The Experts below are selected from a list of 998793 Experts worldwide ranked by ideXlab platform
Kerstin Kaufmann - One of the best experts on this subject based on the ideXlab platform.
-
flowering locus c in monocots and the tandem origin of angiosperm specific mads box genes
Nature Communications, 2013Co-Authors: Philip Ruelens, Ruud A De Maagd, Sebastian Proost, Gunter Theisen, Koen Geuten, Kerstin KaufmannAbstract:MADS-box genes regulate flowering plant development, but their evolutionary origins are unclear. Here, Ruelens et al. show that three major, apparently flowering plant-specific, MADS-box gene clades are derived from a single ancestral tandem duplication, and identify FLOWERING LOCUS C-like genes in cereals.
-
flowering locus c in monocots and the tandem origin of angiosperm specific mads box genes
Nature Communications, 2013Co-Authors: Philip Ruelens, Ruud A De Maagd, Sebastian Proost, Gunter Theisen, Koen Geuten, Kerstin KaufmannAbstract:MADS-domain transcription factors have been shown to act as key repressors or activators of the transition to flowering and as master regulators of reproductive organ identities. Despite their important roles in plant development, the origin of several MADS-box subfamilies has remained enigmatic so far. Here we demonstrate, through a combination of genome synteny and phylogenetic reconstructions, the origin of three major, apparently angiosperm-specific MADS-box gene clades: FLOWERING LOCUS C- (FLC-), SQUAMOSA- (SQUA-) and SEPALLATA- (SEP-)-like genes. We find that these lineages derive from a single ancestral tandem duplication in a common ancestor of extant seed plants. Contrary to common belief, we show that FLC-like genes are present in cereals where they can also act as floral repressors responsive to prolonged cold or vernalization. This opens a new perspective on the translation of findings from Arabidopsis to cereal crops, in which vernalization was originally described.
-
developmental and evolutionary diversity of plant mads domain factors insights from recent studies
Development, 2012Co-Authors: Richard G H Immink, Gerco C Angenent, Kerstin Kaufmann, Cezary SmaczniakAbstract:Members of the MADS-box transcription factor family play essential roles in almost every developmental process in plants. Many MADS-box genes have conserved functions across the flowering plants, but some have acquired novel functions in specific species during evolution. The analyses of MADS-domain protein interactions and target genes have provided new insights into their molecular functions. Here, we review recent findings on MADS-box gene functions in Arabidopsis and discuss the evolutionary history and functional diversification of this gene family in plants. We also discuss possible mechanisms of action of MADS-domain proteins based on their interactions with chromatin-associated factors and other transcriptional regulators.
Gerco C Angenent - One of the best experts on this subject based on the ideXlab platform.
-
Comparative analysis of binding patterns of MADS-domain proteins in Arabidopsis thaliana
'Springer Science and Business Media LLC', 2018Co-Authors: Niels Aerts, Gerco C Angenent, Hilda Van Mourik, Suzanne De Bruijn, Aalt D J Van DijkAbstract:Abstract Background Correct flower formation requires highly specific temporal and spatial regulation of gene expression. In Arabidopsis thaliana the majority of the master regulators that determine flower organ identity belong to the MADS-domain transcription factor family. The canonical DNA binding motif for this transcription factor family is the CArG-box, which has the consensus CC(A/T)6GG. However, so far, a comprehensive analysis of MADS-domain binding patterns has not yet been performed. Results Eight publicly available ChIP-seq datasets of MADS-domain proteins that regulate the floral transition and flower formation were analyzed. Surprisingly, the preferred DNA binding motif of each protein was a CArG-box with an NAA extension. Furthermore, motifs of other transcription factors were found in the vicinity of binding sites of MADS-domain transcription factors, suggesting that interaction of MADS-domain proteins with other transcription factors is important for target gene regulation. Finally, conservation of CArG-boxes between Arabidopsis ecotypes was assessed to obtain information about their evolutionary importance. CArG-boxes that fully matched the consensus were more conserved than other CArG-boxes, suggesting that the perfect CArG-box is evolutionary more important than other CArG-box variants. Conclusion Our analysis provides detailed insight into MADS-domain protein binding patterns. The results underline the importance of an extended version of the CArG-box and provide a first view on evolutionary conservation of MADS-domain protein binding sites in Arabidopsis ecotypes
