E2F4 regulates the cell cycle and DNA replication in the silkworm, Bombyx mori

Bmgsb directly activates Bmubxn-4 to inhibit the DNA endoreplication and affect the cell fate in the silk gland of Bombyx mori

Silk protein produced by the silk gland of silkworm (Bombyx mori), finds extensive application in tissue engineering and biomedicine. Elucidating the molecular mechanisms governing silk gland development is critical for optimizing silk protein production and its biomedical applications. Prior studies demonstrated that Bmgsb influences cell fate determination through modulation of endoreplication. To further investigate the molecular mechanism of Bmgsb, transcriptome analysis identified a novel gene, designated Bmubxn-4. Dual-luciferase reporter and electrophoretic mobility shift assays (EMSA) demonstrated that Bmgsb directly regulates Bmubxn-4 transcription. Bmubxn-4 knockdown in the ASG resulted in increased cell size, DNA endoreplication and upregulation of cell cycle-related genes. Bmubxn-4 knockdown in the AMSG resulted in developmental defects and upregulation of ubiquitin-proteasome system (UPS)-related genes. These findings indicate that Bmubxn-4, a direct target gene of Bmgsb, plays a crucial role in silk gland cell redifferentiation and DNA endoreplication. This study provides novel insights into silk gland cell differentiation and the transcriptional regulation of silk protein.

BmE2F1 regulates endoreplication of silk gland cells in silkworm, Bombyx mori

Endoreplication is particularly important in the context of silk protein synthesis within the silk gland cells of silkworms. Our previous research indicated that the BmE2F1 enhances the silk yield of silkworm cocoons, but the underlying molecular mechanism remains elusive. In this study, we employed RNA-sequencing to dissect the transcriptional profiles of silk glands in the wild-type Dazao silkworm strain and the overexpression (OE) silkworm strain with specific overexpression of the BmE2F1 gene in silk glands. Among the 1126 differentially expressed genes (DEGs), many related to DNA replication (endoreplication in silk glands of silkworm larvae) were significantly enriched. Quantitative real-time PCR confirmed that overexpression of BmE2F1 led to a substantial increase in the expression of 13 genes involved in the DNA replication pathway. Additionally, BmE2F1 upregulated the expression of BmCyclin E, a pivotal gene in the G/S phase transition. Moreover, BmE2F1 overexpression in silk glands significantly boosted DNA replication and concurrently increased the DNA content within silk glands. In conclusion, BmE2F1 regulates endoreplication in silk gland cells of silkworms through dual mechanisms: firstly, by enhancing the formation of the DNA replication complex; and secondly, by facilitating the cells' entry into the S phase.

Bombyx moriSuppressor of Hairless is involved in the regulation of the silkworm cell cycle and endoreplication of the silk glands

The Notch signaling pathway is important in cell cycle regulation and cell proliferation. The transcriptional repressor Suppressor of Hairless [Su(H)] is a molecular switch for downstream target genes of the Notch signaling pathway but the regulatory mechanism of the Su(H) gene in the cell cycle is unclear. We determined the function of the Notch signaling pathway and Bombyx mori Su(H) [BmSu(H)] in the regulation of the silkworm cell cycle. Inhibition of Notch signaling promoted the replication of DNA in silkworm gland cells and expression of the BmSu(H) gene was significantly reduced. Overexpression of the BmSu(H) gene inhibited DNA replication and cell proliferation of silkworm cells, whereas knockout of the BmSu(H) gene promoted DNA replication and cell proliferation. Knockout of the BmSu(H) in silkworms improved the efficiency of silk gland cell endoreplication and increased important economic traits. We demonstrated that BmSu(H) protein can directly bind to the promoters of BmCyclinA, BmCyclinE and BmCDK1 genes, inhibiting or promoting their transcription at the cell and individual level. This study identified molecular targets for genetic improvement of the silkworm and also provided insights into the regulatory mechanism of the cell cycle.

E2F4 regulates cell cycle to mediate embryonic development in pigs

In mammals, E2 factor (E2F) acts as a cell cycle regulator. E2F transcription factor 4 (E2F4) is a member of the E2F family of transcription factors and usually represents predominant E2F activity in cells. The E2F4 gene has been extensively studied in animals and is associated with multiple functions, such as cell cycle regulation and apoptosis; however, little is known about its role during embryonic development. In this study, we investigated the function of E2F4 and its mechanism of action in porcine embryo development. For this purpose, we knocked down E2F4 by microinjecting double-stranded RNA of E2F4 at the 1-cell stage. The results showed that E2F4 knockdown in porcine embryos led to a significant decrease in the blastocyst rate and total cell number. Defective E2F4 expression reduced the level of G1/S checkpoints (cyclin E-cyclin-dependent kinase 2) and cell cycle-related gene expression at the 4-cell embryo stage and blastocyst. Moreover, a decrease in E2F4 expression increased phosphorylated H2A.X variant histones and activated ataxia telangiectasia mutated (ATM) and p53-p21 pathway. In addition, E2F4 depletion caused a significant decrease in histone acetylation. Taken together, E2F4 plays a critical role as a transcriptional activator in the development of porcine embryos, an observation that contradicts its well-established role as a transcription repressor.