Your search keyword '"Weiss, Julia"' showing total 9 results

1. The Snapdragon LATE ELONGATED HYPOCOTYL Plays A Dual Role in Activating Floral Growth and Scent Emission.

Author

Terry MI, Pérez-Sanz F, Navarro PJ, Weiss J, and Egea-Cortines M

Subjects

Gene Expression Regulation, Plant, Antirrhinum growth & development, Antirrhinum metabolism, Circadian Clocks physiology, Circadian Rhythm Signaling Peptides and Proteins physiology, Flowers growth & development, Flowers metabolism, Plant Proteins physiology, Volatile Organic Compounds metabolism

Abstract

The plant circadian clock controls a large number of internal processes, including growth and metabolism. Scent emission displays a circadian pattern in many species such as the snapdragon. Here we show that knocking down LATE ELONGATED HYPOCOTYL in Antirrhinum majus affects growth and scent emission. In order to gain an understanding of the growth kinetics, we took a phenomic approach using in-house artificial vision systems, obtaining time-lapse videos. Wild type flowers showed a higher growth speed than knockdown plants. The maximal growth rate was decreased by 22% in plants with lower LHY expression. Floral volatiles were differentially affected as RNAi plants showed advanced emission of compounds synthesized from cinnamic acid and delayed emission of metabolites of benzoic acid. The monoterpenes myrcene and ocimene were delayed, whereas the sesquiterpene farnesene was advanced. Overall, transgenic lines showed an altered volatile emission pattern and displayed a modified scent profile. Our results show that AmLHY plays an important role in the quantitative and qualitative control of floral growth and scent emission.

Published

2019

2. Meristem maintenance, auxin, jasmonic and abscisic acid pathways as a mechanism for phenotypic plasticity in Antirrhinum majus.

Author

Weiss J, Alcantud-Rodriguez R, Toksöz T, and Egea-Cortines M

Subjects

Abscisic Acid genetics, Abscisic Acid metabolism, Antirrhinum growth & development, Antirrhinum metabolism, Cyclopentanes metabolism, Flowers genetics, Flowers growth & development, Gene Expression Profiling, Gene Expression Regulation, Plant, Indoleacetic Acids metabolism, Meristem growth & development, Meristem metabolism, Oxylipins metabolism, Plant Leaves growth & development, Plant Proteins genetics, Plant Shoots genetics, Plant Shoots growth & development, Plants, Genetically Modified, Signal Transduction genetics, Antirrhinum genetics, Meristem genetics, Plant Leaves genetics, Plant Proteins biosynthesis

Abstract

Plants grow under climatic changing conditions that cause modifications in vegetative and reproductive development. The degree of changes in organ development i.e. its phenotypic plasticity seems to be determined by the organ identity and the type of environmental cue. We used intraspecific competition and found that Antirrhinum majus behaves as a decoupled species for lateral organ size and number. Crowding causes decreases in leaf size and increased leaf number whereas floral size is robust and floral number is reduced. Genes involved in shoot apical meristem maintenance like ROA and HIRZ, cell cycle (CYCD3a; CYCD3b, HISTONE H4) or organ polarity (GRAM) were not significantly downregulated under crowding conditions. A transcriptomic analysis of inflorescence meristems showed Gene Ontology enriched pathways upregulated including Jasmonic and Abscisic acid synthesis and or signalling. Genes involved in auxin synthesis such as AmTAR2 and signalling AmANT were not affected by crowding. In contrast, AmJAZ1, AmMYB21, AmOPCL1 and AmABA2 were significantly upregulated. Our work provides a mechanistic working hypothesis where a robust SAM and stable auxin signalling enables a homogeneous floral size while changes in JA and ABA signalling maybe responsible for the decreased leaf size and floral number.

