In vitro and in cellulae methods for determining the target protein SUMOylation.

Post-translational modifications (PTMs) provide a critical means of calibrating the functional proteome and, thus, are extensively utilized by the eukaryotes to exert spatio-temporal regulation on the cellular machinery rapidly. Ubiquitination and phosphorylation are examples of the well-documented PTMs. SUMOylation, the reversible conjugation of the Small Ubiquitin-related MOdifier (SUMO) at a specific lysine residue on a target protein, bears striking similarity with ubiquitination and follows an enzymatic cascade for the attachment of SUMO to the target protein. Unlike Ubiquitination, SUMOylation can modulate the target protein's structure, stability, activity, localization, and interaction. Thus, SUMOylation regulates cellular events such as signal transduction, cell-cycle progression, transcription, nucleocytoplasmic transport, and stress responses. Accordingly, deregulation of SUMOylation is an avenue for diseases, which makes the investigation of SUMO and its substrates within the cell essential. However, the low extent of SUMOylation has posed a significant challenge in detecting SUMO modification within the cell. Bioinformatics tools can help predict SUMOylation, and mass-spectrometric analysis can identify a pool of cellular protein SUMOylome. Nevertheless, the biochemical methods for observing the enhanced level of in vitro SUMOylation help validate protein SUMOylation, critical lysine(s) utilized in the process, and its effect on substrate protein function. This chapter provides a detailed account of biochemical methods commonly utilized to detect SUMOylated proteins that are central for understanding the biological functions and mechanism of regulation of SUMO targets.

Molecular and Phenotypic Characterization Following RNAi Mediated Knockdown in Drosophila.

Loss of function studies shed significant light on the involvement of a gene or gene product in different cellular processes. Short hairpin RNA (shRNA) mediated RNA interference (RNAi) is a classical yet straightforward technique frequently used to knock down a gene for assessing its function. Similar perturbations in gene expression can be achieved by siRNA, microRNA, or CRISPR-Cas9 methods also. In Drosophila genetics, the UAS-GAL4 system is utilized to express RNAi and make ubiquitous and tissue-specific knockdowns possible. The UAS-GAL4 system borrows genetic components of S. cerevisiae, hence rule out the possibility of accidental expression of the system. In particular, this technique uses a target-specific shRNA, and the expression of the same is governed by the upstream activating sequence (UAS). Controlled expression of GAL4, regulated by specific promoters, can drive the interfering RNA expression ubiquitously or in a tissue-specific manner. The knockdown efficiency is measured by RNA isolation and semiquantitative RT-PCR reaction followed by agarose gel electrophoresis. We have employed immunostaining procedure also to assess knockdown efficiency. RNAi provides researchers with an option to decrease the gene product levels (equivalent to hypomorph condition) and study the outcomes. UAS-GAL4 based RNAi method provides spatio-temporal regulation of gene expression and helps deduce the function of a gene required during early developmental stages also.