METHODS: Site-directed mutagenesis and chloroplast transformation have been used to test the essentiality of these modifications by replacing each of the residues with alanine (Ala). Biochemical analyses were done to determine the specificity factors and kinetic constants.
RESULTS: Replacing the modified-residues in Chlamydomonas Rubisco affected the enzyme's catalytic activity. Substituting hydroxy-Pro-104 and methyl-Cys-256 with alanine influenced Rubisco catalysis.
CONCLUSION: This is the first study on these posttranslationally-modified residues in Rubisco by genetic engineering. As these forms of modifications/regulation are not available in plants, the modified residues could be a means to modulate Rubisco activity.
GENERAL SIGNIFICANCE: With a better understanding of Rubisco structure-function, we can define targets for improving the enzyme.
OBJECTIVE: The main objective of the present review is to highlight the structural signature, classification, its mechanism and application from basic science to medicine and future challenges for this genome editing tool kit.
RESULTS: The present review provides a brief description of the recent development of CRISPR-Cas9 genome editing technology. We discuss the paradigms shift for this next generation genome editing technology, CRISPR. The CRISPR structural significance, classification and its different applications are also being discussed. We portray the future challenges for this extraordinary genome in vivo editing tool. We also highlight the role of CRISPR genome editing in curing many diseases.
CONCLUSION: Scientists and researchers are constantly looking one genome editing tool that is competent, simple and low-cost assembly of nucleases. It can target any particular site without any off-target mutations in the genome. The CRISPR-Cas9 has all of the above characteristics. The genome engineering technology may be a strong and inspiring technology meant for the next generation of drug development.