown to catalyze remarkable oxidation reactions. The present study addresses the mechanism of benzylic oxygenations catalyzed by the extracellular peroxygenase of the agaric basidiomycete Agrocybe aegerita. The peroxygenase oxidized toluene and 4-nitrotoluene via the corresponding alcohols and aldehydes to give benzoic acids. The reactions proceeded stepwise with total conversions of 93% for toluene and 12% for 4-nitrotoluene. Using H₂¹⁸O₂ as the co-substrate, we show here that H₂O₂ is the source of the oxygen introduced at each reaction step. A. aegerita peroxygenase resembles cytochromes P450 and heme chloroperoxidase in catalyzing benzylic hydroxylations.     

Sequence and Secondary Structure of the Mitochondrial Small-Subunit rRNA V4, V6, and V9 Domains Reveal Highly Species-Specific Variations within the Genus Agrocybe

A comparative study of variable domains V4, V6, and V9 of the mitochondrial small-subunit (SSU) rRNA was carried out with the genus Agrocybe by PCR amplification of 42 wild isolates belonging to 10 species, Agrocybe aegerita, Agrocybe dura, Agrocybe chaxingu, Agrocybe erebia, Agrocybe firma, Agrocybe praecox, Agrocybe paludosa, Agrocybe pediades, Agrocybe alnetorum, and Agrocybe vervacti. Sequencing of the PCR products showed that the three domains in the isolates belonging to the same species were the same length and had the same sequence, while variations were found among the 10 species. Alignment of the sequences showed that nucleotide motifs encountered in the smallest sequence of each variable domain were also found in the largest sequence, indicating that the sequences evolved by insertion-deletion events. Determination of the secondary structure of each domain revealed that the insertion-deletion events commonly occurred in regions not directly involved in the secondary structure (i.e., the loops). Moreover, conserved sequences ranging from 4 to 25 nucleotides long were found at the beginning and end of each domain and could constitute genus-specific sequences. Comparisons of the V4, V6, and V9 secondary structures resulted in identification of the following four groups: (i) group I, which was characterized by the presence of additional P23-1 and P23-3 helices in the V4 domain and the lack of the P49-1 helix in V9 and included A. aegerita, A. chaxingu, and A. erebia; (ii) group II, which had the P23-3 helix in V4 and the P49-1 helix in V9 and included A. pediades; (iii) group III, which did not have additional helices in V4, had the P49-1 helix in V9 and included A. paludosa, A. firma, A. alnetorum, and A. praecox; and (iv) group IV, which lacked both the V4 additional helices and the P49-1 helix in V9 and included A. vervacti and A. dura. This grouping of species was supported by the structure of a consensus tree based on the variable domain sequences. The conservation of the sequences of the V4, V6, and V9 domains of the mitochondrial SSU rRNA within species and the high degree of interspecific variation found in the Agrocybe species studied open the way for these sequences to be used as specific molecular markers of the Basidiomycota.     

Conformational change of a unique sequence in a fungal galectin from Agrocybe cylindracea controls glycan ligand-binding specificity

A fungal galectin from Agrocybe cylindracea (ACG) exhibits broad binding specificity for β-galactose–containing glycans. We determined the crystal structures of wild-type ACG and the N46A mutant, with and without glycan ligands. From these structures and a saccharide-binding analysis of the N46A mutant, we revealed that a conformational change of a unique insertion sequence containing Asn46 provides two binding modes for ACG, and thereby confers broad binding specificity. We propose that the unique sequence provides these two distinct glycan-binding modes by an induced-fit mechanism.     

DNA sequence and secondary structure of the mitochondrial small subunit ribosomal RNA coding region including a group-IC2 intron from the cultivated basidiomycete Agrocybe aegerita

Due to their structural complexity and their evolutionary dimension, rRNAs are the most investigated nucleic acids in prokaryotes, eukaryotes and organelles. However, no complete sequence of a mitochondrial small subunit (SSU) rRNA was available in the basidiomycotina subdivision. The mitochondrial gene encoding the SSU rRNA of the cultivated basidiomycete Agrocybe aegerita was cloned and its complete nucleotide sequence achieved; the 5′- and 3′-ends were localized by nuclease S1 mapping, leading to a size of 3277 nt. The secondary structure of the SSU rRNA (1906 nt in size) possessed all the helices and loops of the prokaryotic model; a unique modification was found in a conserved nucleotide predicted by the model: the nt 487 was A instead of C. The same modification, has been found in all the partial basidiomycete mitochondrial sequences available in databases. The Agrocybe aegerita SSU rRNA was characterized by large and unusual extensions leading to additional helices in the variable domains V4, V6 and V9, which were the longest of the known prokaryotic or mitochondrial SSU rRNAs. Nucleotide sequence analysis indicated a 1371-bp intron, belonging to subgroup-IC2, located in a conserved loop in the 3′-part of the SSU rRNA. This intron, which is the second example reported in a fungal mitochondrial SSU rDNA, encoded a putative protein (407 aa) sharing homologies with endonucleases involved in group-I intron mobility. This report constitutes the first complete mitochondrial SSU rRNA sequence and secondary structure of any member of the basidiomycotina subdivision.     

