The 1986 Chernobyl nuclear power plant accident increased papillary thyroid carcinoma (PTC) incidence in surrounding regions, particularly for radioactive iodine (131I)–exposed children. We analyzed genomic, transcriptomic, and epigenomic characteristics of 440 PTCs from Ukraine (from 359 individuals with estimated childhood 131I exposure and 81 unexposed children born after 1986). PTCs displayed radiation dose–dependent enrichment of fusion drivers, nearly all in the mitogen-activated protein kinase pathway, and increases in small deletions and simple/balanced structural variants that were clonal and bore hallmarks of nonhomologous end-joining repair. Radiation-related genomic alterations were more pronounced for individuals who were younger at exposure. Transcriptomic and epigenomic features were strongly associated with driver events but not radiation dose. Our results point to DNA double-strand breaks as early carcinogenic events that subsequently enable PTC growth after environmental radiation exposure.
SUMMARY Meiotic homologous recombination (HR) is important for proper chromosomal segregation during gametogenesis and facilitates evolutionary adaptation via genomic reshuffling. In most eukaryotes, HR is mediated by two recombinases, the ubiquitous RAD51 and the meiosis-specific DMC1. The role of RAD51 in mammalian meiosis is unclear and study of its function is limited due to embryonic lethality of RAD51 knockouts. Here, we developed an in-vivo meiotic knockdown and protein complementation system to study RAD51 during mouse spermatogenesis. We show that RAD51 is crucial during meiotic prophase and its loss leads to depletion of late prophase I spermatocytes through a p53-dependent apoptotic pathway. This phenotype is distinct from that observed in the DMC1 knockdown. Our meiotic knockdown and complementation system establishes an experimental platform for mechanistic studies of meiotic proteins with unknown functions or essential genes for which a testis-specific knockout is not possible.
Artemia has evolved a unique developmental pattern of encysted embryos to cope with various environmental threats. Cell divisions totally cease during the preemergence developmental stage from gastrula to prenauplius. The molecular mechanism of this, however, remains unknown. Our study focuses on the involvement of p90 ribosomal S6 kinase (RSK), a family of serine/threonine kinase-mediating signal transduction downstream of mitogen-activated protein kinase cascades, in the termination of cell cycle arrest during the post-embryonic development of Artemia-encysted gastrula. With immunochemistry, morphology, and cell cycle analysis, the identified Artemia RSK was established to be specifically activated during the post-embryonic and early larval developmental stages when arrested cells of encysted embryos resumed mitoses. In vivo knockdown of RSK activity by RNA interference, kinase inhibition, and antibody neutralization consistently induced defective larvae with distinct gaps between the exoskeleton and internal tissues. In these abnormal individuals, mitoses were detected to be largely inhibited in the affected regions. These results display the requirement of RSK activity during Artemia development and suggest its role in termination of cell cycle (G 2 /M phase) arrest and promotion of mitogenesis. Our findings may, thus, provide insights into the regulation of cell division during Artemia post-embryonic development and reveal further aspects of RSK functions. p90 ribosomal S6 kinase (p90 RSK , also known as RSK) is a family of serine/threonine kinase that mediates signal transduction downstream of mitogen-activated protein kinase cascades (1). RSKs 2 consist of two distinct and functional kinase domains, the N-terminal kinase domain and the C-terminal kinase domain connected by a regulatory linker (2). The typical RSK possesses six phosphorylation sites, and its in vivo activation is achieved upon their consecutive phosphorylations. Mutation analysis reveals four of the six sites are essential for the kinase activation (Ser-221 in N-terminal kinase domain, Ser-363 and Ser-380 in the linker, and Thr-573 in C-terminal kinase domain, according to the human RSK1 sequence) (3).RSKs are present in most vertebrate species (1, 4), and RSKrelated molecules have also been identified in several invertebrates (5, 6). RSK family members have been reported to be multifunctional in the regulation of diverse cellular processes including transcriptional regulation, cell cycle control, cell survival, and many others (4). Within mammalian cells, RSKs are thought to promote G 1 progression by stimulating growth-related protein synthesis and inhibiting negative regulation (7). It is, thus, shown that the RSK inhibitor SL0101 can effectively inhibit proliferations of the human breast cancer cell and the hamster ovary cell (8, 9).Artemia possesses powerful adaptations to extreme environments that often include aspects of hypersalinity, anoxia, and large changes in ionic composition and temperature. As a strategy to cope with such en...
Previously, we have identified and characterized a male reproduction‐related kazal‐type peptidase inhibitor (MRPINK) gene from the prawn, Macrobrachium rosenbergii. In the present study, MRPINK was discovered to have an inhibitory effect on the gelatinolytic activity of M. rosenbergii sperm and immunofluorescence analysis revealed it bound specifically onto the base of sperm. The proteolytic activity of sperm extracts to vitelline coat components was also detected to be interfered by MRPINK. Furthermore, a novel gelatinase on sperm was found to be specifically inhibited by MRPINK and was named M. rosenbergii sperm gelatinase (MSG). MSG was then isolated and purified by reversed‐phase high performance liquid chromatography combining with gelatinolytic assay. By amino‐terminal amino acid sequence analysis and molecular cloning, the primary structure of MSG was determined. The data presented in this study provided evidence that MRPINK has an inhibitory effect on the gelatinolytic activity as well as proteolytic activity of prawn sperm and specifically blocks the activity of MSG. Mol. Reprod. Dev. 75: 1327–1337, 2008. © 2008 Wiley‐Liss, Inc.
