Abstract Background Congenital heart disease (CHD) is a prevalent congenital cardiac malformation, which lacks effective early biological diagnosis and intervention. MicroRNAs, as epigenetic regulators of cardiac development, provide potential biomarkers for the diagnosis and treatment of CHD. However, the mechanisms underlying miRNAs-mediated regulation of cardiac development and CHD malformation remain to be further elucidated. This study aimed to explore the function of microRNA-20b-5p (miR-20b-5p) in cardiac development and CHD pathogenesis. Methods and results miRNA expression profiling identified that miR-20b-5p was significantly downregulated during a 12-day cardiac differentiation of human embryonic stem cells (hESCs), whereas it was markedly upregulated in plasma samples of atrial septal defect (ASD) patients. Our results further revealed that miR-20b-5p suppressed hESCs-derived cardiac differentiation by targeting tet methylcytosine dioxygenase 2 (TET2) and 5-hydroxymethylcytosine, leading to a reduction in key cardiac transcription factors including GATA4 , NKX2.5 , TBX5 , MYH6 and cTnT . Additionally, knockdown of TET2 significantly inhibited cardiac differentiation, which could be partially restored by miR-20b-5p inhibition. Conclusions Collectively, this study provides compelling evidence that miR-20b-5p functions as an inhibitory regulator in hESCs-derived cardiac differentiation by targeting TET2, highlighting its potential as a biomarker for ASD.
Objective To identify the functional single‐nucleotide polymorphisms (SNPs) and mechanisms conferring increased risk of hand osteoarthritis (OA) at the ALDH1A2 locus, which is a retinoic acid regulatory gene. Methods Tissue samples from 247 patients with knee, hip, or hand OA who had undergone joint surgery were included. RNA‐sequencing analysis was used to investigate differential expression of ALDH1A2 and other retinoic acid signaling pathway genes in cartilage. Expression of ALDH1A2 in joint tissues obtained from multiple sites was quantified using quantitative reverse transcription–polymerase chain reaction. Allelic expression imbalance (AEI) was measured by pyrosequencing. The consequences of ALDH1A2 depletion by RNA interference were assessed in primary human chondrocytes. In silico and in vitro analyses were used to pinpoint which, among 62 highly correlated SNPs, could account for the association at the locus. Results ALDH1A2 expression was observed across multiple joint tissue samples, including osteochondral tissue from the hand. The expression of ALDH1A2 and of several retinoic acid signaling genes was different in diseased cartilage compared to non‐diseased cartilage, with ALDH1A2 showing lower levels in OA cartilage. Experimental depletion of ALDH1A2 resulted in changes in the expression levels of a number of chondrogenic markers, including SOX9 . In addition, reduced expression of the OA risk–conferring allele was witnessed in a number of joint tissues, with the strongest effect in cartilage. The intronic SNP rs12915901 recapitulated the AEI observed in patient tissues, while the Ets transcription factors were identified as potential mediators of this effect. Conclusion The ALDH1A2 locus seems to increase the risk of hand OA through decreased expression of ALDH1A2 in joint tissues, with the effect dependent on rs12915901. These findings indicate a mechanism that may now be targeted to modulate OA risk.
Abstract The genome DNA is consistently threatened by a variety of intrinsic and exogenous DNA damage factors. Cell cycle checkpoint is one important mechanism in response to DNA damage and maintaining genome stability. In tumor cells, gene alterations, such as CCNE1 amplification (encoding for Cyclin E1), result in G1/S checkpoint loss and replication stress, leading to high dependency on the G2/M checkpoint. PKMYT1 inhibits crucial checkpoint protein CDK1 activity by phosphorylating CDK1 at the residues of Thr-14 and Tyr-15 in the G2/M phase. In CCNE1 amplification cells, the inhibition of PKMYT1 leads to the reduction of pCDK1 and loss of G2/M checkpoint, consequently results in premature mitosis and the accumulation of DNA damage, then finally induces cell death. Here we identify a novel small molecular ZM-2322, which displays robust intracellular binding to PKMYT1 and inhibits the specific downstream phosphorylation of CDK1 Thr-14 with IC50 values of 14 nM and 29 nM, respectively. ZM-2322 strongly inhibits the proliferation of the HCC1569 cell line with CCNE1 high-level amplification and shows a >400 × selectivity folds over a CCNE1 wildtype cell line SKOV3. ZM-2322 also shows significant inhibition of tumor growth in a dose-dependent manner in the HCC1569 xenograft model, and the efficacy correlates well with PK and target inhibition. There is evidence showing that loss-of-function mutations of FBXW7, a cyclin E E3 ligase, lead to cyclin E accumulation and are synthetic-lethal with PKMYT1 inhibition. Consistently, a potent anti-proliferation of ZM-2322 is observed in DLD-1 FBXW7 -/- cells, but not DLD-1 parental cells. These data suggest a high potency of ZM-2322 on PKMYT1 inhibition and a potential good kinase selectivity which is further confirmed by using a kinase panel biochemical assay. As expected, when compared head-to-head with another clinical PKMYT1 inhibitor RP-6306 which shows inhibitory effect on 27 of 217 human kinases with inhibition rates >90% at 1 μM, ZM-2322 is found to be a much more PKMYT1-selective inhibitor and hits only several individual kinases under the same assay condition, suggesting a potentiality in better safety profile and higher dose tolerance. Furthermore, our data illustrates that in combination with gemcitabine, ZM-2322 elicits strong synergetic anti-proliferation activities on HCC1569 cells in vitro and results in tumor regression with a minor effect on body weight in vivo. Besides, a strong synergy effect is also observed in the combo of ZM-2322 and ATR inhibitor in HCC1569 in vitro. These data indicate that ZM-2322 has the potential of application expansion and good tolerance under continuous administration. Taken together, our data suggest that ZM-2322 is a potent and highly selective PKMYT1 inhibitor. Citation Format: Feng Zhou, Lu Liu, Lei Jiang, Baoying Cheng, Zhentao Li, Dongxing Zhu, Jianbin Xue, Liting Xue, Renhong Tang. Discovery of ZM-2322, a highly selective, potent inhibitor of membrane-associated tyrosine- and threonine-specific cdc2-inhibitory kinase (PKMYT1) [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 591.
