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Floral development

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vibhakhanna1

after floral induction, the inflorescence meristem eventually forms the floral meristem. the process is controlled by an array of homeotic genes. this also involves microRNAs for their regulation

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DR. VIBHA KHANNA Asso. Prof. (Botany) SPC GOVERNMENT COLLEGE AJMER (Rajasthan)
PLANT PHYSIOLOGY THE FLOWERING PROCESS PRESENTATION 5: Floral Development: Genetic And Molecular Analysis
Flowering Process Vegetative Meristem • Undergoes floral induction on genetic level Inflorescence Meristem • Produce small leaves before it next produces floral meristem. Floral Meristem • Under goes a series of developmental changes (Floral development), on genetic level, that eventually give rise to the four basic structures of the flower --- sepals, petals, stamens and carpels. • Each of these structures is derived sequentially from a whorl that develops from the floral meristem. Whorl 1 to 4 • 1: First to appear, and it develops into the sepal • 2. Develops into petals • 3: Define the stamen (male reproductive organs) and • 4. Forms carpel (female reproductive organs).
Flowering Process • From a genetic perspecitive, two phenotypic changes that control vegetative and floral growth are programmed in the plant. • The first genetic change involves the switch from the vegetative to the floral state (floral induction). • The second genetic event follows the commitment of the plant to form flowers (floral development). • A series of genes are sequentially turned on and off to obtain its final unique identity.
Genes That Regulate Floral Development • Two major categories : – Floral meristem identity genes : Activity of these genes, in the immature primordia formed at the flanks of the shoot apical meristem (inflorescence meristem), results in its transition to form the floral meristem. – Floral organ identity genes: Floral organ identity genes directly control floral organ identity. • {Five key genes initially were identified in Arabidopsis that specify floral organ identity. APETALA1 [AP1], APETALA2 [AP2], APETALA3 [AP3], PISTILLATA [PI] and AGAMOUS [AG].}
Floral meristem identity genes • The CENTRORADIALUS (CEN) gene in snapdragons and the Arabidopsis homologue of CEN (TERMINAL FLOWER 1 or TFL1) is expressed during the vegetative phase of development, and has the additional function of delaying the inflorescence development, i.e., the reproductive transition. They suppress the terminal flower formation. • The gene that suppresses terminal flower formation, basically, suppresses expression of genes, which specifies floral meristem identity. • The next step in the reproductive process is the specification of floral meristems—those meristems that will actually produce flowers . • In Snapdragons FLORICAULA (FLO), specifies floral meristem identity. • In Arabidopsis, LEAFY (LFY), APETALA 1 (AP1), and CAULIFLOWER (CAL) are floral meristem identity genes . • LFY is the homologue of FLO in snapdragons, and its upregulation during development is key to the transition to reproductive development . • Expression of these genes is necessary for the transition from an inflorescence meristem to a floral meristem.
Floral meristem identity genes • LEAFY is the first gene expressed. • The LEAFY mRNA first appears in the flanks of the inflorescence meristem, the exact location from which the floral meristem will develop. Its expression rises through stages 1 and 2 (floral meristem identification stage), and disappears in stages 3 and 4 (first expression of floral organ identity genes). • LEAFY has two functions --- – It is necessary for the conversion of the inflorescence meristem to a floral meristem and – It define the petals and stamens. • APETALA1, another gene involved in the commitment to flowering, also plays a role in sepal and petal development. • As LEAFY, APETALA1 is expressed in cells at the margin of the inflorescence meristem during stage 1 and 2. • Because whorls 1 and 2 give rise to sepals and petals, respectively, it is not surprising that APETALA1continues to be expressed in these whorls during stages 3 and 4, while its expression disapppers from whorls 3 and 4 during these stages.
