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7. Additional file 1 of Diurnal RNAPII-tethered chromatin interactions are associated with rhythmic gene expression in rice

Author

Deng, Li, Gao, Baibai, Zhao, Lun, Zhang, Ying, Zhang, Qing, Guo, Minrong, Yang, Yongqing, Wang, Shuangqi, Xie, Liang, Lou, Hao, Ma, Meng, Zhang, Wei, Cao, Zhilin, Zhang, Qinghua, McClung, C. Robertson, Li, Guoliang, and Li, Xingwang

Abstract

Additional file 1: Figure S1. Summary of meteorological data in Wuhan from July 7, 08:00 to July 9, 08:00, 2017. Figure S2. Rhythmic occupancy of RNA polymerase II (RNAPII). Figure S3. Whole-transcriptome RNA-seq analysis of rhythmic gene expression in paddy field rice leaves. Figure S4. Reproducibility and loop span of RNAPII-mediated ChIA-PET data. Figure S5. Global patterns of chromatin interactions in rice. Figure S6. Characterization of RNAPII-mediated chromatin interactions. Figure S7. Percentage of overlap or dynamic anchors throughout the day and the correlation between peak intensity and transcription. Figure S8. Properties of RNAPII-organized chromatin spatial clusters (CSCs). Figure S9. Interaction frequencies around AM- and PM- specific node genes in the RNAPII-arranged networks. Figure S10. Features of node genes in the RNAPII-mediated networks. Figure S11. Core circadian clock genes-associated chromatin interaction networks.

Published
2022
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9. Genetic and genomic resources to study natural variation in Brassica rapa

Author

Lou, Ping, primary, Woody, Scott, additional, Greenham, Kathleen, additional, VanBuren, Robert, additional, Colle, Marivi, additional, Edger, Patrick P., additional, Sartor, Ryan, additional, Zheng, Yakun, additional, Levendoski, Nathan, additional, Lim, Jan, additional, So, Calvin, additional, Stoveken, Brian, additional, Woody, Timothy, additional, Zhao, Jianjun, additional, Shen, Shuxing, additional, Amasino, Richard M., additional, and McClung, C. Robertson, additional

Published
2020
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14. Populations Are Differentiated in Biological Rhythms without Explicit Elevational Clines in the Plant Mimulus laciniatus.

Author

Leinonen, Päivi H., Salmela, Matti J., Greenham, Kathleen, McClung, C. Robertson, and Willis, John H.

Subjects
BIOLOGICAL rhythms, FLOWERING time, POPULATION differentiation, PLANT selection, MOLECULAR clock, SPATIAL variation, BIOLOGICAL laboratories, PLANT capacity
Abstract

Environmental variation along an elevational gradient can yield phenotypic differentiation resulting from varying selection pressures on plant traits related to seasonal responses. Thus, genetic clines can evolve in a suite of traits, including the circadian clock, that drives daily cycling in varied traits and that shares its genetic background with adaptation to seasonality. We used populations of annual Mimulus laciniatus from different elevations in the Sierra Nevada in California to explore among-population differentiation in the circadian clock, flowering responses to photoperiod, and phenological traits (days to cotyledon emergence, days to flowering, and days to seed ripening) in controlled common-garden conditions. Further, we examined correlations of these traits with environmental variables related to temperature and precipitation. We observed that the circadian period in leaf movement was differentiated among populations sampled within about 100 km, with population means varying by 1.6 h. Significant local genetic variation occurred within 2 populations in which circadian period among families varied by up to 1.8 h. Replicated treatments with variable ecologically relevant photoperiods revealed marked population differentiation in critical day length for flowering that ranged from 11.0 to 14.1 h, corresponding to the time period between late February and mid-May in the wild. Flowering time varied among populations in a 14-h photoperiod. Regardless of this substantial population-level diversity, obvious linear clinality in trait variability across elevations could not be determined based on our genotypic sample; it is possible that more complex spatial patterns of variation arise in complex terrains such as those in the Sierra Nevada. Moreover, we did not find statistically significant bivariate correlations between population means of different traits. Our research contributes to the understanding of genetic variation in the circadian clock and in seasonal responses in natural populations, highlighting the need for more comprehensive investigations on the association between the clock and other adaptive traits in plants. [ABSTRACT FROM AUTHOR]

Published
2020
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16. Author Correction: The F-box protein FKF1 inhibits dimerization of COP1 in the control of photoperiodic flowering

Author

Lee, Byoung-Doo, primary, Kim, Mi Ri, additional, Kang, Min-Young, additional, Cha, Joon-Yung, additional, Han, Su-Hyun, additional, Nawkar, Ganesh M., additional, Sakuraba, Yasuhito, additional, Lee, Sang Yeol, additional, Imaizumi, Takato, additional, McClung, C. Robertson, additional, Kim, Woe-Yeon, additional, and Paek, Nam-Chon, additional

Published
2018
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25. Circadian control of ORE1 by PRR9 positively regulates leaf senescence in Arabidopsis.

