Project description:Minor intron-containing genes (MIGs), which require the minor spliceosome (MiS) for their splicing, are highly represented among genes involved in mouse spermatogenesis. Leveraging gene- and intron-level ortholog data, we show that conservation of these genes as MIGs is particularly strong in chordates but not in other species groups, suggesting lineage-specific changes to their splicing regulation. A role for the MiS in splicing during spermatogenesis was reinforced by the cell-type specific expression patterns of MiS snRNAs and directly tested using Stra8-Cre mediated ablation of Rnu11, which encodes for the MiS U11 snRNA. Rnu11 mutant testes were smaller, and presented with multiple mitotic and meiotic defects, increased cell death, and a reduction in mature sperm at matched timepoints. RNA sequencing of P14 whole testes revealed minor intron retention and alternative splicing events in MIGs that are key regulators of genomic stability, cell cycle progression, and gene expression regulation, contributing to the variable cellular defects. RT-PCR of fractionated cell types of the testes confirmed splicing defects of key MIGs in cell-type enriched samples. The multifaceted molecular disruption resulted in defective meiotic recombination, telomere morphology, chromosome synapsis and XY-chromosome association. Overall, we highlight the molecular and cellular processes that are regulated by the MiS.

Project description:Aberrant RNA splicing is tightly linked to diseases, including metabolic dysfunction-associated steatotic liver disease (MASLD). Here, we revealed that minor intron splicing, a unique and conserved RNA processing event, is largely disrupted upon the progression of metabolic dysfunction-associated steatohepatitis (MASH) in mice and humans. We demonstrated deficiency of minor intron splicing in the liver induces MASH transition upon obesity-induced insulin resistance and LXR activation. Mechanistically, inactivation of minor intron splicing leads to minor intron retention of Insig1 and Insig2, resulting in premature termination of translation, which drives proteolytic activation of SREBP1c. This mechanism is conserved in human patients with MASH. Notably, disrupted minor intron splicing activates glutamine reductive metabolism for de novo lipogenesis through the induction of Idh1, which causes the accumulation of ammonia in the liver, thereby initiating hepatic fibrosis upon LXR activation. Ammonia clearance or IDH1 inhibition blocks hepatic fibrogenesis and mitigates MASH progression. More importantly, the overexpression of Zrsr1 restored minor intron retention and ameliorated the development of MASH, indicating that dysfunctional minor intron splicing is an emerging pathogenic mechanism that drives MASH progression. Additionally, reductive carboxylation flux triggered by minor intron retention in hepatocytes serves as a crucial checkpoint and potential target for MASH therapy.

Project description:Most metazoans contain two distinct pre-mRNA splicing machineries: the major spliceosome, which removes >99% of introns, and the minor spliceosome, which recognizes <1% of introns. Despite their rarity, minor introns are exquisitely conserved amongst species, suggesting important regulatory functions. However, physiologic roles for the minor spliceosome and the relevance of recurrent, leukemia-associated mutations affecting minor spliceosome components are not well understood. Here, we identify that mutational loss of the minor spliceosomal factor ZRSR2 enhances hematopoietic stem cell self-renewal via impaired minor intron splicing that converges on LZTR1, a regulator of Ras-related GTPases. LZTR1 minor intron retention is additionally observed in Noonan syndrome and diverse cancers. These data uncover minor intron recognition as a regulator of hematopoiesis and mechanistic links between ZRSR2 mutations, LZTR1, and leukemia.