Floral organ identity genes • Floral organ identity genes – Floral organ identity genes directly control floral organ identity. – Five key genes initially were identified in Arabidopsis that specify floral organ identity. APETALA1 [AP1], APETALA2 [AP2], APETALA3 [AP3], PISTILLATA [PI] and AGAMOUS [AG]. • These genes are homeotic genes. • All homeotic genes that have been identified so far, in plants, encode transcription factors. • Most plant homeotic genes belong to a class of related sequences known as MADS box genes.
The ‘Classical’ ABC Model • The ABC model partially explains the determination of floral organ identity • The ABC model was discovered by Elliot Meyerowitz, Enrico Coen in 1991. • According to this model, the five floral organ identity genes, described above, fall into three classes ABC defining three different kinds of activities.
The ‘Classical’ ABC Model: Class A • Class A activity , encoded by AP1 and AP2 , controls organ identity in the first and second whorls. • Loss of class A activity results in the formation of carpels instead of sepals in the first whorl and of stamens instead of petals in the second whorl. • Loss of class A activity results in the spread of class C activity throughout the meristem. • ovulata is an A function gene of snapdragon similar to APETALA2.
The ‘Classical’ ABC Model: Class B • Class B activity , encoded by AP3 and PI, controls organ determination in the second and third whorls. • Loss of class B activity results in the formation of sepals instead of petals in the second whorl, and of carpels instead of stamens in the third whorl. • Loss of class B activity results in the expression of only class A and class C activities. • deficiens and globosa are snapdragon genes that have homologous functions to the Arabidopsis B function genes.
The ‘Classical’ ABC Model: Class C • Class C activity , encoded by AG, controls events in the third and fourth whorls. • Loss of class C activity results in the formation of petals instead of stamens in the third whorl and of sepal instead of carpel in the fourth whorl. • Loss of class C activity results in the expression of only class A activity throughout the floral meristem. • In the absence of class C activity, the fourth whorl (normally a carpel) is replaced by a new flower. • A snapdragon gene similar to AGAMOUS is pleniflora.
The Quartet Model: ABCE Model • The Quartet model first discover by Theissen 2001. • According to the Quartet model, floral organ identity is regulated by tetrameric complexes of the ABCE proteins. • The ABCE Model was formulated based on genetic experiments in Arabidopsis and Antirrhinum. • Arabidopsis class E genes are required for the activities of the A,B and C genes. • In Sepallata1-4 mutants, all of the floral organs resemble vegetative leaves, suggesting that SEP genes are required for floral meristem identity. • ABCE Model for floral organ determination in which SEPs act as Class E genes required for floral organ identity.
The ABCE model for flower patterning • According to the `classic' ABC model of flower patterning, the combinatorial activity of three genetic functions, A, B and C, are sufficient to specify the four floral organs. • According to the ABC model, – `A' on its own specifies sepal fate in the outermost whorl, – `A' and `B' together determine petals in the second whorl. – The stamens in the third whorl are specified by the combinatorial activities of `B' and `C', whereas – `C' alone is responsible for the formation of carpels in the centre of the flower. • In Arabidopsis, – A-class activity is conferred by APETALA1 (AP1) and AP2, the latter of which is a target of miR172. – AP3 and PISTILLATA (PI) have B-class function, and – C-class function in the centre of the emerging flower is conferred by AGAMOUS (AG). • More recently, the `ABC' model has been expanded to include a fourth, `E', function. – The E-class genes SEPALLATA1 (SEP1), SEP2, SEP3 and SEP4 play a crucial role as co-regulators in all four whorls, and underpin the leafy nature of all floral organs.
Class D Genes Are Required For Ovule Formation. • Class D activities were first discovered in petunia. • Silencing, MADS box genes known to be involved in floral development in petunia, FLORAL- BINDING PROTEIN7/11[FBP7/11] , resulted in the growth of styles and stigmas in the locations normally occupied by ovules.
