The functionally conserved human lncRNA motif GULF lowers glucose and lipid levels in obese mice
Zhe Li, … , Hang Sun, Haiming Cao
Zhe Li, … , Hang Sun, Haiming Cao
Published September 16, 2025
Citation Information: J Clin Invest. 2025;135(18):e186355. https://doi.org/10.1172/JCI186355.
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Research Article Metabolism

The functionally conserved human lncRNA motif GULF lowers glucose and lipid levels in obese mice

Abstract

Growing evidence links human long noncoding RNAs (lncRNAs) to metabolic disease pathogenesis, yet no FDA-approved drugs target human lncRNAs. Most human lncRNAs lack conservation in other mammals, complicating efforts to define their roles and identify therapeutic targets. Here, we leveraged the concept of functionally conserved lncRNAs (FCLs) — lncRNAs that share function despite no sequence similarity — to develop a framework for identifying human lncRNAs as therapeutic targets for metabolic disorders. We used expression quantitative trait loci mapping and functional conservation analyses to pinpoint human lncRNAs influenced by disease-associated SNPs and with potential functionally conserved mouse equivalents. We identified human and mouse GULLs (glucose and lipid lowering), which regulate glucose and lipid metabolism by binding CRTC2, thereby modulating gluconeogenic genes via CREB and lipogenic genes via SREBP1. Despite their lack of sequence similarity, both lncRNAs demonstrated similar metabolic effects in obese mice, with more pronounced benefits from long-term activation. To identify druggable sites, we mapped GULLs’ binding motifs to CRTC2 (termed GULFs). Standalone human GULF, an RNA oligomer resembling FDA-approved siRNAs, significantly improved glucose and lipid levels in obese mice. This framework highlights functionally conserved human lncRNAs as promising therapeutic targets, exemplified by GULLs’ potential as a glucose- and lipid-lowering therapeutic.

Authors

Zhe Li, Sunmi Seok, Chengfei Jiang, Ping Li, Yonghe Ma, Hang Sun, Haiming Cao

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Figure 1

Identification of h/mGULLs as a pair of functionally conserved lncRNAs closely related to metabolic disorders.

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Identification of h/mGULLs as a pair of functionally conserved lncRNAs c...
(A) Flowchart for screening the functional conserved lncRNA candidates that are closely associated with metabolic disorders with human GWAS data and nanopore sequencing data (GSE224278). hGULL/mGULL was selected for further study. (B) Graphical representation of location and details of hGULL/mGULL on human or mouse chromosomes from Integrative Genomics Viewer and UCSC Genome Browser (human GRCh38/hg38 and mouse GRCm39/mm39). (C) Graphical representation of the rescue experiment. Mice were injected with 3 groups of adenoviruses: Ad-Ctrl (Lac+pAdV5), mGULL knockdown (Ad-shmGULL+pAdV5), or rescue group (Ad-shmGULL+Ad-hGULL). (D) Heatmap showing the top 600 significantly expressed genes in the mGULL knockdown and mGULL knockdown with hGULL overexpression rescue groups. (E) Gene Ontology (GO) enrichment analysis focused on the biological processes that can be rescued, summarized based on |normalized enrichment score| > 1.5, P < 0.01, and adjusted P value (FDR) < 0.1 from gene set enrichment analysis. The differentially expressed genes were defined as |log2(fold change)| > 0.5 and P < 0.05. (F) Quantitative reverse transcriptase PCR (qRT-PCR) analysis of mRNA levels of lipid synthesis genes (Elovl6, Acc1, Acly, Gck, Scd1, and Fasn), gluconeogenesis genes (G6pc and Pck1), and β-oxidation genes (Cpt1a and Mcad) in rescue assay. *Comparison between Ad-Ctrl and Ad-shmGULL groups; #comparison between Ad-shmGULL and Ad-shmGULL+hGULL groups. (G and H) Plasma/liver TG level, GTT, and ITT were determined in the rescue assay. *Comparison between Ad-Ctrl and Ad-shmGULL groups; #comparison between Ad-shmGULL and Ad-shmGULL+hGULL groups. (I) Immunoblot assay determined the protein levels of p-AKT, AKT, p-GSK3β, and GSK3β in the rescue assay with or without insulin treatment. Data are shown as mean ± SD, 1-way ANOVA, in FH. *P < 0.05, **P < 0.01, ***P < 0.001; #P < 0.05, ##P < 0.01, ###P < 0.001.