Project description:Most eukaryotes harbor two distinct pre-mRNA splicing machineries: the major spliceosome, which removes >99% of introns, and the minor spliceosome, which removes rare, evolutionarily conserved introns. Although hypothesized to serve important regulatory functions, physiologic roles for the minor spliceosome are not well understood. For example, the minor spliceosome component ZRSR2 is subject to recurrent, leukemia-associated mutations, yet functional connections between minor introns, hematopoiesis, and cancers are unclear. Here, we identify that impaired minor intron excision via ZRSR2 loss enhances hematopoietic stem cell self-renewal. CRISPR screens mimicking nonsense-mediated decay of minor intron-containing mRNAs converged on LZTR1, a regulator of Ras-related GTPases. LZTR1 minor intron retention was also discovered in the RASopathy Noonan syndrome, due to intronic mutations disrupting splicing, and diverse solid tumors. These data uncover minor intron recognition as a regulator of hematopoiesis, noncoding mutations within minor introns as cancer drivers, and links between ZRSR2 mutations, LZTR1 regulation, and leukemias.

Project description:Minor intron retention resulting from dysregulation of minor intron splicing factors is an emerging risk factor for the metabolic-associated steatotic liver disease (MASLD). However, whether impaired expression of these splicing factors exerts critical roles in MASLD progression independent of their minor intron splicing activity remains largely undefined. Here, we show that hepatic expression of the minor intron splicing factor Zrsr1 is significantly downregulated in mice fed a high-fat diet (HFD), while canonical minor intron splicing remains unperturbed. Hepatic Zrsr1 overexpression effectively mitigates HFD-induced obesity and insulin resistance, demonstrating that Zrsr1 expression protects MASLD progression via a minor intron splicing-independent mechanism. Notably, Zrsr1 cell-autonomously suppresses liver X receptor (LXR) activation-induced de novo lipogenesis in both hepatocyte models and mouse models. Mechanistically, we demonstrate that Zrsr1 directly interacts with LXRα, and this physical interaction suppresses the transactivation of the LXRα/retinoid X receptor α (RXRα) complex, thereby inhibiting the subsequent transcription of sterol regulatory element-binding protein 1c (Srebp1c). Collectively, these findings define a novel, splicing-independent function of the minor intron splicing factor Zrsr1 in mediating hepatic de novo lipogenesis via constraining the LXR-SREBP1c axis, which in turn mitigates MASLD progression. This work expands the functional repertoire of minor intron splicing factors beyond their classical splicing role, providing new insights into the molecular mechanisms underlying hepatic fatty acid metabolism and MASLD pathogenesis.

Project description:Minor intron retention resulting from dysregulation of minor intron splicing factors is an emerging risk factor for the metabolic-associated steatotic liver disease (MASLD). However, whether impaired expression of these splicing factors exerts critical roles in MASLD progression independent of their minor intron splicing activity remains largely undefined. Here, we show that hepatic expression of the minor intron splicing factor Zrsr1 is significantly downregulated in mice fed a high-fat diet (HFD), while canonical minor intron splicing remains unperturbed. Hepatic Zrsr1 overexpression effectively mitigates HFD-induced obesity and insulin resistance, demonstrating that Zrsr1 expression protects MASLD progression via a minor intron splicing-independent mechanism. Notably, Zrsr1 cell-autonomously suppresses liver X receptor (LXR) activation-induced de novo lipogenesis in both hepatocyte models and mouse models. Mechanistically, we demonstrate that Zrsr1 directly interacts with LXRα, and this physical interaction suppresses the transactivation of the LXRα/retinoid X receptor α (RXRα) complex, thereby inhibiting the subsequent transcription of sterol regulatory element-binding protein 1c (Srebp1c). Collectively, these findings define a novel, splicing-independent function of the minor intron splicing factor Zrsr1 in mediating hepatic de novo lipogenesis via constraining the LXR-SREBP1c axis, which in turn mitigates MASLD progression. This work expands the functional repertoire of minor intron splicing factors beyond their classical splicing role, providing new insights into the molecular mechanisms underlying hepatic fatty acid metabolism and MASLD pathogenesis.