Regulation of Phase Transition by microRNA • A model of the sequential action of miR156, miR172 and their respective targets in regulating phase transitions in A. thaliana. • Abbreviations: AG, AGAMOUS; AP1, APETALA1; AP2, APETALA2; FUL, FRUITFULL; LFY, LEAFY; miR156, mature miRNA156; miR172, mature miRNA172; SEP3, SEPALLATA3; SOC1, SUPRESSOR OF OVEREXPRESSION OF CONSTANS 1; SPL, SQUAMOSA PROMOTER BINDING PROTEIN-LIKE.
miR172/AP2 regulate transition to flowering • The different pathways that regulate flowering can be categorised as: – pathways that actively promote flowering, such as the photoperiod, light quality, gibberellic acid and ambient temperature pathways, or – pathways that enable flowering by removing floral repressors from the system. • SPL genes and miR172 are the`enabling factors', as their activity ultimately leads to the shutting down of the AP2-like floral repressors that regulate `meristem competence’. • miR156, which prevents precocious flowering until plants have reached a permissive age, is also an `enabling factor'. • However, the miR156-targeted SPL genes – regulate the expression of miR172 and thus the AP2-like floral repressors, – SPL proteins have also directly bind to and promote the expression of floral integrator genes, such as SOC1 and floral meristem identity genes such as LFY, FUL and AP1. • AP2, besides its role as a floral repressor also functions in floral patterning.
Regulation of flower development by miR172/AP2 • Besides its role in regulating phase transitions, miR172 and its targets appear to also play a role in floral patterning. • AP2 expression is actually restricted to the outer two whorls, while the expression of miR172 is restricted to the centre of young floral primordia. • AP2 and miR172 are engaged in a negative-feedback loop that presumably helps to establish a sharp boundary between the inner and the outer whorls of the emerging flower. • In this scenario, AP2 not only directly binds to AG and prevents its transcription in the outer two whorls, but it is also at the same time cleared from the centre of the floral primordium by the activity of miR172.
↑ in miR172 Induces Transition to Flowering • Increased levels of miR172 result in the downregulation of AP2-like transcription factors that normally repress flowering. • Release from this repression, in combination with the flower-promoting actions of SPL3, SPL4 and SPL5, makes the plant competent to flower and the transition to flowering can occur. • In addition to its role as a floral repressor, AP2 contributes to the patterning of the emerging flower. • Both AP2 and miR172 participate in establishing a sharp boundary between the vegetative outer organs (sepals, petals) and the inner whorls of reproductive organs (stamen, carpels).
MADS-box • The MADS box is a conserved sequence motif. • The genes which contain this motif are called the MADS box gene family. • In plants, MADS box genes are involved in controlling all major aspects of development, including male and female gametophyte development, embryo and seed development, as well as root, flower and fruit development. • The MADS box gene family got its name later as an Acronym referring to the four founding members. – MCM1 from the budding yeast , Saccharomyces cerevisiae. – AGAMOUS from the thale cress Arabidopsis thaliana. – DEFICIENS from the snapdragon Antirrhinum majus. – SRF from the human Homo sapiens.
MADS-box genes • The MADS box encodes the DNA binding MADS domain. • MADS domain proteins are generally transcription factors. • Each of these genes contains a 56-amino acid sequence that is necessary for the protein to bind to DNA. • This sequence is located near the amino terminal end of the protein, and is called the MADS-box. • Plant MADS-box genes contain a second conserved sequence called the K-domain because its sequences is similar to the coiled coil domain of keratin. This region is primarily involved in the protein- protein interactions.
Activity of MADS-box Genes • The MADS box gene transcription factors form tetramers that bind to CC[A/T]6GG sequences, the so called CArG-box, in the regulatory regions of their target genes. • When the tetramers bind two different CArG-boxes on the same target gene, the boxes are brought into close proximity, causing DNA bending.
Activity of MADS-box Genes • The Model is based on the observation that MADS box genes dimerize, and two dimers can come together, forming a tetramer. • These tetramers are hypothesized to bind CArG-boxes on target genes and modify their expression.
