Related references
Note: Only part of the references are listed.Florigen trafficking integrates photoperiod and temperature signals in Arabidopsis
Lu Liu et al.
JOURNAL OF INTEGRATIVE PLANT BIOLOGY (2020)
Transcriptome profiling reveals phase-specific gene expression in the developing barley inflorescence
Huiran Liu et al.
CROP JOURNAL (2020)
Diversity of photoperiodic responses in oats
I. G. Loskutov et al.
VAVILOVSKII ZHURNAL GENETIKI I SELEKTSII (2019)
Regulation of FT splicing by an endogenous cue in temperate grasses
Zhengrui Qin et al.
Nature Communications (2017)
Simulation of oat development cycle by photoperiod and temperature
Rubia D. Mantai et al.
REVISTA BRASILEIRA DE ENGENHARIA AGRICOLA E AMBIENTAL (2017)
Photoperiodic and thermosensory pathways interact through CONSTANS to promote flowering at high temperature under short days
Virginia Fernandez et al.
PLANT JOURNAL (2016)
A unique approach to demonstrating that apical bud temperature specifically determines leaf initiation rate in the dicot Cucumis sativus
Andreas Savvides et al.
PLANTA (2016)
Temperatures and the growth and development of maize and rice: a review
Berta Sanchez et al.
GLOBAL CHANGE BIOLOGY (2014)
Flowering time regulation: photoperiod- and temperature-sensing in leaves
Young Hun Song et al.
TRENDS IN PLANT SCIENCE (2013)
Tagging and mapping candidate loci for vernalization and flower initiation in hexaploid oat
Itamar C. Nava et al.
MOLECULAR BREEDING (2012)
Variability of phyllochron, plastochron and rate of increase in height in photoperiod-sensitive Sorghum varieties
B. Clerget et al.
ANNALS OF BOTANY (2008)
Flowering time in oat: Genotype characterization for photoperiod and vernalization response
A. B. Locatelli et al.
FIELD CROPS RESEARCH (2008)
Phytomers, phyllochrons, phenology and temperate cereal development
GS McMaster
JOURNAL OF AGRICULTURAL SCIENCE (2005)
Spring wheat leaf appearance and temperature: Extending the paradigm?
GS McMaster et al.
ANNALS OF BOTANY (2003)