Data

Data from: Microsatellite markers from the Ion Torrent: a multi-species contrast to 454 shotgun sequencing

The University of Western Australia
Elliott, Carole P. ; Enright, Neal J. ; Allcock, Richard J. N. ; Gardner, Michael G. ; Meglécz, Emese ; Anthony, Janet ; Krauss, Siegfried L.
Viewed: [[ro.stat.viewed]] Cited: [[ro.stat.cited]] Accessed: [[ro.stat.accessed]]
ctx_ver=Z39.88-2004&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Adc&rfr_id=info%3Asid%2FANDS&rft_id=info:doi10.5061/dryad.vv82q&rft.title=Data from: Microsatellite markers from the Ion Torrent: a multi-species contrast to 454 shotgun sequencing&rft.identifier=10.5061/dryad.vv82q&rft.publisher=DRYAD&rft.description=The development and screening of microsatellite markers have been accelerated by next-generation sequencing (NGS) technology and in particular GS-FLX pyro-sequencing (454). More recent platforms such as the PGM semiconductor sequencer (Ion Torrent) offer potential benefits such as dramatic reductions in cost, but to date have not been well utilized. Here, we critically compare the advantages and disadvantages of microsatellite development using PGM semiconductor sequencing and GS-FLX pyro-sequencing for two gymnosperm (a conifer and a cycad) and one angiosperm species. We show that these NGS platforms differ in the quantity of returned sequence data, unique microsatellite data and primer design opportunities, mostly consistent with the differences in read length. The strength of the PGM lies in the large amount of data generated at a comparatively lower cost and time. The strength of GS-FLX lies in the return of longer average length sequences and therefore greater flexibility in producing markers with variable product length, due to longer flanking regions, which is ideal for capillary multiplexing. These differences need to be considered when choosing a NGS method for microsatellite discovery. However, the ongoing improvement in read lengths of the NGS platforms will reduce the disadvantage of the current short read lengths, particularly for the PGM platform, allowing greater flexibility in primer design coupled with the power of a larger number of sequences.,IonXpress_001_Macrozamia riedleiIonXpress_001_Macrozamia.fastaIonXpress_015_Podocarpus drouynianusIonXpress_015_Podocarpus.fastaIonXpress_016_Ricinocarpos,&rft.creator=Elliott, Carole P. &rft.creator=Enright, Neal J. &rft.creator=Allcock, Richard J. N. &rft.creator=Gardner, Michael G. &rft.creator=Meglécz, Emese &rft.creator=Anthony, Janet &rft.creator=Krauss, Siegfried L. &rft.date=2014&rft.relation=http://research-repository.uwa.edu.au/en/publications/43af3663-4700-42a6-81fc-ec6eab37a764&rft_subject=Macrozamia riedlei&rft_subject=Podocarpus drouynianus&rft_subject=Plant Mating Systems&rft_subject=Landscape Genetics&rft_subject=Ricinocarpos brevis&rft_subject=Angiosperms&rft_subject=Ecological Genetics&rft_subject=Gymnosperms&rft_subject=Population Genetics - Empirical&rft.type=dataset&rft.language=English Access the data
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The development and screening of microsatellite markers have been accelerated by next-generation sequencing (NGS) technology and in particular GS-FLX pyro-sequencing (454). More recent platforms such as the PGM semiconductor sequencer (Ion Torrent) offer potential benefits such as dramatic reductions in cost, but to date have not been well utilized. Here, we critically compare the advantages and disadvantages of microsatellite development using PGM semiconductor sequencing and GS-FLX pyro-sequencing for two gymnosperm (a conifer and a cycad) and one angiosperm species. We show that these NGS platforms differ in the quantity of returned sequence data, unique microsatellite data and primer design opportunities, mostly consistent with the differences in read length. The strength of the PGM lies in the large amount of data generated at a comparatively lower cost and time. The strength of GS-FLX lies in the return of longer average length sequences and therefore greater flexibility in producing markers with variable product length, due to longer flanking regions, which is ideal for capillary multiplexing. These differences need to be considered when choosing a NGS method for microsatellite discovery. However, the ongoing improvement in read lengths of the NGS platforms will reduce the disadvantage of the current short read lengths, particularly for the PGM platform, allowing greater flexibility in primer design coupled with the power of a larger number of sequences.,IonXpress_001_Macrozamia riedleiIonXpress_001_Macrozamia.fastaIonXpress_015_Podocarpus drouynianusIonXpress_015_Podocarpus.fastaIonXpress_016_Ricinocarpos,

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External Organisations
Murdoch University; Flinders University; South Australian Museum; Aix-Marseille Université; French National Centre for Scientific Research (Dynamique du Langage)
Associated Persons
Neal J. Enright (Creator); Michael G. Gardner (Creator); Emese Meglécz (Creator)

Issued: 2014-01-01

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Subjects
Angiosperms | Ecological Genetics | Gymnosperms | Landscape Genetics | Macrozamia riedlei | Plant Mating Systems | Podocarpus drouynianus | Population Genetics - Empirical | Ricinocarpos brevis |

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