Project description:Aberrant RNA splicing is tightly linked to diseases, including metabolic dysfunction-associated steatotic liver disease (MASLD). Here, we revealed that minor intron splicing, a unique and conserved RNA processing event, is largely disrupted upon the progression of metabolic dysfunction-associated steatohepatitis (MASH) in mice and humans. We demonstrated deficiency of minor intron splicing in the liver induces MASH transition upon obesity-induced insulin resistance and LXR activation. Mechanistically, inactivation of minor intron splicing leads to minor intron retention of Insig1 and Insig2, resulting in premature termination of translation, which drives proteolytic activation of SREBP1c. This mechanism is conserved in human patients with MASH. Notably, disrupted minor intron splicing activates glutamine reductive metabolism for de novo lipogenesis through the induction of Idh1, which causes the accumulation of ammonia in the liver, thereby initiating hepatic fibrosis upon LXR activation. Ammonia clearance or IDH1 inhibition blocks hepatic fibrogenesis and mitigates MASH progression. More importantly, the overexpression of Zrsr1 restored minor intron retention and ameliorated the development of MASH, indicating that dysfunctional minor intron splicing is an emerging pathogenic mechanism that drives MASH progression. Additionally, reductive carboxylation flux triggered by minor intron retention in hepatocytes serves as a crucial checkpoint and potential target for MASH therapy.

Project description:Aneuploidy is the leading cause of miscarriage and congenital birth defects, and a hallmark of cancer. Despite this strong association with human disease, the genetic causes of aneuploidy remain largely unknown. Through exome sequencing of patients with constitutional mosaic aneuploidy, we identified biallelic truncating mutations in CENATAC (CCDC84). We show that CENATAC is a novel component of the minor (U12-dependent) spliceosome that promotes splicing of a specific, rare minor intron subtype. This subtype is characterized by AT-AN splice sites and relatively high basal levels of intron retention. CENATAC depletion or expression of disease mutants resulted in excessive retention of AT-AN minor introns in ~100 genes enriched for nucleocytoplasmic transport and cell cycle regulators, and caused chromosome segregation errors. Our findings reveal selectivity in minor intron splicing and suggest a link between minor spliceosome defects and constitutional aneuploidy in humans.

Project description:The minor spliceosome is evolutionarily conserved in higher eukaryotes, but its biological significance remains poorly understood. Here, by precise CRISPR/Cas9-mediated disruption of the U12 and U6atac snRNAs, we report that a defective minor spliceosome is responsible for spinal muscular atrophy (SMA) associated phenotypes in Drosophila. Using a newly developed bioinformatic approach, we identified a large set of minor spliceosome-sensitive splicing events and demonstrate that three sensitive intron-containing neural genes, Pcyt2, Zmynd10, and Fas3, directly contribute to disease development as evidenced by the ability of their cDNAs to rescue the SMA-associated phenotypes in muscle development, neuromuscular junctions, and locomotion. Interestingly, many splice sites in sensitive introns are recognizable by both minor and major spliceosomes, suggesting a new mechanism of splicing regulation through competition between minor and major spliceosomes. These findings reveal a vital contribution of the minor spliceosome to SMA and to regulated splicing in animals.

Project description:Mutations in the minor spliceosome components such as RNU4atac, a small nuclear RNA (snRNA), are linked to primary microcephaly. We have reported that in the conditional knockout (cKO) mice for Rnu11, a minor spliceosome snRNA, minor intron splicing defect in minor intron-containing genes (MIGs) regulating cell cycle resulted in cell cycle defect with a concomitant increase in yH2aX+ cells and P53-mediated apoptosis. Trp53 ablation in the Rnu11 cKO mice did not prevent microcephaly. Although RNAseq analysis of the double knockout (dKO) pallium reflected transcriptomic shift towards the control from the cKO. We found elevated minor intron retention and alternative splicing across minor introns in the dKO. Disruption of these minor intron-containing genes (MIGs) resulted in cell cycle defect that was detected earlier and was more severe in the dKO, but with delayed detection of yH2aX+ DNA damage. Thus, P53 might also play a role in causing DNA damage in the developing pallium. In all, our findings further refine our understanding of the role of the minor spliceosome in cortical development and identify MIGs underpinning microcephaly in minor spliceosome-related disease.