Project description:Oxaliplatin as a first-line drug frequently causes the chemo-resistance on colorectal cancer (CRC). N6-methyladenosine (m6A) methylation has been largely acknowledged in multiple biological functions. However, the molecular mechanisms underlying the m6A methylation in modulating anticancer drug resistance in CRC are still obscure. In present study, RIP-seq was conducted to investigate the occupancy of N6-methyladenosine RNA binding protein 3 (YTHDF3) served as “readers” that can recognize m6A modification site in HCT116 cells with oxaliplatin resistance (HCT116R). Then, YTHDF3 was knockdown by siRNA in HCT116 cells with oxaliplatin resistance, and RIP-seq was further conducted to investigate m6A methylation of HCT116, HCT116R and HCT116R cells with YTHDF3 knockdown.

Project description:The branched-chain amino acids (BCAA) are essential to animal growth and intramuscular fat deposition, and also metabolic health (circulating level elevated in obesity and diabetes). However, the molecular role and effect of valine on muscle growth and fat deposition were less explored. Valine supplementation significantly affected mouse muscle growth, increasing the abdominal fat but decreasing the back fat. In the leg muscle, the expression levels of genes related to autophagy and fat deposition were significantly disturbed. Furthermore, valine promotes lipid deposition in myoblasts in a dose-dependent manner, and co-treatment of valine and palmitic acid can act in concert to enhance lipid deposition in myoblast. Moreover, transcriptome sequencing on myoblasts revealed that the signaling pathways such as mTOR, PI3K-AKT and fatty acid metabolism were activated after valine treatment, and palmitic acid additionally stimulated signaling pathways related to lipid metabolism in myoblasts. Therefore, valine could independently activate the autophagy pathway, and the fatty acid metabolism pathway to enhance intramuscular fat deposition

Project description:Dietary protein is a critical regulator of metabolic health and aging in diverse species, and many of the benefits of low-protein diets are recapitulated by restriction of the three branched-chain amino acids (BCAAs), leucine, isoleucine, and valine. In mouse models of Alzheimer’s disease (AD), dietary supplementation with BCAAs worsens AD neuropathology, while restriction of any of the BCAAs improves cognitive deficits. We recently discovered that each BCAA has distinct metabolic effects, with the restriction of isoleucine alone being sufficient to improve metabolic health and extend lifespan and healthspan in genetically diverse mice. Here, we investigate the effect of restricting each individual BCAA on metabolic health and the development and progression of AD in the 3xTg mouse model. We find that restriction of isoleucine and valine, but not leucine, promotes metabolic health. Restricting any of the three BCAAs improved short-term memory in males, with isoleucine restriction having the strongest effect, while restricting valine has the greatest cognitive benefits in females. Restriction of each BCAA had distinct effects on AD pathology, mTOR signaling, autophagy, and survival. Transcriptomic analysis of the brain revealed both distinct and shared, and highly sex-specific, molecular impacts of restricting each BCAA, and we identify a set of significantly altered pathways strongly associated with reduced AD pathology and improved cognitive performance in males. Our findings suggest that restricting any of the BCAAs, particularly isoleucine or valine, may form the basis of a novel sex-specific approach to prevent or delay the progression of AD.

Project description:Cells regulate protein synthesis in response to fluctuating nutrient availability through highly coordinated mechanisms that affect both translation initiation and elongation. Branched-chain amino acids (BCAAs) - leucine, isoleucine, and valine - are essential nutrients with a significant impact on cellular physiology. However, how their simultaneous depletion affects the translational machinery and dynamics remains largely unclear. Here, we examine the immediate effects of short-term BCAA limitation on translational dynamics in mammalian cells. We performed RNA sequencing (RNA-seq) and ribosome profiling (Ribo-seq) on NIH3T3 cells subjected to single, double, or triple BCAA deprivation. Our analyses revealed increased ribosome dwell times in the deprived conditions, with especially strong stalling at all valine codons during valine and triple starvation, while leucine and isoleucine depletion triggered more moderate, codon-specific effects. Notably, isoleucine-specific stalling largely diminished under triple deprivation, likely due to early elongation bottlenecks at valine codons. Correlating these stalling events with tRNA charging levels revealed distinct tRNA isoacceptor regulation in each starvation condition. In addition, integrating proteome data showed that many proteins downregulated under BCAA deprivation harbor stalling sites, suggesting that compromised elongation contributes to decreased protein output. Together, these findings suggest that differential ribosome stalling under BCAA limitation reflects a balance between amino acid supply, tRNA charging dynamics, and stress pathway modulation, illustrating that codon usage biases can profoundly influence the global landscape of translation under nutrient stress.

