In silico design and validation of a highly degenerate primer pair: a systematic approach
Autor: | Oluwaseyi Matthew Oretade, Oluwatoyin Folake Olukunle, Bukola Rukayat Oyelere, Prosper Obed Chukwuemeka, Michael Omoniyi Elabiyi, Joy Oseme Eigbe, Usman Garba Kurmi, Emmanuel Oluwasegun Akinsola, Oyeyemi Janet Oretade, Christopher Busayo Olowosoke, Haruna Isiyaku Umar, Lucky Efe Isunu |
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Jazyk: | angličtina |
Rok vydání: | 2020 |
Předmět: |
0301 basic medicine
Systematic Coverage lcsh:QH426-470 Computer science Bioinformatics In silico C12O lcsh:Biotechnology 030106 microbiology Population MC-DPD Genetic materials Computational biology 03 medical and health sciences Software Degenerate primers lcsh:TP248.13-248.65 Genetics Accessible education HYDEN Graphical user interface education.field_of_study business.industry Research In silico PCR lcsh:Genetics 030104 developmental biology Software design Primer (molecular biology) business Heuristics Biotechnology |
Zdroj: | Journal of Genetic Engineering and Biotechnology, Vol 18, Iss 1, Pp 1-17 (2020) Journal of Genetic Engineering & Biotechnology |
ISSN: | 2090-5920 |
DOI: | 10.1186/s43141-020-00086-y |
Popis: | Background The techniques of amplifying genetic materials have enabled the extensive study of several biological activities outside the biological milieu of living systems. More recently, this approach has been extended to amplify population of genes, from evolutionarily related gene family for detection and evaluation of microbial consortial with several unique potentialities (e.g., enzymatic degradability). Conceivably, primer mixtures containing substitutions of different bases at specific sites (degenerate primers) have enabled the amplification of these genes in PCR reaction. However, the degenerate primer design problem (DPD) is a constraint to designing this kind of primer. To date, different algorithms now exist to solve various versions of DPD problem, many of which, only few addresses and satisfy the criteria to design primers that can extensively cover high through-put sequences while striking the balance between specificity and efficiency. The highly degenerate primer (HYDEN) design software program primarily addresses this variant of DPD problem termed “maximum coverage-degenerate primer design (MC-DPD)” and its heuristics have been substantiated for optimal efficiency from significant successes in PCR. In spite of the premium presented for designing degenerate primers, literature search has indicated relatively little use of its heuristics. This has been thought to result from the complexity of the program since it is run only by command-line, hence limiting its accessibility. To solve this problem, researchers have optionally considered the manual design of degenerate primers or design through software programs that provides accessibility through a graphical user interface (GUI). Realizing this, we have attempted in this study to provide a user-friendly approach for researchers with little or no background in bioinformatics to design degenerate primers using HYDEN Results Virtual Tests of our designed degenerate primer pair through in silico PCR substantiated the correspondence between efficiency and coverage with the target sequences as pre-defined by the initial HYDEN output, thereby validating the potentials of HYDEN to effectively solve the MC-DPD problem. Additionally, the designed primer-pair mechanistically amplified all sequences used as a positive control with no amplification observed in the negative controls. Conclusion In this study, we provided a turnkey protocol to simplify the design of degenerate primers using the heuristics of the HYDEN software program. |
Databáze: | OpenAIRE |
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