Activity of MADS-box Genes • Although all MADS box proteins can form higher order complexes, not all of these are able to bind DNA. • For example, Class B factors [AP3 and PI] bind DNA only as heterodimers, whereas both homodimers and heterodimers of Classes A, C and E can bind DNA. • According to the Model, tetramers composed of different homodimers and heterodimers of MADS domain proteins can exert combinatorial control over floral organ identity.
An Overview of Flower Development • Floral meristem identity genes initiate a cascade of gene expression that turns on region-specifying (cadastral) genes, which further specify pattern by initiating transcription of floral organ identity genes . • SUPERMAN (SUP) is an example of a cadastral gene in Arabidopsis that plays a role in specifying boundaries for organ identity gene expression. • The patterning of the flower is explained by the `classical' ABC model, according to which the combinatorial interaction of three classes of homeotic functions (A, B and C), provides the positional information that determines the fate of the emerging floral organs • The ABC genes code for transcription factors that initiate a cascade of events leading to the actual production of floral parts.
An Overview of Flower Development • In brief, – in the outermost whorl of the Arabidopsis flower, sepals are specified by the activity of AP1 and AP2 (A class). – In the second whorl, the activity of A-class proteins overlaps with those of the B-class proteins PISTILLATA and APETALA3 to establish petals. – Similarly, overlapping activity of the B-class proteins with that of the C- class protein AGAMOUS (AG) induces stamen fate in the third whorl. – Finally, in the innermost whorl, AG controls the formation of carpels. – In addition to the ABC genes, class D genes, specifically regulate ovule development. – More recently, four highly redundant genes, SEPALLATA1 (SEP1), SEP2, SEP3 and SEP4, that are required for the pattering of all four whorls of the emerging flower have been identified and have been added to the ABC model as E-class function genes. • An important feature of the ABC model is that A-class and C-class function are mutually exclusive. • Genes capable of producing B are normally inhibited in whorl 4 by cadastral genes like SUPERMAN.
The Molecular Expression of Floral Organ Genes • The genetic model predicts that the A organ identity genes will be expressed in the tissues from which sepals and petals are derived. Although APETALA2 is classified as an A function gene, mutants of this genes also affect stamen and carpel development. This gene is shown to be expressed in all four whorls. The expression of the other A gene, APETALA1 appears to be restricted to whorls 1 and 2. • The genetic model has also suggested that C organ identity genes are negatively regulated by the expression of A genes. This would lead to a hypothesis stating that the expression of C genes such as AGAMOUS would not appear in cells giving rise A function organs. Early expression of the AGAMOUS genes is restricted to whorls 3 and 4; later in development, the expression of AGAMOUS is restricted to specific cell types. – In stamens, the gene is not found in any cells that give rise to the pollen, nor is it expressed in the pollen grain itself. – And in the carpel cells, AGAMOUS is only epxpressed in the outer cells of the ovule. • B gene function genes have been suggested to control petal and stamen function (whorl 2 and 3, respectively). Both APETALA3 and PISTILLATA are found to be expressed in the appropriate whorls. PISTILLATA though is also found to be expressed in whorl 4 that gives rise to carpels.
Glossary • Cadastral genes: Genes that restrict the action of other genes to specific regions of the organism. • Homeobox genes are a large family of genes involved in directing the body structure formation. • Homeotic genes: Group of genes that control the pattern of body formation. They encode proteins which are the transcription factors that direct cells to form various parts of the body. (A homeotic protein can activate one gene but repress another, producing effects that are complementary and necessary for the ordered development of an organism.) • Hox genes: the developmental control genes responsible for directing the body plan along the AP axis (anterior–posterior axis) and the proteins it codes for are transcription factors. • miRNAs (microRNAs) are short non-coding RNAs that regulate gene expression post-transcriptionally. They generally bind to the 3'-UTR (untranslated region) of their target mRNAs and repress protein production by destabilizing the mRNA and translational silencing.