Published

2016

3. Validation of Aintegumenta as a gene to modify floral size in ornamental plants.

Author

Manchado-Rojo M, Weiss J, and Egea-Cortines M

Subjects

Antirrhinum anatomy & histology, Antirrhinum growth & development, Arabidopsis genetics, Arabidopsis Proteins metabolism, Down-Regulation, Flowers anatomy & histology, Flowers growth & development, Gene Expression, Petunia anatomy & histology, Petunia growth & development, Phenotype, Phylogeny, Plants, Genetically Modified, RNA Interference, Transcription Factors metabolism, Up-Regulation, Antirrhinum genetics, Arabidopsis Proteins genetics, Flowers genetics, Gene Expression Regulation, Plant, Petunia genetics, Transcription Factors genetics

Abstract

The gene AINTEGUMENTA (AtANT) is an APETALA2 transcription factor in Arabidopsis activating growth downstream of auxin signalling. Lateral organ size is positively correlated with ANT expression in Arabidopsis. We tested the use of AtANT as a tool to modify floral size in two different plants used as model organisms and ornamental crops, Petunia × hybrida and Antirrhinum majus. Petunia plants expressing PhANT RNAi showed a decrease in PhANT expression correlated with smaller petal limbs. In contrast Petunia plants overexpressing AtANT had larger petal limbs. Petal tube length was less affected in down-regulation of PhANT or overexpression of AtANT. Overexpression of AtANT in Antirrhinum caused increased flower size via increased petal limb width and tube length. Down-regulation of PhANT showed an effect on cell size while overexpression of AtANT in Petunia and Antirrhinum caused significant increases in cell expansion that could explain the differences in floral organ size. The endogenous expression levels of PhANT and AmANT tended to be higher in the limb than in the tube in both Antirrhinum and Petunia. AtANT overexpression caused significant AmANT up-regulation in Antirrhinum limbs but not of PhANT in Petunia, indicating differences in the regulatory network. The differential effect of AtANT on limb and tube in Petunia and Antirrhinum correspond to phenotypic differences observed in natural variation in the corresponding genus indicating a relation between the phenotypic space of a genus and the effect of modified ANT levels, validating ANT as a gene to modify floral size., (© 2014 Society for Experimental Biology, Association of Applied Biologists and John Wiley & Sons Ltd.)

Published

2014

4. Quantitative levels of Deficiens and Globosa during late petal development show a complex transcriptional network topology of B function.

Author

Manchado-Rojo M, Delgado-Benarroch L, Roca MJ, Weiss J, and Egea-Cortines M

Subjects

Acyclic Monoterpenes, Alkenes analysis, Alkenes metabolism, Antirrhinum anatomy & histology, Antirrhinum growth & development, Antirrhinum metabolism, Benzoates analysis, Benzoates metabolism, DEFICIENS Protein genetics, DEFICIENS Protein metabolism, Flowers growth & development, Flowers metabolism, Gene Expression, Gene Expression Regulation, Plant genetics, Gene Regulatory Networks, Genotype, Homeodomain Proteins genetics, Homeodomain Proteins metabolism, Models, Biological, Monoterpenes analysis, Monoterpenes metabolism, Mutation, Oils, Volatile analysis, Phenotype, Plant Leaves anatomy & histology, Plant Leaves genetics, Plant Leaves growth & development, Plant Leaves metabolism, Plant Proteins metabolism, Plants, Genetically Modified, RNA Interference, Antirrhinum genetics, Flowers genetics, Gene Expression Regulation, Developmental genetics, Oils, Volatile metabolism, Plant Proteins genetics

