Predicting the Impact of Alternative Splicing on Plant MADS Domain Protein Function

Several genome-wide studies demonstrated that alternative splicing (AS) significantly increases the transcriptome complexity in plants. However, the impact of AS on the functional diversity of proteins is difficult to assess using genome-wide approaches. The availability of detailed sequence annotations for specific genes and gene families allows for a more detailed assessment of the potential effect of AS on their function. One example is the plant MADS-domain transcription factor family, members of which interact to form protein complexes that function in transcription regulation. Here, we perform an in silico analysis of the potential impact of AS on the protein-protein interaction capabilities of MIKC-type MADS-domain proteins. We first confirmed the expression of transcript isoforms resulting from predicted AS events. Expressed transcript isoforms were considered functional if they were likely to be translated and if their corresponding AS events either had an effect on predicted dimerisation motifs or occurred in regions known to be involved in multimeric complex formation, or otherwise, if their effect was conserved in different species. Nine out of twelve MIKC MADS-box genes predicted to produce multiple protein isoforms harbored putative functional AS events according to those criteria. AS events with conserved effects were only found at the borders of or within the K-box domain. We illustrate how AS can contribute to the evolution of interaction networks through an example of selective inclusion of a recently evolved interaction motif in the MADS AFFECTING FLOWERING1-3 (MAF1–3) subclade. Furthermore, we demonstrate the potential effect of an AS event in SHORT VEGETATIVE PHASE (SVP), resulting in the deletion of a short sequence stretch including a predicted interaction motif, by overexpression of the fully spliced and the alternatively spliced SVP transcripts. For most of the AS events we were able to formulate hypotheses about the potential impact on the interaction capabilities of the encoded MIKC proteins.

[1]  D. Cook,et al.  Characterization and comparison of intron structure and alternative splicing between Medicago truncatula, Populus trichocarpa, Arabidopsis and rice , 2008, Plant Molecular Biology.

[2]  Rainer Melzer,et al.  MIKC-type MADS-domain proteins: structural modularity, protein interactions and network evolution in land plants. , 2005, Gene.

[3]  J. Garcia-Fernández,et al.  Internal and external paralogy in the evolution of tropomyosin genes in metazoans. , 2010, Molecular biology and evolution.

[4]  E V Koonin,et al.  Origin of alternative splicing by tandem exon duplication. , 2001, Human molecular genetics.

[5]  Kerstin Kaufmann,et al.  The 'ABC' of MADS domain protein behaviour and interactions. , 2010, Seminars in cell & developmental biology.

[6]  Trey Ideker,et al.  Cytoscape 2.8: new features for data integration and network visualization , 2010, Bioinform..

[7]  Christus,et al.  A General Method Applicable to the Search for Similarities in the Amino Acid Sequence of Two Proteins , 2022 .

[8]  Rolf Apweiler,et al.  InterProScan - an integration platform for the signature-recognition methods in InterPro , 2001, Bioinform..

[9]  Henry D. Priest,et al.  Genome-wide mapping of alternative splicing in Arabidopsis thaliana. , 2010, Genome research.

[10]  E. Wang,et al.  Analysis and design of RNA sequencing experiments for identifying isoform regulation , 2010, Nature Methods.

[11]  W. Barbazuk,et al.  Genome-wide analyses of alternative splicing in plants: opportunities and challenges. , 2008, Genome research.

[12]  M. Purugganan,et al.  Complex rearrangements lead to novel chimeric gene fusion polymorphisms at the Arabidopsis thaliana MAF2-5 flowering time gene cluster. , 2008, Molecular biology and evolution.

[13]  Joel Dudley,et al.  MEGA: A biologist-centric software for evolutionary analysis of DNA and protein sequences , 2008, Briefings Bioinform..

[14]  Detlef Weigel,et al.  Comprehensive Interaction Map of the Arabidopsis MADS Box Transcription Factorsw⃞ , 2005, The Plant Cell Online.

[15]  D. Soltis,et al.  Sequence and Expression Studies of A‐, B‐, and E‐Class MADS‐Box Homologues in Eupomatia (Eupomatiaceae): Support for the Bracteate Origin of the Calyptra , 2005, International Journal of Plant Sciences.