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Floral development

  • 1. DR. VIBHA KHANNA Asso. Prof. (Botany) SPC GOVERNMENT COLLEGE AJMER (Rajasthan)
  • 2. PLANT PHYSIOLOGY THE FLOWERING PROCESS PRESENTATION 5: Floral Development: Genetic And Molecular Analysis
  • 3. Flowering Process Vegetative Meristem • Undergoes floral induction on genetic level Inflorescence Meristem • Produce small leaves before it next produces floral meristem. Floral Meristem • Under goes a series of developmental changes (Floral development), on genetic level, that eventually give rise to the four basic structures of the flower --- sepals, petals, stamens and carpels. • Each of these structures is derived sequentially from a whorl that develops from the floral meristem. Whorl 1 to 4 • 1: First to appear, and it develops into the sepal • 2. Develops into petals • 3: Define the stamen (male reproductive organs) and • 4. Forms carpel (female reproductive organs).
  • 4. Flowering Process • From a genetic perspecitive, two phenotypic changes that control vegetative and floral growth are programmed in the plant. • The first genetic change involves the switch from the vegetative to the floral state (floral induction). • The second genetic event follows the commitment of the plant to form flowers (floral development). • A series of genes are sequentially turned on and off to obtain its final unique identity.
  • 5. Genes That Regulate Floral Development • Two major categories : – Floral meristem identity genes : Activity of these genes, in the immature primordia formed at the flanks of the shoot apical meristem (inflorescence meristem), results in its transition to form the floral meristem. – Floral organ identity genes: Floral organ identity genes directly control floral organ identity. • {Five key genes initially were identified in Arabidopsis that specify floral organ identity. APETALA1 [AP1], APETALA2 [AP2], APETALA3 [AP3], PISTILLATA [PI] and AGAMOUS [AG].}
  • 6. Floral meristem identity genes • The CENTRORADIALUS (CEN) gene in snapdragons and the Arabidopsis homologue of CEN (TERMINAL FLOWER 1 or TFL1) is expressed during the vegetative phase of development, and has the additional function of delaying the inflorescence development, i.e., the reproductive transition. They suppress the terminal flower formation. • The gene that suppresses terminal flower formation, basically, suppresses expression of genes, which specifies floral meristem identity. • The next step in the reproductive process is the specification of floral meristems—those meristems that will actually produce flowers . • In Snapdragons FLORICAULA (FLO), specifies floral meristem identity. • In Arabidopsis, LEAFY (LFY), APETALA 1 (AP1), and CAULIFLOWER (CAL) are floral meristem identity genes . • LFY is the homologue of FLO in snapdragons, and its upregulation during development is key to the transition to reproductive development . • Expression of these genes is necessary for the transition from an inflorescence meristem to a floral meristem.
  • 7. Floral meristem identity genes • LEAFY is the first gene expressed. • The LEAFY mRNA first appears in the flanks of the inflorescence meristem, the exact location from which the floral meristem will develop. Its expression rises through stages 1 and 2 (floral meristem identification stage), and disappears in stages 3 and 4 (first expression of floral organ identity genes). • LEAFY has two functions --- – It is necessary for the conversion of the inflorescence meristem to a floral meristem and – It define the petals and stamens. • APETALA1, another gene involved in the commitment to flowering, also plays a role in sepal and petal development. • As LEAFY, APETALA1 is expressed in cells at the margin of the inflorescence meristem during stage 1 and 2. • Because whorls 1 and 2 give rise to sepals and petals, respectively, it is not surprising that APETALA1continues to be expressed in these whorls during stages 3 and 4, while its expression disapppers from whorls 3 and 4 during these stages.
  • 8. Floral organ identity genes • Floral organ identity genes – Floral organ identity genes directly control floral organ identity. – Five key genes initially were identified in Arabidopsis that specify floral organ identity. APETALA1 [AP1], APETALA2 [AP2], APETALA3 [AP3], PISTILLATA [PI] and AGAMOUS [AG]. • These genes are homeotic genes. • All homeotic genes that have been identified so far, in plants, encode transcription factors. • Most plant homeotic genes belong to a class of related sequences known as MADS box genes.