Abstract

The transcriptional network topology of B function in Antirrhinum, required for petal and stamen development, is thought to rely on initial activation of transcription of DEFICIENS (DEF) and GLOBOSA (GLO), followed by a positive autoregulatory loop maintaining gene expression levels. Here, we show that the mutant compacta (co), whose vegetative growth and petal size are affected, plays a role in B function. Late events in petal morphogenesis such as development of conical cell area and scent emissions were reduced in co and def (nicotianoides) (def (nic) ), and absent in co def (nic) double mutants, suggesting a role for CO in petal identity. Expression of DEF was down-regulated in co but surprisingly GLO was not affected. We investigated the levels of DEF and GLO at late stages of petal development in the co, def (nic) and glo-1 mutants, and established a reliable transformation protocol that yielded RNAi-DEF lines. We show that the threshold levels of DEF or GLO required to obtain petal tissue are approximately 11% of wild-type. The relationship between DEF and GLO transcripts is not equal or constant and changes during development. Furthermore, down-regulation of DEF or GLO does not cause parallel down-regulation of the partner. Our results demonstrate that, at late stages of petal development, the B function transcriptional network topology is not based on positive autoregulation, and has additional components of transcriptional maintenance. Our results suggest changes in network topology that may allow changes in protein complexes that would explain the fact that not all petal traits appear early in development., (© 2012 The Authors. The Plant Journal © 2012 Blackwell Publishing Ltd.)

Published

2012

5. A molecular recombination map of Antirrhinum majus.

Author

Schwarz-Sommer Z, Gübitz T, Weiss J, Gómez-di-Marco P, Delgado-Benarroch L, Hudson A, and Egea-Cortines M

Subjects

Crosses, Genetic, DNA Transposable Elements genetics, Expressed Sequence Tags, Genetic Markers genetics, Mutation, Phenotype, Antirrhinum genetics, Chromosome Mapping methods, Chromosomes, Plant genetics, Recombination, Genetic

Abstract

Background: Genetic recombination maps provide important frameworks for comparative genomics, identifying gene functions, assembling genome sequences and for breeding. The molecular recombination map currently available for the model eudicot Antirrhinum majus is the result of a cross with Antirrhinum molle, limiting its usefulness within A. majus., Results: We created a molecular linkage map of A. majus based on segregation of markers in the F2 population of two inbred lab strains of A. majus. The resulting map consisted of over 300 markers in eight linkage groups, which could be aligned with a classical recombination map and the A. majus karyotype. The distribution of recombination frequencies and distorted transmission of parental alleles differed from those of a previous inter-species hybrid. The differences varied in magnitude and direction between chromosomes, suggesting that they had multiple causes. The map, which covered an estimated of 95% of the genome with an average interval of 2 cM, was used to analyze the distribution of a newly discovered family of MITE transposons and tested for its utility in positioning seven mutations that affect aspects of plant size., Conclusions: The current map has an estimated interval of 1.28 Mb between markers. It shows a lower level of transmission ratio distortion and a longer length than the previous inter-species map, making it potentially more useful. The molecular recombination map further indicates that the IDLE MITE transposons are distributed throughout the genome and are relatively stable. The map proved effective in mapping classical morphological mutations of A. majus.

Published

2010

6. The mutants compacta ähnlich, Nitida and Grandiflora define developmental compartments and a compensation mechanism in floral development in Antirrhinum majus.

Author

Delgado-Benarroch L, Weiss J, and Egea-Cortines M

Subjects

Antirrhinum cytology, Antirrhinum ultrastructure, Cell Division, Cell Proliferation, Cell Size, DNA, Plant metabolism, Flow Cytometry, Flowers cytology, Flowers ultrastructure, Phenotype, Reproduction, Antirrhinum genetics, Antirrhinum growth & development, Flowers genetics, Flowers growth & development, Mutation genetics

Abstract

In order to improve our understanding of floral size control we characterised three mutants of Antirrhinum majus with different macroscopic floral phenotypes. The recessive mutant compacta ähnlich has smaller flowers affected mainly in petal lobe expansion, the dominant mutant Grandiflora has overall larger organs, whilst the semidominant mutation Nitida exhibits smaller flowers in a dose-dependent manner. We developed a cell map in order to establish the cellular phenotypes of the mutants. Changes in organ size were both organ- and region-specific. Nitida and compacta ähnlich affected cell expansion in proximal and distal petal regions, respectively, suggesting differential regulation between petal lobe regions. Although petal size was smaller in compacta ähnlich than in wild type, conical cells were significantly bigger, suggesting a compensation mechanism involved in petal development. Grandiflora had larger cells in petals and increased cell division in stamens and styles, suggesting a relationship between genes controlling organ size and organ identity. The level of ploidy in petals of Grandiflora and coan was found to be equivalent to wild type petals and leaves, ruling out an excess of growth via endoreduplication. We discuss our results in terms of current models about control of lateral organ size.

