CRISPR-Cas Technology Turns Chlamydomonas reinhardtii into a Flagship for Algal Biotechnology

Microalgae represent some of the most promising eukaryotic platforms in biotechnology due to their rapid growth, simple cultivation requirements, reliance on sunlight as a primary energy source, and ability to synthesize high-value bioactive compounds. These characteristics have made microalgae attractive candidates in various fields, including biofuel production, carbon capture, and pharmaceutical development. However, several technical limitations have limited their large-scale use as sustainable biofactories. A paradigm shift is currently occurring thanks to the genetic manipulation of microalgae, driven by CRISPR-Cas technology. Significant progress has been made in the model species Chlamydomonas reinhardtii, particularly in the targeted and efficient insertion of foreign DNA. Despite this progress, key challenges remain, and further optimization of CRISPR-Cas methodologies is needed to fully unleash the genetic potential of this organism. This review provides an overview of the convergence of CRISPR-Cas technologies in microalgae research, highlighting their impact on genetic studies, metabolic engineering, and industrial applications. It summarizes recent advances in microalgal genome editing through CRISPR systems, outlines current technical challenges, and highlights future directions for improving the implementation of this innovative technology in microalgal biotechnology.