Exploring quantum frontiers in protein structure prediction: techniques, challenges, and opportunities.

Protein folding is governed by the principle of free energy minimization, where a protein's native tertiary structure corresponds to the global minimum on an energy landscape shaped by quantum mechanical interactions such as hydrogen bonding, van der Waals forces, and electron delocalization. Despite significant advances in template-based modeling (TBM), ab-initio simulations, and deep learning approaches, classical methods continue to face challenges due to the exponential complexity of the conformational search space and the approximations involved in modeling molecular interactions. Although AlphaFold, a deep learning-based protein modeling tool, has achieved a remarkable score of 92.4 in the critical assessment of protein structure prediction (CASP), classical protein structure prediction (PSP) remains hindered by the computational limitations of conventional binary architecture in representing the physical constraints of biomolecular systems. By representing the combinatorial explosion of possible conformations as a more tractable optimization problem, quantum computing offers a fundamentally new paradigm for protein three-dimensional (3D) structure prediction. In this review, we explore how quantum computing (QC) techniques including quantum annealing, quantum optimization algorithms, and hybrid quantum-classical approaches can leverage quantum properties such as superposition, entanglement, and tunneling to more efficiently navigate the complex energy landscapes associated with protein folding. While current challenges, including limited qubit fidelity, error correction, and scalability, remain, the integration of quantum algorithms with classical strategies holds significant promise for advancing structural biology, with profound implications for drug discovery and the understanding of complex biomolecular systems.