Published

2009

7. FORMOSA controls cell division and expansion during floral development in Antirrhinum majus.

Author

Delgado-Benarroch L, Causier B, Weiss J, and Egea-Cortines M

Subjects

Amino Acid Sequence, Antirrhinum cytology, Antirrhinum growth & development, Cell Cycle, Cell Division, Cell Size, Cyclin D, Cyclins genetics, Flowers cytology, Flowers ultrastructure, Gene Expression Regulation, Developmental, Gene Expression Regulation, Plant, In Situ Hybridization, Microscopy, Electron, Scanning, Molecular Sequence Data, Phylogeny, Plant Proteins classification, Plant Proteins physiology, Reverse Transcriptase Polymerase Chain Reaction, Sequence Homology, Amino Acid, Antirrhinum genetics, Flowers genetics, Plant Proteins genetics

Abstract

Control of organ size is the product of coordinated cell division and expansion. In plants where one of these pathways is perturbed, organ size is often unaffected as compensation mechanisms are brought into play. The number of founder cells in organ primordia, dividing cells, and the period of cell proliferation determine cell number in lateral organs. We have identified the Antirrhinum FORMOSA (FO) gene as a specific regulator of floral size. Analysis of cell size and number in the fo mutant, which has increased flower size, indicates that FO is an organ-specific inhibitor of cell division and activator of cell expansion. Increased cell number in fo floral organs correlated with upregulation of genes involved in the cell cycle. In Arabidopsis the AINTEGUMENTA (ANT) gene promotes cell division. In the fo mutant increased cell number also correlates with upregulation of an Antirrhinum ANT-like gene (Am-ANT) in inflorescences that is very closely related to ANT and shares a similar expression pattern, suggesting that they may be functional equivalents. Increased cell proliferation is thought to be compensated for by reduced cell expansion to maintain organ size. In Arabidopsis petal cell expansion is inhibited by the BIGPETAL (BPE) gene, and in the fo mutant reduced cell size corresponded to upregulation of an Antirrhinum BPE-like gene (Am-BPE). Our data suggest that FO inhibits cell proliferation by negatively regulating Am-ANT, and acts upstream of Am-BPE to coordinate floral organ size. This demonstrates that organ size is modulated by the organ-specific control of both general and local gene networks.

Published

2009

8. Phenotypic Space and Variation of Floral Scent Profiles during Late Flower Development in Antirrhinum.

Author

Weiss, Julia, Mühlemann, Joëlle K., Ruiz-Hernández, Victoria, Dudareva, Natalia, and Egea-Cortines, Marcos

Subjects

SNAPDRAGONS, PHENOTYPES, VOLATILE organic compounds

Abstract

The genus Antirrhinum comprises about 28 species with a center of origin in the Iberian Peninsula. They show an important diversity of growing niches. We have performed a comprehensive analysis of scent profiles in eight wild species, Antirrhinum linkianum, A. tortuosum, A. cirrigherum, A. latifolium, A. meonanthum, A. braun-blanquetii, A. barrelieri, and A. graniticum. We used also two laboratory inbred lines A. majus, 165E and Sippe50. We identified 63 volatile organic compounds (VOCs) belonging to phenylpropanoids, benzenoids, mono- and sesquiterpenes, nitrogen-containing compounds, and aliphatic alcohols previously described in plants. Twenty-four VOCs were produced at levels higher than 2% of total VOC emission, while other VOCs were emitted in trace amounts. The absolute scent emission varied during flower maturation and species. The lowest emitting was A. meonanthum while A. tortuosum had the largest emissions. Species were clustered according to their scent profiles and the resulting dendrogram matched the current species phylogeny. However, two accessions, A. majus Sippe 50 and A. braun-blanquetii, showed development-specific changes in their VOC composition, suggesting a precise control and fine tuning of scent profiles. Cluster analysis of the different scent components failed to identify a specific synthesis pathway, indicating a key role of scent profiles as blends. There is considerable degree of chemodiversity in scent profiles in Antirrhinum. The specific developmental stage plays an important role in scent quantitative emissions. The relative robustness of the bouquets could be an adaptation to local pollinators. [ABSTRACT FROM AUTHOR]

