alexa Identification, cloning, and expression of uracil-DNA glycosylase from Atlantic cod (Gadus morhua): characterization and homology modeling of the cold-active catalytic domain.
Chemical Engineering

Chemical Engineering

Journal of Thermodynamics & Catalysis

Author(s): Lanes O, Leiros I, Smals AO, Willassen NP

Abstract Share this page

Abstract Two distinct forms of the highly conserved uracil-DNA glycosylase (UNG) have been isolated from Atlantic cod (Gadus morhua) liver cDNA by rapid amplification of cDNA ends (RACE). From the cDNA sequences, both forms were deduced to encode an open reading frame of 301 amino acids, with an identical 267-amino-acid C-terminal region and different N-terminal regions of 34 amino acids. By comparison with the human UNG sequences, the two forms were identified as possible mitochondrial (cUNG1) and nuclear (cUNG2) forms. Several constructs of recombinant cUNG (rcUNG) were expressed in Escherichia coli in order to optimize the yield. The recombinant enzyme was purified to apparent homogeneity as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Activity and stability experiments showed that rcUNG was similar to cUNG previously purified from Atlantic cod liver, and was more pH- and temperature labile than a recombinant human UNG (rhUNG). Under optimal assay conditions for both rcUNG and rhUNG, the turnover number (k(cat)) was three times higher for rcUNG compared with rhUNG, with an identical K(M), resulting in a threefold higher catalytic efficiency (k(cat)/K(M)) for rcUNG. These activity and stability experiments reveal cold-adapted features in rcUNG. Homology models of the catalytic domains of Atlantic cod (cUNG) and mouse uracil-DNA glycosylase (mUNG) were built using the human UNG (hUNG) crystal structure as a template. The unique amino acid substitutions observed in cod UNG were mainly located in the N- and C-terminal parts of the sequence. The analysis indicated a more stable N-terminal, a more flexible C-terminal, and a less stabilized core in cUNG as compared with the mammalian UNGs. Substitution of several amino acids in or near the DNA-binding site in cUNG could give rise to a more positively charged surface and a higher electrostatic potential near the active site compared with the mammalian UNGs. The higher potential may increase the electrostatic interactions between the enzyme and DNA, and may explain the increased substrate affinity and, in combination with the higher flexibility, the higher catalytic efficiency observed for rcUNG.
This article was published in Extremophiles and referenced in Journal of Thermodynamics & Catalysis

Relevant Expert PPTs

Relevant Speaker PPTs

Recommended Conferences

OMICS International Journals
 
Make the best use of Scientific Research and information from our 700 + peer reviewed, Open Access Journals
International Conferences 2017-18
 
Meet Inspiring Speakers and Experts at our 3000+ Global Annual Meetings

Contact Us

Agri, Food, Aqua and Veterinary Science Journals

Dr. Krish

agrifoodaquavet@omicsonline.com

1-702-714-7001 Extn: 9040

Clinical and Biochemistry Journals

Datta A

clinical_biochem@omicsonline.com

1-702-714-7001Extn: 9037

Business & Management Journals

Ronald

business@omicsonline.com

1-702-714-7001Extn: 9042

Chemical Engineering and Chemistry Journals

Gabriel Shaw

chemicaleng_chemistry@omicsonline.com

1-702-714-7001 Extn: 9040

Earth & Environmental Sciences

Katie Wilson

environmentalsci@omicsonline.com

1-702-714-7001Extn: 9042

Engineering Journals

James Franklin

engineering@omicsonline.com

1-702-714-7001Extn: 9042

General Science and Health care Journals

Andrea Jason

generalsci_healthcare@omicsonline.com

1-702-714-7001Extn: 9043

Genetics and Molecular Biology Journals

Anna Melissa

genetics_molbio@omicsonline.com

1-702-714-7001 Extn: 9006

Immunology & Microbiology Journals

David Gorantl

immuno_microbio@omicsonline.com

1-702-714-7001Extn: 9014

Informatics Journals

Stephanie Skinner

omics@omicsonline.com

1-702-714-7001Extn: 9039

Material Sciences Journals

Rachle Green

materialsci@omicsonline.com

1-702-714-7001Extn: 9039

Mathematics and Physics Journals

Jim Willison

mathematics_physics@omicsonline.com

1-702-714-7001 Extn: 9042

Medical Journals

Nimmi Anna

medical@omicsonline.com

1-702-714-7001 Extn: 9038

Neuroscience & Psychology Journals

Nathan T

neuro_psychology@omicsonline.com

1-702-714-7001Extn: 9041

Pharmaceutical Sciences Journals

John Behannon

pharma@omicsonline.com

1-702-714-7001Extn: 9007

Social & Political Science Journals

Steve Harry

social_politicalsci@omicsonline.com

1-702-714-7001 Extn: 9042

 
© 2008-2017 OMICS International - Open Access Publisher. Best viewed in Mozilla Firefox | Google Chrome | Above IE 7.0 version