-
developmental and evolutionary diversity of plant mads domain factors insights from recent studies
Development, 2012Co-Authors: Richard G H Immink, Gerco C Angenent, Kerstin Kaufmann, Cezary SmaczniakAbstract:Members of the MADS-box transcription factor family play essential roles in almost every developmental process in plants. Many MADS-box genes have conserved functions across the flowering plants, but some have acquired novel functions in specific species during evolution. The analyses of MADS-domain protein interactions and target genes have provided new insights into their molecular functions. Here, we review recent findings on MADS-box gene functions in Arabidopsis and discuss the evolutionary history and functional diversification of this gene family in plants. We also discuss possible mechanisms of action of MADS-domain proteins based on their interactions with chromatin-associated factors and other transcriptional regulators.
-
toward the analysis of the petunia mads box gene family by reverse and forward transposon insertion mutagenesis approaches b c and d floral organ identity functions require sepallata like mads box genes in petunia
The Plant Cell, 2003Co-Authors: Michiel Vandenbussche, Gerco C Angenent, Silvia Ferrario, Johannes Zethof, Erik Souer, Ronald Koes, Giovanni Battista Tornielli, Mario Pezzotti, Tom GeratsAbstract:We have initiated a systematic functional analysis of the MADS box, intervening region, K domain, C domain-type MADS box gene family in petunia. The starting point for this has been a reverse-genetics approach, aiming to select for transposon insertions into any MADS box gene. We have developed and applied a family signature insertion screening protocol that is highly suited for this purpose, resulting in the isolation of 32 insertion mutants in 20 different MADS box genes. In addition, we identified three more MADS box gene insertion mutants using a candidate-gene approach. The defined insertion lines provide a sound foundation for a systematic functional analysis of the MADS box gene family in petunia. Here, we focus on the analysis of Floral Binding Protein2 (FBP2) and FBP5 genes that encode the E-function, which in Arabidopsis has been shown to be required for B and C floral organ identity functions. fbp2 mutants display sepaloid petals and ectopic inflorescences originating from the third floral whorl, whereas fbp5 mutants appear as wild type. In fbp2 fbp5 double mutants, reversion of floral organs to leaf-like organs is increased further. Strikingly, ovules are replaced by leaf-like structures in the carpel, indicating that in addition to the B- and C-functions, the D-function, which specifies ovule development, requires E-function activity. Finally, we compare our data with results obtained using cosuppression approaches and conclude that the latter might be less suited for assigning functions to individual members of the MADS box gene family.
-
the mads box gene fbp2 is required for sepallata function in petunia
The Plant Cell, 2003Co-Authors: Silvia Ferrario, Richard G H Immink, A V Shchennikova, Jacqueline Busscherlange, Gerco C AngenentAbstract:The ABC model, which was accepted for almost a decade as a paradigm for flower development in angiosperms, has been subjected recently to a significant modification with the introduction of the new class of E-function genes. This function is required for the proper action of the B- and C-class homeotic proteins and is provided in Arabidopsis by the SEPALLATA1/2/3 MADS box transcription factors. A triple mutant in these partially redundant genes displays homeotic conversion of petals, stamens, and carpels into sepaloid organs and loss of determinacy in the center of the flower. A similar phenotype was obtained by cosuppression of the MADS box gene FBP2 in petunia. Here, we provide evidence that this phenotype is caused by the downregulation of both FBP2 and the paralog FBP5. Functional complementation of the sepallata mutant by FBP2 and our finding that the FBP2 protein forms multimeric complexes with other floral homeotic MADS box proteins indicate that FBP2 represents the same E function as SEP3 in Arabidopsis.
