👤 Kazunari Nohara

G-Quadruplexes (G4s) are noncanonical nucleic acid secondary structures enriched in genomic regions critical for transcription and replication. These dynamic scaffolds recruit G4-binding proteins (G4BPs), thereby regulating diverse cellular processes. However, the functional roles of G4BPs in the G4-bound state remain poorly defined. Here, we report the development of G4L-PROTACs-bifunctional small molecules that couple a G4 ligand with an E3 ligase recruiter to achieve selective proteasomal degradation of G4-bound G4BPs. Unlike RNAi or CRISPR-Cas9, which eliminate proteins irrespective of binding state, G4L-PROTACs enable depletion of G4BPs only when associated with G4s. Using model G4 motifs from telomeres and the NRAS 5' UTR, we demonstrated in vitro ternary complex formation. In cells, G4L-PROTAC treatment reduced endogenous levels of the G4-resolving helicase DHX36, resulting in a marked increase in intracellular G4 abundance, as shown by BG4 immunofluorescence. This phenotype highlights the ability of G4L-PROTACs to modulate the G4-protein equilibrium in living cells. Notably, G4L-PROTACs do not induce G4-mediated transcriptional silencing, underscoring their precision in modulating nucleic acid-protein interactions. This strategy offers a powerful platform for probing G4-G4BP functions and holds promise for therapeutic targeting of G4-associated proteins. Show less

Multi-organ regulation underlies metabolic health, especially in the context of adipose-liver dysfunction during obesity. Previous findings identified Melinjo seed extract (MSE) as a promising modulator of metabolic disorders, although its active component remained unknown. Gnetin C, a trans-resveratrol dimer from MSE, likely serves as the key factor, yet its direct metabolic role remains unclear. Here, Gnetin C was administered to high-fat diet (HFD)-fed mice, which significantly improved body weight and fasting glucose, attributed to enhanced adiponectin (APN) multimerization. In adipose tissue, Gnetin C directly promotes APN multimerization and suppresses fat accumulation by up-regulating the PPARγ-DsbA-L axis, while concurrently modulating hepatic Sirt1, which may contribute to increased FGF21 production. This paracrine FGF21 signaling, suggested by elevated Fgfr1 in hepatocytes and βKlotho in adipocytes, further augments APN multimerization. These findings underscore the importance of a multi-tissue approach to obesity management and position Gnetin C as an integrative therapeutic candidate, restoring metabolic balance via dual adipose and hepatic effects in HFD mice. Show less

Little data exist regarding the clinical application of whole exome sequencing (WES) for the molecular diagnosis of severe hypertriglyceridemia (HTG). WES was performed for 28 probands exhibiting severe HTG (≥1000 mg/dl) without any transient causes. We evaluated recessive and dominant inheritance models in known monogenic HTG genes, followed by disease-network gene prioritization and copy number variation (CNV) analyses to identify causative variants and a novel genetic mechanism for severe HTG. We identified possible causative variants for severe HTG, including three novel variants, in nine probands (32%). In the recessive inheritance model, we identified two homozygous subjects with lipoprotein lipase (LPL) deficiency and one subject harboring compound heterozygous variants in both LPL and APOA5 genes (hyperchylomicronemia). In the dominant inheritance model, we identified probands harboring deleterious heterozygous variants in LPL, glucokinase regulatory protein, and solute carrier family 25 member 40 genes, possibly associated with this extreme HTG phenotype. However, gene prioritization and CNV analyses did not validate the novel genes associated with severe HTG. In 28 probands with severe HTG, we identified potential causative variants within nine genes associated with rare Mendelian dyslipidemias. Clinical WES may be feasible for such extreme cases, potentially leading to appropriate therapies. Show less

Ammonia detoxification is essential for physiological well-being, and the urea cycle in liver plays a predominant role in ammonia disposal. Nobiletin (NOB), a natural dietary flavonoid, is known to exhibit various physiological efficacies. In the current study, we investigated a potential role of NOB in ammonia control and the underlying cellular mechanism. C57BL/6 mice were fed with regular chow (RC), high-fat (HFD) or high-protein diet (HPD) and treated with either vehicle or NOB. Serum and/or urine levels of ammonia and urea were measured. Liver expression of genes encoding urea cycle enzymes and C/EBP transcription factors was determined over the circadian cycle. Luciferase reporter assays were carried out to investigate function of CCAAT consensus elements on the carbamoyl phosphate synthetase (Cps1) gene promoter. A circadian clock-deficient mouse mutant, Clock (Δ19/Δ19) , was utilized to examine a requisite role of the circadian clock in mediating NOB induction of Cps1. NOB was able to lower serum ammonia levels in mice fed with RC, HFD or HPD. Compared with RC, HFD repressed the mRNA and protein expression of Cps1, encoding the rate-limiting enzyme of the urea cycle. Interestingly, NOB rescued CPS1 protein levels under the HFD condition via induction of the transcription factors C/EBPα and C/EBPβ. Expression of other urea cycle genes was also decreased by HFD relative to RC and again restored by NOB to varying degrees, which, in conjunction with Cps1 promoter reporter analysis, suggested a C/EBP-dependent mechanism for the co-induction of urea cycle genes by NOB. In comparison, HPD markedly increased CPS1 levels relative to RC, yet NOB did not further enrich CPS1 to a significant extent. Using the circadian mouse mutant Clock (Δ19/Δ19) , we also showed that a functional circadian clock, known to modulate C/EBP and CPS1 expression, was required for NOB induction of CPS1 under the HFD condition. NOB, a dietary flavonoid, exhibits a broad activity in ammonia control across varying diets, and regulates urea cycle function via C/EBP-and clock-dependent regulatory mechanisms. Show less