Computational Protein Design as a Cost Function Network Optimization Problem

Proteins are the main active molecules of life. Although natural proteins play many roles, as enzymes or antibodies for example, there is a need to go beyond the repertoire of natural proteins to produce engineered proteins that precisely meet application requirements, in terms of function, stability, activity or other protein capacities. Computational Protein Design aims at designing new proteins from first principles, using full-atom molecular models. However, the size and complexity of proteins require approximations to make them amenable to energetic optimization queries. These approximations make the design process less reliable, and a provable optimal solution may fail. In practice, expensive libraries of solutions are therefore generated and tested. In this paper, we explore the idea of generating libraries of provably diverse low-energy solutions by extending cost function network algorithms with dedicated automaton-based diversity constraints on a large set of realistic full protein redesign problems. We observe that it is possible to generate provably diverse libraries in reasonable time and that the produced libraries do enhance the Native Sequence Recovery, a traditional measure of design methods reliability.

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Guaranted Diversity and Optimality in Cost Function Network Based Computational Protein Design Methods

10.20944/preprints202104.0250.v1 ◽

2021 ◽

Author(s):

Manon Ruffini ◽

Jelena Vucinic ◽

Simon de Givry ◽

George Katsirelos ◽

Sophie Barbe ◽

...

Keyword(s):

Cost Function ◽

Protein Design ◽

Optimal Solution ◽

Design Methods ◽

Computational Protein Design ◽

Large Set ◽

Network Algorithms ◽

Native Sequence ◽

Application Requirements ◽

Function Network

Proteins are the main active molecules of Life. While natural proteins play many roles, as enzymes or antibodies for example, there is a need to go beyond the repertoire of natural proteins to produce engineered proteins that precisely meet application requirements, in terms of function, stability, activity or other protein capacities. Computational Protein Design aims at designing new proteins from first principles, using full-atom molecular models. However, the size and complexity of proteins require approximations to make them amenable to energetic optimization queries. These approximations make the design process less reliable and a provable optimal solution may fail. In practice, expensive libraries of solutions are therefore generated and tested. In this paper, we explore the idea of generating libraries of provably diverse low energy solutions by extending Cost Function Network algorithms with dedicated automaton-based diversity constraints on a large set of realistic full protein redesign problems. We observe that it is possible to generate provably diverse libraries in reasonable time and that the produced libraries do enhance the Native Sequence Recovery, a traditional measure of design methods reliability.

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Variable Neighborhood Search with Cost Function Networks To Solve Large Computational Protein Design Problems

Journal of Chemical Information and Modeling ◽

10.1021/acs.jcim.8b00510 ◽

2018 ◽

Vol 59 (1) ◽

pp. 127-136 ◽

Cited By ~ 1

Author(s):

Antoine Charpentier ◽

David Mignon ◽

Sophie Barbe ◽

Juan Cortes ◽

Thomas Schiex ◽

...

Keyword(s):

Cost Function ◽

Protein Design ◽

Variable Neighborhood Search ◽

Computational Protein Design ◽

Neighborhood Search ◽

Design Problems

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An exact approach for the multicommodity network optimization problem with a step cost function

RAIRO - Operations Research ◽

10.1051/ro/2019017 ◽

2019 ◽

Vol 53 (4) ◽

pp. 1279-1295 ◽

Cited By ~ 1

Author(s):

Imen Mejri ◽

Mohamed Haouari ◽

Safa Bhar Layeb ◽

Farah Zeghal Mansour

Keyword(s):

Cost Function ◽

Network Optimization ◽

Optimization Problem ◽

Planning Problem ◽

Large Set ◽

Constraint Generation ◽

Exact Separation ◽

Installation Cost ◽

Facility Capacity

We investigate the Multicommodity Network Optimization Problem with a Step Cost Function (MNOP-SCF) where the available facilities to be installed on the edges have discrete step-increasing cost and capacity functions. This strategic long-term planning problem requires installing at most one facility capacity on each edge so that all the demands are routed and the total installation cost is minimized. We describe a path-based formulation that we solve exactly using an enhanced constraint generation based procedure combined with columns and new cuts generation algorithms. The main contribution of this work is the development of a new exact separation model that identifies the most violated bipartition inequalities coupled with a knapsack-based problem that derives additional cuts. To assess the performance of the proposed approach, we conducted computational experiments on a large set of randomly generated instances. The results show that it delivers optimal solutions for large instances with up to 100 nodes, 600 edges, and 4950 commodities while in the literature, the best developed approaches are limited to instances with 50 nodes, 100 edges, and 1225 commodities.

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