TY - JOUR A1 - Abdirashid, Hashim A1 - Lenhard, Michael T1 - Say it with double flowers JF - Journal of experimental botany N2 - Every year, lovers world-wide rely on mutants to show their feelings on Valentine's Day. This is because many of the most popular ornamental flowering plants have been selected to form extra petals at the expense of reproductive organs to enhance their attractiveness and aesthetic value to humans. This so-called 'double flower' (DF) phenotype, first described more than 2000 years ago (Meyerowitz et al., 1989) is present, for example, in many modern roses, carnations, peonies, and camellias. Gattolin et al. (2020) now identify a unifying explanation for the molecular basis of many of these DF cultivars. KW - ABCE model KW - APETALA2 KW - double flowers KW - flower development KW - homoeotic KW - mutants KW - microRNA172 Y1 - 2020 U6 - https://doi.org/10.1093/jxb/eraa109 SN - 0022-0957 SN - 1460-2431 VL - 71 IS - 9 SP - 2469 EP - 2471 PB - Oxford Univ. Press CY - Oxford ER - TY - GEN A1 - Bartholomäus, Lisa A1 - Lenhard, Michael T1 - Plant Biology: Learning to Love Yourself T2 - Current biology N2 - In self-incompatible plants the female style rejects self pollen, yet the extent to which the female style in the many self-compatible species can still select between different pollen genotypes and thus bias fertilization success is unclear. A new study identifies the molecular basis for how styles of the self-compatible coyote tobacco bias the fertilization success of pollen genotypes using matching gene expression patterns in a manner analogous to cryptic female choice in animals. Y1 - 2019 U6 - https://doi.org/10.1016/j.cub.2019.06.015 SN - 0960-9822 SN - 1879-0445 VL - 29 IS - 14 SP - R695 EP - R697 PB - Cell Press CY - Cambridge ER - TY - JOUR A1 - Bollier, Norbert A1 - Sicard, Adrien A1 - Leblond, Julie A1 - Latrasse, David A1 - Gonzalez, Nathalie A1 - Gevaudant, Frederic A1 - Benhamed, Moussa A1 - Raynaud, Cecile A1 - Lenhard, Michael A1 - Chevalier, Christian A1 - Hernould, Michel A1 - Delmas, Frederic T1 - At-MINI ZINC FINGER2 and Sl-INHIBITOR OF MERISTEM ACTIVITY, a Conserved Missing Link in the Regulation of Floral Meristem Termination in Arabidopsis and Tomato JF - The plant cell N2 - In angiosperms, the gynoecium is the last structure to develop within the flower due to the determinate fate of floral meristem (FM) stem cells. The maintenance of stem cell activity before its arrest at the stage called FM termination affects the number of carpels that develop. The necessary inhibition at this stage of WUSCHEL (WUS), which is responsible for stem cell maintenance, involves a two-step mechanism. Direct repression mediated by the MADS domain transcription factor AGAMOUS (AG), followed by indirect repression requiring the C2H2 zinc-finger protein KNUCKLES (KNU), allow for the complete termination of floral stem cell activity. Here, we show that Arabidopsis thaliana MINI ZINC FINGER2 (AtMIF2) and its homolog in tomato (Solanum lycopersicum), INHIBITOR OF MERISTEM ACTIVITY (SlIMA), participate in the FM termination process by functioning as adaptor proteins. AtMIF2 and SlIMA recruit AtKNU and SlKNU, respectively, to form a transcriptional repressor complex together with TOPLESS and HISTONE DEACETYLASE19. AtMIF2 and SlIMA bind to the WUS and SIWUS loci in the respective plants, leading to their repression. These results provide important insights into the molecular mechanisms governing (FM) termination and highlight the essential role of AtMIF2/SlIMA during this developmental step, which determines carpel number and therefore fruit size. Y1 - 2018 U6 - https://doi.org/10.1105/tpc.17.00653 SN - 1040-4651 SN - 1532-298X VL - 30 IS - 1 SP - 83 EP - 100 PB - American Society of Plant Physiologists CY - Rockville ER - TY - JOUR A1 - Breuninger, Holger A1 - Lenhard, Michael T1 - Control of tissue and organ growth in plants Y1 - 2010 SN - 0070-2153 ER - TY - GEN A1 - Breuninger, Holger A1 - Lenhard, Michael T1 - Expression of the central growth regulator BIG BROTHER is regulated by multiple cis-elements N2 - Background Much of the organismal variation we observe in nature is due to differences in organ size. The observation that even closely related species can show large, stably inherited differences in organ size indicates a strong genetic component to the control of organ size. Despite recent progress in