Figure 23.1 Structures of active and inactive ABAs

Slides:

Advertisements

Similar presentations

Roles in Seed Dormancy and Stomatal Closure

Advertisements

Biol 352 Lecture 10 Brassinosteroids February 7, 2007.

A Seed Maturation and Antistress Signal

The Biological Role of Abscisic Acid in Precocious Seed Germination

Gibberellins: Regulators of Plant Height and Seed Germination

The role of Abscissic acid in Water Stress

Control Systems in Plants

HORMONE PHYSIOLOGY AND SIGNAL TRANSDUCTION Huseyin Tombuloglu, Phd. GBE 304 Spring 2015.

Skotomorphogenesis Seed germination Genes and enzymes Embryo and Seed development Plant life cycle.

Plant Structure & Reproductive Development. Angeosperms.

Plant Water Deficit Responses HORT 301 – Plant Physiology November 11, 2009 Taiz and Zeiger, Chapter 26 (p ), Web Topic 26.1 Abiotic stress – environmental.

Plant Anatomy and Transport chapters 35 and 36 --focus on sap flow--

Plant Water Deficit Responses HORT 301 – Plant Physiology

Plant Hormones 101 MUPGRET Workshop.

The redistribution of auxin during gravitropism in maize roots.

The Interactions of Plant Hormones and rop Genes By Malem Gutema Mentor Dr. John Fowler Dr. John Fowler Summer 2004.

Chapter 24.  Considered plant hormones because of their ability to cause dramatic changes in growth and differentiation at low concentrations  Brassica.

P247. Figure 9-1 p248 Figure 9-2 p251 p251 Figure 9-3 p253.

Figure 1.1 The observer in the truck sees the ball move in a vertical path when thrown upward. (b) The Earth observer views the path of the ball as a parabola.

Seed development, arrest and germination Seed –Embryo –Seed coat Thick walled cells, waxy –Nutritive tissue Endospermic vs. non-endospermic.

Transport in Vascular Plants Chapter 36. Transport in Plants Occurs on three levels:  the uptake and loss of water and solutes by individual cells 

Photosynthesis The Way plants make their own food.

ABA Signaling in Guard Cells Entails a Dynamic Protein–Protein Interaction Relay from the PYL-RCAR Family Receptors to Ion Channels Sung Chul Lee, Chae.

Looking at Leaves. Leaf Parts of leave you can see : 1. blade and petiole.

Chapter 23.  One molecule!  Named on assumption of role in abscission of leaves and other tissues. 2.

Ch. 35(structure) Ch. 36(function) Roots and stems - absorption and transport pp Leaves - sungathering and power source pp : also see p.

Leaf Notes. Leaf Diagram Evolution of Photosynthesis First organisms = heterotrophic Problem: Too many organisms, not enough food Certain cells gained.

Long-Distance Transport in Plants

Transpiration and pressure flow

Arabidopsis basic leucine zipper transcription factors involved in an abscisic acid-dependent signal transduction pathway under drought and high- salinity.

Chapter 23 Abscisic acid (ABA): ¤ a seed maturation dormin: a growth inhibitor was purified from sycamore leaves collected in early autumn, when the trees.

22 In-Text Art, p. 650 Ethylene PP5e-ITA-22-p650-0.jpg.

Transport in plants occurs on three levels:

Seed dormancy is important for plant survival

01/anthropology.jpg.

ATG AREB1 (At1g45249) AREB2 (At3g19290) ABF3 (At4g34000) ABF1 (At1g49720) No treatmentABA, 6h Chr. 1 areb1 (SALK_002984) // Chr. 3 Chr. 4 abf1-2 (SALK_132819)

Transport in Plants :2 Year 11: Biology. Stomates and transpiration The cuticle which covers the plant stops it drying out, by reducing water loss However.

Arabidopsis OST1 Protein Kinase Mediates the Regulation of Stomatal Aperture by Abscisic Acid and Acts Upstream of Reactive Oxygen Species Production by.

ABSCISIC ACID (ABA) A Seed Maturation and Antistress Signal (Naturally occurring, active form)(Inactive in stomatal closure) (Inactive, but interconvertible.

Growth regulators Auxins Cytokinins Gibberellins Abscisic Acid

・Salt responsive genes ・AP2/ERF TFs ・ABA signaling ・AP2/ERF TFs

Figure 21.1 Tumor that formed on a tomato stem infected with the crown gall bacterium PP5e-Fig jpg.

Resource Acquisition and Transport in Plants

Stem and Leaf Structures

Blue-light Responses: Morphogenesis and Stomatal Movements

Unit 3 Chapter 22 Ethylene: The Gaseous Hormone

Regulators of Cell Expansion and Development

Transport in plants.

Regulating Growth Plant Hormones

Chapter 29 Part 3.

Why does a city need a transport system

Volume 100, Issue 1, Pages (January 2000)

التعامل مع ضغوطات العمل إعداد وتقديم إقبال المطيري

Why can your knees get wet If you stand in a puddle?

Are GTGs ABA's Biggest Fans?

Volume 23, Issue 1, Pages (January 2013)

Christoph-Martin Geilfus Molecular Plant

Véronique Hugouvieux, June M. Kwak, Julian I. Schroeder Cell

Volume 3, Issue 4, Pages (April 2003)

Plant Pathogens Trick Guard Cells into Opening the Gates

Intracellular signalling: Sphingosine-1-phosphate branches out

Cellular signalling: Stressing the importance of PIP3

Shoot–Root Communication in Flowering Plants

Intracellular signalling: Sphingosine-1-phosphate branches out

Abscisic acid function in plant development

ABA Signaling in Guard Cells Entails a Dynamic Protein–Protein Interaction Relay from the PYL-RCAR Family Receptors to Ion Channels Sung Chul Lee, Chae.

Increasing Freezing Tolerance: Kinase Regulation of ICE1

Volume 3, Issue 4, Pages (April 2003)

Presentation transcript:

Figure 23.1 Structures of active and inactive ABAs PP5e-Fig-23-01-0.jpg

Figure 23.2 Simplified diagram of ABA biosynthesis via the terpenoid pathway PP5e-Fig-23-02-0.jpg

Figure 23.3 Precocious germination in the ABA-deficient vivipary 14 mutant of maize PP5e-Fig-23-03-0.jpg

Figure 23.4 Changes in three variables in maize in response to water stress PP5e-Fig-23-04-0.jpg

Figure 23.5 Dynamics of ABA-dependent reporter response to root-sensed water stress PP5e-Fig-23-05-0.jpg

Figure 23.6 Redistribution of ABA in the leaf from alkalinization of xylem sap during water stress PP5e-Fig-23-06-0.jpg

Figure 23.7 A model of ABA interactions with three of its candidate receptor classes PP5e-Fig-23-07-0.jpg

Figure 23.15 Simplified model for ABA signaling in stomatal guard cells PP5e-Fig-23-15-0.jpg