C Nathan Hancock
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Explore the profile of C Nathan Hancock including associated specialties, affiliations and a list of published articles.
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28
Citations
778
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Recent Articles
1.
Stupar R, Locke A, Allen D, Stacey M, Ma J, Weiss J, et al.
Plant Genome
. 2024 Nov;
17(4):e20516.
PMID: 39572930
This strategic plan summarizes the major accomplishments achieved in the last quinquennial by the soybean [Glycine max (L.) Merr.] genetics and genomics research community and outlines key priorities for the...
2.
Hancock C, Germany T, Redd P, Timmons J, Lipford J, Burns S, et al.
Plant Direct
. 2024 Nov;
8(11):e70011.
PMID: 39513014
Screening a transposon-mutagenized soybean population led to the discovery of a recessively inherited chlorotic phenotype. This "y24" phenotype results in smaller stature, weaker stems, and a smaller root system. Genome...
3.
Liu P, Panda K, Edwards S, Swanson R, Yi H, Pandesha P, et al.
Nature
. 2024 Jun;
631(8021):593-600.
PMID: 38926583
The current technologies to place new DNA into specific locations in plant genomes are low frequency and error-prone, and this inefficiency hampers genome-editing approaches to develop improved crops. Often considered...
4.
Hancock C, Germany T, Redd P, Timmons J, Lipford J, Burns S, et al.
bioRxiv
. 2024 Feb;
PMID: 38352530
Screening a transposon-mutagenized soybean population led to the discovery of a recessively inherited chlorotic phenotype. This "vir1" phenotype results in smaller stature, weaker stems, and a smaller root system with...
5.
Mudunkothge J, Hancock C, Krizek B
Methods Mol Biol
. 2023 Aug;
2686:351-363.
PMID: 37540369
The β-glucuronidase (GUS) reporter gene system is an important technique with versatile uses in the study of flower development in a broad range of species. Transcriptional and translational GUS fusions...
6.
Redd P, Payero L, Gilbert D, Page C, King R, McAssey E, et al.
Front Cell Dev Biol
. 2023 Jun;
11:1184046.
PMID: 37363729
Class II DNA transposable elements account for significant portions of eukaryotic genomes and contribute to genome evolution through their mobilization. To escape inactivating mutations and persist in the host genome...
7.
Renken K, Mendoza S, Diaz S, Slotkin R, Hancock C
MicroPubl Biol
. 2023 Jun;
2023.
PMID: 37273575
The plant-specific RNA Polymerase V (Pol V) plays a key role in gene silencing, but its role in repair of double stranded DNA breaks is unclear. Excision of the transposable...
8.
Redd P, Diaz S, Weidner D, Benjamin J, Hancock C
Mob DNA
. 2023 Feb;
14(1):1.
PMID: 36774502
Background: DNA transposable elements are mobilized by a "cut and paste" mechanism catalyzed by the binding of one or more transposase proteins to terminal inverted repeats (TIRs) to form a...
9.
Herbert A, Hancock C, Cox B, Schnabel G, Moreno D, Carvalho R, et al.
Front Microbiol
. 2022 Mar;
13:821808.
PMID: 35283838
pv. () causes bacterial spot, a major worldwide disease of species. Very few chemical management options are available for this disease and frequent applications of oxytetracycline (OTC) in the United...
10.
Nguyen C, Dohnalkova A, Hancock C, Kirk K, Stacey G, Stacey M
Plant Genome
. 2021 Dec;
16(2):e20171.
PMID: 34904377
De novo purine biosynthesis is required for the incorporation of fixed nitrogen in ureide exporting nodules, as formed on soybean [Glycine max (L.) Merr.] roots. However, in many cases, the...