  • 9. The ‘Classical’ ABC Model • The ABC model partially explains the determination of floral organ identity • The ABC model was discovered by Elliot Meyerowitz, Enrico Coen in 1991. • According to this model, the five floral organ identity genes, described above, fall into three classes ABC defining three different kinds of activities.
  • 10. The ‘Classical’ ABC Model: Class A • Class A activity , encoded by AP1 and AP2 , controls organ identity in the first and second whorls. • Loss of class A activity results in the formation of carpels instead of sepals in the first whorl and of stamens instead of petals in the second whorl. • Loss of class A activity results in the spread of class C activity throughout the meristem. • ovulata is an A function gene of snapdragon similar to APETALA2.
  • 11. The ‘Classical’ ABC Model: Class B • Class B activity , encoded by AP3 and PI, controls organ determination in the second and third whorls. • Loss of class B activity results in the formation of sepals instead of petals in the second whorl, and of carpels instead of stamens in the third whorl. • Loss of class B activity results in the expression of only class A and class C activities. • deficiens and globosa are snapdragon genes that have homologous functions to the Arabidopsis B function genes.
  • 12. The ‘Classical’ ABC Model: Class C • Class C activity , encoded by AG, controls events in the third and fourth whorls. • Loss of class C activity results in the formation of petals instead of stamens in the third whorl and of sepal instead of carpel in the fourth whorl. • Loss of class C activity results in the expression of only class A activity throughout the floral meristem. • In the absence of class C activity, the fourth whorl (normally a carpel) is replaced by a new flower. • A snapdragon gene similar to AGAMOUS is pleniflora.
  • 13. The Quartet Model: ABCE Model • The Quartet model first discover by Theissen 2001. • According to the Quartet model, floral organ identity is regulated by tetrameric complexes of the ABCE proteins. • The ABCE Model was formulated based on genetic experiments in Arabidopsis and Antirrhinum. • Arabidopsis class E genes are required for the activities of the A,B and C genes. • In Sepallata1-4 mutants, all of the floral organs resemble vegetative leaves, suggesting that SEP genes are required for floral meristem identity. • ABCE Model for floral organ determination in which SEPs act as Class E genes required for floral organ identity.
  • 14. The ABCE model for flower patterning • According to the `classic' ABC model of flower patterning, the combinatorial activity of three genetic functions, A, B and C, are sufficient to specify the four floral organs. • According to the ABC model, – `A' on its own specifies sepal fate in the outermost whorl, – `A' and `B' together determine petals in the second whorl. – The stamens in the third whorl are specified by the combinatorial activities of `B' and `C', whereas – `C' alone is responsible for the formation of carpels in the centre of the flower. • In Arabidopsis, – A-class activity is conferred by APETALA1 (AP1) and AP2, the latter of which is a target of miR172. – AP3 and PISTILLATA (PI) have B-class function, and – C-class function in the centre of the emerging flower is conferred by AGAMOUS (AG). • More recently, the `ABC' model has been expanded to include a fourth, `E', function. – The E-class genes SEPALLATA1 (SEP1), SEP2, SEP3 and SEP4 play a crucial role as co-regulators in all four whorls, and underpin the leafy nature of all floral organs.
  • 15. Class D Genes Are Required For Ovule Formation. • Class D activities were first discovered in petunia. • Silencing, MADS box genes known to be involved in floral development in petunia, FLORAL- BINDING PROTEIN7/11[FBP7/11] , resulted in the growth of styles and stigmas in the locations normally occupied by ovules.
  • 16. Regulation of Phase Transition by microRNA • A model of the sequential action of miR156, miR172 and their respective targets in regulating phase transitions in A. thaliana. • Abbreviations: AG, AGAMOUS; AP1, APETALA1; AP2, APETALA2; FUL, FRUITFULL; LFY, LEAFY; miR156, mature miRNA156; miR172, mature miRNA172; SEP3, SEPALLATA3; SOC1, SUPRESSOR OF OVEREXPRESSION OF CONSTANS 1; SPL, SQUAMOSA PROMOTER BINDING PROTEIN-LIKE.
