短暂的采收冷冻延迟会明显改变肾脏代谢组,导致假阳性和假阴性结果。

Yahya Alsawaf, Igor Maksimovic, Jamie Zheng, Song Zhang, Ivan Vuckovic, Petras Dzeja, Slobodan Macura, Maria V Irazabal
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引用次数: 0

摘要

不同代谢途径的异常与多种肾脏疾病有关。代谢组学分析可用于确定器官特异性代谢指纹。然而,传统的采集方法依赖于安乐死后的组织采集,这会导致缺血状况和代谢组变化,从而给最终研究带来伪影。我们优化了肾脏采集和冷冻的钳夹冷冻技术,大大缩短了缺血和冷冻时间,更接近体内代谢的快照。在这项研究中,我们对使用我们的方法和传统技术获取的肾脏的代谢组进行了表征和比较,以确定哪些代谢物会受到短暂缺血和冷冻延迟的影响,哪些代谢物更稳定。我们用 Sprague Dawley 大鼠作为野生型(WT)肾脏模型,用 PCK、多囊肾病(PKD)大鼠作为 CKD 肾脏模型。最后,我们比较了钳夹冷冻和延迟WT肾脏与PKD肾脏的代谢概况,以确定哪些代谢变化最有可能在PKD体内观察到,哪些可能是假阳性或阴性结果。我们的数据表明,短时间的采集-冷冻延迟足以使WT和PKD肾脏发生深刻的代谢变化。有趣的是,虽然延迟在 WT 和 PKD 肾脏中的效果相似,但也存在明显差异,导致在比较这些基因型时出现假阳性和阴性结果。获得的数据表明,肾脏代谢组学的快速钳夹冷冻技术能更准确地解释与疾病状态相关的体内代谢变化。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A brief harvesting-freezing delay significantly alters the kidney metabolome and leads to false positive and negative results.

Abnormalities in distinct metabolic pathways have been associated with the pathogenesis and progression of many forms of kidney disease. Metabolomics analyses can be used to determine organ-specific metabolic fingerprints and, ideally, should represent the metabolic state of the organ at the exact moment the sample is harvested. However, conventional harvesting methods depend on posteuthanasia tissue harvest, which results in ischemia conditions and metabolome changes that could potentially introduce artifacts into the final studies. We recently optimized a modified clamp-freezing technique for rodent kidney harvesting and freezing, significantly reducing ischemia and freezing times and granting a closer snapshot of in vivo metabolism. In this study, we characterized and compared the metabolome of kidneys harvested using our modified approach versus traditional techniques to determine which metabolites are preferentially affected by a brief lapse of ischemia and freezing delay and which are more stable. We used Sprague-Dawley rats as a model of wild-type (WT) kidneys and PCK [polycystic kidney disease (PKD)] rats as a model of chronic kidney disease kidneys. Finally, we compared the metabolic profile of clamp-frozen and delayed WT and PKD kidneys to determine which metabolic changes are most likely observed in vivo in PKD and which could be subjected to false positive or negative results. Our data indicate that a short harvesting-freezing delay is sufficient to impart profound metabolic changes in WT and PKD kidneys, leading to false positive and negative differences when comparing these genotypes. In addition, we identified a group of metabolites that were more stable. Interestingly, while the delay had a similar effect between WT and PKD, there were notable differences. The data obtained indicate that the quick clamp-freezing technique for kidney metabolomics provides a more accurate interpretation of the in vivo metabolic changes associated with the disease state. NEW & NOTEWORTHY Our study shows that a brief harvesting-freezing delay associated with organ collection and freezing can significantly alter the kidney metabolic profile of both male and female wild-type and a genetic model of chronic kidney disease. Importantly, given that the effect of this delay differs among genotypes, it is not safe to assume that equally delaying harvesting-freezing in wild-type and polycystic kidney disease kidneys adequately controls this effect, ultimately leading to false positive and negative results among different renal diseases.

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