Published

2016

9. Efectos genéticos y medio ambientales en la estructura fenotípica de Antirrhinum

Author

Raquel Alcantud Rodríguez, Weiss, Julia Rosl, Egea Gutiérrez-Cortines, Marcos, and Ingeniería Agronómica

Subjects

Biología molecular vegetal, Cultivos y clima, 2417.14 Genética Vegetal, 2417 Biología Vegetal (Botánica), Genética vegetal, Botánica y clima, Botánica, Antirrhinum, Medio ambiente, Genética

Abstract

[SPA] El desarrollo de plantas está altamente afectado por las condiciones ambientales. El interés por mejorar la tolerancia de los cultivos al estrés abiótico como temperatura, espacio, luz y sombra ha aumentado en los últimos años y se buscan estrategias biotecnológicas para conseguirlo. El cambio climático va a tener un gran impacto en la actividad agrícola y en la productividad de los ecosistemas orgánicos (Rosenzweig et al., 2014). Las diferencias fenotípicas en Antirrhinum majus pueden revelar como se adapta y responde a un conjunto complejo de señales ambientales. Hoy nos enfrentamos a un desafío para mejorar las plantas y prepararnos para todos los cambios que ya se están produciendo, lo que exigirá multitud de esfuerzos de diferentes ciencias y conocimientos tradicionales y modernos. Dependiendo de las circunstancias, las plantas muestran variabilidad en el desarrollo vegetativo y reproductivo. El grado de variabilidad parece depender de la plasticidad fenotípica de la especie y del órgano. El objetivo de esta tesis fue el análisis del nivel de plasticidad fenotípica de la especie Antirrhinum majus bajo diversas condiciones ambientales y el examen de la base génica de estos cambios. El crecimiento de plantas en condición de hacinamiento resulta en una situación de competencia intra-específica. Observamos que, bajo estas condiciones, Antirrhinum majus muestra un desacoplamiento entre el tamaño y número de los órganos laterales con una disminución en el tamaño de la hoja y un aumento en el número de hojas, mientras que las flores mantuvieron un tamaño robusto pero una reducción en el número. A pesar de estos cambios, el hacinamiento no pareció afectar determinados aspectos del desarrollo de los meristemos apicales de inflorescencia según lo indicado por la expresión estable de los genes ROA, HIRZ (mantenimiento de meristemo), CYCD3a, CYCD3b, HISTONE H4 (ciclo celular) o GRAM (polaridad de órganos). Sin embargo, un análisis transcriptómico del tejido de meristemo de inflorescencia mostró una serie de genes sobre-expresados, pertenecientes a la ruta de síntesis y / o señalización de ácido jasmónico y abscísico (AmJAZ1, AmMYB21, AmOPCL1 y AmABA2) mientras que genes implicados en la síntesis de auxinas no se vieron afectados (AmTAR2, AmANT). Basado en los resultados fenotípicos y transcriptómicos, proponemos la hipótesis de que el SAM robusto y una señalización de auxina estable permiten un tamaño floral homogéneo, mientras que los cambios en la señalización de JA y ABA pueden ser responsables de la disminución del tamaño de la hoja y del número de órganos laterales Un tamaño robusto de la flor es de gran importancia con respecto a la reproducción de la especie ya que afecta a la interacción flor-polinizador. Otras características florales que juegan un papel para la atracción de polinizadores, la propagación y también para el valor ornamental, incluyen el tamaño, la arquitectura, el color, la fragancia y la viabilidad del polen. Analizamos la plasticidad de estos caracteres en Antirrhinum majus en respuesta a temperaturas variables, un aspecto especialmente importante considerando el cambio en el clima global. La mayoría de los rasgos cambiaron en dirección opuesta dependiendo de si se aplicó el régimen de frío o calor. Mientras temperaturas bajas (15/5 ºC) frente a temperaturas estándar (22/15 ºC) produjeron una mayor pigmentación de pétalos, un aumento en el tamaño floral, una reducción en el número de flores y una mayor viabilidad del polen, las temperaturas altas (30/23 ºC) resultaron en flores más pálidas y más pequeñas, un número de flores estable y una reducida viabilidad del polen. En ambos casos se observó tanto una reducción en la