Computational Molecular Biology 2024 Vol.14, No.3, 95-96 http://bioscipublisher.com/index.php/cmb 95 Editoroal Open Access Embracing AI's Role in Structural Biology While Recognizing Its Limits Computational Molecular Biology, 2024, Vol.14, No.3 doi: 10.5376/cmb.2024.14.0011 This is an open access article published under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. Preferred citation for this article: 2024, Embracing AI's role in structural biology while recognizing its limits, Computational Molecular Biology, 14(3): 95-96 (doi: 10.5376/cmb.2024.14.0011) he realm of structural biology has witnessed an unprecedented transformation with the advent of artificial intelligence (AI) technologies, most notably through the work of AlphaFold. On May 8, 2024, a pivotal paper by Abramson, Adler, Dunger, et al., published in Nature, demonstrated the impressive capabilities of AlphaFold 3 in accurately predicting biomolecular interactions (Abramson et al., 2024). This breakthrough represents a significant leap in our ability to decipher the intricate architecture of proteins, a fundamental building block of life. Yet, as we celebrate this achievement, it is imperative to consider the diverse perspectives within the scientific community regarding the role and limitations of AI in this field. Dr. Shi Yigong, President of Westlake University and renowned structural biologist, has been a vocal advocate for the transformative potential of AI in structural biology. He highlights the staggering progress AI has enabled, noting that within a mere few years, AI has predicted the structures of over 600,000,000 or 700 million proteins, vastly expanding our structural database from 220,000 experimentally determined structures to an almost unfathomable scale. Shi asserts, “AI’s rapid advancements have fundamentally altered our understanding of protein structures, offering a database that is several orders of magnitude larger than what we had before. This scale of change inevitably influences our comprehension of life sciences, drug discovery, and disease treatment” (Credit: Tai Media AGI, Video ID: sphMGEP2FvbOKcq). Shi's enthusiasm stems from the ability of AI to expedite processes that previously required extensive time and resources. He recounts how tasks that once took his team of doctoral students years to complete can now be accomplished in mere weeks with AI assistance. This acceleration allows researchers to shift their focus from the painstaking process of data collection to the more intellectually stimulating tasks of hypothesis testing and functional exploration. Contrastingly, Yan Ning, a distinguished structural biologist and former professor at Princeton University, now serving as the dean of President of Shenzhen Medical Academy of Research and Translation, adopts a more cautious stance. While acknowledging AI’s impressive achievements, Yan emphasizes the current limitations of AI, particularly its inability to fully replicate the dynamic nature of biomolecular structures. She underscores the importance of experimental validation and the discovery of multiple conformations of proteins, which are crucial for understanding their functional mechanisms and identifying new drug targets. Yan remarks, “AI can predict a static structure, but the true beauty and complexity of proteins lie in their dynamic states. To truly understand a protein’s function, we must observe it in various conformations, something AI currently struggles with” (Credit: Tai Media AGI, Video ID: sphMGEP2FvbOKcq ). Yan’s reservations are grounded in her extensive experience and the unpredictable nature of experimental science. She cites instances where experimental techniques have revealed unexpected conformations and interactions that AI predictions missed, highlighting the indispensable role of empirical research. Her insights T To unlock the full potential of scientific discovery, we must leverage the power ofAIwhile maintaining the rigorof experimental validation.
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