  • 17. miR172/AP2 regulate transition to flowering • The different pathways that regulate flowering can be categorised as: – pathways that actively promote flowering, such as the photoperiod, light quality, gibberellic acid and ambient temperature pathways, or – pathways that enable flowering by removing floral repressors from the system. • SPL genes and miR172 are the`enabling factors', as their activity ultimately leads to the shutting down of the AP2-like floral repressors that regulate `meristem competence’. • miR156, which prevents precocious flowering until plants have reached a permissive age, is also an `enabling factor'. • However, the miR156-targeted SPL genes – regulate the expression of miR172 and thus the AP2-like floral repressors, – SPL proteins have also directly bind to and promote the expression of floral integrator genes, such as SOC1 and floral meristem identity genes such as LFY, FUL and AP1. • AP2, besides its role as a floral repressor also functions in floral patterning.
  • 18. Regulation of flower development by miR172/AP2 • Besides its role in regulating phase transitions, miR172 and its targets appear to also play a role in floral patterning. • AP2 expression is actually restricted to the outer two whorls, while the expression of miR172 is restricted to the centre of young floral primordia. • AP2 and miR172 are engaged in a negative-feedback loop that presumably helps to establish a sharp boundary between the inner and the outer whorls of the emerging flower. • In this scenario, AP2 not only directly binds to AG and prevents its transcription in the outer two whorls, but it is also at the same time cleared from the centre of the floral primordium by the activity of miR172.
  • 19. ↑ in miR172 Induces Transition to Flowering • Increased levels of miR172 result in the downregulation of AP2-like transcription factors that normally repress flowering. • Release from this repression, in combination with the flower-promoting actions of SPL3, SPL4 and SPL5, makes the plant competent to flower and the transition to flowering can occur. • In addition to its role as a floral repressor, AP2 contributes to the patterning of the emerging flower. • Both AP2 and miR172 participate in establishing a sharp boundary between the vegetative outer organs (sepals, petals) and the inner whorls of reproductive organs (stamen, carpels).
  • 20. MADS-box • The MADS box is a conserved sequence motif. • The genes which contain this motif are called the MADS box gene family. • In plants, MADS box genes are involved in controlling all major aspects of development, including male and female gametophyte development, embryo and seed development, as well as root, flower and fruit development. • The MADS box gene family got its name later as an Acronym referring to the four founding members. – MCM1 from the budding yeast , Saccharomyces cerevisiae. – AGAMOUS from the thale cress Arabidopsis thaliana. – DEFICIENS from the snapdragon Antirrhinum majus. – SRF from the human Homo sapiens.
  • 21. MADS-box genes • The MADS box encodes the DNA binding MADS domain. • MADS domain proteins are generally transcription factors. • Each of these genes contains a 56-amino acid sequence that is necessary for the protein to bind to DNA. • This sequence is located near the amino terminal end of the protein, and is called the MADS-box. • Plant MADS-box genes contain a second conserved sequence called the K-domain because its sequences is similar to the coiled coil domain of keratin. This region is primarily involved in the protein- protein interactions.
  • 22. Activity of MADS-box Genes • The MADS box gene transcription factors form tetramers that bind to CC[A/T]6GG sequences, the so called CArG-box, in the regulatory regions of their target genes. • When the tetramers bind two different CArG-boxes on the same target gene, the boxes are brought into close proximity, causing DNA bending.
  • 23. Activity of MADS-box Genes • The Model is based on the observation that MADS box genes dimerize, and two dimers can come together, forming a tetramer. • These tetramers are hypothesized to bind CArG-boxes on target genes and modify their expression.
