Testing the ABC floral-organ identity model: expression of A and C function genes

Similar documents
Floral Organ Mutants and the Study of Organ Morphogenesis

Regulation of Floral-Organ- Type by SUPERMAN

Regulation of Floral Organ Identity. Dr. Chloe Diamond Mara

Genetic Specification of floral organ identity. Initiating floral development. Deciding when to initiate flowering - induced mutations -in Nature

Arabidopsis: Flower Development and Patterning

Supplemental Data. Müller-Xing et al. (2014). Plant Cell /tpc

UFO and LEAFY in Arabidopsis

FILAMENTOUS FLOWER Controls the Formation and Development of Arabidopsis Inflorescences and Floral Meristems

Genetics of Floral Development An Evo-Devo Approach

The SEP4 Gene of Arabidopsis thaliana Functions in Floral Organ and Meristem Identity

From model plants to crops: the MADS box family of gene controlling flower development in Crocus (Crocus sativus L.)

A genetic and molecular model for flower development in Arabidopsis thaliana

The Ff.010 Gene Product Regulates the Expression Domain of Homeotic Genes AP3 and PI in Arabidopsis Flowers

The Role of Lipids in Flowering Development of Arabidopsis Enhanced pah1pah2 Plants. Toshiro Ito 1 & Lee Lishi 2

Activation of the Arabidopsis B Class Homeotic Genes by APETALA1

Functional Diversification of the Two C-Class MADS Box Genes OSMADS3 and OSMADS58 in Oryza sativa W OA

The Arabidopsis homeotic genes APETALA3 and PISTILLATA are sufficient to provide the B class organ identity function

The Flower - what is it? 1/31/18. Magnoliophyta - Flowering Plants. Magnoliophyta - Flowering Plants. Magnoliophyta - Flowering Plants

ARGONAUTE10 and ARGONAUTE1 Regulate the Termination of Floral Stem Cells Through Two MicroRNAs in Arabidopsis

Supplemental Figure S1. The number of hydathodes is reduced in the as2-1 rev-1

PLENA and FARINELLI: redundancy and regulatory interactions between two Antirrhinum MADS-box factors controlling flower development

2014 Pearson Education, Inc. 1

Specification of Arabidopsis floral meristem identity by repression of flowering time genes

BIOLOGY 363 VASCULAR PLANTS LABORATORY #12

Determination of Arabidopsis Floral Meristem ldentity by AGA MOUS

Sex Determination in the Monoecious Species Cucumber Is Confined to Specific Floral Whorls

Redundantly in the Temporal Regulation of Floral Meristem Termination in Arabidopsis thaliana W

BIOLOGY 460/560 PLANT PHYSIOLOGY LABORATORY #12

Genes Directing Flower Development in Arabidopsis

How To Make A Seed EMBRYONIC DEVELOPMENT AND THE LIFE CYCLE OF ANGIOSPERMS NORA COOPER JAZMIN SAMANO DOMINIC SAADI

RABBIT EARS is a second-whorl repressor of AGAMOUS that maintains spatial boundaries in Arabidopsis flowers

POLYGONUM EMBRYO SAC CHALAZAL END ANTIPODAL CELL EMBRYO SAC OVULE L.S.

Genetic Separation of Third and Fourth Whorl Functions of AGAMOUS

CLAVATA1, a regulator of meristem and flower development in Arabidopsis

Supplemental Data. Wu et al. (2010). Plant Cell /tpc

A LEAFY co-regulator encoded by UNUSUAL FLORAL ORGANS Ilha Lee, Diana S. Wolfe, Ove Nilsson and Detlef Weigel

AINTEGUMENTA Contributes to Organ Polarity and Regulates Growth of Lateral Organs in Combination with YABBY Genes 1

Morphogenesis, Anatomical Observation and Primary Genetic Analysis of a Multi-glume Floral Organ Mutant in Rice

Teaching A2 Biology Practical Skills Appendix 2

Involvement of CUP-SHAPED COTYLEDON Genes in Gynoecium and Ovule Development in Arabidopsis thaliana

The early inflorescence of Arabidopsis thaliana demonstrates positional effects in floral organ growth and meristem patterning

CRABS CLAW and SPATULA, two Arabidopsis genes that control carpel

LABORATORY 2: Flowers

Divergence of Function and Regulation of Class B Floral Organ ldentity Genes

Flower Morphology. Flower Structure

HANABA TARANU Is a GATA Transcription Factor That Regulates Shoot Apical Meristem and Flower Development in Arabidopsis W

The AINTEGUMENTA Gene of Arabidopsis Required for Ovule and Female Gametophyte Development 1s Related to the Floral Homeotic Gene APETALA2

