Auxin: The Plant Growth Hormone PDF

Summary

This document discusses the plant hormone auxin, explaining its role in regulating various developmental processes in plants. It covers topics including its diverse functions, mechanisms of action, relationship with other hormones and role in plant tropisms.

Full Transcript

Auxin: The Plant Growth
Hormone
 WHAT IS HORMONE ?
Hormones are chemical messengers that are
produced in one cell and modulate cellular
processes in another cell by interacting with
specific proteins that function as receptors
linked to cellular transduction pathway.
 Types of hormones
Endocrine hormones Paracrine hormones
Hormones that are Hormones that act on cells
transported to sites of adjacent to the source of
action in tissues distant synthesis are referred to as
from their site of synthesis paracrine hormones.
are referred to as endocrine
hormones
 Plant hormones
The plant development is regulated by six
major hormones:
Auxins
Gibberellins
Cytokinins
Ethylene
Abscisic acid
Brassinosteroids
Table 39.1
 Plant hormones
There are some signaling molecules
(hormones) like jasmonic acid,salicylic acid
and small polypeptides that play roles in
resistance to pathogens and defence against
herbivores.
Strigolactone regulates the outgrowth of letral
buds.
 Introduction to Auxin
First growth hormone to be studied in plants
Play important role in growth and
development of plant
Developmental processes like stem
elongation, apical dominance, root initiation,
fruit development, meristem development is
controlled by auxin
 Introduction to Auxin
Auxin and cytokinin are required for viability
of the plant embryo
Whereas other hormones act as regulators of
discrete developmental processes
 The Emergence of the Auxin concept
Charles Darwin and his son Francis studied plant
growth phenomena involving tropisms
Their interest of study was the bending of plant
towards light
The phenomenon, which is caused by
differential growth, is called phototropism
Seedlings of canary grass ( Phalaris canariensis)
Young leaves are in protective organ called
coleptile
 Coleoptiles are highly sensitive to light
The power of movement in plants 1881
1926 Frits Went’s studied growth promoting
chemicals in tips of Avena sativa
 The Principle Auxin: Indole-3-Acetic
acid
In the mid 1930,it was determined that natural
auxin is indole-3-acetic acid
Various other auxins are found in plant
Auxins are the compound with biological
activities similar to those IAA
Cell elongation in coleptile and stem section
Cell division in callus cultures
Formation of adventitious roots on detached
leaves and stem
 Synthetic Auxins
Naphthalene acetic acid (NAA) and
indolebutyric acid (IBA) have many uses in
agriculture and horticulture
-Prevent abscission in apples and berries
-Promote flowering & fruiting in pineapples

2,4-dichlorophenoxyacetic acid (2,4-D) is a
herbicide commonly used to kill weeds
15
Physiological
effect of Auxin
 CELL ELONGATION
Auxin was discovered as the hormone
involved in the bending of coleoptiles toward
light
Auxins Promote Growth in Stems and
Coleoptiles,While Inhibiting Growth in Roots
Auxin transport basipetally from shoot apex to
the tissue below
Auxin causes continued elongation of these
cells
CELL ELONGATION
 Action of auxin: Plant tropism
3 main guidance systems control the
orientation of the plant axis
Phototropism
Gravitropism
Thigmotropism
 Phototropism is mediated by the lateral
redistribution of auxin
Charles and Francis Darwin provided the first clue
concerning the mechanism of phototropism.
When a shoot is growing vertically, auxin is
transported polarly
Auxin can also be transported vertically
Cholodny- went model of phototropism
Perception of a unilateral light stimulus
A decrease in basipetal IAA transport and
diversion to lateral transport in response to the
phototropic stimulus
 Phototropism is mediated by the lateral
redistribution of auxin
Precise sites of auxin production, light perception and
lateral transport have been difficult to define.
In maize coleoptiles auxin accumulation zone is upper
1-2mm of tip, the zones of photosensing and lateral
transport are within the upper 5mm of the tip.
Similar zones are observed in true shoots of all
monocots and dicots.
Two flavoproteins, Phototropin 1 and 2 are
photoreceptors for the blue light signaling pathway.
The action spectrum for blue light activation of kinase
activity matches the action spectrum for phototropism.
 Phototropism is mediated by the lateral
redistribution of auxin
Phototropin 1 displays a lateral gradient in
phosphorylation.
Phototropin phosphorylation results in
dissociation of plasma membrane proteins
In coleoptiles, phototropin phosphorylation
gradient induce the lateral movement of
auxin.
 Phototropism is mediated by the lateral
redistribution of auxin
Agar block\ coleoptiles curvature bioassay
supported the colodny-went models
prediction.
Acidification of the apoplast plays a role in
phototropic growth.
Phototropic auxin movement involves
inhibition of ABCB 19, destabilization of PIN1
and inhibition\ or relocalization of laterally
localized PIN3 proteins
Phototropism is mediated by the lateral
redistribution of auxin
 When dark grown
Gravitropism Avena seedlings
involves are
lateral redistribution
oriented horizontally, the coleoptiles
of auxin bend
upwards in response to gravity.
Tissues below the tip are able to respond to
gravity as well.
Lateral distribution of auxin is more difficult to
demonstrate in shoot apical meristem than in
coleoptiles.
Gravitropism involves lateral redistribution
of auxin
Dense plastids serve as gravity sensors

