The circadian clock goes genomic

Staiger D, Shin J, Johansson M, Davis SJ (2013)
Genome Biology 14(6).

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Large-scale biology among plant species, as well as comparative genomics of circadian clock architecture and clock-regulated output processes, have greatly advanced our understanding of the endogenous timing system in plants.
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Staiger D, Shin J, Johansson M, Davis SJ. The circadian clock goes genomic. Genome Biology. 2013;14(6).
Staiger, D., Shin, J., Johansson, M., & Davis, S. J. (2013). The circadian clock goes genomic. Genome Biology, 14(6).
Staiger, D., Shin, J., Johansson, M., and Davis, S. J. (2013). The circadian clock goes genomic. Genome Biology 14.
Staiger, D., et al., 2013. The circadian clock goes genomic. Genome Biology, 14(6).
D. Staiger, et al., “The circadian clock goes genomic”, Genome Biology, vol. 14, 2013.
Staiger, D., Shin, J., Johansson, M., Davis, S.J.: The circadian clock goes genomic. Genome Biology. 14, (2013).
Staiger, Dorothee, Shin, Jieun, Johansson, Mikael, and Davis, Seth J. “The circadian clock goes genomic”. Genome Biology 14.6 (2013).
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7 Citations in Europe PMC

Data provided by Europe PubMed Central.

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The spliceosome assembly factor GEMIN2 attenuates the effects of temperature on alternative splicing and circadian rhythms.
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Osmotic stress at the barley root affects expression of circadian clock genes in the shoot.
Habte E, Muller LM, Shtaya M, Davis SJ, von Korff M., Plant Cell Environ. 37(6), 2014
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