The classical nuclear localization signal receptor, importin-alpha, is required for efficient transition through the G1/S stage of the cell cycle in Saccharomyces cerevisiae

There is significant evidence linking nucleocytoplasmic transport to cell cycle control. The budding yeast, Saccharomyces cerevisiae, serves as an ideal model system for studying transport events critical to cell cycle progression because the nuclear envelope remains intact throughout the cell cycle. Previous studies linked the classical nuclear localization signal (cNLS) receptor, importin-alpha/Srp1, to the G(2)/M transition of the cell cycle. Here, we utilize two engineered mutants of importin-alpha/Srp1 with specific molecular defects to explore how protein import affects cell cycle progression. One mutant, Srp1-E402Q, is defective in binding to cNLS cargoes that contain two clusters of basic residues termed a bipartite cNLS. The other mutant, Srp1-55, has defects in release of cNLS cargoes into the nucleus. Consistent with distinct in vivo functional consequences for each of the Srp1 mutants analyzed, we find that overexpression of different nuclear transport factors can suppress the temperature-sensitive growth defects of each mutant. Studies aimed at understanding how each of these mutants affects cell cycle progression reveal a profound defect at the G(1) to S phase transition in both srp1-E402Q and srp1-55 mutants as well as a modest G(1)/S defect in the temperature-sensitive srp1-31 mutant, which was previously implicated in G(2)/M. We take advantage of the characterized defects in the srp1-E402Q and srp1-55 mutants to predict candidate cargo proteins likely to be affected in these mutants and provide evidence that three of these cargoes, Cdc45, Yox1, and Mcm10, are not efficiently localized to the nucleus in importin-alpha mutants. These results reveal that the classical nuclear protein import pathway makes important contributions to the G(1)/S cell cycle transition.     

Topological studies of hSVCT1, the human sodium-dependent vitamin C transporter and the influence of N-glycosylation on its intracellular targeting

The Na⁺-dependent transporters, hSVCT1 and hSVCT2, were assessed in COS-1 cells for their membrane topology. Antibodies to N- and C-termini of hSVCT1 and C-terminus of hSVCT2 identified positive immunofluorescence only after permeabilisation, suggesting these regions are intracellular. PNGase F treatment confirmed that WT hSVCT1 (∼ 70-100 kDa) is glycosylated and site-directed mutagenesis of the three putative N-glycosylation sites, Asn138, Asn144, Asn230, demonstrated that mutants N138Q and N144Q were glycosylated (∼ 68-90 kDa) with only 31-65% of WT l-ascorbic acid (AA) uptake while the glycosylation profile of N230Q remained unaltered (∼ 98% of WT activity). However, the N138Q/N144Q double mutant displayed barely detectable membrane expression at ∼ 65 kDa, no apparent glycosylation and minimal AA uptake (< 10%) with no discernible improvement in expression or activity when cultured at 28 °C or 37 °C. Marker protein immunocytochemistry with N138Q/N144Q identified intracellular aggregates with hSVCT1 localised at the nuclear membrane but absent at the plasma membrane thus implicating its role as a possible intracellular transporter and suggesting N-glycosylation is required for hSVCT1 membrane targeting. Also, Lys242 on the same putative hydrophilic loop as Asn230 after biotinylation was inaccessible from the extracellular side when analysed by MALDI-TOF MS. A new hSVCT1 secondary structure model supporting these findings is proposed.     

