Leveraging human–mouse studies to advance the genetics of hearing impairment in Africa

IF 3.2 4区医学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY Journal of Gene Medicine Pub Date : 2024-07-01 DOI:10.1002/jgm.3714

Kili James, Oluwafemi G. Oluwole

引用次数: 0

Abstract

Mouse models are used extensively to understand human pathobiology and mechanistic functions of disease-associated loci. However, in this review, we investigate the potential of using genetic mouse models to identify genetic markers that can disrupt hearing thresholds in mice and then target the hearing-enriched orthologues and loci in humans. Currently, little is known about the real prevalence of genes that cause hearing impairment (HI) in Africa. Pre-screening mouse cell lines to identify orthologues of interest has the potential to improve the genetic diagnosis for HI in Africa to a significant percentage, for example, 10–20%. Furthermore, the functionality of a candidate gene derived from mouse screening with heterogeneous genetic backgrounds and multi-omic approaches can shed light on the molecular, genetic heterogeneity and plausible mode of inheritance of a gene in hearing-impaired individuals especially in the absence of large families to investigate.

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利用人鼠研究推动非洲听力障碍遗传学的发展。

小鼠模型被广泛用于了解人类病理生物学和疾病相关基因座的机理功能。然而，在这篇综述中，我们研究了利用遗传小鼠模型来确定可破坏小鼠听力阈值的遗传标记的潜力，然后将目标锁定在人类的听力富集直系同源物和基因座上。目前，人们对导致听力损伤（HI）的基因在非洲的实际流行情况知之甚少。预先筛选小鼠细胞系以确定感兴趣的直系同源物，有可能将非洲听力障碍的基因诊断率提高到相当高的比例，例如 10-20%。此外，通过异质遗传背景小鼠筛选和多组学方法得出的候选基因的功能性，可以揭示听力受损个体中该基因的分子、遗传异质性和可能的遗传模式，尤其是在没有大家族可供调查的情况下。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Gene Medicine 医学-生物工程与应用微生物

CiteScore

6.40

自引率

0.00%

发文量

审稿时长

6-12 weeks

期刊介绍： The aims and scope of The Journal of Gene Medicine include cutting-edge science of gene transfer and its applications in gene and cell therapy, genome editing with precision nucleases, epigenetic modifications of host genome by small molecules, siRNA, microRNA and other noncoding RNAs as therapeutic gene-modulating agents or targets, biomarkers for precision medicine, and gene-based prognostic/diagnostic studies. Key areas of interest are the design of novel synthetic and viral vectors, novel therapeutic nucleic acids such as mRNA, modified microRNAs and siRNAs, antagomirs, aptamers, antisense and exon-skipping agents, refined genome editing tools using nucleic acid /protein combinations, physically or biologically targeted delivery and gene modulation, ex vivo or in vivo pharmacological studies including animal models, and human clinical trials. Papers presenting research into the mechanisms underlying transfer and action of gene medicines, the application of the new technologies for stem cell modification or nucleic acid based vaccines, the identification of new genetic or epigenetic variations as biomarkers to direct precision medicine, and the preclinical/clinical development of gene/expression signatures indicative of diagnosis or predictive of prognosis are also encouraged.