A possible role for flowering locus T-encoding genes in interpreting environmental and internal cues affecting olive (Olea europaea L.) flower induction.

Olive (Olea europaea L.) inflorescences, formed in lateral buds, flower in spring. However, there is some debate regarding time of flower induction and inflorescence initiation. Olive juvenility and seasonality of flowering were altered by overexpressing genes encoding flowering locus T (FT). OeFT1 and OeFT2 caused early flowering under short days when expressed in Arabidopsis. Expression of OeFT1/2 in olive leaves and OeFT2 in buds increased in winter, while initiation of inflorescences occurred i n late winter. Trees exposed to an artificial warm winter expressed low levels of OeFT1/2 in leaves and did not flower. Olive flower induction thus seems to be mediated by an increase in FT levels in response to cold winters. Olive flowering is dependent on additional internal factors. It was severely reduced in trees that carried a heavy fruit load the previous season (harvested in November) and in trees without fruit to which cold temperatures were artificially applied in summer. Expression analysis suggested that these internal factors work either by reducing the increase in OeFT1/2 expression or through putative flowering repressors such as TFL1. With expected warmer winters, future consumption of olive oil, as part of a healthy Mediterranean diet, should benefit from better understanding these factors.

Novel roles for GIGANTEA revealed under environmental conditions that modify its expression in Arabidopsis and Medicago truncatula.

GIGANTEA (GI) is a large nuclear protein which is involved in circadian-clock function, red-light signaling and photoperiodic flowering. Accumulation of GI transcript displays a strong diurnal pattern, and is under circadian-clock control, as demonstrated in several diverse species. Clock entrainment and compensation, as well as flowering time, are largely responsive to changes in the environment. We asked if part of this response is mediated through modification of GI expression. We identified a strong response of GI expression to changes in temperature and light, in both Arabidopsis and the model legume Medicago truncatula. Extreme temperatures resulted in increased GI trough levels. Light increased GI expression near dawn and the response to light appeared to be gated by the circadian clock. We provide evidence that the GI response to blue and far-red light requires CRYPTOCHROME function in Arabidopsis. Unknown roles for GI in both blue-light deetiolation and precocious flowering under warm short days were revealed. Plants seem to respond to changes in the environment partly through environmentally induced modifications of a basal clock-regulated pattern of GI transcript accumulation.