Bench Marks

Improvements in automation and acquisition time have made the microscope a viable platform for performing hundreds of concurrent parallel experiments. Using these sorts of tools, it is now possible to run high-throughput screens for protein function and interaction in living cells, examining dynamic cellular processes to distinguish between primary and secondary phenotypes, and to study the phenotype kinetics. In the August issue of Cold Spring Harbor Protocols, Jan Ellenberg and colleagues from the EMBL present High-Throughput Microscopy Using Live Mammalian Cells, an overview of how to screen live cells using imaging technologies. The article examines each aspect of the general screening process and considers specific examples in the processing of time-lapse experiments. The techniques discussed are based on the use of cultured mammalian cells, but the concepts are easily transferred to cultured cells from other species like Drosophila and small organisms such as C. elegans.

Immunoprecipitation is a commonly used technique for isolating and purifying a protein of interest. An antibody for the protein is incubated with a cell extract, and the resulting antibody/antigen complex is pulled out of solution. The method used for preparation of the cell extract can be critical for the experiment’s success. The choice of lysis conditions must be tailored to the nature of the epitope recognized by the immunoprecipitating antibody. Lysis of Cultured Cells for Immunoprecipitation, featured in the August issue of Cold Spring Harbor Protocols provides instructions for the lysis of cells grown as monolayer cultures and cells grown in suspension. The protocol offers a detailed comparison between different commonly used lysis buffers and protease inhibitor cocktails, as well as a guide to preparing a general protease inhibitor cocktail. As one of our featured articles, the protocol is freely available to subscribers and non-subscribers alike.

Producing recombinant proteins in bacterial hosts is a widely-used laboratory procedure. But generating a large yield of protein is often challenging. Getting enough raw material for experiments can be a time-consuming and frustrating process. In the August issue of Cold Spring Harbor Protocols, Jianjun Wang and colleagues present a method for Preparation of Very-High-Yield Recombinant Proteins using Novel High-Cell-Density Bacterial Expression Methods. By combining traditional IPTG induction with high-cell-density auto-induction, the method routinely produces 15-35 mg of pure protein from 50 mL bacterial cell cultures. Detailed protocols are given for preparation of a starting culture, double colony selection and optimization of expression conditions, which ensure plasmid stability resulting in a high yield of recombinant protein production.

Zinc finger nucleases (ZFNs) are artificial restriction enzymes made by fusing an engineered zinc finger DNA-binding domain to the DNA cleavage domain of a restriction enzyme. ZFNs can be used to generate targeted genomic deletions of large segments of DNA in a wide variety of cell types and organisms. In the August issue of Cold Spring Harbor Protocols, Jin-Soo Kim and colleagues present Analysis of Targeted Chromosomal Deletions Induced by Zinc Finger Nucleases, a detailed protocol for the detection and analysis of large genomic deletions in cultured cells introduced by the expression of ZFNs. The method described allows researchers to detect and estimate the frequency of ZFN-induced genomic deletions by simple PCR-based methods. As one of our featured articles, the protocol is freely available to subscribers and non-subscribers alike.