CLAVATA3 is a specific regulator of shoot and floral meristem development

Open Flower. Juvenile leaf Flowerbud. Carpel 35 NA NA NA NA 61 NA 95 NA NA 15 NA 41 3 NA

The ULT1 and ULT2 trxg Genes Play Overlapping Roles in Arabidopsis Development and Gene Regulation

BELL1 and AGAMOUS genes promote ovule identity in Arabidopsis thaliana

Arabidopsis PRC1 core component AtRING1 regulates stem cell-determining carpel development mainly through repression of class I KNOX genes

Flowering Plant Reproduction

ANGIOSPERM L.S. POLLEN GRAIN

Turning floral organs into leaves, leaves into floral organs Koji Goto*, Junko Kyozuka and John L Bowman

The NGATHA Genes Direct Style Development in the Arabidopsis Gynoecium C W

Beth A. Krizek & Marcie Eaddy

Termination of Stem Cell Maintenance in Arabidopsis Floral Meristems by Interactions

The Homeotic Protein AGAMOUS Controls Late Stamen Development by Regulating a Jasmonate Biosynthetic Gene in Arabidopsis W

An Enhancer Trap Line Associated with a D-Class Cyclin Gene in Arabidopsis 1

The Maize PI/GLO Ortholog Zmm16/sterile tassel silky ear1 Interacts with the Zygomorphy and Sex Determination Pathways in Flower Development OPEN

plant reproduction Alternation of Generations chapter 38

Bract reduction in Cruciferae: possible genetic mechanisms and evolution

Migrating adults Multiple adults of the same species are seen flying steadily in a uniform direction without stopping.

The Flower, Pollination, and Seeds

Supplemental Information. Spatial Auxin Signaling. Controls Leaf Flattening in Arabidopsis

Anatomy of a New Sepaloid Mutant Flower in Sugarbeet 1

Ectopic Expression of AINTEGUMENTA in Arabidopsis Plants Results in Increased Growth of Floral Organs

Flower Morphology. Flower Structure. Name

Homeotic Transformation of Ovules into Carpel-like Structures in Arabidopsis

Copyright 2015 Kelsey Diane Galimba

plant reproduction chapter 40 Alternation of Generations

Peony Flower Anatomy I

Plant Terminology. Floral Symmetry

The Structure of a Flower Information Sheet

The potential role of B-function gene involved in floral development for double flowers formation in Camellia changii Ye

A genetic framework for fruit patterning in Arabidopsis thaliana

Chapter 38: Angiosperm Reproduction and Biotechnology: To Seed or Not to Seed

Introduction. Copyright 2002 Pearson Education, Inc., publishing as Benjamin Cummings

Gwyneth C. Ingram,a Justin Goodrich,a Mark D. Wilkinson,b Rüdiger Simon,a George W. Haughn,b and Enrico S. Coena,

Botany Physiology. Due Date Code Period Earned Points

Introduction. Copyright 2002 Pearson Education, Inc., publishing as Benjamin Cummings

Functional conservation and diversification of class E floral homeotic genes in rice (Oryza sativa)

Parts of a Flower. Stamen = Pistil = Petals (corolla) Sepals (calyx) Perianth = Receptacle Peduncle / Pedicel. anther + filament

PETAL LOSS, a trihelix transcription factor gene, regulates perianth

Reproduction in plants

Fatty Acid Desaturation

Supporting Information


Del Feigal, AFC; Kent Waliser, Sagemoor Farms; Wild Willow Orchards; John Ferguson and Julie Tarara, USDA-ARS; Bhaskar Bondada, WSU Tri-cities

BIOLOGY CLASS: VIII TOPIC: Life Processes: Growth, Reproduction & Development (plants) Difference between self-pollination & cross pollination

ACURIOUS malformation in one of the flowers on a raceme of

Chapter 38 Angiosperm Reproduction and Biotechnology

AINTEGUMENTA, an A PETA LAP-like Gene of Arabidopsis with Pleiotropic Roles in Ovule Development and Floral Organ Growth

A novel class of MYB factors controls sperm

TSO1 functions in cell division during Arabidopsis flower development

REPRODUCTION IN FLOWERING PLANTS

Angiosperm Reproduction and Biotechnology

Reproductive Development and Structure

Transcription:

Objectives: Testing the ABC floral-organ identity model: expression of A and C function genes To test the validity of the ABC model for floral organ identity we will: 1. Use the model to make predictions concerning the phenotype of double or triple loss-offunction mutants and compare with the actual double mutant phenotypes. 2. Clone and sequence the ABC genes. Look for similarities with sequenced genes already in the database. 3. Determine the time and place of expression for each ABC gene and consider whether the expression correlates with the functional domain defined by the loss-of-function phenotype. 4. Test regulatory interactions between ABC genes by examining how the loss-of-function of one gene affects the expression domain of another. 5. Create gain-of-function mutants by generating transgenic plants carrying an ABC gene cdna under the control of the CaMV35S promoter.