cantidad de compuestos órganicos volátiles (VOCs, volatile organic compounds) emitidos como cambios en el perfil de VOCs durante la apertura floral. Los resultados muestran que el nivel de plasticidad fenotípica depende del tipo de cambio ambiental. Mientras la condición de hacinamiento provoca cambios en el número pero no en el tamaño de flores, los cambios en temperatura si afectan el tamaño floral y, en caso de temperaturas bajas, también el número de flores. Estos cambios pueden, en combinación con las otras características florales, tener consecuencias de gran alcance tanto con respecto a la interacción planta-polinizador como para el valor ornamental de Antirrhinum majus. Considerando los cambios en los caracteres florales anteriormente mencionados y teniendo en cuenta los resultados transcriptómicos bajo hacinamiento, analizamos la expresión de una serie de genes marcadores: del ciclo celular (AmCYCD3a y AmH4), de expansión celular (AmEXP y AmBP), señalización de auxinas (AmANT), síntesis de antocianinas (AmCHS), desarrollo de células cónicas (AmMIXTA) y síntesis del volátil metilbenzoato (AmBAMT). Mientras la expresión de genes que controlan la expansión no se alteró significativamente, AmH4, un marcador de síntesis de ADN, se regulaba negativamente a temperaturas más altas y más bajas, indicando un efecto de temperatura sobre la división celular y por lo tanto sobre el número de células. La producción de pétalos más grandes a temperaturas más bajas podría deberse a un mayor período de división celular. La pigmentación intensa de pétalos a bajas temperaturas se puede explicar por el aumento en la expresión de AmCHS, mientras que la reducida pigmentación a altas temperaturas no se vio relacionada con cambios en la expresión de AmCHS, señalando a un efecto sobre enzimas de degradación de antocianinas. Las temperaturas adversas provocaron una disminución significativa en la expresión de AmMIXTA, un gen que controla la formación de células cónicas. Éstas juegan un papel en la atracción de polinizadores y en la producción de volátiles. El gen BAMT (Benzoic acid Carboxymethyl Transferase), involucrado en la síntesis de metibenzoato, uno de los principales compuestos de VOCs en A. majus, se expresa en células cónicas. Sin embargo, la expresión de BAMT no se alteró significativamente, indicando posibles cambios al nivel pos-traduccional de BAMT o en el flujo metabólico. [ENG] Plant development is highly affected by environmental conditions. The interest in improving the tolerance of crops to abiotic stress such as temperature, space, light and shade has increased in recent years and biotechnological strategies are sought to achieve it. Climate change will have a great impact on agricultural activity and the productivity of organic ecosystems (Rosenzweig et al., 2014). Phenotypic differences in Antirrhinum majus can reveal how it adapts and responds to a complex set of environmental signals. Today we face a challenge to improve plants and prepare for all the changes that are already taking place, which will require a multitude of efforts from different traditional and modern sciences and knowledge. Depending on the circumstances, plants show variability in the vegetative and reproductive development. The degree of variability seems to depend on the phenotypic plasticity of the species and / or the organ. The objective of this thesis was to analyze the level of phenotypic plasticity of the species Antirrhinum majus under various environmental conditions and the examination of the genetic basis of these changes. The growth of plants under crowding conditions results in a situation of intraspecific competition. We observed that under these conditions, Antirrhinum majus shows a decoupling between the size and number of the lateral organs with a decrease in the size of the leaf and an increase in the number of leaves, while the flowers maintained a robust size but showed a reduction in the number. Despite these changes, crowding did not appear to affect certain aspects of the development of the apical meristems as indicated by the stable expression of the genes ROA, HIRZ (meristem