-
Analysis of the petunia MADS-box transcription factor family
Molecular genetics and genomics : MGG, 2003Co-Authors: Richard G H Immink, M Busscher, Silvia Ferrario, Jacqueline Busscher-lange, Maarten Kooiker, Gerco C AngenentAbstract:Transcription factors are key regulators of plant development. One of the major groups of transcription factors is the MADS-box family, of which at least 80 members are encoded in the Arabidopsis genome. In this study, 23 members of the petunia MADS-box transcription factor family were investigated by Northern hybridisation, phylogenetic and yeast two-hybrid analyses. Many of the genes characterised appeared to have one or more close relatives that shared similar expression patterns. Comparison of the binding interactions of these proteins revealed that some show similar interaction patterns, and hence are likely to be functionally redundant. From an evolutionary point of view, their coding genes are probably derived from a recent duplication event. Furthermore, protein-protein interaction patterns, in combination with expression patterns and phylogenetic classification, appear to offer good criteria for the identification of functional homologues. Based on comparison of such data between petunia and Arabidopsis, functions can be predicted for several MADS-box transcription factors in both species.
Gunter Theisen - One of the best experts on this subject based on the ideXlab platform.
-
dna binding properties of the mads domain transcription factor sepallata3 and mutant variants characterized by selex seq
Plant Molecular Biology, 2021Co-Authors: Sandra Kappel, Ralf Eggeling, Florian Rumpler, Marco Groth, Rainer Melzer, Gunter TheisenAbstract:We studied the DNA-binding profile of the MADS-domain transcription factor SEPALLATA3 and mutant variants by SELEX-seq. DNA-binding characteristics of SEPALLATA3 mutant proteins lead us to propose a novel DNA-binding mode. MIKC-type MADS-domain proteins, which function as essential transcription factors in plant development, bind as dimers to a 10-base-pair AT-rich motif termed CArG-box. However, this consensus motif cannot fully explain how the abundant family members in flowering plants can bind different target genes in specific ways. The aim of this study was to better understand the DNA-binding specificity of MADS-domain transcription factors. Also, we wanted to understand the role of a highly conserved arginine residue for binding specificity of the MADS-domain transcription factor family. Here, we studied the DNA-binding profile of the floral homeotic MADS-domain protein SEPALLATA3 by performing SELEX followed by high-throughput sequencing (SELEX-seq). We found a diverse set of bound sequences and could estimate the in vitro binding affinities of SEPALLATA3 to a huge number of different sequences. We found evidence for the preference of AT-rich motifs as flanking sequences. Whereas different CArG-boxes can act as SEPALLATA3 binding sites, our findings suggest that the preferred flanking motifs are almost always the same and thus mostly independent of the identity of the central CArG-box motif. Analysis of SEPALLATA3 proteins with a single amino acid substitution at position 3 of the DNA-binding MADS-domain further revealed that the conserved arginine residue, which has been shown to be involved in a shape readout mechanism, is especially important for the recognition of nucleotides at positions 3 and 8 of the CArG-box motif. This leads us to propose a novel DNA-binding mode for SEPALLATA3, which is different from that of other MADS-domain proteins known.
-
flowering locus c in monocots and the tandem origin of angiosperm specific mads box genes
Nature Communications, 2013Co-Authors: Philip Ruelens, Ruud A De Maagd, Sebastian Proost, Gunter Theisen, Koen Geuten, Kerstin KaufmannAbstract:MADS-box genes regulate flowering plant development, but their evolutionary origins are unclear. Here, Ruelens et al. show that three major, apparently flowering plant-specific, MADS-box gene clades are derived from a single ancestral tandem duplication, and identify FLOWERING LOCUS C-like genes in cereals.
