Alicia Flores-Roco, Belinda M Lago, Ricardo Villa-Bellosta
{"title":"葡萄糖水平升高会扰乱细胞外焦磷酸代谢,从而增加血管钙化的风险。","authors":"Alicia Flores-Roco, Belinda M Lago, Ricardo Villa-Bellosta","doi":"10.1186/s12933-024-02502-w","DOIUrl":null,"url":null,"abstract":"<p><strong>Background: </strong>Vascular calcification is a major contributor to cardiovascular disease, especially diabetes, where it exacerbates morbidity and mortality. Although pyrophosphate is a recognized natural inhibitor of vascular calcification, there have been no prior studies examining its specific deficiency in diabetic conditions. This study is the first to analyze the direct link between elevated glucose levels and disruptions in extracellular pyrophosphate metabolism.</p><p><strong>Methods: </strong>Rat aortic smooth muscle cells, streptozotocin (STZ)-induced diabetic rats, and diabetic human aortic smooth muscle cells were used to assess the effects of elevated glucose levels on pyrophosphate metabolism and vascular calcification. The techniques used include extracellular pyrophosphate metabolism assays, thin-layer chromatography, phosphate-induced calcification assays, BrdU incorporation for DNA synthesis, aortic smooth muscle cell viability and proliferation assays, and quantitative PCR for enzyme expression analysis. Additionally, extracellular pyrophosphate metabolism was examined through the use of radiolabeled isotopes to track ATP and pyrophosphate transformations.</p><p><strong>Results: </strong>Elevated glucose led to a significant reduction in extracellular pyrophosphate across all diabetic models. This metabolic disruption was marked by notable downregulation of both the expression and activity of ectonucleotide pyrophosphatase/phosphodiesterase 1, a key enzyme that converts ATP to pyrophosphate. We also observed an upregulation of ectonucleoside triphosphate diphosphohydrolase 1, which preferentially hydrolyzes ATP to inorganic phosphate rather than pyrophosphate. Moreover, tissue-nonspecific alkaline phosphatase activity was markedly elevated across all diabetic models. This shift in enzyme activity significantly reduced the pyrophosphate/phosphate ratio. In addition, we noted a marked downregulation of matrix Gla protein, another inhibitor of vascular calcification. The impaired pyrophosphate metabolism was further corroborated by calcification experiments across all three diabetic models, which demonstrated an increased propensity for vascular calcification.</p><p><strong>Conclusions: </strong>This study demonstrated that diabetes-induced high glucose disrupts extracellular pyrophosphate metabolism, compromising its protective role against vascular calcification. These findings identify pyrophosphate deficiency as a potential mechanism in diabetic vascular calcification, highlighting a new therapeutic target. Strategies aimed at restoring or enhancing pyrophosphate levels may offer significant potential in mitigating cardiovascular complications in diabetic patients, meriting further investigation.</p>","PeriodicalId":9374,"journal":{"name":"Cardiovascular Diabetology","volume":"23 1","pages":"405"},"PeriodicalIF":8.5000,"publicationDate":"2024-11-11","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.ncbi.nlm.nih.gov/pmc/articles/PMC11555999/pdf/","citationCount":"0","resultStr":"{\"title\":\"Elevated glucose levels increase vascular calcification risk by disrupting extracellular pyrophosphate metabolism.\",\"authors\":\"Alicia Flores-Roco, Belinda M Lago, Ricardo Villa-Bellosta\",\"doi\":\"10.1186/s12933-024-02502-w\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><strong>Background: </strong>Vascular calcification is a major contributor to cardiovascular disease, especially diabetes, where it exacerbates morbidity and mortality. Although pyrophosphate is a recognized natural inhibitor of vascular calcification, there have been no prior studies examining its specific deficiency in diabetic conditions. This study is the first to analyze the direct link between elevated glucose levels and disruptions in extracellular pyrophosphate metabolism.</p><p><strong>Methods: </strong>Rat aortic smooth muscle cells, streptozotocin (STZ)-induced diabetic rats, and diabetic human aortic smooth muscle cells were used to assess the effects of elevated glucose levels on pyrophosphate metabolism and vascular calcification. The techniques used include extracellular pyrophosphate metabolism assays, thin-layer chromatography, phosphate-induced calcification assays, BrdU incorporation for DNA synthesis, aortic smooth muscle cell viability and proliferation assays, and quantitative PCR for enzyme expression analysis. Additionally, extracellular pyrophosphate metabolism was examined through the use of radiolabeled isotopes to track ATP and pyrophosphate transformations.