Your search keyword '"Wolfe, Brian R."' showing total 2 results

1. Nucleic acid sequence design via efficient ensemble defect optimization.

Author

Zadeh JN, Wolfe BR, and Pierce NA

Subjects

Base Sequence, Molecular Sequence Data, Nucleic Acid Conformation, Algorithms, DNA chemistry, RNA chemistry

Abstract

We describe an algorithm for designing the sequence of one or more interacting nucleic acid strands intended to adopt a target secondary structure at equilibrium. Sequence design is formulated as an optimization problem with the goal of reducing the ensemble defect below a user-specified stop condition. For a candidate sequence and a given target secondary structure, the ensemble defect is the average number of incorrectly paired nucleotides at equilibrium evaluated over the ensemble of unpseudoknotted secondary structures. To reduce the computational cost of accepting or rejecting mutations to a random initial sequence, candidate mutations are evaluated on the leaf nodes of a tree-decomposition of the target structure. During leaf optimization, defect-weighted mutation sampling is used to select each candidate mutation position with probability proportional to its contribution to the ensemble defect of the leaf. As subsequences are merged moving up the tree, emergent structural defects resulting from crosstalk between sibling sequences are eliminated via reoptimization within the defective subtree starting from new random subsequences. Using a Θ(N(3) ) dynamic program to evaluate the ensemble defect of a target structure with N nucleotides, this hierarchical approach implies an asymptotic optimality bound on design time: for sufficiently large N, the cost of sequence design is bounded below by 4/3 the cost of a single evaluation of the ensemble defect for the full sequence. Hence, the design algorithm has time complexity Ω(N(3) ). For target structures containing N ∈{100,200,400,800,1600,3200} nucleotides and duplex stems ranging from 1 to 30 base pairs, RNA sequence designs at 37°C typically succeed in satisfying a stop condition with ensemble defect less than N/100. Empirically, the sequence design algorithm exhibits asymptotic optimality and the exponent in the time complexity bound is sharp., (Copyright © 2010 Wiley Periodicals, Inc.)

Published

2011

2. NUPACK: Analysis and design of nucleic acid systems.

Author

Zadeh, Joseph N., Steenberg, Conrad D., Bois, Justin S., Wolfe, Brian R., Pierce, Marshall B., Khan, Asif R., Dirks, Robert M., and Pierce, Niles A.

Subjects

COMPUTER software, NUCLEIC acids, INTERNET servers, COMPUTER algorithms, COMPUTER interfaces, THERMODYNAMICS, DNA, RNA

Abstract

The Nucleic Acid Package (NUPACK) is a growing software suite for the analysis and design of nucleic acid systems. The NUPACK web server () currently enables: NUPACK algorithms are formulated in terms of nucleic acid secondary structure. In most cases, pseudoknots are excluded from the structural ensemble. © 2010 Wiley Periodicals, Inc. J Comput Chem, 2010 [ABSTRACT FROM AUTHOR]

Published

2011