Genetic Analysis of Complex Disease. Группа авторов
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Название: Genetic Analysis of Complex Disease

Автор: Группа авторов

Издательство: John Wiley & Sons Limited

Жанр: Биология

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isbn: 9781119104070

isbn:

СКАЧАТЬ proposed trait‐associated variant is introduced into the germline of the organism and the resulting offspring are examined for evidence of the abnormal phenotype. With knockout models, the action of the gene in question is eliminated and the offspring are examined for evidence of an abnormal phenotype. Similar experiments can be performed in cultured cells, where the introduction of the variant (or gene knockout) is easier. However, finding the appropriate cell line and determining the appropriate cellular phenotype corresponding to the trait may be difficult. Recent advances in generating relevant cellular models have utilized inducible pluripotent stem cell (iPSC) technology, by which cells (blood, fibroblast) from an individual with a phenotype and genotype of interest can be reprogrammed and differentiated to a cell type of interest (such as neuron or retinal pigment epithelium). Such cells might be closer to the affected tissue type and have more recognizable phenotypes due to the genetic variant under study. A further advance incorporates gene editing technology (e.g. CRISPR/Cas9) into the approach, whereby an established iPSC line can be edited to introduce (or correct) a variant of interest. Such an approach eliminates the need to draw a sample from a person known to carry a variant of interest and allows examination of isogenic cell lines with and without the variant for phenotypic changes. These approaches are rapidly evolving, and frequently revised sources, such as Current Protocols in Human Genetics, should be consulted for the latest details on functional studies using these approaches.

      Foster Interaction of Necessary Expertise

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      Develop Careful Study Design

      It may seem self‐evident that a careful study design is necessary for a successful study. However, it is not enough to decide on a general design of “collect cases and controls, genotype on a genome‐wide chip, do GWAS analysis.” Each step in the study requires substantial thought, and the decisions made at one step will have implications for each of the others. Much as a team of engineers and architects must project unintended side effects from a change in a structural design, lest a catastrophic failure ensue, researchers must consider carefully all aspects of the experimental design lest they doom themselves to making inappropriate conclusions based on inadequately obtained and interpreted results.

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