</p><p><strong>Results: </strong>Elevated glucose led to a significant reduction in extracellular pyrophosphate across all diabetic models. This metabolic disruption was marked by notable downregulation of both the expression and activity of ectonucleotide pyrophosphatase/phosphodiesterase 1, a key enzyme that converts ATP to pyrophosphate. We also observed an upregulation of ectonucleoside triphosphate diphosphohydrolase 1, which preferentially hydrolyzes ATP to inorganic phosphate rather than pyrophosphate. Moreover, tissue-nonspecific alkaline phosphatase activity was markedly elevated across all diabetic models. This shift in enzyme activity significantly reduced the pyrophosphate/phosphate ratio. In addition, we noted a marked downregulation of matrix Gla protein, another inhibitor of vascular calcification. The impaired pyrophosphate metabolism was further corroborated by calcification experiments across all three diabetic models, which demonstrated an increased propensity for vascular calcification.</p><p><strong>Conclusions: </strong>This study demonstrated that diabetes-induced high glucose disrupts extracellular pyrophosphate metabolism, compromising its protective role against vascular calcification. These findings identify pyrophosphate deficiency as a potential mechanism in diabetic vascular calcification, highlighting a new therapeutic target. 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引用次数: 0
摘要
背景:血管钙化是心血管疾病,尤其是糖尿病的一个主要诱因,它加剧了糖尿病的发病率和死亡率。尽管焦磷酸是一种公认的血管钙化天然抑制剂,但此前还没有研究对糖尿病患者缺乏焦磷酸的具体情况进行过研究。本研究首次分析了葡萄糖水平升高与细胞外焦磷酸代谢紊乱之间的直接联系:方法:使用大鼠主动脉平滑肌细胞、链脲佐菌素(STZ)诱导的糖尿病大鼠和糖尿病人主动脉平滑肌细胞来评估葡萄糖水平升高对焦磷酸代谢和血管钙化的影响。使用的技术包括细胞外焦磷酸盐代谢测定、薄层色谱法、磷酸盐诱导钙化测定、DNA 合成的 BrdU 结合、主动脉平滑肌细胞活力和增殖测定以及酶表达定量 PCR 分析。此外,还通过使用放射性同位素追踪 ATP 和焦磷酸的转化,对细胞外焦磷酸代谢进行了检测:结果:在所有糖尿病模型中,葡萄糖升高导致细胞外焦磷酸显著减少。这种代谢紊乱表现为外切核苷酸焦磷酸酶/磷酸二酯酶1(一种将ATP转化为焦磷酸的关键酶)的表达和活性明显下调。我们还观察到外核苷酸三磷酸二磷酸水解酶 1 的上调,该酶优先将 ATP 水解为无机磷酸盐,而不是焦磷酸。此外,所有糖尿病模型的组织非特异性碱性磷酸酶活性都明显升高。酶活性的这种变化大大降低了焦磷酸/磷酸比率。此外,我们还注意到基质 Gla 蛋白(血管钙化的另一种抑制因子)明显下调。所有三种糖尿病模型的钙化实验进一步证实了焦磷酸代谢受损,这表明血管钙化倾向增加:这项研究表明,糖尿病诱导的高血糖会破坏细胞外焦磷酸代谢,损害其对血管钙化的保护作用。这些发现确定了焦磷酸盐缺乏是糖尿病血管钙化的潜在机制,突出了一个新的治疗目标。旨在恢复或提高焦磷酸水平的策略可能为减轻糖尿病患者的心血管并发症提供巨大潜力,值得进一步研究。
Background: Vascular calcification is a major contributor to cardiovascular disease, especially diabetes, where it exacerbates morbidity and mortality. Although pyrophosphate is a recognized natural inhibitor of vascular calcification, there have been no prior studies examining its specific deficiency in diabetic conditions. This study is the first to analyze the direct link between elevated glucose levels and disruptions in extracellular pyrophosphate metabolism.
Methods: Rat aortic smooth muscle cells, streptozotocin (STZ)-induced diabetic rats, and diabetic human aortic smooth muscle cells were used to assess the effects of elevated glucose levels on pyrophosphate metabolism and vascular calcification. The techniques used include extracellular pyrophosphate metabolism assays, thin-layer chromatography, phosphate-induced calcification assays, BrdU incorporation for DNA synthesis, aortic smooth muscle cell viability and proliferation assays, and quantitative PCR for enzyme expression analysis. Additionally, extracellular pyrophosphate metabolism was examined through the use of radiolabeled isotopes to track ATP and pyrophosphate transformations.
Results: Elevated glucose led to a significant reduction in extracellular pyrophosphate across all diabetic models. This metabolic disruption was marked by notable downregulation of both the expression and activity of ectonucleotide pyrophosphatase/phosphodiesterase 1, a key enzyme that converts ATP to pyrophosphate. We also observed an upregulation of ectonucleoside triphosphate diphosphohydrolase 1, which preferentially hydrolyzes ATP to inorganic phosphate rather than pyrophosphate. Moreover, tissue-nonspecific alkaline phosphatase activity was markedly elevated across all diabetic models. This shift in enzyme activity significantly reduced the pyrophosphate/phosphate ratio. In addition, we noted a marked downregulation of matrix Gla protein, another inhibitor of vascular calcification. The impaired pyrophosphate metabolism was further corroborated by calcification experiments across all three diabetic models, which demonstrated an increased propensity for vascular calcification.
Conclusions: This study demonstrated that diabetes-induced high glucose disrupts extracellular pyrophosphate metabolism, compromising its protective role against vascular calcification. These findings identify pyrophosphate deficiency as a potential mechanism in diabetic vascular calcification, highlighting a new therapeutic target. Strategies aimed at restoring or enhancing pyrophosphate levels may offer significant potential in mitigating cardiovascular complications in diabetic patients, meriting further investigation.
期刊介绍:
Cardiovascular Diabetology is a journal that welcomes manuscripts exploring various aspects of the relationship between diabetes, cardiovascular health, and the metabolic syndrome. We invite submissions related to clinical studies, genetic investigations, experimental research, pharmacological studies, epidemiological analyses, and molecular biology research in this field.