-
flowering locus c in monocots and the tandem origin of angiosperm specific mads box genes
Nature Communications, 2013Co-Authors: Philip Ruelens, Ruud A De Maagd, Sebastian Proost, Gunter Theisen, Koen Geuten, Kerstin KaufmannAbstract:MADS-domain transcription factors have been shown to act as key repressors or activators of the transition to flowering and as master regulators of reproductive organ identities. Despite their important roles in plant development, the origin of several MADS-box subfamilies has remained enigmatic so far. Here we demonstrate, through a combination of genome synteny and phylogenetic reconstructions, the origin of three major, apparently angiosperm-specific MADS-box gene clades: FLOWERING LOCUS C- (FLC-), SQUAMOSA- (SQUA-) and SEPALLATA- (SEP-)-like genes. We find that these lineages derive from a single ancestral tandem duplication in a common ancestor of extant seed plants. Contrary to common belief, we show that FLC-like genes are present in cereals where they can also act as floral repressors responsive to prolonged cold or vernalization. This opens a new perspective on the translation of findings from Arabidopsis to cereal crops, in which vernalization was originally described.
-
selaginella genome analysis entering the homoplasy heaven of the mads world
Frontiers in Plant Science, 2012Co-Authors: Lydia Gramzow, Gunter Theisen, Barbara A Ambrose, Elizabeth I Barker, Christian Schulz, Neil W Ashton, Amy LittAbstract:In flowering plants, arguably the most significant transcription factors regulating development are MADS-domain proteins, encoded by Type I and Type II MADS-box genes. Type II genes are divided into the MIKCC and MIKC* groups. In angiosperms, these types and groups play distinct roles in the development of female gametophytes, embryos, and seeds (Type I); vegetative and floral tissues in sporophytes (MIKCC); and male gametophytes (MIKC*), but their functions in other plants are largely unknown. The complete set of MADS-box genes has been described for several angiosperms and a moss, Physcomitrella patens. Our examination of the complete genome sequence of a lycophyte, Selaginella moellendorffii, revealed 19 putative MADS-box genes (13 Type I, 3 MIKCC, and 3 MIKC*). Our results suggest that the most recent common ancestor of vascular plants possessed at least two Type I and two Type II genes. None of the S. moellendorffii MIKCC genes were identified as orthologs of any floral organ identity genes. This strongly corroborates the view that the clades of floral organ identity genes originated in a common ancestor of seed plants after the lineage that led to lycophytes had branched off, and that expansion of MIKCC genes in the lineage leading to seed plants facilitated the evolution of their unique reproductive organs. The number of MIKC* genes and the ratio of MIKC* to MIKCC genes is lower in S. moellendorffii and angiosperms than in P. patens, correlated with reduction of the gametophyte in vascular plants. Our data indicate that Type I genes duplicated and diversified independently within lycophytes and seed plants. Our observations on MADS-box gene evolution echo morphological evolution since the two lineages of vascular plants appear to have arrived independently at similar body plans. Our annotation of MADS-box genes in S. moellendorffii provides the basis for functional studies to reveal the roles of this crucial gene family in basal vascular plants.
-
expression of mads box genes zmm8 and zmm14 during inflorescence development of zea mays discriminates between the upper and the lower floret of each spikelet
Development Genes and Evolution, 1999Co-Authors: Jorge Cacharron, Heinz Saedler, Gunter TheisenAbstract:Most floral meristem and organ identity genes of dicotyledonous plants belong to the MADS box gene family. Since they are generally transcribed in those tissues and organs whose identity they determine, they are excellent markers for developmental processes. Here we report the cDNA cloning of a pair of MADS box genes, ZMM8 and ZMM14, from the monocotyledonous plant maize. Maize inflorescences are composed of spikelets which contain two florets, an upper and a lower one. Although upper and lower florets develop in a very similar way in male inflorescences, ZMM8 and ZMM14 expression was found in all organs of upper florets, but no transcripts were detected in lower florets. In contrast, two other MADS box genes were found to be expressed in lower florets in the same way as in upper florets. Our observations suggest that during spikelet development ZMM8 and ZMM14 work as selector genes which are involved in distinguishing the upper from the lower floret. Alternatively, these genes may be involved in conferring determinacy to the spikelet or upper floret meristem. Our data suggest that in the phylogenetic lineage that led to maize an ancient type of MADS box gene has been recruited during evolution for the establishment of novel positional information not found within the simple inflorescences of dicotyledonous plants such as Arabidopsis.
