Transcript PLB203-2009
Circadian rhythms and photperiodism
Eva Farre
Objectives for today:
Students will be able to:
•Distinguish between circadian vs. diurnal rhythms
•Interpret the role of the circadian clock in photoperiodism
•Understand the current molecular model for daylength sensing
What processes are regulated by day length?
Examples to discuss today:
*Flowering time
*Growth cessation and bud set
Circadian vs. diel/diurnal oscillations
Case 1: Flowering time regulation in Arabidopsis
Short days
Long days
FT and CO are necessary for flowering under long day
conditions
wild type
co
ft
co ft
co-ox
co-ox ft
co ft-ox
MODEL
Long Days
early
late
late
late
early
late
early
+ long days
CO
FT
OX= overexpressor
co = constants mutant
ft = flowering locus T mutant
Short Days
late
late
late
late
early
late
early
Flowering
FT and CO are
necessary for flowering in
LD and function in the
same pathway
FT acts downstream of
CO
How does CO know it is a long day?
Hour glass model
External coincidence model
(Bunning's 1936)
Internal coincidence model
(Pittendrigh 1960)
Yanovsky & Kay 2003
Previous knowledge:
CO activates FT under long days
FT induces flowering
Light is necessary for FT induction
Circadian clock mutants display flowering phenotypes
Questions:
1. When does the peak of CO RNA expression occur in
wild type Arabidopsis plants?
2. Does the CO expression peak at the same under long
day and under short day conditions in the wild type?
3. Does the expression of FT change between short day
and long day conditions in the wild type?
Figures 1 and 2: CO effect on FT under 24 h days
CO
FT
toc1-1
Wild-type
Questions:
4. What is the circadian period of the toc1-1 mutant
under constant light conditions?
5. What is the flowering phenotype of the toc1-1 mutant
grown under short day conditions (8 h light and 24 h total
day length)?
6. What is the flowering phenotype of the toc1-1 mutant
grown under days of only 21h total length?
7. How does the toc1-1 mutation influence the
expression of CO?
Figure 1
toc1-1
Wild-type
Figure 2
toc1-1
Wild-type
Questions:
8. What happens to FT expression in plants
overexpressing CO, i.e. with constitutive high levels of CO
expression?
9. What does CO need to induce the expression of FT?
Figure 4
Questions:
10. Does the data presented in this paper support the
“external coincidence model” or the “internal
coincidence model” of flowering time?
The external coincidence model
Imaizumi and Kay, 2006
Could this model explain the day length dependent
growth arrest phenotypes of trees?
Low FT levels correlate with faster growth arrest and
bud formation
mutant lines with decreased FT levels
Different aspen clones display differences in the timing
of growth arrest
19 light: 5 h night
arrest
arrest
growth
growth
Different aspen clones display differences in the timing
of growth arrest
North
earlier (longer days)
later (shorter days)
South
Questions:
a. Based on what you have learned from the work of
Yanovsky & Kay, establish a hypothesis that could explain
the observations of Bohlenius et al.
b. Why would this be of evolutionary advantage to the
trees?
19 light: 5 h night
NORTH
arrest
arrest
growth
SOUTH
growth
The circadian clock regulates the phase/timing of gene
expression
Entrainment experiment
Q3. Predict the growth pattern of the seedling in frame 3. What is the rationale
for your prediction?
Individuals write on carbonless paper.
Entrainability of circadian clocks
CAB2:LUC
Thain et al., Curr Biol 2000
http://millar.bio.ed.ac.uk/video.html