  • 24. Activity of MADS-box Genes • Although all MADS box proteins can form higher order complexes, not all of these are able to bind DNA. • For example, Class B factors [AP3 and PI] bind DNA only as heterodimers, whereas both homodimers and heterodimers of Classes A, C and E can bind DNA. • According to the Model, tetramers composed of different homodimers and heterodimers of MADS domain proteins can exert combinatorial control over floral organ identity.
  • 25. An Overview of Flower Development • Floral meristem identity genes initiate a cascade of gene expression that turns on region-specifying (cadastral) genes, which further specify pattern by initiating transcription of floral organ identity genes . • SUPERMAN (SUP) is an example of a cadastral gene in Arabidopsis that plays a role in specifying boundaries for organ identity gene expression. • The patterning of the flower is explained by the `classical' ABC model, according to which the combinatorial interaction of three classes of homeotic functions (A, B and C), provides the positional information that determines the fate of the emerging floral organs • The ABC genes code for transcription factors that initiate a cascade of events leading to the actual production of floral parts.
  • 26. An Overview of Flower Development • In brief, – in the outermost whorl of the Arabidopsis flower, sepals are specified by the activity of AP1 and AP2 (A class). – In the second whorl, the activity of A-class proteins overlaps with those of the B-class proteins PISTILLATA and APETALA3 to establish petals. – Similarly, overlapping activity of the B-class proteins with that of the C- class protein AGAMOUS (AG) induces stamen fate in the third whorl. – Finally, in the innermost whorl, AG controls the formation of carpels. – In addition to the ABC genes, class D genes, specifically regulate ovule development. – More recently, four highly redundant genes, SEPALLATA1 (SEP1), SEP2, SEP3 and SEP4, that are required for the pattering of all four whorls of the emerging flower have been identified and have been added to the ABC model as E-class function genes. • An important feature of the ABC model is that A-class and C-class function are mutually exclusive. • Genes capable of producing B are normally inhibited in whorl 4 by cadastral genes like SUPERMAN.
  • 27. The Molecular Expression of Floral Organ Genes • The genetic model predicts that the A organ identity genes will be expressed in the tissues from which sepals and petals are derived. Although APETALA2 is classified as an A function gene, mutants of this genes also affect stamen and carpel development. This gene is shown to be expressed in all four whorls. The expression of the other A gene, APETALA1 appears to be restricted to whorls 1 and 2. • The genetic model has also suggested that C organ identity genes are negatively regulated by the expression of A genes. This would lead to a hypothesis stating that the expression of C genes such as AGAMOUS would not appear in cells giving rise A function organs. Early expression of the AGAMOUS genes is restricted to whorls 3 and 4; later in development, the expression of AGAMOUS is restricted to specific cell types. – In stamens, the gene is not found in any cells that give rise to the pollen, nor is it expressed in the pollen grain itself. – And in the carpel cells, AGAMOUS is only epxpressed in the outer cells of the ovule. • B gene function genes have been suggested to control petal and stamen function (whorl 2 and 3, respectively). Both APETALA3 and PISTILLATA are found to be expressed in the appropriate whorls. PISTILLATA though is also found to be expressed in whorl 4 that gives rise to carpels.
  • 28. Glossary • Cadastral genes: Genes that restrict the action of other genes to specific regions of the organism. • Homeobox genes are a large family of genes involved in directing the body structure formation. • Homeotic genes: Group of genes that control the pattern of body formation. They encode proteins which are the transcription factors that direct cells to form various parts of the body. (A homeotic protein can activate one gene but repress another, producing effects that are complementary and necessary for the ordered development of an organism.) • Hox genes: the developmental control genes responsible for directing the body plan along the AP axis (anterior–posterior axis) and the proteins it codes for are transcription factors. • miRNAs (microRNAs) are short non-coding RNAs that regulate gene expression post-transcriptionally. They generally bind to the 3'-UTR (untranslated region) of their target mRNAs and repress protein production by destabilizing the mRNA and translational silencing.