the flowering process is the combined effect of environmental factors like light and temperature. vernalisation is the epigenetic memory that leads to genetic regulation of the process
3. Vernalisation
• Lysenko (1928), a Russian worker, found that by
providing low temperature treatment to young
plants or moistened seeds, the cold requiring
annual and biennial plants can be made to flower
in one growing season.
• He called the effect of this chilling treatment as
vernalization (from Latin vernus, "of the spring").
• Vernalization prepares the plant to flower.
• Vernalization is a process of shortening of the
juvenile or vegetative phase and hastening
flowering by a previous cold treatment.
4.
5. Definition
• Vernalization, can be defined as the induction of
a plant's flowering process by exposure to the
prolonged cold of winter, or by an artificial
equivalent.
• It is the process whereby flowering is promoted
by a cold treatment given to a fully hydrated seed
(i.e., a seed that has imbibed water) or to a
growing plant.
• This may be reversed if the period of low
temperature is interrupted, an effect known as
‘devernalization’.
6. Significance
• Vernalization ensures that reproductive development
and seed production occurs in spring and winters,
rather than in autumn.
• It has been interpreted as an adaptation of plants from
temperate climates to seasonal changes.
• Vernalization is an important adaptation of plants
growing at high latitudes or altitudes to ensure that
flowering occurs in the warmer days of spring or
summer, allowing sufficient time for seed development
before the onset of winter.
• Vernalization is important in agriculture as various crop
plants, including the winter cereals, must experience a
prolonged period at low temperatures to initiate
flowering in the spring.
7. Mechanism
• Vernalization effects are directly perceived by the
imbibed embryo and communicated to all
meristematic tissues originating at the embryo
apex.
• Vernalization illustrates the epigenetic memory of
plant cells that lasts over months and is
transmitted via the mitosis of meristematic cells
• The plant apex may sense vernalizing
temperatures from seed imbibition, throughout
the vegetative phase.
• Epigenetics is defined as the study of hereditary and
reversible mitotic as well as meiotic changes, which
affect gene expression without any modifications of DNA
sequence
8. Mechanism
• The vernalization process can be viewed as the
conversion of digital epigenetic information
stored at the cellular level into a quantitative
response of the whole organism.
• Plants mainly sense environmental conditions
through organs such as leaves, but the
developmental decision: to flower, occurs in
the meristem at the apex.
• This implies that the epigenetic silencing of FLC is
relayed by a signal promoting flowering at the
level of the organism and over a distance.
11. Activation of FLC
• FLOWERING LOCUS C (FLC) is a key flower
repressor which is regulated, both positively and
negatively, by posttranslational histone
modifications.
• Vernalization epigenetically silences FLC
expression by repressive modifications of
histones, such as dimethylation of histone H3
lysine-9 (H3K9me2 and H3K27me3).
• In contrast, RNA polymerase II-associated
complex (Paf1c) activates FLC expression by
increasing methylation of H3K4 and H3K36.
14. FT the immediate target of FLC
• FT is an immediate downstream target of FLC
repression and encodes a small globular protein that
translocates from the leaves to the shoot apex, thus
representing a key component of this mobile flowering
signal (probably the ‘vernalin’).
• The decision of ‘when to flower’ largely depends on
the level of FT expression, which is strongly influenced
by seasonal cues such as the length of
the photoperiod and warm temperatures
• Modulation of the chromatin state at the FT locus thus
illustrates as to how chromatin contributes to precise
transcriptional regulation by sensing environmental
signals.