Author

Hyunmin Kim, Hyo Jung Kim, Quy Thi Vu, Sukjoon Jung, McClung, C. Robertson, Sunghyun Hong, and Hong Gil Nam

Subjects
CIRCADIAN rhythms, ANGIOSPERMS, TRANSCRIPTION factors, AGING, ARABIDOPSIS
Abstract

The circadian clock coordinates the daily cyclic rhythm of numerous biological processes by regulating a large portion of the transcriptome. In animals, the circadian clock is involved in aging and senescence, and circadian disruption by mutations in clock genes frequently accelerates aging. Conversely, aging alters circadian rhythmicity, which causes age-associated physiological alterations. However, interactions between the circadian clock and aging have been rarely studied in plants. Here, we investigated potential roles for the circadian clock in the regulation of leaf senescence in plants. Members of the evening complex in Arabidopsis circadian clock, EARLY FLOWERING 3 (ELF3), EARLY FLOWERING 4 (ELF4), and LUX ARRHYTHMO (LUX), as well as the morning component PSEUDO-RESPONSE REGULATOR 9 (PRR9), affect both age-dependent and dark-induced leaf senescence. The circadian clock regulates the expression of several senescence-related transcription factors. In particular, PRR9 binds directly to the promoter of the positive aging regulator ORESARA1 (ORE1) gene to promote its expression. PRR9 also represses miR164, a posttranscriptional repressor of ORE1. Consistently, genetic analysis revealed that delayed leaf senescence of a prr9 mutant was rescued by ORE1 overexpression. Thus, PRR9, a core circadian component, is a key regulator of leaf senescence via positive regulation of ORE1 through a feed-forward pathway involving posttranscriptional regulation by miR164 and direct transcriptional regulation. Our results indicate that, in plants, the circadian clock and leaf senescence are intimately interwoven as are the clock and aging in animals. [ABSTRACT FROM AUTHOR]

Published
2018
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26. The F-box protein FKF1 inhibits dimerization of COP1 in the control of photoperiodic flowering.

Author

Byoung-Doo Lee, Mi Ri Kim, Min-Young Kang, Joon-Yung Cha, Su-Hyun Han, Nawkar, Ganesh M., Yasuhito Sakuraba, Sang Yeol Lee, Takato Imaizumi, McClung, C. Robertson, Woe-Yeon Kim, and Nam-Chon Paek

Abstract

In Arabidopsis thaliana, CONSTANS (CO) plays an essential role in the regulation of photoperiodic flowering under long-day conditions. CO protein is stable only in the afternoon of long days, when it induces the expression of FLOWERING LOCUS T (FT), which promotes flowering. The blue-light photoreceptor FLAVIN-BINDING, KELCH REPEAT, F-BOX1 (FKF1) interacts with CO and stabilizes it by an unknown mechanism. Here, we provide genetic and biochemical evidence that FKF1 inhibits CONSTITUTIVE PHOTOMORPHOGENIC1 (COP1)- dependent CO degradation. Light-activated FKF1 has no apparent effect on COP1 stability but can interact with and negatively regulate COP1. We show that FKF1 can inhibit COP1 homodimerization. Mutation of the coiled-coil domain in COP1, which prevents dimer formation, impairs COP1 function in coordinating flowering time. Based on these results, we propose a model whereby the light- and day length-dependent interaction between FKF1 and COP1 controls CO stability to regulate flowering time. [ABSTRACT FROM AUTHOR]

Published
2017
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33. Geographic Variation of Plant Circadian Clock Function in Natural and Agricultural Settings.

Author

Greenham, Kathleen, Lou, Ping, Puzey, Joshua R., Kumar, Ganesh, Arnevik, Cindy, Fand, Hany, Willis, John H., and McClung, C. Robertson

Subjects
COMMON monkeyflower, SOYBEAN, CIRCADIAN rhythms, ABIOTIC stress, PLANT breeding, PLANTS
Abstract

The increasing demand for improved agricultural production will require more efficient breeding for traits that maintain yield under heterogeneous environments. The internal circadian oscillator is essential for perceiving and coordinating environmental cues such as day length, temperature, and abiotic stress responses within physiological processes. To investigate the contribution of the circadian clock to local adaptability, we have analyzed circadian period by leaf movement in natural populations of Mimulus guttatus and domesticated cultivars of Glycine max. We detected consistent variation in circadian period along a latitudinal gradient in annual populations of the wild plant and the selectively bred crop, and this provides novel evidence of natural and artificial selection for circadian performance. These findings provide new support that the circadian clock acts as a central regulator of plant adaptability and further highlight the potential of applying circadian clock gene variation to marker-assisted breeding programs in crops. [ABSTRACT FROM AUTHOR]

Published
2017
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34. Variation in circadian rhythms is maintained among and within populations in Boechera stricta.

