Project description:RNA interference (RNAi) is a fundamental strategy for gene silencing via small interfering RNAs (siRNAs) that program Argonaute (Ago) effectors, and is related to endogenous silencing via microRNAs (miRNAs). Although most efforts focus on factors that are required for miRNA/RNAi function, biological systems are typically subject to repression. Using molecular genetic approaches, we uncover ALAS1, the first enzyme in the heme biosynthesis pathway, as a repressor of miRNA accumulation in cells and in mice. This was non-intuitive, since heme is known to play a positive role as a cofactor for the nuclear miRNA processing machinery. Instead, we show that ALAS1 (but not other core heme biosynthesis factors) limits RISC assembly and activity. Notably, ALAS1 is the target of one the few current FDA-approved siRNA drugs (Givosiran). Our data have implications for side effects of Givosiran, but also for RNAi therapies in general. We provide evidence that depletion of ALAS1 enhances siRNA-mediated knockdown, suggesting that Givosiran is a viable RNAi adjuvant.

Project description:RNA interference (RNAi) is a fundamental strategy for gene silencing via small interfering RNAs (siRNAs) that program Argonaute (Ago) effectors, and is related to endogenous silencing via microRNAs (miRNAs). Although most efforts focus on factors that are required for miRNA/RNAi function, biological systems are typically subject to repression. Using molecular genetic approaches, we uncover ALAS1, the first enzyme in the heme biosynthesis pathway, as a repressor of miRNA accumulation in cells and in mice. This was non-intuitive, since heme is known to play a positive role as a cofactor for the nuclear miRNA processing machinery. Instead, we show that ALAS1 (but not other core heme biosynthesis factors) limits RISC assembly and activity. Notably, ALAS1 is the target of one the few current FDA-approved siRNA drugs (Givosiran). Our data have implications for side effects of Givosiran, but also for RNAi therapies in general. We provide evidence that depletion of ALAS1 enhances siRNA-mediated knockdown, suggesting that Givosiran is a viable RNAi adjuvant.

Project description:RNA interference (RNAi) is a fundamental strategy for gene silencing via small interfering RNAs (siRNAs) that program Argonaute (Ago) effectors, and is related to endogenous silencing via microRNAs (miRNAs). Although most efforts focus on factors that are required for miRNA/RNAi function, biological systems are typically subject to repression. Using molecular genetic approaches, we uncover ALAS1, the first enzyme in the heme biosynthesis pathway, as a repressor of miRNA accumulation in cells and in mice. This was non-intuitive, since heme is known to play a positive role as a cofactor for the nuclear miRNA processing machinery. Instead, we show that ALAS1 (but not other core heme biosynthesis factors) limits RISC assembly and activity. Notably, ALAS1 is the target of one the few current FDA-approved siRNA drugs (Givosiran). Our data have implications for side effects of Givosiran, but also for RNAi therapies in general. We provide evidence that depletion of ALAS1 enhances siRNA-mediated knockdown, suggesting that Givosiran is a viable RNAi adjuvant.

Project description:Noncanonical role of ALAS1 as a heme-independent inhibitor of small RNA–mediated silencing [hepatocyte_sRNA-seq]

Project description:Noncanonical role of ALAS1 as a heme-independent inhibitor of small RNA–mediated silencing [HEK293T_sRNA-seq]

Project description:Noncanonical role of ALAS1 as a heme-independent inhibitor of small RNA–mediated silencing [hepatocyte RNA-Seq]

Project description:Noncanonical role of ALAS1 as a heme-independent inhibitor of small RNA–mediated silencing [Ago2-CLEAR-CLIP]

Project description:The liver, a pivotal organ in human metabolism, serves as a primary site for heme biosynthesis, critical for detoxification and drug metabolism. Maintaining precise control over heme production is paramount in healthy livers to meet high metabolic demands while averting potential toxicity from intermediate metabolites, notably protoporphyrin IX. Intriguingly, our recent research uncovers a disrupted heme biosynthesis process termed 'Porphyrin Overdrive' in cancers, fostering the accumulation of heme intermediates, potentially bolstering tumor survival. Here, we investigate heme and porphyrin metabolism in both healthy and oncogenic human livers, utilizing primary human liver transcriptomics and single-cell RNA sequencing (scRNAseq). Our investigations unveil robust gene expression patterns in heme biosynthesis in healthy livers, supporting electron transport chain (ETC) and cytochrome P450 function, devoid of intermediate accumulation. Conversely, liver cancers exhibit impaired heme biosynthesis and massive downregulation of cytochrome P450 expression. Notably, despite diminished drug metabolism, heme supply to the ETC remains largely unaltered or even elevated with cancer progression, suggesting a metabolic priority shift. Liver cancers selectively accumulate intermediates, absent in normal tissues, implicating their role in disease advancement as inferred by expression. Furthermore, our findings establish a link between diminished drug metabolism, augmented ETC function, porphyrin accumulation, and inferior overall survival in aggressive cancers, indicating potential targets for clinical therapy development.

Project description:Alas2 gene encodes the rate-limiting enzyme in heme biosynthesis. CRISPR/Cas9-mediated ablation of two Alas2 intronic cis-elements strongly reduced GATA-1-induced Alas2 transcription, heme biosynthesis, and GATA-1 regulation of other vital constituents of the erythroid cell transcriptome. Bypassing Alas2 function in Alas2 cis-element-mutant (double mutant) cells by providing its catalytic product 5-aminolevulinic acid (5-ALA) rescued heme biosynthesis and the GATA-1-dependent genetic network. We discovered a GATA factor- and heme-dependent circuit that establishes the erythroid cell transcriptome.

Project description:Alas2 gene encodes the rate-limiting enzyme in heme biosynthesis. CRISPR/Cas9-mediated ablation of two Alas2 intronic cis-elements strongly reduced GATA-1-induced Alas2 transcription, heme biosynthesis, and GATA-1 regulation of other vital constituents of the erythroid cell transcriptome. Bypassing Alas2 function in Alas2 cis-element-mutant (double mutant) cells by providing its catalytic product 5-aminolevulinic acid (5-ALA) rescued heme biosynthesis and the GATA-1-dependent genetic network. We discovered a GATA factor- and heme-dependent circuit that establishes the erythroid cell transcriptome. G1E-ER-GATA-1 WT and double mutant cells were examined. Untreated WT, beta-estradiol-treated WT, beta-estradiol-treated double-mutant, and beta-estradiol/5-ALA-treated double-mutant cells were subjected to RNA-seq.