A Primer on Protein Engineering
What is protein engineering?
Protein engineering is the modification or creation of proteins to enhance their properties or develop entirely new functions. It combines principles from molecular biology, genetics, and biochemistry to design and manipulate the structure, stability, activity, and specificity of proteins. Much like how an architect skillfully designs and builds a skyscraper, a protein engineer builds at the molecular scale using amino acids and chemical bonds in place of steel and glass.Why is protein engineering useful? Who can benefit?
Proteins are key players in biology. They’re responsible for nearly every aspect of cellular life, from carrying out reactions to providing structural support. Likewise, proteins are often a core component in many of the products we use on a daily basis, like certain medicines, cosmetics, clothing, and even food. Protein engineering offers the potential to tailor these proteins to meet the specific needs of each application to maximize results and enable the development of sophisticated, high-functioning technology. For example, protein engineering can design new enzymes with improved catalytic activity for laundry detergents, protein-based therapeutics with enhanced stability and efficacy to treat human disease, and proteins with superior mechanical strength and temperature tolerance for construction of environmentally sustainable bioplastics, just to name a few. In every industry where a protein is at play, regardless of where in the process, protein engineering can deliver a major benefit!How are proteins engineered? What techniques exist?
The main goal of protein engineering is to modify or create proteins with improved characteristics, such as increased stability, enhanced catalytic activity, altered binding specificity, or novel functions not found in nature. This can be achieved through various techniques, such as rational design, directed evolution, and computational design. -
Rational design relies on a deep understanding of the relationship between protein structure and function to make targeted modifications to specific amino acids or protein domains with the aim of achieving a desired protein behavior. This approach can make small changes to an existing protein, like surface mutations to improve an enzyme’s solubility, or can build entirely new proteins from existing parts, such as the construction of a chimeric antigen receptor on T-cells. Rational design can be employed to achieve a wide variety of different engineering goals and its targeted nature means a more streamlined design-build-test cycle, often significantly reducing the number of designs required to achieve the desired outcome.
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Directed evolution mimics natural selection in the laboratory and involves creating diverse libraries of protein variants through random or focused mutagenesis and selecting for variants that exhibit ideal properties. It is an iterative process that allows for the gradual improvement of protein characteristics over multiple rounds of design and selection. One example of this technique is the evolution of an enzyme to increase its heat tolerance and improve its utility for biomass conversion during biofuel production. Directed evolution is often the best choice when the protein of interest is an existing protein with little structural or functional information available. In this situation, the path towards achieving the desired outcome is often unclear so this approach allows for screening of a wide mutation space to identify initial design leads for refinement in later iterations.
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Computational approaches have made great strides in recent years, enabling protein engineers to model protein structures and reduce dependence on experimental structural determination. AlphaFold2 and RoseTTAFold are two examples of deep learning approaches that have dramatically improved the structural modeling space. Additional deep learning approaches are under development that allow for computational design, or de novo design, of proteins. This offers the potential to create entirely new, non-natural proteins with specified structure and function based on knowledge of protein folding energetics and structure-function relationships. De novo design is most successful when building proteins with greater than 80% novelty, such as the design of a fully non-natural inhibitor of PD-L1. Refinements to existing proteins or design of multi-domain chimeras are often best accomplished by other methods.
Protein Diversity: Many Forms, Many Functions
Despite their differences, all proteins rely on the same building blocks and physical principles.