A mutant of hydrophobin HGFI tuning the self-assembly behaviour and biosurfactant activity

Hydrophobins are a series of low molecular weight proteins produced by filamentous fungi that play an important role in fungal growth. They have a globular structure and possess a unique hydrophobic patch on their surface that makes them amphiphilic, making them among the most surface-active proteins. Herein, the surface charge properties of HGFI, a class I hydrophobin from Grifola frondosa, were altered by replacing the negatively charged Glu24 with a positively charged Lys to generate the ME24 mutant. Pichia pastoris GS115 was used for recombinant expression of the ME24 mutant, which was purified by a two-step procedure. The function of the mutated residue in HGFI self-assembly was investigated. Reverse-phase high-performance liquid chromatography analysis revealed that the polarity of ME24 was enhanced compared with HGFI. Circular dichroism, thioflavin T assay, water contact angle and atomic force microscopy indicated that Glu24 participates in rodlet formation. Water solubility detection and dynamic light scattering showed that Glu24 affects the assembled state of HGFI in aqueous solution. The behaviour of the mutant in an emulsion, in the dispersion of insoluble materials and in large-scaled protein production suggests the functions of hydrophobins can be tuned for new applications.

     

The DnaJ protein OsDjA6 negatively regulates rice innate immunity to the blast fungus Magnaporthe oryzae

Rice blast, caused by Magnaporthe oryzae (synonym: Pyricularia oryzae), severely reduces rice production and grain quality. The molecular mechanism of rice resistance to M. oryzae is not fully understood. In this study, we identified a chaperone DnaJ protein, OsDjA6, which is involved in basal resistance to M. oryzae in rice. The OsDjA6 protein is distributed in the entire rice cell. The expression of OsDjA6 is significantly induced in rice after infection with a compatible isolate. Silencing of OsDjA6 in transgenic rice enhances resistance to M. oryzae and also results in an increased burst of reactive oxygen species after flg22 and chitin treatments. In addition, the expression levels of WRKY45, NPR1 and PR5 are increased in OsDjA6 RNAi plants, indicating that OsDjA6 may mediate resistance by affecting the salicylic acid pathway. Finally, we found that OsDjA6 interacts directly with the E3 ligase OsZFP1 in vitro and in vivo. These results suggest that the DnaJ protein OsDjA6 negatively regulates rice innate immunity, probably via the ubiquitination proteasome degradation pathway.     

The DNA Methyltransferase DNMT1 and Tyrosine-Protein Kinase KIT Cooperatively Promote Resistance to 5-Aza-2′-deoxycytidine (Decitabine) and Midostaurin (PKC412) in Lung Cancer Cells

Lung cancer cells are sensitive to 5-aza-2′-deoxycytidine (decitabine) or midostaurin (PKC412), because decitabine restores the expression of methylation-silenced tumor suppressor genes, whereas PKC412 inhibits hyperactive kinase signaling, which is essential for cancer cell growth. Here, we demonstrated that resistance to decitabine (decitabine^R) or PKC412 (PKC412^R) eventually results from simultaneously remethylated DNA and reactivated kinase cascades. Indeed, both decitabine^R and PKC412^R displayed the up-regulation of DNA methyltransferase DNMT1 and tyrosine-protein kinase KIT, the enhanced phosphorylation of KIT and its downstream effectors, and the increased global and gene-specific DNA methylation with the down-regulation of tumor suppressor gene epithelial cadherin CDH1. Interestingly, decitabine^R and PKC412^R had higher capability of colony formation and wound healing than parental cells in vitro, which were attributed to the hyperactive DNMT1 or KIT, because inactivation of KIT or DNMT1 reciprocally blocked decitabine^R or PKC412^R cell proliferation. Further, DNMT1 knockdown sensitized PKC412^R cells to PKC412; conversely, KIT depletion synergized with decitabine in eliminating decitabine^R. Importantly, when engrafted into nude mice, decitabine^R and PKC412^R had faster proliferation with stronger tumorigenicity that was caused by the reactivated KIT kinase signaling and further CDH1 silencing. These findings identify functional cross-talk between KIT and DNMT1 in the development of drug resistance, implying the reciprocal targeting of protein kinases and DNA methyltransferases as an essential strategy for durable responses in lung cancer.     

Temporal and spatial characteristics of male cone development in Metasequoia glyptostroboides Hu et Cheng

Metasequoia glyptostroboides, a famous relic species of conifer that survived in China, has been successfully planted in large numbers across the world. However, limited information on male cone development in the species is available. In this study, we observed the morphological and anatomical changes that occur during male cone development in M. glyptostroboides using semi-thin sections and scanning electron microscopy. The male cones were borne oppositely on one-year-old twigs that were mainly located around the outer and sunlit parts of crown. Male cones were initiated from early September and shed pollen in the following February. Each cone consisted of spirally arranged microsporophylls subtended by decussate sterile scales, and each microsporophyll commonly consisted of three microsporangia and a phylloclade. The microsporangial wall was composed of an epidermis, endothecium, and tapetum. In mid-February, the endothecium and tapetum layers disintegrated, and in the epidermal layer the cell walls were thickened with inner protrusions. Subsequently, dehiscence of the microsporangia occurred through rupturing of the microsporangial wall along the dehiscence line. These results suggest that the structure, morphology, architecture and arrangement of male cones of M. glyptostroboides are mainly associated with the production, protection and dispersal of pollen for optimization of wind pollination.