Arabidopsis Floral Development Inflorescence SEM Mature Flower

Flower Development

Arabidopsis Floral Development Inflorescence SEM Inflorescence Section

Arabidopsis Floral Development Inflorescence SEM Inflorescence Section in situ hybridization

A Model For Control of Organ Type sepal petal stamen carpel 1 2 3 4 B (AP3, PI) A (AP1, AP2) C (AG)

AG expression in wild type Inflorescence SEM Inflorescence Section in situ hybridization

AG expression in wild type

AG expression in wild type Mature Flower Inflorescence Section in situ hybridization

A Model For Control of Organ Type sepal petal stamen carpel 1 2 3 4 B (AP3, PI) A (AP1, AP2) C (AG)

AP1 expression in wild type Inflorescence SEM Inflorescence Section in situ hybridization

AP1 expression in wild type

AG expression AP1 expression

A Model For Control of Organ Type sepal petal stamen carpel 1 2 3 4 B (AP3, PI) A (AP1, AP2) C (AG)

AP2 expression in wild type Inflorescence SEM Inflorescence Section in situ hybridization

AP2 expression in wild type

A Model For Control of Organ Type Ap2 mutant carpel stamen stamen carpel 1 2 3 4 B (AP3, PI) C (AG) Where will AG be expressed?

AG expression in an Ap2 mutant

A Model For Control of Organ Type: Ag mutant sepal petal petal sepal 1 2 3 4 A (AP1, AP2) B (AP3, PI) Where will Ap1 be expressed?

AP1 expression in an Ag mutant

A Model For Control of Organ Type: Ag mutant sepal petal petal sepal 1 2 3 4 A (AP1, AP2) B (AP3, PI) Where will Ap2 be expressed?

AP2 expression in an Ag mutant (unchanged)

A Model For Control of Organ Type: 35SAG???? sepal petal stamen carpel 1 2 3 4 B (AP3, PI) A (AP1, AP2) C (AG) C (AG)

Structure of wild type and mutant Arabidopsis flowers Whorl 1 Whorl 2 Whorl 3 Whorl 4 WT SEPAL PETAL STAMEN CARPEL 35S E Ag O 35S E AP2 O 35S E AP1 O?? STAMEN CARPEL SEPAL/ STAMEN/ STAMEN CARPEL CARPEL no organ

A Model For Control of Organ Type: 35SAP2 or 35SAP1???? sepal petal stamen carpel 1 2 3 4 B (AP3, PI) A (AP1, AP2) C (AG) A (AP1 OR AP2)

Structure of wild type and mutant Arabidopsis flowers Whorl 1 Whorl 2 Whorl 3 Whorl 4 WT SEPAL PETAL STAMEN CARPEL 35S E AG O 35S E AP2 O?? STAMEN CARPEL SEPAL/ STAMEN/ STAMEN CARPEL CARPEL no organ SEPAL PETAL STAMEN CARPEL SEPAL PETAL STAMEN CARPEL 35S E AP1 O SEPAL PETAL STAMEN CARPEL SEPAL PETAL STAMEN CARPEL

Review of: Analysis of Class A and C expression. 1. In wild type plants, AP1 transcript is first observed throughout the stage 1 floral meristem but disappears from the centre of the stage 3 floral meristem. In later stages it continues to be expressed in developing sepals and petals. 2. In wild type plants, AP2 transcript is observed throughout the stage 1 floral meristem and continues to be found in all whorls in later stages of floral development. 3. In wild type plants, AG transcript is first observed in the central region of the stage 3 floral meristem. In later stages it continues to be expressed in developing stamens and carpels. 4. n Ap2 mutants AG transcript appears in late stage 2/early stage 3 throughout the floral meristem although AG is most strongly expressed in the center of the floral meristem. 5. In Ag mutants AP1 transcript persists throughout the developing flower past stage three. The pattern of AP2 transcript in an Ag mutant is the same as in wild type. 6. Ectopic expression of AP2 or AP1 using the CaMV35S promoter does not affect floral organ type.

Hypothesis for A-C function interactions 1. AP1 and AP2 appear early and are needed to specify perianth. 2. AG appears in stage 3 and negatively regulates expression of AP1 in inner cells and promotes formation of reproductive organs. 3. AP1 and AP2 prevent AG expression in perianth. 4. At least one other regulator must exist to promote AG expression in the centre at stage 3.

2024 © healthdocbox.com Privacy Policy | Terms of Service | Feedback