Heterologous transformation of Agrocybe aegerita with a bacterial neomycin-resistance gene fused to a fungal promoter-like DNA sequence

DNA sequences of the basidiomycete Agrocybe aegerita were cloned in E. coli based on their ability to drive the expression of the bacterial promoterless tetracycline (Tc)-resistance gene. A 0.48% frequency of the cloned sequences promoted antibiotic-resistance. The sequence conferring the highest Tc resistance (40 μg/ml) was selected to drive the expression in E. coli of two other promoterless genes encoding chloramphenicol and neomycin resistance. One of the derivative vectors, pN13-A2, carrying a chimeric neomycin-resistance gene, was used to transform an A. aegerita neomycin-sensitive strain by protoplast electroporation. Transformation frequencies ranged from 1 to 2.8 transformants per μg of DNA per 10³ viable cells, in a relatively high background of spontaneous-resistant colonies (2% of the surviving protoplasts). Molecular analyses showed that transformation had occurred by the integration of pN13-A2 sequences, either ectopically or at the resident locus carrying the A. aegerita promoter-like sequence, with probable molecular rearrangements. The nucleotide sequence of the promoter-like fragment revealed the presence of a CT motif that is known to be involved in a promoter function in some highly expressed genes of filamentous fungi.     

Functional Interaction of the Ras Effector RASSF5 with the Tyrosine Kinase Lck: Critical Role in Nucleocytoplasmic Transport and Cell Cycle Regulation

RASSF5 is a member of the Ras association domain family, which is known to be involved in cell growth regulation. Expression of RASSF5 is extinguished selectively by epigenetic mechanism(s) in different cancers and cell lines, and reexpression usually suppresses cell proliferation and tumorigenicity. To date, the mechanism regulating RASSF5 nuclear transport and its role in cell growth regulation remains unclear. Using heterokaryon assay, we have demonstrated that RASSF5 shuttles between the nucleus and the cytoplasm, and its export from the nucleus is sensitive to leptomycin B, suggesting that RASSF5 is exported from the nucleus by a CRM-1-dependent export pathway. We further demonstrate that RASSF5 contains a hydrophobic-rich nuclear export signal (NES) towards the C-terminus and two nuclear localization signals—one each at the N-terminus and the C-terminus. Combination of mutational and immunofluorescence analyses suggests that the functional NES residing between amino acids 260 and 300 in the C-terminus is necessary for the efficient export of RASSF5 from the nucleus. In addition, substitution of conserved hydrophobic residues within the minimal NES impaired RASSF5 export from the nucleus. Furthermore, exchange of proline residues within the putative Src homology 3 binding motifs altered the export of RASSF5 from the nucleus despite the presence of functional NES, suggesting that multiple domains independently modulate the nucleocytoplasmic transport of RASSF5. Interestingly, the present investigation provided evidence that RASSF5 interacts with the tyrosine kinase Lck through its C-terminal Src homology 2 binding motif and showed that Lck-mediated phosphorylation is critical for the efficient translocation of RASSF5 into the nuclear compartment. Interestingly, our data demonstrate that wild type and nuclear export defective (ΔNES) mutant of RASSF5 but not the import defective mutant of accumulate the cells at G1/S phase and induce apoptosis. Furthermore, the Lck-interaction-defective mutant of RASSF5 induces apoptosis without altering cell cycle progression, suggesting that RASSF5 induces apoptosis independent of cell cycle arrest. Together, our data demonstrate that interaction with Lck is critical for RASSF5 phosphorylation, which in turn regulates the cell growth control activity of RASSF5. Finally, we have shown that RASSF5 encodes four splice variants and is translocated to the nucleus by the classical nuclear import pathway. One of the splice variants, RASSF5C, was found to be localized in the cytoplasm and translocated into the nucleus upon leptomycin B treatment despite the absence of N-terminal nuclear localization signal, suggesting that distribution of RASSF5 variants in different cellular compartments may be critical for Ras-dependent cell growth regulation. Collectively, the present investigation provided evidence that Lck-mediated phosphorylation regulates the nucleocytoplasmic shuttling and cell growth control activities of RASSF5.     

Novel Small Molecule XPO1/CRM1 Inhibitors Induce Nuclear Accumulation of TP53, Phosphorylated MAPK and Apoptosis in Human Melanoma Cells