BackgroundCysts of Artemia can remain in a dormant state for long periods with a very low metabolic rate, and only resume their development with the approach of favorable conditions. The post-diapause development is a very complicated process involving a variety of metabolic and biochemical events. However, the intrinsic mechanisms that regulate this process are unclear.ResultsHerein we report the specific activation of an AMP-activated protein kinase (AMPK) in the post-diapause developmental process of Artemia. Using a phospho-AMPKα antibody, AMPK was shown to be phosphorylated in the post-diapause developmental process. Results of kinase assay analysis showed that this phosphorylation is essential for AMPK activation. Using whole-mount immunohistochemistry, phosphorylated AMPK was shown to be predominantly located in the ectoderm of the early developed embryos in a ring shape; however, the location and shape of the activation region changed as development proceeded. Additionally, Western blotting analysis on different portions of the cyst extracts showed that phosphorylated AMPKα localized to the nuclei and this location was not affected by intracellular pH. Confocal microscopy analysis of immunofluorescent stained cyst nuclei further showed that AMPKα localized to the nuclei when activated. Moreover, cellular AMP, ADP, and ATP levels in developing cysts were determined by HPLC, and the results showed that the activation of Artemia AMPK may not be associated with cellular AMP:ATP ratios, suggesting other pathways for regulation of Artemia AMPK activity.ConclusionTogether, we report evidence demonstrating the activation of AMPK in Artemia developing cysts and present an argument for its role in the development-related gene expression and energy control in certain cells during post-diapause development of Artemia.
Peptidase inhibitors in the male reproductive tract are well known in mammals, in which they play roles in protecting the tract epithelium against proteolytic damage or in regulating the fertilization process. By screening the subtracted cDNA clones enriched for male reproductive tract-specific transcripts, one clone encoding a putative protein that showed significant similarity to Kazal-type peptidase inhibitor (KPI) was obtained. This is the first report of an invertebrate in which a male reproductive tract-specific KPI gene has been identified and characterized. The gene contains a 405-bp open reading frame (ORF), a 72 bp 5' untranslated region (UTR), and a 259 bp 3' UTR. The conceptually translated protein consisted of a 21-amino-acid signal peptide and a 113-amino-acid mature polypeptide with two Kazal-type domains (named after the discoverer). Significant levels of the mRNA were observed only in the male reproductive tract, while mRNA expression was not detected in any other tissues tested. The transcription of the gene remained constant during maturation, although not in the postlarval stage. In situ hybridization demonstrated the presence of the mRNA in the secretory epithelial cells of vas deferens and terminal ampullae.
Integration of Human Papillomaviruses (HPV) is an important mechanism of carcinogenesis but is absent in a significant fraction of HPV16+ tumors. We applied long-read whole-genome sequencing (WGS) to cervical cancer cell lines and tumors. In two HPV16+ cell lines, we identified large tandem arrays of full-length and truncated viral genomes integrated into multiple locations indicating formation as extrachromosomal DNA (HPV superspreading). An HPV16+ cell line with episomal DNA has tandem arrays of full-length, truncated, and rearranged HPV16 genomes (multimer episomes). WGS of HPV16+ cervical tumors revealed that 11/20 with only episomal HPV (EP) have intact monomer episomes. The remaining nine EP tumors have multimer and rearranged HPV genomes. Most HPV rearrangements disrupt the E1 and E2 genes, and EP tumors overexpress the E6 and E7 viral oncogenes. Tumors with both episomal and integrated HPV16 display multimer episomes and concatemers of human and viral sequences. One tumor has a recurrent deletion of an inhibitory site regulating E6 and E7 expression, and another has a recurrent duplication consistent with HPV superspreading. Therefore, HPV16 can cause cancer without integration through aberrant episomal replication, forming rearranged and multimer episomes.
Thrombocytopenia-absent radii (TAR) syndrome, characterized by neonatal thrombocytopenia and bilateral radial aplasia with thumbs present, is typically caused by the inheritance of a 1q21.1 deletion and a single-nucelotide polymorphism in RBM8A on the nondeleted allele. We evaluated two siblings with TAR-like dysmorphology but lacking thrombocytopenia in infancy. Family NCI-107 participated in an IRB-approved cohort study and underwent comprehensive clinical and genomic evaluations, including aCGH, whole-exome, whole-genome, and targeted sequencing. Gene expression assays and electromobility shift assays (EMSAs) were performed to evaluate the variant of interest. The previously identified TAR-associated 1q21.1 deletion was present in the affected siblings and one healthy parent. Multiple sequencing approaches did not identify previously described TAR-associated SNPs or mutations in relevant genes. We discovered rs61746197 A > G heterozygosity in the parent without the deletion and apparent hemizygosity in both siblings. rs61746197 A > G overlaps a RelA–p65 binding motif, and EMSAs indicate the A allele has higher transcription factor binding efficiency than the G allele. Stimulation of K562 cells to induce megakaryocyte differentiation abrogated the shift of both reference and alternative probes. The 1q21.1 TAR-associated deletion in combination with the G variant of rs61746197 on the nondeleted allele is associated with a TAR-like phenotype. rs61746197 G could be a functional enhancer/repressor element, but more studies are required to identify the specific factor(s) responsible. Overall, our findings suggest a role of rs61746197 A > G and human disease in the setting of a 1q21.1 deletion on the other chromosome.
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