Author

Salmela, Matti J., Greenham, Kathleen, Lou, Ping, McClung, C. Robertson, Ewers, Brent E., and Weinig, Cynthia

Subjects
BIOLOGICAL variation, CIRCADIAN rhythms, PLANT species, PLANT genetics, EFFECT of environment on plants
Abstract

Circadian clocks have evolved independently in all three domains of life, and fitness benefits of a functional clock have been demonstrated in experimental genotypes in controlled conditions. Still, little is known about genetic variation in the clock and its fitness consequences in natural populations from heterogeneous environments. Using Wyoming populations of the Arabidopsis relative Boechera stricta as our study system, we demonstrate that genetic variation in the clock can occur at multiple levels: means of circadian period among populations sampled at different elevations differed by less than 1 h, but means among families sampled within populations varied by as much as 3.5 h. Growth traits also varied among and within populations. Within the population with the most circadian variation, we observed evidence for a positive correlation between period and growth and a negative correlation between period and root-to-shoot ratio. We then tested whether performance tradeoffs existed among families of this population across simulated seasonal settings. Growth rankings of families were similar across seasonal environments, but for root-to-shoot ratio, genotype × environment interactions contributed significantly to total variation. Therefore, further experiments are needed to identify evolutionary mechanisms that preserve substantial quantitative genetic diversity in the clock in this and other species. [ABSTRACT FROM AUTHOR]

Published
2016
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35. Selection during crop diversification involves correlated evolution of the circadian clock and ecophysiological traits in Brassica rapa.

Author

Yarkhunova, Yulia, Edwards, Christine E., Ewers, Brent E., Baker, Robert L., Aston, Timothy Llewellyn, McClung, C. Robertson, Lou, Ping, and Weinig, Cynthia

Subjects
CROP diversification, CROP ecophysiology, BOK choy, CHINESE cabbage, PLANT biomass, GAS exchange in plants, PLANTS & the environment
Abstract

Crop selection often leads to dramatic morphological diversification, in which allocation to the harvestable component increases. Shifts in allocation are predicted to impact (as well as rely on) physiological traits; yet, little is known about the evolution of gas exchange and related anatomical features during crop diversification., In Brassica rapa, we tested for physiological differentiation among three crop morphotypes (leaf, turnip, and oilseed) and for correlated evolution of circadian, gas exchange, and phenological traits. We also examined internal and surficial leaf anatomical features and biochemical limits to photosynthesis., Crop types differed in gas exchange; oilseed varieties had higher net carbon assimilation and stomatal conductance relative to vegetable types. Phylogenetically independent contrasts indicated correlated evolution between circadian traits and both gas exchange and biomass accumulation; shifts to shorter circadian period (closer to 24 h) between phylogenetic nodes are associated with higher stomatal conductance, lower photosynthetic rate (when CO2 supply is factored out), and lower biomass accumulation. Crop type differences in gas exchange are also associated with stomatal density, epidermal thickness, numbers of palisade layers, and biochemical limits to photosynthesis., Brassica crop diversification involves correlated evolution of circadian and physiological traits, which is potentially relevant to understanding mechanistic targets for crop improvement. [ABSTRACT FROM AUTHOR]

Published
2016
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36. The Plant Circadian Oscillator.

Author

McClung, C. Robertson

Subjects
*CIRCADIAN rhythms, *GENE regulatory networks, *PROTEIN stability, *ENVIRONMENTAL permits, *RNA splicing, *PLANT breeding, *ABIOTIC stress
Abstract

It has been nearly 300 years since the first scientific demonstration of a self-sustaining circadian clock in plants. It has become clear that plants are richly rhythmic, and many aspects of plant biology, including photosynthetic light harvesting and carbon assimilation, resistance to abiotic stresses, pathogens, and pests, photoperiodic flower induction, petal movement, and floral fragrance emission, exhibit circadian rhythmicity in one or more plant species. Much experimental effort, primarily, but not exclusively in Arabidopsis thaliana, has been expended to characterize and understand the plant circadian oscillator, which has been revealed to be a highly complex network of interlocked transcriptional feedback loops. In addition, the plant circadian oscillator has employed a panoply of post-transcriptional regulatory mechanisms, including alternative splicing, adjustable rates of translation, and regulated protein activity and stability. This review focuses on our present understanding of the regulatory network that comprises the plant circadian oscillator. The complexity of this oscillatory network facilitates the maintenance of robust rhythmicity in response to environmental extremes and permits nuanced control of multiple clock outputs. Consistent with this view, the clock is emerging as a target of domestication and presents multiple targets for targeted breeding to improve crop performance. [ABSTRACT FROM AUTHOR]

Published
2019
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37. Rhythmic Leaf and Cotyledon Movement Analysis.

Author

Lou P, Greenham K, and McClung CR

Subjects
Circadian Rhythm, Movement, Plants, Cotyledon, Plant Leaves genetics
Abstract

The first descriptions of circadian rhythms were of the rhythmic leaf movements of plants. Rhythmic leaf movements offer a sensitive, noninvasive, nondestructive, and non-transgenic assay of plant circadian rhythms that can be readily automated, greatly facilitating genetic studies. Rhythmic leaf movement is particularly useful for the assessment of standing variation in clock function and can be readily applied to a diverse array of dicotyledonous plants, including both wild species and domesticated crops., (© 2022. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published
2022
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