John M Cheeseman
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Explore the profile of John M Cheeseman including associated specialties, affiliations and a list of published articles.
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11
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569
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Recent Articles
1.
Cheeseman J
Funct Plant Biol
. 2020 Jul;
36(8):721-731.
PMID: 32688682
HO is an ubiquitous compound involved in signalling, metabolic control, stress responses and development. The compatibility of leaf tissue levels with these functions has, however, often been questioned. The objective...
2.
Cheeseman J
Funct Plant Biol
. 2020 Jun;
40(9):759-774.
PMID: 32481149
The successful integration of activity in saline environments requires flexibility of responses at all levels, from genes to life cycles. Because plants are complex systems, there is no 'best' or...
3.
Kazachkova Y, Eshel G, Pantha P, Cheeseman J, Dassanayake M, Barak S
Plant Physiol
. 2018 Sep;
178(3):972-988.
PMID: 30237204
Halophytes are able to thrive in salt concentrations that would kill 99% of other plant species, and identifying their salt-adaptive mechanisms has great potential for improving the tolerance of crop...
4.
Cheeseman J
New Phytol
. 2014 Dec;
206(2):557-70.
PMID: 25495078
The effective development of salt tolerant crops requires an understanding that the evolution of halophytes, glycophytes and our major grain crops has involved significantly different processes. Halophytes (and other edaphic...
5.
Wu H, Zhang Z, Wang J, Oh D, Dassanayake M, Liu B, et al.
Proc Natl Acad Sci U S A
. 2012 Jul;
109(30):12219-24.
PMID: 22778405
Thellungiella salsuginea, a close relative of Arabidopsis, represents an extremophile model for abiotic stress tolerance studies. We present the draft sequence of the T. salsuginea genome, assembled based on ~134-fold...
6.
Oh D, Dassanayake M, Bohnert H, Cheeseman J
Genome Biol
. 2012 Mar;
13(3):241.
PMID: 22390828
Extremophile plants thrive in places where most plant species cannot survive. Recent developments in high-throughput technologies and comparative genomics are shedding light on the evolutionary mechanisms leading to their adaptation.
7.
Dassanayake M, Oh D, Haas J, Hernandez A, Hong H, Ali S, et al.
Nat Genet
. 2011 Aug;
43(9):913-8.
PMID: 21822265
Thellungiella parvula is related to Arabidopsis thaliana and is endemic to saline, resource-poor habitats, making it a model for the evolution of plant adaptation to extreme environments. Here we present...
8.
Dassanayake M, Oh D, Hong H, Bohnert H, Cheeseman J
Trends Plant Sci
. 2010 Nov;
16(1):1-3.
PMID: 21094076
No abstract available.
9.
Oh D, Dassanayake M, Haas J, Kropornika A, Wright C, DUrzo M, et al.
Plant Physiol
. 2010 Sep;
154(3):1040-52.
PMID: 20833729
The genome of Thellungiella parvula, a halophytic relative of Arabidopsis (Arabidopsis thaliana), is being assembled using Roche-454 sequencing. Analyses of a 10-Mb scaffold revealed synteny with Arabidopsis, with recombination and...
10.
Dassanayake M, Haas J, Bohnert H, Cheeseman J
Funct Integr Genomics
. 2010 Jan;
10(4):523-32.
PMID: 20107865
We present here the Mangrove Transcriptome Database (MTDB), an integrated, web-based platform providing transcript information from all 28 mangrove species for which information is available. Sequences are annotated, and when...