To avoid the ethical issues of embryonic stem cells, genome engineering has focused on inducible pluripotent stem cells, which can develop into all 3 germ layers. The ability to detect methylation patterns in these cells allows research into pluripotency markers. The recently developed CRISPR system has allowed widespread application of genome engineering techniques. The CRISPR-Cas9 system, a potent system for genome editing, can be used for gene knockout or knock-in genome manipulations through substitution of a target genetic sequence with a desired donor sequence. Two types of genome engineering can be initiated: homologous or nonhomologous DNA repair by the Cas9 nuclease. Delivery of the CRISPR-Cas9 and target donor vectors in human pluripotent stem cells can be accomplished via viral and nonviral delivery methods. Nonviral delivery includes lipid-mediated transfection and electroporation. It has become the most common and efficient in vitro delivery method for human pluripotent stem cells. The CRISPR-Cas9 system can be combined with inducible pluripotent stem cells to generate single or multiple gene knockouts, correct mutations, or insert reporter transgenes. Knockouts can also be utilized to investigate epigenetic roles and targets, such as investigation of DNA methylation. CRISPR could be combined with human pluripotent stem cells to explore genetic determinants of lineage choice, differentiation, and stem cell fate, allowing investigators to study how various genes or noncoding elements contribute to specific processes and pathways. The CRISPR-Cas9 system can also be used to create null or nucleasedead Cas9, which has no enzymatic activity but has been utilized through fusion with other functional protein domains. In conclusion, RNA-guided genome targeting will have broad implications for synthetic biology, direct perturbation of gene networks, and targeted ex vivo and in vivo gene therapy.