[16]  P. Yen,et al.  Physiological and molecular basis of thyroid hormone action. , 2001, Physiological reviews.

[17]  John W. S. Brown,et al.  Monitoring changes in alternative precursor messenger RNA splicing in multiple gene transcripts. , 2007, The Plant journal : for cell and molecular biology.

[18]  Z. Schwarz‐Sommer,et al.  Floral organ identity: 20 years of ABCs. , 2010, Seminars in cell & developmental biology.

[19]  R. Amasino,et al.  Identification of a MADS-box gene, FLOWERING LOCUS M, that represses flowering. , 2001, The Plant journal : for cell and molecular biology.

[20]  Huai Wang,et al.  A transcriptional repression motif in the MADS factor AGL15 is involved in recruitment of histone deacetylase complex components. , 2008, The Plant journal : for cell and molecular biology.

[21]  D. Weigel,et al.  Temperature Induced Flowering in Arabidopsis thaliana , 2006, Plant signaling & behavior.

[22]  G. Simpson,et al.  Regulation of flowering time by RNA processing. , 2008, Current topics in microbiology and immunology.

[23]  M. Lascoux,et al.  Splicing Variation at a FLOWERING LOCUS C Homeolog Is Associated With Flowering Time Variation in the Tetraploid Capsella bursa-pastoris , 2009, Genetics.

[24]  Roeland C. H. J. van Ham,et al.  Sequence Motifs in MADS Transcription Factors Responsible for Specificity and Diversification of Protein-Protein Interaction , 2010, PLoS Comput. Biol..

[25]  M S Waterman,et al.  Identification of common molecular subsequences. , 1981, Journal of molecular biology.

[26]  J. Ecker,et al.  FRIGIDA-Independent Variation in Flowering Time of Natural Arabidopsis thaliana Accessions , 2005, Genetics.

[27]  G. Theißen,et al.  The major clades of MADS-box genes and their role in the development and evolution of flowering plants. , 2003, Molecular phylogenetics and evolution.

[28]  Lior Pachter,et al.  Sequence Analysis , 2020, Definitions.

[29]  Jack A. M. Leunissen,et al.  QualitySNP: a pipeline for detecting single nucleotide polymorphisms and insertions/deletions in EST data from diploid and polyploid species , 2006, BMC Bioinformatics.

[30]  T. Nilsen,et al.  Expansion of the eukaryotic proteome by alternative splicing , 2010, Nature.

[31]  Gonçalo R. Abecasis,et al.  The Sequence Alignment/Map format and SAMtools , 2009, Bioinform..

[32]  Jialing Yao,et al.  PtFLC homolog from trifoliate orange (Poncirus trifoliata) is regulated by alternative splicing and experiences seasonal fluctuation in expression level , 2009, Planta.

[33]  Peter G Zhang,et al.  Extensive divergence in alternative splicing patterns after gene and genome duplication during the evolutionary history of Arabidopsis. , 2010, Molecular biology and evolution.

[34]  M. Purugganan,et al.  Epistatic interaction between Arabidopsis FRI and FLC flowering time genes generates a latitudinal cline in a life history trait. , 2004, Proceedings of the National Academy of Sciences of the United States of America.

[35]  Qunfeng Dong,et al.  PlantGDB, plant genome database and analysis tools , 2004, Nucleic Acids Res..

[36]  D. Horner,et al.  Molecular and Phylogenetic Analyses of the Complete MADS-Box Transcription Factor Family in Arabidopsis Article, publication date, and citation information can be found at www.plantcell.org/cgi/doi/10.1105/tpc.011544. , 2003, The Plant Cell Online.

[37]  Yi Xing,et al.  Evidence of functional selection pressure for alternative splicingevents that accelerate evolution of protein subsequences , 2005, Genome Biology.

[38]  S. Bergonzi,et al.  Single amino acid change alters the ability to specify male or female organ identity , 2010, Proceedings of the National Academy of Sciences.

[39]  S. Brenner,et al.  Evidence for the widespread coupling of alternative splicing and nonsense-mediated mRNA decay in humans , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[40]  Robert J. Schmitz,et al.  Evolutionary Conservation of the FLOWERING LOCUS C-Mediated Vernalization Response: Evidence From the Sugar Beet (Beta vulgaris) , 2007, Genetics.

