Generating and working with Drosophila cell cultures: Current challenges and opportunities.

Q1 Biochemistry, Genetics and Molecular Biology Wiley Interdisciplinary Reviews: Developmental Biology Pub Date : 2019-05-01 Epub Date: 2018-12-18 DOI:10.1002/wdev.339
Arthur Luhur, Kristin M Klueg, Andrew C Zelhof
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引用次数: 19

Abstract

The use of Drosophila cell cultures has positively impacted both fundamental and biomedical research. The most widely used cell lines: Schneider, Kc, the CNS and imaginal disc lines continue to be the choice for many applications. Drosophila cell lines provide a homogenous source of cells suitable for biochemical experimentations, transcriptomics, functional genomics, and biomedical applications. They are amenable to RNA interference and serve as a platform for high-throughput screens to identify relevant candidate genes or drugs for any biological process. Currently, CRISPR-based functional genomics are also being developed for Drosophila cell lines. Even though many uniquely derived cell lines exist, cell genetic techniques such the transgenic UAS-GAL4-based RasV12 oncogene expression, CRISPR-Cas9 editing and recombination mediated cassette exchange are likely to drive the establishment of many more lines from specific tissues, cells, or genotypes. However, the pace of creating new lines is hindered by several factors inherent to working with Drosophila cell cultures: single cell cloning, optimal media formulations and culture conditions capable of supporting lines from novel tissue sources or genotypes. Moreover, even though many Drosophila cell lines are morphologically and transcriptionally distinct it may be necessary to implement a standard for Drosophila cell line authentication, ensuring the identity and purity of each cell line. Altogether, recent advances and a standardized authentication effort should improve the utility of Drosophila cell cultures as a relevant model for fundamental and biomedical research. This article is categorized under: Technologies > Analysis of Cell, Tissue, and Animal Phenotypes.

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果蝇细胞培养的产生和工作:当前的挑战和机遇。
果蝇细胞培养的使用对基础研究和生物医学研究都产生了积极的影响。最广泛使用的细胞系:施耐德,Kc, CNS和成像光盘细胞系继续成为许多应用的选择。果蝇细胞系为生物化学实验、转录组学、功能基因组学和生物医学应用提供了一种同质的细胞来源。它们易受RNA干扰,可作为高通量筛选的平台,用于识别任何生物过程的相关候选基因或药物。目前,基于crispr的功能基因组学也正在为果蝇细胞系开发。尽管存在许多独特的衍生细胞系,但细胞遗传技术,如基于转基因uas - gal4的RasV12癌基因表达、CRISPR-Cas9编辑和重组介导的盒式交换,可能会推动从特定组织、细胞或基因型中建立更多的细胞系。然而,创造新品系的步伐受到果蝇细胞培养的几个固有因素的阻碍:单细胞克隆、最佳培养基配方和能够从新组织来源或基因型中支持品系的培养条件。此外,尽管许多果蝇细胞系在形态和转录上是不同的,但可能有必要实施果蝇细胞系认证标准,以确保每个细胞系的身份和纯度。总之,最近的进展和标准化的认证工作应该提高果蝇细胞培养作为基础和生物医学研究的相关模型的效用。本文分类如下:技术>细胞、组织和动物表型分析。
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期刊介绍: Developmental biology is concerned with the fundamental question of how a single cell, the fertilized egg, ultimately produces a complex, fully patterned adult organism. This problem is studied on many different biological levels, from the molecular to the organismal. Developed in association with the Society for Developmental Biology, WIREs Developmental Biology will provide a unique interdisciplinary forum dedicated to fostering excellence in research and education and communicating key advances in this important field. The collaborative and integrative ethos of the WIREs model will facilitate connections to related disciplines such as genetics, systems biology, bioengineering, and psychology. The topical coverage of WIREs Developmental Biology includes: Establishment of Spatial and Temporal Patterns; Gene Expression and Transcriptional Hierarchies; Signaling Pathways; Early Embryonic Development; Invertebrate Organogenesis; Vertebrate Organogenesis; Nervous System Development; Birth Defects; Adult Stem Cells, Tissue Renewal and Regeneration; Cell Types and Issues Specific to Plants; Comparative Development and Evolution; and Technologies.
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