Koen Geuten - One of the best experts on this subject based on the ideXlab platform.
-
flowering locus c in monocots and the tandem origin of angiosperm specific mads box genes
Nature Communications, 2013Co-Authors: Philip Ruelens, Ruud A De Maagd, Sebastian Proost, Gunter Theisen, Koen Geuten, Kerstin KaufmannAbstract:MADS-box genes regulate flowering plant development, but their evolutionary origins are unclear. Here, Ruelens et al. show that three major, apparently flowering plant-specific, MADS-box gene clades are derived from a single ancestral tandem duplication, and identify FLOWERING LOCUS C-like genes in cereals.
-
flowering locus c in monocots and the tandem origin of angiosperm specific mads box genes
Nature Communications, 2013Co-Authors: Philip Ruelens, Ruud A De Maagd, Sebastian Proost, Gunter Theisen, Koen Geuten, Kerstin KaufmannAbstract:MADS-domain transcription factors have been shown to act as key repressors or activators of the transition to flowering and as master regulators of reproductive organ identities. Despite their important roles in plant development, the origin of several MADS-box subfamilies has remained enigmatic so far. Here we demonstrate, through a combination of genome synteny and phylogenetic reconstructions, the origin of three major, apparently angiosperm-specific MADS-box gene clades: FLOWERING LOCUS C- (FLC-), SQUAMOSA- (SQUA-) and SEPALLATA- (SEP-)-like genes. We find that these lineages derive from a single ancestral tandem duplication in a common ancestor of extant seed plants. Contrary to common belief, we show that FLC-like genes are present in cereals where they can also act as floral repressors responsive to prolonged cold or vernalization. This opens a new perspective on the translation of findings from Arabidopsis to cereal crops, in which vernalization was originally described.
-
hidden variability of floral homeotic b genes in solanaceae provides a molecular basis for the evolution of novel functions
The Plant Cell, 2010Co-Authors: Koen Geuten, Vivian F IrishAbstract:B-class MADS box genes specify petal and stamen identities in several core eudicot species. Members of the Solanaceae possess duplicate copies of these genes, allowing for diversification of function. To examine the changing roles of such duplicate orthologs, we assessed the functions of B-class genes in Nicotiana benthamiana and tomato (Solanum lycopersicum) using virus-induced gene silencing and RNA interference approaches. Loss of function of individual duplicates can have distinct phenotypes, yet complete loss of B-class gene function results in extreme homeotic transformations of petal and stamen identities. We also show that these duplicate gene products have qualitatively different protein-protein interaction capabilities and different regulatory roles. Thus, compensatory changes in B-class MADS box gene duplicate function have occurred in the Solanaceae, in that individual gene roles are distinct, but their combined functions are equivalent. Furthermore, we show that species-specific differences in the stamen regulatory network are associated with differences in the expression of the microRNA miR169. Whereas there is considerable plasticity in individual B-class MADS box transcription factor function, there is overall conservation in the roles of the multimeric MADS box B-class protein complexes, providing robustness in the specification of petal and stamen identities. Such hidden variability in gene function as we observe for individual B-class genes can provide a molecular basis for the evolution of regulatory functions that result in novel morphologies.