[41]  Mitsuyasu Hasebe,et al.  Evolution and divergence of the MADS-box gene family based on genome-wide expression analyses. , 2003, Molecular biology and evolution.

[42]  Yuichiro Watanabe,et al.  Context analysis of termination codons in mRNA that are recognized by plant NMD. , 2007, Plant & cell physiology.

[43]  Rodrigo Lopez,et al.  Clustal W and Clustal X version 2.0 , 2007, Bioinform..

[44]  G. Bonnema,et al.  A naturally occurring splicing site mutation in the Brassica rapa FLC1 gene is associated with variation in flowering time , 2009, Journal of experimental botany.

[45]  L. Lepiniec,et al.  The TRANSPARENT TESTA16 Locus Encodes the ARABIDOPSIS BSISTER MADS Domain Protein and Is Required for Proper Development and Pigmentation of the Seed Coat Article, publication date, and citation information can be found at www.plantcell.org/cgi/doi/10.1105/tpc.004127. , 2002, The Plant Cell Online.

[46]  S. Clough,et al.  Floral dip: a simplified method for Agrobacterium-mediated transformation of Arabidopsis thaliana. , 1998, The Plant journal : for cell and molecular biology.

[47]  Christopher J. Lee,et al.  Alternative splicing in the human, mouse and rat genomes is associated with an increased frequency of exon creation and/or loss , 2003, Nature Genetics.

[48]  Hagen Blankenburg,et al.  The implications of alternative splicing in the ENCODE protein complement , 2007, Proceedings of the National Academy of Sciences.

[49]  V. Brendel,et al.  Genomewide comparative analysis of alternative splicing in plants. , 2006, Proceedings of the National Academy of Sciences of the United States of America.

[50]  Terry Gaasterland,et al.  Alternative splicing of mouse transcription factors affects their DNA-binding domain architecture and is tissue specific , 2004, Genome Biology.

[51]  N. Saitou,et al.  The neighbor-joining method: a new method for reconstructing phylogenetic trees. , 1987, Molecular biology and evolution.

[52]  E. Meyerowitz,et al.  MADS domain proteins in plant development. , 1997, Biological chemistry.

[53]  U. Grossniklaus,et al.  A Bsister MADS-box gene involved in ovule and seed development in petunia and Arabidopsis. , 2006, The Plant journal : for cell and molecular biology.

[54]  W. Stiekema,et al.  Comparative analysis indicates that alternative splicing in plants has a limited role in functional expansion of the proteome , 2009, BMC Genomics.

[55]  Yingzhen Yang,et al.  The K domain mediates heterodimerization of the Arabidopsis floral organ identity proteins, APETALA3 and PISTILLATA. , 2003, The Plant journal : for cell and molecular biology.

[56]  E. Álvarez-Buylla,et al.  An ancestral MADS-box gene duplication occurred before the divergence of plants and animals. , 2000, Proceedings of the National Academy of Sciences of the United States of America.

[57]  Stefan de Folter,et al.  SEPALLATA3: the 'glue' for MADS box transcription factor complex formation , 2009, Genome Biology.

[58]  Jeroen Raes,et al.  And then there were many: MADS goes genomic. , 2003, Trends in plant science.

[59]  H. Saedler,et al.  Mutant analysis, protein–protein interactions and subcellular localization of the Arabidopsis Bsister (ABS) protein , 2005, Molecular Genetics and Genomics.

[60]  Russ B Altman,et al.  Large scale study of protein domain distribution in the context of alternative splicing. , 2003, Nucleic acids research.

[61]  P. Huijser,et al.  Molecular cloning of SVP: a negative regulator of the floral transition in Arabidopsis. , 2000, The Plant journal : for cell and molecular biology.

[62]  David L Robertson,et al.  Choose your partners: dimerization in eukaryotic transcription factors. , 2008, Trends in biochemical sciences.

[63]  Kay Denyer,et al.  Two Paralogous Genes Encoding Small Subunits of ADP-glucose Pyrophosphorylase in Maize, Bt2 and L2, Replace the Single Alternatively Spliced Gene Found in Other Cereal Species , 2007, Journal of Molecular Evolution.

[64]  John Moult,et al.  Structural implication of splicing stochastics , 2009 .

