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Magnetoreception in Plants
FIGURE 5.6 Schematic representation of gene expression patterns in Arabidopsis thaliana leaves and foral meri
stem under near-null magnetic feld (NNMF). Leaf gene regulation of clock, photoperiod pathway, vernalization
pathway, gibberellin pathway, and regulatory network are depicted during early, intermediate, and late stages of
fowering. An early downregulation of clock, photoperiod, gibberellin, and vernalization pathways is accompanied
by a downregulation of AP1 and GA20ox. In the foral meristem, NNMF determines an early downregulation of
the gibberellin pathway, AGL24 and AP1, with a signifcant upregulation of LFY, FD, and SVP. In intermediate
times, AGL24 is upregulated, whereas at late times AP1 is upregulated. Te gibberellin pathway is downregulated
in early and intermediate times, whereas no regulation is found in late times. In both leaves and foral meristem
data, upregulation is shown in black areas, downregulation in gray areas, and no regulation in white. According to
Fornara et al. (2010), Jaeger et al. (2013), and Valentim et al. (2015). (Modifed from Agliassa et al. (2018a).)
NAC050 and NAC052 were also signifcantly downregulated. Terefore, exposure of A. thaliana to
NNMF causes a delay in the transition to fowering due to a combined regulation of leaves and foral
meristem genes (Figure 5.6).
An early downregulation of clock, photoperiod, gibberellin, and vernalization pathways is accom
panied by a downregulation of AP1 and GA20ox. FLC is upregulated by NNMF in early fowering
induction. In the foral meristem, the strong downregulation of FT and FLC in early phases of foral
development is accompanied by the downregulation of the gibberellin pathway and the upregulation of
FD, SVP, and the transcription factor LFY. Te common downregulation of AP1 in both foral meristem
and leaves is associated with the delay in fowering. In the foral meristem and leaves, the progressive
upregulation of AGL24, AP1, GI, and SVP from early to late phase of plant development is correlated to
the delay of fowering. Tese events are followed by the progressive reduction of gibberellin pathway
downregulation. Tese results indicate that NNMF does not prevent fowering, and that variations of
the MF are sufcient to modulate specifc genes in the early stages of fower induction that are associated
with the observed delay. However, the gene expression regulation might not refect the post-translational