Optimizing restriction site placement for synthetic genomes

Pablo Montes; Heraldo Memelli; Charles B. Ward; Joondong Kim; Joseph S.B. Mitchell; Steven Skiena

doi:10.1016/j.ic.2012.02.003

Optimizing restriction site placement for synthetic genomes

Pablo Montes
, Heraldo Memelli
, Charles B. Ward
, Joondong Kim
, Joseph S.B. Mitchell
, Steven Skiena

Stony Brook University

Research output: Contribution to journal › Article › peer-review

3 Scopus citations

Abstract

Restriction enzymes are the workhorses of molecular biology. We introduce a new problem which arises in the course of our project to design virus variants to serve as potential vaccines: we wish to modify virus-length genomes to introduce large numbers of unique restriction enzyme recognition sites while preserving wild-type function by substitution of synonymous codons. We show that the resulting problem is NP-Complete, give an exponential-time algorithm, as well as well-performing heuristics, and give excellent results for five sample viral genomes. Our resulting modified genomes have several times more unique restriction sites and reduce the maximum gap between adjacent sites by three to nine-fold.

Original language	English
Pages (from-to)	59-69
Number of pages	11
Journal	Information and Computation
Volume	213
DOIs	https://doi.org/10.1016/j.ic.2012.02.003
State	Published - Apr 2012

Keywords

Genome refactoring
Restriction enzyme placement
Synthetic biology

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10.1016/j.ic.2012.02.003

Cite this

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title = "Optimizing restriction site placement for synthetic genomes",

abstract = "Restriction enzymes are the workhorses of molecular biology. We introduce a new problem which arises in the course of our project to design virus variants to serve as potential vaccines: we wish to modify virus-length genomes to introduce large numbers of unique restriction enzyme recognition sites while preserving wild-type function by substitution of synonymous codons. We show that the resulting problem is NP-Complete, give an exponential-time algorithm, as well as well-performing heuristics, and give excellent results for five sample viral genomes. Our resulting modified genomes have several times more unique restriction sites and reduce the maximum gap between adjacent sites by three to nine-fold.",

keywords = "Genome refactoring, Restriction enzyme placement, Synthetic biology",

author = "Pablo Montes and Heraldo Memelli and Ward, \{Charles B.\} and Joondong Kim and Mitchell, \{Joseph S.B.\} and Steven Skiena",

year = "2012",

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doi = "10.1016/j.ic.2012.02.003",

language = "English",

volume = "213",

pages = "59--69",

journal = "Information and Computation",

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T1 - Optimizing restriction site placement for synthetic genomes

AU - Montes, Pablo

AU - Memelli, Heraldo

AU - Ward, Charles B.

AU - Kim, Joondong

AU - Mitchell, Joseph S.B.

AU - Skiena, Steven

PY - 2012/4

Y1 - 2012/4

N2 - Restriction enzymes are the workhorses of molecular biology. We introduce a new problem which arises in the course of our project to design virus variants to serve as potential vaccines: we wish to modify virus-length genomes to introduce large numbers of unique restriction enzyme recognition sites while preserving wild-type function by substitution of synonymous codons. We show that the resulting problem is NP-Complete, give an exponential-time algorithm, as well as well-performing heuristics, and give excellent results for five sample viral genomes. Our resulting modified genomes have several times more unique restriction sites and reduce the maximum gap between adjacent sites by three to nine-fold.

AB - Restriction enzymes are the workhorses of molecular biology. We introduce a new problem which arises in the course of our project to design virus variants to serve as potential vaccines: we wish to modify virus-length genomes to introduce large numbers of unique restriction enzyme recognition sites while preserving wild-type function by substitution of synonymous codons. We show that the resulting problem is NP-Complete, give an exponential-time algorithm, as well as well-performing heuristics, and give excellent results for five sample viral genomes. Our resulting modified genomes have several times more unique restriction sites and reduce the maximum gap between adjacent sites by three to nine-fold.

KW - Genome refactoring

KW - Restriction enzyme placement

KW - Synthetic biology

UR - https://www.scopus.com/pages/publications/84862780922

U2 - 10.1016/j.ic.2012.02.003

DO - 10.1016/j.ic.2012.02.003

M3 - Article

AN - SCOPUS:84862780922

SN - 0890-5401

VL - 213

SP - 59

EP - 69

JO - Information and Computation

JF - Information and Computation

ER -

Optimizing restriction site placement for synthetic genomes

Abstract

Keywords

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