[65]  G. Ast,et al.  Alternative splicing and evolution: diversification, exon definition and function , 2010, Nature Reviews Genetics.

[66]  David Penny,et al.  Functional and evolutionary analysis of alternatively spliced genes is consistent with an early eukaryotic origin of alternative splicing , 2007, BMC Evolutionary Biology.

[67]  Matsumoto,et al.  Rose MADS-box genes 'MASAKO C1 and D1' homologous to class C floral identity genes. , 2000, Plant science : an international journal of experimental plant biology.

[68]  J. Riechmann,et al.  Analysis of the Arabidopsis MADS AFFECTING FLOWERING Gene Family: MAF2 Prevents Vernalization by Short Periods of Cold Article, publication date, and citation information can be found at www.plantcell.org/cgi/doi/10.1105/tpc.009506. Online version contains Web-only data. , 2003, The Plant Cell Online.

[69]  D. Lightfoot,et al.  Evidence for alternative splicing of MADS-box transcripts in developing cotton fibre cells , 2007, Molecular Genetics and Genomics.

[70]  D. Penny,et al.  Patterns of intron loss and gain in plants: intron loss-dominated evolution and genome-wide comparison of O. sativa and A. thaliana. , 2006, Molecular biology and evolution.

[71]  R. Harcourt,et al.  Eucalyptus has functional equivalents of the Arabidopsis AP1 gene , 1997, Plant Molecular Biology.

[72]  Robert D. Finn,et al.  Pfam: clans, web tools and services , 2005, Nucleic Acids Res..

[73]  Yang Wu,et al.  A repressor complex governs the integration of flowering signals in Arabidopsis. , 2008, Developmental cell.

[74]  H. Saedler,et al.  Two ancient classes of MIKC-type MADS-box genes are present in the moss Physcomitrella patens. , 2002, Molecular biology and evolution.

[75]  X. Gu,et al.  Evolution of alternative splicing after gene duplication. , 2005, Genome research.

[76]  Yingzhen Yang,et al.  Defining subdomains of the K domain important for protein–protein interactions of plant MADS proteins , 2004, Plant Molecular Biology.

[77]  F. Salamini,et al.  ZEMa, a member of a novel group of MADS box genes, is alternatively spliced in maize endosperm. , 1995, Nucleic acids research.

[78]  Volker Brendel,et al.  Cross-species EST alignments reveal novel and conserved alternative splicing events in legumes , 2008, BMC Plant Biology.

[79]  A. Hoekema,et al.  A small-scale procedure for the rapid isolation of plant RNAs. , 1989, Nucleic acids research.

[80]  Gregory D. Schuler,et al.  Database resources of the National Center for Biotechnology Information: update , 2004, Nucleic acids research.

[81]  D. Weigel,et al.  Potent Induction of Arabidopsis thaliana Flowering by Elevated Growth Temperature , 2006, PLoS genetics.

[82]  E. Meyerowitz,et al.  Cell-type specific analysis of translating RNAs in developing flowers reveals new levels of control , 2010, Molecular Systems Biology.

[83]  Z. Schwarz‐Sommer,et al.  Evolution in Action: Following Function in Duplicated Floral Homeotic Genes , 2005, Current Biology.

[84]  I. Longden,et al.  EMBOSS: the European Molecular Biology Open Software Suite. , 2000, Trends in genetics : TIG.

[85]  Peer Bork,et al.  Common exon duplication in animals and its role in alternative splicing. , 2002, Human molecular genetics.

[86]  Cajo J. F. ter Braak,et al.  Predicting and understanding transcription factor interactions based on sequence level determinants of combinatorial control , 2008, Bioinform..

[87]  S. Masiero,et al.  INCOMPOSITA: a MADS-box gene controlling prophyll development and floral meristem identity in Antirrhinum , 2004, Development.

[88]  X. Huang,et al.  CAP3: A DNA sequence assembly program. , 1999, Genome research.

[89]  M. Stitt,et al.  Genome-Wide Identification and Testing of Superior Reference Genes for Transcript Normalization in Arabidopsis1[w] , 2005, Plant Physiology.

[90]  S. Brenner,et al.  Duplication, degeneration and subfunctionalization of the nested synapsin-Timp genes in Fugu. , 2003, Trends in genetics : TIG.