maintenance), CYCD3a, CYCD3b, HISTONE H4 (cell cycle) or GRAM (organ polarity). However, a transcriptomic analysis of the inflorescence meristem tissue showed a series of overexpressed genes, belonging to the routes of synthesis and / or signaling of jasmonic and abscisic acid (AmJAZ1, AmMYB21, AmOPCL1 y AmABA2) while genes involved in the synthesis of auxins were not affected (AmTAR2, AmANT). Based on the phenotypic and transcriptomic results, we propose the hypothesis that robust SAM and stable auxin signaling allows a homogeneous floral size, while changes in the signaling of JA and ABA may be responsible for the decrease in leaf size and the number of lateral organs. A robust flower size is of great importance with respect to the reproduction of the species since it affects the flower-pollinator interaction. Other floral characteristics, which play a role for pollinator attraction, propagation and also as ornamental value, include the size, architecture, color, fragrance and viability of the pollen. We analyzed the plasticity of these characters in Antirrhinum majus in response to variable temperatures, an especially important aspect considering the change in the global climate. Most features changed in the opposite direction depending on whether a cold or heat regime was applied. While low temperatures (15/5 ºC) versus standard temperatures (22/15 ºC) produced a stronger petal pigmentation, an increase in floral size, a reduction in the number of flowers and an increased pollen viability, high temperatures (30/23 ° C) resulted in paler and smaller flowers, reduced pollen viability, while flower number was stable. In both cases, a reduction in the amount of emitted volatile organic compounds (VOCs) was observed as well as changes in the VOC profile during the floral opening. The results show that phenotypic plasticity depends on the type of environmental change. While the crowding condition caused changes in the number but not in the size of flowers, changes in temperature affected the floral size and, in case of low temperatures, also the number of flowers. These changes may, in combination with the other floral traits, have far-reaching consequences both with respect to the plant-pollinator interaction and for the ornamental value of Antirrhinum majus. Considering the changes in the floral characters mentioned above and taking into account the transcriptomic results under crowding condition, we analyzed the expression of a series of marker genes of the cell cycle (AmCYCD3a y AmH4), cell expansion (AmEXP y AmBP), auxin signaling (AmANT), anthocyanin synthesis (AmCHS), conical cell development (AmMIXTA) and the synthesis of the volatile methylbenzoate (AmBAMT). While the expression of genes that control cell expansion was not significantly altered, AmH4, a DNA synthesis marker, was downregulated at higher and lower temperatures, indicating a temperature effect on cell division and therefore on the number of cells. The production of larger petals at lower temperatures might be due to a longer period of cell division. Intense pigmentation of petals at low temperatures can be explained by the increase in AmCHS expression, while reduced pigmentation at high temperatures was not correlated with changes in AmCHS expression, pointing to a temperature control over anthocyanin degradating enzymes or other enzymes in the pathway. Adverse temperatures caused a significant decrease in the expression of AmMIXTA, a gene that controls the formation of conical cells, which play a role in the attraction of pollinators and in the production of volatiles. The BAMT (Benzoic acid Carboxymethyl Transferase) gene, involved in the synthesis of methylbenzoate, one of the main VOC compound in A. majus, is expressed in conical cells. However, the expression of BAMT was not significantly altered, indicating possible changes on the post-translational level of BAMT. Escuela Internacional de Doctorado de la Universidad Politécnica de Cartagena Universidad Politécnica de Cartagena Programa de Doctorado en Técnicas Avanzadas en Investigación y Desarrollo Agrario y Alimentario

Published

2020