-
expression divergence of the agl6 mads domain transcription factor lineage after a core eudicot duplication suggests functional diversification
BMC Plant Biology, 2010Co-Authors: Tom Viaene, Dries Vekemans, Annette Becker, Siegbert Melzer, Koen GeutenAbstract:Because of their known role as transcriptional regulators of key plant developmental processes, the diversification of MADS-box gene function is thought to be a major driving force in the developmental evolution of plants. Yet the function of some MADS-box gene subfamilies has remained elusive thus far. One such lineage, AGL6, has now been functionally characterized in three angiosperm species, but a phylogenetic framework for comparison of AGL6 gene function is currently missing.
Sanjay Kapoor - One of the best experts on this subject based on the ideXlab platform.
-
mads box gene family in rice genome wide identification organization and expression profiling during reproductive development and stress
BMC Genomics, 2007Co-Authors: R Arora, Pinky Agarwal, Swatismita Ray, Ashok Kumar Singh, Vijay P Singh, Akhilesh K Tyagi, Sanjay KapoorAbstract:Background MADS-box transcription factors, besides being involved in floral organ specification, have also been implicated in several aspects of plant growth and development. In recent years, there have been reports on genomic localization, protein motif structure, phylogenetic relationships, gene structure and expression of the entire MADS-box family in the model plant system, Arabidopsis. Though there have been some studies in rice as well, an analysis of the complete MADS-box family along with a comprehensive expression profiling was still awaited after the completion of rice genome sequencing. Furthermore, owing to the role of MADS-box family in flower development, an analysis involving structure, expression and functional aspects of MADS-box genes in rice and Arabidopsis was required to understand the role of this gene family in reproductive development.
-
mads box gene family in rice genome wide identification organization and expression profiling during reproductive development and stress
BMC Genomics, 2007Co-Authors: R Arora, Pinky Agarwal, Swatismita Ray, Ashok Kumar Singh, Vijay P Singh, Akhilesh K Tyagi, Sanjay KapoorAbstract:MADS-box transcription factors, besides being involved in floral organ specification, have also been implicated in several aspects of plant growth and development. In recent years, there have been reports on genomic localization, protein motif structure, phylogenetic relationships, gene structure and expression of the entire MADS-box family in the model plant system, Arabidopsis. Though there have been some studies in rice as well, an analysis of the complete MADS-box family along with a comprehensive expression profiling was still awaited after the completion of rice genome sequencing. Furthermore, owing to the role of MADS-box family in flower development, an analysis involving structure, expression and functional aspects of MADS-box genes in rice and Arabidopsis was required to understand the role of this gene family in reproductive development. A genome-wide molecular characterization and microarray-based expression profiling of the genes encoding MADS-box transcription factor family in rice is presented. Using a thorough annotation exercise, 75 MADS-box genes have been identified in rice and categorized into MIKCc, MIKC*, Mα, Mβ and Mγ groups based on phylogeny. Chromosomal localization of these genes reveals that 16 MADS-box genes, mostly MIKCc-type, are located within the duplicated segments of the rice genome, whereas most of the M-type genes, 20 in all, seem to have resulted from tandem duplications. Nine members belonging to the Mβ group, which was considered absent in monocots, have also been identified. The expression profiles of all the MADS-box genes have been analyzed under 11 temporal stages of panicle and seed development, three abiotic stress conditions, along with three stages of vegetative development. Transcripts for 31 genes accumulate preferentially in the reproductive phase, of which, 12 genes are specifically expressed in seeds, and six genes show expression specific to panicle development. Differential expression of seven genes under stress conditions is also evident. An attempt has been made to gain insight into plausible functions of rice MADS-box genes by collating the expression data of functionally validated genes in rice and Arabidopsis. Only a limited number of MADS genes have been functionally validated in rice. A comprehensive annotation and transcriptome profiling undertaken in this investigation adds to our understanding of the involvement of MADS-box family genes during reproductive development and stress in rice and also provides the basis for selection of candidate genes for functional validation studies.
