短指/趾的分子遗传学研究进展

短指/趾(Brachydactyly, BD)是指(趾)骨和/或掌(跖)骨短小、缺失或融合导致的手/足先天畸形, 是一组以骨发育障碍为特征的肢体畸形疾病。BD可单独出现, 也可作为综合征的一种体征, 还可伴随其他的手/足畸形如并指/趾、多指/趾、短缺畸形和指/趾骨关节融合出现。绝大多数单纯型BD呈常染色体显性遗传, 存在表现度不同和外显不全。大多数单纯型BD和一些综合征型BD的致病基因缺陷已经被鉴定。BMP (Bone morphogenetic protein)通路参与正常指/趾发育, 且已知的BD致病基因直接或间接参与该通路。文章综述了BD分子遗传学研究方面的新进展, 将有助于BD致病机制的研究和基因诊疗的开展。     

Advances in medical genetics.

Although advances in medical genetics are designed ultimately to help human beings receive better health care, they pose many problems for society. Some of these concerns are real, but others result from misunderstanding and/or misrepresentation of the true implication of certain developments in genetics. It is obvious that the geneticist must play a dual role in society as scientist and as advocate. Although such a duality or role is not easy, it is not impossible. However, it does mean that the training of the medical geneticist must include more than exposure to the scientific approach.     

非常规酵母的分子遗传学及合成生物学研究进展

先进的合成生物学技术与传统的分子遗传学技术的结合更有助于实现酵母底盘细胞的快速改造和优化。酵母合成生物学研究最早开始于常规酵母——酿酒酵母(Saccharomyces cerevisiae),近些年来又迅速扩展至一些非常规酵母,包括巴斯德毕赤酵母(Pichiapastoris)、解脂耶氏酵母(Yarrowialipolytica)、乳酸克鲁维酵母(Kluyveromyces lactis)和多形汉逊酵母(Hansenula polymorpha)等。借助合成生物学技术与工具,目前科学家们已经成功开发出了能够高效生产生物材料、生物燃料、生物基化学品、蛋白质制剂、食品添加剂和药物等工业产品的重组非常规酵母工程菌株。本文系统总结了合成生物学工具(主要是基因组编辑工具)、合成生物学组件(主要是启动子和终止子)和相关分子遗传学方法在上述非常规酵母系统(底盘细胞)中的最新研究进展和应用情况,并讨论了其他合成生物学技术在这些非常规酵母表达系统中的潜在适用性和应用前景。这为研究人员利用合成生物学方法在这一新型非模式微生物底盘细胞中设计和构建各种高附加值工业产品的异源合成模块并最终实现目标化合物的高效生物合成提供了科学的理论指导。     

Unraveling the genetics of human obesity

The use of modern molecular biology tools in deciphering the perturbed biochemistry and physiology underlying the obese state has proven invaluable. Identifying the hypothalamic leptin/melanocortin pathway as critical in many cases of monogenic obesity has permitted targeted, hypothesis-driven experiments to be performed, and has implicated new candidates as causative for previously uncharacterized clinical cases of obesity. Meanwhile, the effects of mutations in the melanocortin-4 receptor gene, for which the obese phenotype varies in the degree of severity among individuals, are now thought to be influenced by one's environmental surroundings. Molecular approaches have revealed that syndromes (Prader-Willi and Bardet-Biedl) previously assumed to be controlled by a single gene are, conversely, regulated by multiple elements. Finally, the application of comprehensive profiling technologies coupled with creative statistical analyses has revealed that interactions between genetic and environmental factors are responsible for the common obesity currently challenging many Westernized societies. As such, an improved understanding of the different “types” of obesity not only permits the development of potential therapies, but also proposes novel and often unexpected directions in deciphering the dysfunctional state of obesity.     

运动能力的遗传学研究进展

个体间运动能力的差异受多种因素影响, 其中环境和遗传因素可能起决定作用。2008年以来涌现了大量的运动能力遗传学研究, 获得了一系列有意义的结果。文章以体力活动水平、肌肉力量及耐力水平3方面为重点, 着重对涉及以上3方面遗传学研究中的研究结果(样本大小、测试表型的质量优劣、运动实验计划的质量高低、研究设计的合理性和新颖性、实验测试的控制情况以及基因分型情况等)进行了比较分析, 以期为研究者提供参考。     

The genetics of human obesity

Obesity is an important cause of morbidity and mortality in developed countries, and is also becoming increasingly prevalent in the developing world. Although environmental factors are important, there is considerable evidence that genes also have a significant role in its pathogenesis. The identification of genes that are involved in monogenic, syndromic and polygenic obesity has greatly increased our knowledge of the mechanisms that underlie this condition. In the future, dissection of the complex genetic architecture of obesity will provide new avenues for treatment and prevention, and will increase our understanding of the regulation of energy balance in humans.     

Pathophysiology and genetics of obesity

Obesity, a global problem, is a multifactorial disorder. The factors are environmental, metabolic and genetic and their interaction with each other regulates the body weight. Imbalance in either of the factors may be responsible for weight gain. With advancement of research techniques in the last decade, genetic studies have been undertaken for several different causative mutations involving obesity loci on different chromosomes. Monogenic and polygenic obesity has been observed however, polygenic forms are more common. So far more than 200 genes in mouse and more than 100 genes in humans have been identified which result in phenotypes that affect body weight regulation. In spite of this knowledge, the field of obesity has still not been explored extensively. There remain a lot of lacuna regarding causes and treatment of obesity. Challenges are still there to identify the exact cause of weight gain and the use of current knowledge for development of anti-obesity drugs targeted for body weight regulation. In this review, we have explained neuropathophysiologic regulation of feeding behaviour and some aspects of obesity-genetics especially with single nucleotide polymorphism of selected candidate genes and their functional aspects mainly in monogenic obesity.