Chemical Biology of the Genome provides a comprehensive overview of essential concepts and principles of genomic and epigenomics dynamics as explored through the lens of chemical biology. Key examples and case studies illustrate chemical biology methods for study and analysis of the genome and epigenome, with an emphasis on relevance to physiological and pathophysiological processes and drug discovery. Authors and international leaders in biochemical studies of the genome, Drs. Siddhartha Roy and Tapas Kundu, adopt an integrated, interdisciplinary approach throughout, demonstrating how fast evolving chemical and mass-scale sequencing tools are increasingly used to interpret biochemical processes of the genome. Later sections discuss chemical modifications of the genome, DNA sequence recognition by proteins and gene regulation, GWAS and EpiGWAS studies, 3D architecture of the genome, and functional genome architecture. In-depth, discovery focused chapters examine intervention in gene networks using SiRNA/ShRNA, miRNA, and anti-miR, small molecule modulation of iPS, drug resistance pathways altered DNA methylation as drug targets, anti-miR as therapeutics, and nanodelivery of drugs.

Here, researchers review the latest breakthroughs in protein research. Their contributions explore emerging principles and techniques and survey important classes of proteins that will play key roles in the field's future. Articles examine the possibility of a Boltzman-like distribution in protein substructures, the new technique of Raman spectroscopy, and compact intermediate states of protein folding. This well-illustrated volume also features coverage of proteins that bind nucleic acids.

Here, researchers review the latest breakthroughs in protein research. Their contributions explore emerging principles and techniques and survey important classes of proteins that will play key roles in the field's future. Articles examine the possibility of a Boltzman-like distribution in protein substructures, the new technique of Raman spectroscopy, and compact intermediate states of protein folding. This well-illustrated volume also features coverage of proteins that bind nucleic acids.

New genomic information has revealed the crucial role that protein–protein interactions (PPIs) play in regulating numerous cellular functions. Aberrant forms of these interactions are common in numerous diseases and thus PPIs have emerged as a vast class of critical drug targets. Despite the importance of PPIs in biology, it has been extremely challenging to convert targets into therapeutics and targeting PPIs had long been considered a very difficult task. However, over the past decade the field has advanced with increasing growth in the number of successful PPI regulators. Protein–Protein Interaction Regulators surveys the latest advances in the structural understanding of PPIs as well as recent developments in modulator discovery.