Despite extensive investigation into estrogen's role in pulmonary hypertension (PH) development, its effects-whether beneficial or detrimental-remains contentious. This study aimed to elucidate estrogen's potential role in PH under normoxic and hypoxic conditions. Utilizing norfenfluramine- and hypoxia-induced rat models of PH, the study evaluated the impact of 17β-estradiol (E2) on PH progression. E2 promoted PH development under normoxia while providing protection under hypoxia. Mechanistically, under normoxia, E2 upregulated methyltransferase-like 3 (METTL3) gene transcription and protein via an estrogen response element-dependent pathway, which in turn elevated the m6A methylation and translational efficiency of 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase isoform 3 (PFKFB3) mRNA, leading to increased PFKFB3 protein levels and enhanced proliferation and migration of pulmonary artery smooth muscle cells (PASMCs). Conversely, under hypoxia, E2 downregulated METTL3 transcription through a hypoxia response element-dependent mechanism, driven by elevated hypoxia-induced factor 1α (HIF-1α) levels, resulting in reduced PFKFB3 protein expression and diminished PASMCs proliferation and migration. Both METTL3 and PFKFB3 proteins are upregulated in the pulmonary arteries of patients with PAH. Collectively, these findings suggest that E2 exerts differential effects on PH progression via dual regulation of the METTL3/PFKFB3 protein under normoxic and hypoxic conditions, positioning the METTL3/PFKFB3 protein as a potential therapeutic target for PH treatment.
A link between increased glycolysis and vascular calcification has recently been reported, but it remains unclear how increased glycolysis contributes to vascular calcification. We therefore investigated the role of PFKFB3, a critical enzyme of glycolysis, in vascular calcification. We found that PFKFB3 expression was upregulated in calcified mouse VSMCs and arteries. We showed that expression of miR-26a-5p and miR-26b-5p in calcified mouse arteries was significantly decreased, and a negative correlation between Pfkfb3 mRNA expression and miR-26a-5p or miR-26b-5p was seen in these samples. Overexpression of miR-26a/b-5p significantly inhibited PFKFB3 expression in VSMCs. Intriguingly, pharmacological inhibition of PFKFB3 using PFK15 or knockdown of PFKFB3 ameliorated vascular calcification in vD3 -overloaded mice in vivo or attenuated high phosphate (Pi)-induced VSMC calcification in vitro. Consistently, knockdown of PFKFB3 significantly reduced glycolysis and osteogenic transdifferentiation of VSMCs, whereas overexpression of PFKFB3 in VSMCs induced the opposite effects. RNA-seq analysis and subsequent experiments revealed that silencing of PFKFB3 inhibited FoxO3 expression in VSMCs. Silencing of FoxO3 phenocopied the effects of PFKFB3 depletion on Ocn and Opg expression but not Alpl in VSMCs. Pyruvate or lactate supplementation, the product of glycolysis, reversed the PFKFB3 depletion-mediated effects on ALP activity and OPG protein expression in VSMCs. Our results reveal that blockade of PFKFB3-mediated glycolysis inhibits vascular calcification in vitro and in vivo. Mechanistically, we show that FoxO3 and lactate production are involved in PFKFB3-driven osteogenic transdifferentiation of VSMCs. PFKFB3 may be a promising therapeutic target for the treatment of vascular calcification.
Calcific aortic valve disease (CAVD) is the most common heart disease of the developed world. It has previously been established that metformin administration reduces arterial calcification via autophagy; however, whether metformin directly regulates CAVD has yet to be elucidated. In the present study we investigated whether metformin alleviates valvular calcification through the autophagy-mediated recycling of Runx2. Calcification was reduced in rat valve interstitial cells (RVICs) by metformin treatment (0.5-1.5 mM) (P < 0.01), with a marked decrease in Runx2 protein expression compared to control cells (P < 0.05). Additionally, upregulated expression of Atg3 and Atg7 (key proteins required for autophagosome formation), was observed following metformin treatment (1 mM). Blocking autophagic flux using Bafilomycin-A1 revealed colocalisation of Runx2 with LC3 puncta in metformin treated RVICs (P < 0.001). Comparable Runx2 accumulation was seen in LC3 positive autolysosomes present within cells that had been treated with both metformin and hydroxychloroquine in combination (P < 0.001). Mechanistic studies employing three-way co-immunoprecipitation with Runx2, p62 and LC3 suggested that Runx2 binds to LC3-II upon metformin treatment in VICs. Together these studies suggest that the utilisation of metformin may represent a novel strategy for the treatment of CAVD.
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