Project description:Cells regulate protein synthesis in response to fluctuating nutrient availability through highly coordinated mechanisms that affect both translation initiation and elongation. Branched-chain amino acids (BCAAs) - leucine, isoleucine, and valine - are essential nutrients with a significant impact on cellular physiology. However, how their simultaneous depletion affects the translational machinery and dynamics remains largely unclear. Here, we examine the immediate effects of short-term BCAA limitation on translational dynamics in mammalian cells. We performed RNA sequencing (RNA-seq) and ribosome profiling (Ribo-seq) on NIH3T3 cells subjected to single, double, or triple BCAA deprivation. Our analyses revealed increased ribosome dwell times in the deprived conditions, with especially strong stalling at all valine codons during valine and triple starvation, while leucine and isoleucine depletion triggered more moderate, codon-specific effects. Notably, isoleucine-specific stalling largely diminished under triple deprivation, likely due to early elongation bottlenecks at valine codons. Correlating these stalling events with tRNA charging levels revealed distinct tRNA isoacceptor regulation in each starvation condition. In addition, integrating proteome data showed that many proteins downregulated under BCAA deprivation harbor stalling sites, suggesting that compromised elongation contributes to decreased protein output. Together, these findings suggest that differential ribosome stalling under BCAA limitation reflects a balance between amino acid supply, tRNA charging dynamics, and stress pathway modulation, illustrating that codon usage biases can profoundly influence the global landscape of translation under nutrient stress.

Project description:This study investigates the immediate effects of single, double, and triple branched-chain amino acid (BCAA) deprivation on translational dynamics in NIH3T3 cells. Using a multi-omics approach combining RNA-seq, ribosome profiling (Ribo-seq), quantitative proteomics, and tRNA charging assays, we systematically assessed global translational output and codon-specific ribosome dwell times. Our findings reveal that BCAA starvation induces diverse and non-additive translational control patterns, reflecting a complex interplay between mTORC1 and GCN2 pathway activation, tRNA isoacceptor availability, and transcript codon usage. Notably, we identified a positional effect where the enrichment of valine codons at the 5' end of transcripts creates an elongation bottleneck under valine and triple BCAA starvation, impacting downstream ribosome occupancy and overall protein output. This study uncovers a previously underappreciated layer of complexity in BCAA-specific translational regulation.

Project description:m6A and YTHDF1, YTHDF2, YTHDF3 mapping of IAV RNA with PAR-CLIP and pA-m6A-seq

Project description:Knocking down YTHDF3 in breast cancer cells resulted in an altered gene expression profile N6-methyl-adenosine (m6A) is the most prevalent internal chemical modification in eukaryotic messenger RNAs and emerging as a critical mRNA chemical mark that mediates post-transcriptional gene expression regulation. YTHDF3 facilitates translation and decay of m6A-modified mRNAs. However, the role for YTHDF3 protein in breast cancer brain metastasis remain to be elucidated. We found that YTHDF3 is overexpressed in brain metastasis of breast cancer cells. Our study will characterize the expression profiling in YTHDF3 silencing breast cancer cells compared to shControl breast cancers cells. The objectives are to identify expression profiles that are specific to shYTHDF3 breast cancer cell to identify new the signaling pathway of YTHDF3 for brain metastasis of breast cancer cells.

Project description:Knocking down YTHDF3 in breast cancer cells resulted in an altered gene expression profile N6-methyl-adenosine (m6A) is the most prevalent internal chemical modification in eukaryotic messenger RNAs and emerging as a critical mRNA chemical mark that mediates post-transcriptional gene expression regulation. YTHDF3 facilitates translation and decay of m6A-modified mRNAs. However, the role for YTHDF3 protein in breast cancer brain metastasis remain to be elucidated. We found that YTHDF3 is overexpressed in brain metastasis of breast cancer cells. Our study will characterize the expression profiling in YTHDF3 silencing breast cancer cells compared to shControl breast cancers cells. The objectives are to identify expression profiles that are specific to shYTHDF3 breast cancer cell to identify new the signaling pathway of YTHDF3 for brain metastasis of breast cancer cells.

Project description:Brain metastasis is a major cause of cancer mortality, but its molecular mechanisms are severely understudied. We found that YTHDF3 overexpression clinically correlates with brain metastases in breast cancer patients and is required for brain metastasis. Silencing YTHDF3 suppressed the brain metastasis of breast cancer cells in vitro and in vivo. Integrated transcriptome and m6A-seq analysis revealed alter expression of selected YTHDF3 target genes, including ST6GALNAC5, GJA1, and EGFR by promoting m6A-dependent translation of these target transcripts. Our work uncovers an essential role of YTHDF3 in controlling the interaction between cancer cells and brain microenvironment, thereby gaining brain metastatic competence.