XPO1/CRM1 is a key nuclear exporter protein that mediates translocation of numerous cellular regulatory proteins. We investigated whether XPO1 is a potential therapeutic target in melanoma using novel selective inhibitors of nuclear export (SINE). In vitro effects of SINE on cell growth and apoptosis were measured by MTS assay and flow cytometry [Annexin V/propidium iodide (PI)], respectively in human metastatic melanoma cell lines. Immunoblot analysis was used to measure nuclear localization of key cellular proteins. The in vivo activity of oral SINE was evaluated in NOD/SCID mice bearing A375 or CHL-1 human melanoma xenografts. SINE compounds induced cytostatic and pro-apoptotic effects in both BRAF wild type and mutant (V600E) cell lines at nanomolar concentrations. The cytostatic and pro-apoptotic effects of XPO1 inhibition were associated with nuclear accumulation of TP53, and CDKN1A induction in the A375 cell line with wild type TP53, while pMAPK accumulated in the nucleus regardless of TP53 status. The orally bioavailable KPT-276 and KPT-330 compounds significantly inhibited growth of A375 (p<0.0001) and CHL-1 (p = 0.0087) human melanoma cell lines in vivo at well tolerated doses. Inhibition of XPO1 using SINE represents a potential therapeutic approach for melanoma across cells with diverse molecular phenotypes by promoting growth inhibition and apoptosis.     

The MADS domain protein DIANA acts together with AGAMOUS-LIKE80 to specify the central cell in Arabidopsis ovules

MADS box genes in plants consist of MIKC-type and type I genes. While MIKC-type genes have been studied extensively, the functions of type I genes are still poorly understood. Evidence suggests that type I MADS box genes are involved in embryo sac and seed development. We investigated two independent T-DNA insertion alleles of the Arabidopsis thaliana type I MADS box gene AGAMOUS-LIKE61 (AGL61) and showed that in agl61 mutant ovules, the polar nuclei do not fuse and central cell morphology is aberrant. Furthermore, the central cell begins to degenerate before fertilization takes place. Although pollen tubes are attracted and perceived by the mutant ovules, neither endosperm development nor zygote formation occurs. AGL61 is expressed in the central cell during the final stages of embryo sac development. An AGL61:green fluorescent protein–β-glucoronidase fusion protein localizes exclusively to the polar nuclei and the secondary nucleus of the central cell. Yeast two-hybrid analysis showed that AGL61 can form a heterodimer with AGL80 and that the nuclear localization of AGL61 is lost in the agl80 mutant. Thus, AGL61 and AGL80 appear to function together to differentiate the central cell in Arabidopsis. We renamed AGL61 DIANA, after the virginal Roman goddess of the hunt.     

Adipogenesis stimulates the nuclear localization of EWS with an increase in its O-GlcNAc glycosylation in 3T3-L1 cells

Although the Ewing sarcoma (EWS) proto-oncoprotein is found in the nucleus and cytosol and is associated with the cell membrane, the regulatory mechanisms of its subcellular localization are still unclear. Here we found that adipogenic stimuli induce the nuclear localization of EWS in 3T3-L1 cells. Tyrosine phosphorylation in the C-terminal PY-nuclear localization signal of EWS was negative throughout adipogenesis. Instead, an adipogenesis-dependent increase in O-linked β-N-acetylglucosamine (O-GlcNAc) glycosylation of EWS was observed. Pharmacological inactivation of O-GlcNAcase in preadipocytes promoted perinuclear localization of EWS. Our findings suggest that the nuclear localization of EWS is partly regulated by the glycosylation.     

Opposing developmental functions of Agrocybe aegerita galectin (AAL) during mycelia differentiation

Mycelia of basidiomycetes differentiating into fruiting body is a controlled developmental process, however the underlying molecular mechanism remains unknown. In previous work, a novel fungal Agrocybe aegerita galectin (AAL) was isolated from A. aegerita in our laboratory. AAL was shown to promote mycelial differentiation in A. aegerita and Auricularia polytricha, indicating that AAL might function as a conserved fruiting initiator during basidiomycete mycelia development. In the current work, we investigate the role of AAL in mycelia differentiation and fruiting body formation. First, the expression and localization of AAL in mycelia, primordium and fruiting body were assessed by Western blotting and immunohistochemistry. AAL was found to be ubiquitously expressed in the primordium and fruiting body but not in the mycelia. AAL facilitated mycelia congregation and promoted fruiting body production when AAL was applied on mycelia. At the same time, when AAL was spread on potato dextrose agar (PDA) medium prior to mycelia inoculation, mycelia exhibited slowed growth rates, resulting in mycelia cords formation and inhibition of fruiting body formation. The 5' regulatory sequence of aal was cloned by 'genome walking'. Here, we show that aal lack introns in the coding region and the upstream 740 bp sequence was characterized by the existence of core promoter elements, which included: two CCAAT boxes (-535/-280), a GC box (-145), a TATA box (-30) and a fungal leader intron within the 5' UTR. The identification of regulatory expression elements may provide an explanation to the stage-specific and high-level expression of aal during fruiting development.