Hugh G Nimmo
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Explore the profile of Hugh G Nimmo including associated specialties, affiliations and a list of published articles.
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31
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1448
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Recent Articles
1.
James A, Sharples C, Laird J, Armstrong E, Guo W, Tzioutziou N, et al.
New Phytol
. 2023 Oct;
241(1):283-297.
PMID: 37897048
Cold stress is one of the major environmental factors that limit growth and yield of plants. However, it is still not fully understood how plants account for daily temperature fluctuations,...
2.
Nimmo H, Laird J
Front Plant Sci
. 2021 Nov;
12:750367.
PMID: 34733306
The core of the plant circadian clock involves multiple interlocking gene expression loops and post-translational controls along with inputs from light and metabolism. The complexity of the interactions is such...
3.
Tzioutziou N, James A, Guo W, Calixto C, Zhang R, Nimmo H, et al.
Methods Mol Biol
. 2021 Oct;
2398:173-188.
PMID: 34674176
RNA-sequencing (RNA-seq) is currently the method of choice for analysis of differential gene expression. To fully exploit the wealth of data generated from genome-wide transcriptomic approaches, the initial design of...
4.
Nimmo H, Fontaine V, Hartwell J, Jenkins G, Nimmo G, Wilkins M
New Phytol
. 2021 Apr;
151(1):91-97.
PMID: 33873386
Phosphoenolpyruvate (PEP) carboxylase plays a number of key roles in the central metabolism of higher plants. The enzyme is regulated by reversible phosphorylation in response to a range of signals...
5.
Hartwell J, Nimmo G, Wilkins M, Jenkins G, Nimmo H
Funct Plant Biol
. 2020 Jul;
29(6):663-668.
PMID: 32689512
This paper originates from a presentation at the IIIrd International Congress on Crassulacean Acid Metabolism, Cape Tribulation, Queensland, Australia, August 2001. In crassulacean acid metabolism (CAM) plants, phosphoenolpyruvate carboxylase (PEPC)...
6.
Nimmo H, Laird J, Bindbeutel R, Nusinow D
Physiol Plant
. 2020 Apr;
169(3):442-451.
PMID: 32303120
The circadian clock regulates the timing of many aspects of plant physiology, and this requires entrainment of the clock to the prevailing day:night cycle. Different plant cells and tissues can...
7.
Calixto C, Tzioutziou N, James A, Hornyik C, Guo W, Zhang R, et al.
Front Plant Sci
. 2019 Mar;
10:235.
PMID: 30891054
Plants re-program their gene expression when responding to changing environmental conditions. Besides differential gene expression, extensive alternative splicing (AS) of pre-mRNAs and changes in expression of long non-coding RNAs (lncRNAs)...
8.
Calixto C, Guo W, James A, Tzioutziou N, Entizne J, Panter P, et al.
Plant Cell
. 2018 May;
30(7):1424-1444.
PMID: 29764987
Plants have adapted to tolerate and survive constantly changing environmental conditions by reprogramming gene expression The dynamics of the contribution of alternative splicing (AS) to stress responses are unknown. RNA-sequencing...
9.
James A, Calixto C, Tzioutziou N, Guo W, Zhang R, Simpson C, et al.
Plant Cell Environ
. 2018 Mar;
41(7):1539-1550.
PMID: 29532482
One of the ways in which plants can respond to temperature is via alternative splicing (AS). Previous work showed that temperature changes affected the splicing of several circadian clock gene...
10.
James A, Sullivan S, Nimmo H
Plant Cell Environ
. 2018 Mar;
41(7):1524-1538.
PMID: 29520807
How plants perceive and respond to temperature remains an important question in the plant sciences. Temperature perception and signal transduction may occur through temperature-sensitive intramolecular folding of primary mRNA transcripts....