Gravity does not form gradient.
The only way of sensing gravity is through the
motion of a sedimenting body.
In plants intracellular gravity sensors are large,
dense amyloplast.
Statoliths –amyloplasts that function as
gravity sensors.
Statocytes-specialized gravity sensing cells in
which statoliths are present.
 Gravity sensing may involve pH and
calcium ions as second messengers
Gravistimulation – when n gravity sensing
mechanisms detect that the root or shoot axis is
out of alignment with the gravity vector, signal
transduction mechanisms transmit this
information to initiate corrective differential
growth.
Localized changes in Ph and Ca2 + gradients are
part of of that signaling.
Changes in intracellular pH can be detected early
in root columella cells responding to gravity.
 Gravity sensing may involve pH and
calcium ions as second messengers
Rapid changes in Ph were observed in Arabidopsis
roots, after roots were roated to a horizontal position.
Activation of the plasma membrane H+-ATPase is one
of the initial event that mediates root gravity
perception.
Ca2+ release from storage pools might be involved in
root gravitropic signal transduction.
Treatment of maize roots with EGTA, prevents ca2+
uptake by cells and inhibits root gravitropism.
Localized changes in internal ca2+ pools have been
observed in root thigmotropism responses.
Gravity sensing may involve pH and
calcium ions as second messengers
 Developmental effects of auxins
Influences every stage of plants life cycle from
germination to senescence
Polar auxin streams directed by PIN proteins
which helps in plant organogenesis
Tissue elongation and maturity
Loss of PIN proteins can cause severe embryonic
defect
Auxin may act conjugation with other hormones,
Ca and reactive oxide for plant development
Auxin Regulates Apical Dominance
Growing apical bud inhibits the lateral bud
growth
In 1920, Skog and Thimann performed an
experiment on bean and result showed that
outgrowth of auxillary bud is inhibited by auxin
that is transported basipetally
The auxin content of bud increases by
decapitation of shoot apex
Auxin control auxillary bud growth by acting in
xylem and interfasicular sclerechyma of shoot
Auxin Regulates Apical Dominance
Strigolactones as signal that interact with
auxin in regulating apical dominance
Strigolactone is a group of trepenoids that
produced in both shoots and roots and is
transported through xylem
Auxin Regulates Apical Dominance
 Auxin transport regulates floral bud
and phyllotaxy
In absence of PIN1, auxin movement to
meristem and phyllotaxy is disturbed
If lanolin paste is applying on side of apical
meristem then leaf perinmodia can be
induced
Auxin with combine action of AUX1,PIN1 &
ABCB19 can predict phyllotactic pattern
 Auxin Promotes the Formation of Lateral
and Adventitious Roots
primary root is inhibited
by auxin concentrations greater than 10–8 M
High concentration initiate lateral and adventitious
roots
Cell division in pericyclic is initiated by IAA transport
acropetally
PIN2, AUX1, ABCB19 & ABCB1 m,ediate uptake auxin
into root
LAX3 promote cell expension & cell wall modification
by uptake auxin into cortical & epidermal cell of roots
 Auxin Promotes the Formation of Lateral
and Adventitious Roots
Cell division and growth is maintained by root
and shoot derived auxin
 Auxin induce vascular differentiation
Vascular differentiation involves interaction of
PIN1, ethylene and other hormones
When apical bud is grafted onto a clamp of
undifferentiated cells forms
Auxins controls the regeneration of vascular
tissues
Auxin induce vascular differentiation
 Auxins delays onset of leaf abscission
Auxins level high inn young leaves and low in
senescing leaves when abscission started
Auxin is transported from leaf blade normally
prevent abscissions
 Auxins promotes fruits development
Regulation of fruit development
After fruit set, fruit growth depends on auxins
Auxins promotes fruits development
 Synthetic auxins have a variety of
commercial uses
Prevention of fruit & leaf drop, induction of
parthenocarpic fruit development, thinnning
of fruit & rooting of cutting for plant
propagation
If excised leaf is dipped in auxins then rooting
enhanced
Parthenocarpic fruit can be induced by
treatment of unpollinated flowers with auxins
 Synthetic auxins have a variety of
commercial uses
2,4-D and dicamba are synthetic auxins which
used in herbicides
2,4-D also used as weed control while
monocotsare able to inactivate synthetic
auxins rapidly than dicots