Targeted gene regulation through epigenome editing in plants.

The precise targeted gene regulation in plants is essential for improving plant traits and gaining a comprehensive understanding of gene functions. The regulation of gene expression in eukaryotes can be achieved through transcriptional and epigenetic mechanisms. Over the last decade, advancements in gene-targeting technologies, along with an expanded understanding of epigenetic gene regulation mechanisms, have significantly contributed to the development of programmable gene regulation tools. In this review, we will discuss the recent progress in targeted plant gene regulation through epigenome editing, emphasizing the role of effector proteins in modulating target gene expression via diverse mechanisms, including DNA methylation, histone modifications, and chromatin remodeling. Additionally, we will also briefly review targeted gene regulation by transcriptional regulation and mRNA modifications in plants.

Distinct enzyme activities of serine protease p37k in silkworm midgut and molting fluid.

Serine proteases possess various biological functions. The serine protease p37k exhibits gelatinolytic activity in the silkworm midgut and degrades cuticular proteins in the molting fluid. In this study, we analyzed the activity changes of recombinant p37k (re-p37k) and p37k in the midgut and molting fluid of Bombyx mori. Firstly, in vitro-expressed re-p37k was activated when a 22 kDa band was observed by western blot. Re-p37k exhibits strong gelatinolytic activity, with the highest activity observed at pH 7.0-9.0 and 45 °C. Compared to p37k in the midgut, re-p37k loses thermal stability but can be restored by midgut extract or ions. E64, AEBSF, and an inhibitor cocktail inhibited the hydrolytic activity of re-p37k on epidermal proteins but did not inhibit the gelatinolytic activity. Subsequently, zymography showed that the positions of gelatinolytic band produced by p37k in the midgut and molting fluid were different, 35 kDa and 40 kDa, respectively. Finally, when heated midgut extract was added to re-p37k or molting fluid, the gelatinolytic band shifted from 40 kDa to 35 kDa, and the proteolytic activity of p37k in the molting fluid was inhibited. Collectively, our results demonstrate that p37k exhibits different activities in various tissues, suggesting its distinct tissue-specific functions during insect metamorphosis.

[Characterization and immunofluorescence localization analysis of carboxypeptidase A in molt fluid of silkworm].

Molting is an important physiological phenomenon of many metamorphosis insects, during which the old and new epidermis are separated by enzymes present in the molting fluid. Various proteomic studies have discovered the presence of Bombyx mori carboxypeptidase A (Bm-CPA) in the molting fluid of silkworm, but its function remains unclear. In order to better understand the role of Bm-CPA in the molting process of silkworm, Bm-CPA was analyzed by bioinformatics analysis, real-time fluorescence quantitative PCR, antibody preparation, immunofluorescence staining, and expression in Pichia pastoris. The results showed that Bm-CPA had a conserved M14 zinc carboxypeptidase domain and glycosylation site. Its expression was regulated by ecdysone 20E, and large expression was observed in the epidermis of the upper cluster stage. Immunofluorescence staining showed that Bm-CPA was enriched in the epidermis during the molting stage, and the inhibitor of Bm-CPA led to the larval death due to the inability to molt. We also successfully obtained a large number of recombinant Bm-CPA proteins by Pichia pastoris expression in vitro. These results may facilitate further understanding the molting development process of silkworm.

Trypsin-type serine protease p37k hydrolyzes CPAP3-type cuticle proteins in the molting fluid of the silkworm Bombyx mori.

Cuticular proteins analogous to peritrophin 3 (CPAP3)-type cuticle proteins constitute a family of proteins with three chitin-binding domains (CBDs) that play an important role in cuticle formation by associating with chitin. In our previous study, we identified CPAP3-type cuticle proteins in the silkworm genome, of which we characterized CPAP3-A2 (BmCBP1), a protein highly expressed in the epidermis. In this study, to elucidate the digestion mechanism of CPAP3-type cuticle proteins, we incubated CPAP3-A2 with molting fluid in vitro and found that its hydrolysis, which was inhibited by serine and cysteine protease inhibitors, produced two major bands with a molecular weight of approximately 22 kD and 11 kD. A trypsin-type serine protease, p37k, was presumed to be responsible for hydrolyzing CPAP3-A2 based on liquid chromatography-tandem mass spectrometry analysis of naturally purified molting fluid. To verify this, p37k was subsequently expressed in Sf9 cells using the Bac-to-Bac baculovirus expression system. In its active form, the recombinant protease could successfully hydrolyze CPAP3-A2. Finally, we analyzed the CPAP3-A2 molting fluid digestion site. When arginine 169 of CPAP3-A2 was mutated to alanine, a weaker hydrolysis of mutant CPAP3-A2 was observed compared to that of normal CPAP3-A2. Collectively, we identified a trypsin-type serine protease that is involved in the degradation of CPAP3-type cuticle proteins, including CPAP3-A2, suggesting that this protease plays an important role during molting in Bombyx mori. These findings provide the basis for further elucidation of the mechanisms underlying insect molting and metamorphosis.