Rachel Lawrence, Kathryn Munn, Hamsa Naser, Laura Thomas, Hasan Haboubi, Lisa Williams, Shareen Doak, Gareth Jenkins
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引用次数: 0
Abstract
The blood cell phosphatidylinositol glycan class A (PIG-A) gene mutation assay has been extensively researched in rodents for in vivo mutagenicity testing and is now being investigated in humans. The PIG-A gene is involved in glycosyl phosphatidylinositol (GPI)-anchor biosynthesis. A single mutation in this X-linked gene can lead to loss of membrane-bound GPI anchors, which can be enumerated via corresponding GPI-anchored proteins (e.g., CD55) using flow cytometry. The studies published to date by different research groups demonstrate a remarkable consistency in PIG-A mutant frequencies. Moreover, with the low background level of mutant erythrocytes in healthy subjects (2.9–5.56 × 10−6 mutants), induction of mutation post genotoxic exposure can be detected. Cigarette smoking, radiotherapy, and occupational exposures, including lead, have been shown to increase mutant levels. Future applications of this test include identifying new harmful agents and establishing new exposure limits. This mutational monitoring approach may also identify individuals at higher risk of cancer development. In addition, identifying protective agents that could mitigate these effects may reduce baseline somatic mutation levels and such behaviors can be encouraged. Further technological progress is required including establishing underlying mechanisms of GPI anchor loss, protocol standardization, and the development of cryopreservation methods to improve GPI-anchor stability over time. If successful, this assay has the potential be widely employed, for example, in rural and low-income countries. Here, we review the current literature on PIG-A mutation in humans and discuss the potential role of this assay in human biomonitoring and disease detection.
血细胞磷脂酰肌醇聚糖A类(PIG-A)基因突变试验已在啮齿类动物体内进行了广泛的研究,用于体内诱变试验,目前正在人类中进行研究。PIG-A基因参与糖基磷脂酰肌醇(GPI)锚定生物合成。该X连锁基因中的单个突变可导致膜结合GPI锚定物的丢失,可以使用流式细胞术通过相应的GPI锚接蛋白(例如CD55)进行计数。迄今为止,不同研究小组发表的研究表明,PIG-a突变频率显著一致。此外,由于健康受试者中突变红细胞的背景水平较低(2.9-5.56 x 10-6突变体),可以检测到基因毒性暴露后的突变诱导。吸烟、放疗和包括铅在内的职业暴露已被证明会增加突变水平。该测试的未来应用包括识别新的有害物质和制定新的接触限值。这种突变监测方法也可以识别癌症发展风险较高的个体。此外,确定可以减轻这些影响的保护剂可能会降低基线体细胞突变水平,并且可以鼓励这种行为。需要进一步的技术进步,包括建立GPI锚丢失的潜在机制、协议标准化和开发冷冻保存方法,以随着时间的推移提高GPI锚的稳定性。如果成功,这种检测方法有可能被广泛应用,例如在农村和低收入国家。在这里,我们回顾了目前关于人类PIG-A突变的文献,并讨论了这种检测方法在人类生物监测和疾病检测中的潜在作用。这篇文章受版权保护。保留所有权利。
期刊介绍:
Environmental and Molecular Mutagenesis publishes original research manuscripts, reviews and commentaries on topics related to six general areas, with an emphasis on subject matter most suited for the readership of EMM as outlined below. The journal is intended for investigators in fields such as molecular biology, biochemistry, microbiology, genetics and epigenetics, genomics and epigenomics, cancer research, neurobiology, heritable mutation, radiation biology, toxicology, and molecular & environmental epidemiology.