Discovery of Zika virus host dependency factors in trophoblasts using CRISPR/Cas9 screening.

Emerging mosquito-borne RNA viruses cause massive health complications worldwide. The Zika virus (ZIKV), in particular, has spread dramatically since 2007 and has provoked epidemics in the Americas and the South Pacific. The lack of antiviral therapy and vaccination has focused research on the investigation of ZIKV-host interactions, in order to understand underlying molecular infection mechanisms. We have established an approach for the analysis of ZIKV host dependency factors in a human trophoblast cell line and applied genome-wide CRISPR/Cas9 knockout mutagenesis. The presented method is especially of value for the identification of factors that are essential for placental infection with the potential to serve as targets for antiviral treatment.

Quantitative proteome analysis of cisplatin-induced apoptotic Jurkat T cells by stable isotope labeling with amino acids in cell culture, SDS-PAGE, and LC-MALDI-TOF/TOF MS.

Quantitative proteome analysis of cisplatin-induced apoptosis in total Jurkat T cell lysates was performed in order to identify modified proteins. Proteins were labeled in cell culture with stable isotopes of arginines, and fractionated by SDS-PAGE. Subsequently, tryptic peptides were analyzed by nano-LC coupled offline to MALDI-TOF/TOF-MS as an alternative to commonly used online LC-ESI-MS. As a result, 26 proteins were found with a relative abundance higher than 1.5, thereof 19 already known and seven unknown to be involved in apoptosis (adenine phosphoribosyltransferase, microsomal signal peptidase 25 kDa subunit, phosphomevalonate kinase, probable rRNA processing protein EBP2, RNA-binding protein 4, transmembrane protein 33, and tetratricopeptide repeat domain 9C). Immunoblotting of core-binding factor beta and elongation factor 2 revealed similar quantitative changes as detected by the SILAC-based proteomics approach. Strikingly, 8 of 26 identified apoptosis-modified proteins contained at least one RNA-binding motif. Three caspase cleavage sites of the 54 kDa nuclear RNA-binding protein (p54nrb) were mapped at DQLD(231) (downward arrow)D, DQVD(286) (downward arrow)R, and MMPD(422) (downward arrow)G by applying caspase-3 to the in vitro translated protein and mutation analysis. The determined caspase cleavage sites were located C-terminal to the two RNA-binding motifs and one (DQLD(231) (downward arrow)D) within the NOPS domain of p54nrb. Concisely, quantitative protein data generated by offline LC-MALDI-MS were shown to be particularly accurate. Furthermore, only regulated peptides were selected in a result-dependent manner for MS/MS analyses and revealed novel apoptosis-modified proteins.

A global approach combining proteome analysis and phenotypic screening with RNA interference yields novel apoptosis regulators.

Global approaches like proteome or transcriptome analyses have been performed extensively to identify candidate genes or proteins involved in biological and pathological processes. Here we describe the identification of proteins implicated in the regulation of apoptosis using proteome analysis and the functional validation of targets by RNA interference. A high-throughput platform for the validation of synthetic small interfering RNAs (siRNAs) by quantitative real-time PCR was established. Genes of the identified factors were silenced by automated siRNA transfection, and their role in apoptotic signaling was investigated. Using this strategy, nine new modulators of apoptosis were identified. A subsequent detailed study demonstrated that hepatoma-derived growth factor (HDGF) is required for TNFalpha-induced release of pro-apoptotic factors from mitochondria. The strategy described here may be used for hypothesis-free, global gene function analysis.

Prediction of translocation and cleavage of heterogeneous ribonuclear proteins and Rho guanine nucleotide dissociation inhibitor 2 during apoptosis by subcellular proteome analysis.

Jurkat T cells induced to undergo apoptosis by the CD95(Fas/Apo-1) pathway were investigated by proteome analysis. The most prominent differing protein spots of apoptotic and nonapoptotic cells were identified as various heterogeneous ribonuclear proteins (hnRNPs) and Rho guanin nucleotide dissociation inhibitor (GDI) 2. In apoptotic cells, four spots slightly differing in molecular mass and/or isoelectric point were identified as Rho GDI 2 with the mass and pI as expected after caspase-3 cleavage near the N-terminus. Subcellular proteome analysis revealed that Rho GDI 2 was highly enriched in the cytosolic fraction, present in minor amounts in the nuclear fraction and absent from the mitochondrial fraction. In apoptotic cells however, the spots representing processed and modified Rho GDI 2 were found in the cytosol, in the nucleus and also the mitochondria at different spot positions. In addition, twelve different hnRNPs were identified to be altered after induction of cell death of which hnRNPs A/B, D, F, H, I and L were hitherto unknown to be modified during apoptosis. Most of the hnRNP spots were found in the nucleus of nonapoptotic cells, whereas these proteins, either modified or unmodified, relocated to the cytosol and/or the mitochondria in apoptotic cells. Our results demonstrate that modification of proteins during apoptosis is often accompanied by their relocalisation between cellular compartments.