identifying factors controlling organ growth in plants, our overall understanding of this process remains limited, partly because the individual factors have not yet been connected into larger regulatory pathways or networks. To begin addressing this aim, we have studied the upstream regulation of expression of BIG BROTHER (BB), a central growth-control gene in Arabidopsis thaliana that prevents overgrowth of organs. Final organ size and BB expression levels are tightly correlated, implying the need for precise control of its expression. BB expression mirrors proliferative activity, yet the gene functions to limit proliferation, suggesting that it acts in an incoherent feedforward loop downstream of growth activators to prevent over-proliferation. Results To investigate the upstream regulation of BB we combined a promoter deletion analysis with a phylogenetic footprinting approach. We were able to narrow down important, highly conserved, cis-regulatory elements within the BB promoter. Promoter sequences of other Brassicaceae species were able to partially complement the A. thaliana bb-1 mutant, suggesting that at least within the Brassicaceae family the regulatory pathways are conserved. Conclusions This work underlines the complexity involved in precise quantitative control of gene expression and lays the foundation for identifying important upstream regulators that determine BB expression levels and thus final organ size. T3 - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 374 KW - Asymmetric interlaced PCR KW - Organ Groth KW - DNA Elements KW - Arabidopsis KW - Plants KW - Brassicaceae KW - Phylogeny KW - Database KW - Place KW - Size Y1 - 2017 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-400971 ER - TY - JOUR A1 - Cuong Nguyen Huu, A1 - Kappel, Christian A1 - Keller, Barbara A1 - Sicard, Adrien A1 - Takebayashi, Yumiko A1 - Breuninger, Holger A1 - Nowak, Michael D. A1 - Bäurle, Isabel A1 - Himmelbach, Axel A1 - Burkart, Michael A1 - Ebbing-Lohaus, Thomas A1 - Sakakibara, Hitoshi A1 - Altschmied, Lothar A1 - Conti, Elena A1 - Lenhard, Michael T1 - Presence versus absence of CYP734A50 underlies the style-length dimorphism in primroses JF - eLife N2 - Heterostyly is a wide-spread floral adaptation to promote outbreeding, yet its genetic basis and evolutionary origin remain poorly understood. In Primula (primroses), heterostyly is controlled by the S-locus supergene that determines the reciprocal arrangement of reproductive organs and incompatibility between the two morphs. However, the identities of the component genes remain unknown. Here, we identify the Primula CYP734A50 gene, encoding a putative brassinosteroid-degrading enzyme, as the G locus that determines the style-length dimorphism. CYP734A50 is only present on the short-styled S-morph haplotype, it is specifically expressed in S-morph styles, and its loss or inactivation leads to long styles. The gene arose by a duplication specific to the Primulaceae lineage and shows an accelerated rate of molecular evolution. Thus, our results provide a mechanistic explanation for the Primula style-length dimorphism and begin to shed light on the evolution of the S-locus as a prime model for a complex plant supergene. Y1 - 2016 U6 - https://doi.org/10.7554/eLife.17956 SN - 2050-084X VL - 5 PB - eLife Sciences Publications CY - Cambridge ER - TY - JOUR A1 - Czesnick, Hjördis A1 - Lenhard, Michael T1 - Size Control in Plants-Lessons from Leaves and Flowers JF - Cold Spring Harbor perspectives in biology N2 - To achieve optimal functionality, plant organs like leaves and petals have to grow to a certain size. Beginning with a limited number of undifferentiated cells, the final size of an organ is attained by a complex interplay of cell proliferation and subsequent cell expansion. Regulatory mechanisms that integrate intrinsic growth signals and environmental cues are required to enable optimal leaf and flower development. This review focuses on plant-specific principles of growth reaching from the cellular to the organ level. The currently known genetic pathways underlying these principles are summarized and network connections are highlighted. Putative non-cell autonomously acting mechanisms that might coordinate plant-cell growth are discussed. Y1 - 2015 U6 - https://doi.org/10.1101/cshperspect.a019190 SN - 1943-0264 VL - 7 IS - 8 PB - Cold Spring Harbor Laboratory Press CY - Cold Spring Harbor, NY ER - TY - JOUR A1 - Czesnick, Hjördis A1 - Lenhard, Michael T1 - Antagonistic control of flowering time by functionally specialized poly(A) polymerases in Arabidopsis thaliana JF - The plant journal N2 - Polyadenylation is a critical 3-end processing step during maturation of pre-mRNAs, and the length of the poly(A) tail affects mRNA stability, nuclear export and translation efficiency. The Arabidopsis thaliana genome encodes three canonical nuclear poly(A) polymerase (PAPS) isoforms fulfilling specialized functions, as reflected by their different mutant phenotypes. While PAPS1 affects several processes, such as the immune response, organ growth and male gametophyte development, the roles of PAPS2 and PAPS4 are largely unknown. Here we demonstrate that PAPS2 and PAPS4 promote flowering in a partially redundant manner. The enzymes act antagonistically to PAPS1, which delays the transition to flowering. The opposite flowering-time phenotypes in paps1 and paps2 paps4 mutants are at least partly due to decreased or increased FLC activity, respectively. In contrast to paps2 paps4 mutants, plants with increased PAPS4 activity flower earlier than the wild-type, concomitant with reduced FLC expression. Double mutant analyses suggest that PAPS2 and PAPS4 act independently of the autonomous pathway components FCA, FY and CstF64. The direct polyadenylation targets of the three PAPS isoforms that mediate their effects on flowering time do not include FLC sense mRNA and remain to be identified. Thus, our results uncover a role for canonical PAPS isoforms in flowering-time control, raising the possibility that modulating the balance of the isoform activities could be used to fine tune the transition to flowering. Significance Statement The length of the poly(A) tail affects mRNA stability, nuclear export and translation efficiency. Arabidopsis has three isoforms of nuclear poly(A) polymerase (PAPS): PAPS1 plays a major role in organ growth and plant defence. Here we show that PAPS2 and PAPS4 redundantly promote flowering and act antagonistically to PAPS1, which delays flowering. We suggest that modulating the activity of these isoforms fine-tunes the transition to flowering. KW - polyadenylation KW - 3-end processing KW - poly(A) polymerase KW - flowering time KW - autonomous pathway KW - Arabidopsis thaliana Y1 - 2016 U6 - https://doi.org/10.1111/tpj.13280 SN - 0960-7412 SN - 1365-313X VL - 88 SP - 570 EP - 583 PB - Wiley-Blackwell CY - Hoboken ER - TY - JOUR A1 - Eldridge, Tilly A1 - Langowski, Lukasz A1 - Stacey, Nicola A1 - Jantzen, Friederike A1 - Moubayidin, Laila A1 - Sicard, Adrien A1 - Southam, Paul A1 - Kennaway, Richard A1 - Lenhard, Michael A1 - Coen, Enrico S. A1 - Ostergaard, Lars T1 - Fruit shape diversity in the Brassicaceae is generated by varying patterns of anisotropy JF - Development : Company of Biologists N2 - Fruits exhibit a vast array of different 3D shapes, from simple spheres and cylinders to more complex curved forms; however, the mechanism by which growth is oriented and coordinated to generate this diversity of forms is unclear. Here, we compare the growth patterns and orientations for two very different fruit shapes in the Brassicaceae: the heart-shaped Capsella rubella silicle and the near-cylindrical Arabidopsis thaliana silique. We show, through a combination of clonal and morphological analyses, that the different shapes involve different patterns of anisotropic growth during three phases. These experimental data can be accounted for by a tissue level model in which specified growth rates vary in space and time and are oriented by a proximodistal polarity field. The resulting tissue conflicts lead to deformation of the tissue as it grows. The model allows us to identify tissue-specific and temporally specific activities required to obtain the individual shapes. One such activity may be provided by the valve-identity gene FRUITFULL, which we show through comparative mutant analysis to modulate fruit shape during post-fertilisation growth of both species. Simple modulations of the model presented here can also broadly account for the variety of shapes in other Brassicaceae species, thus providing a simplified framework for fruit development and shape diversity. KW - Brassicaceae KW - Capsella KW - Arabidopsis KW - Fruit shape KW - Modelling KW - Anisotropic growth Y1 - 2016 U6 - https://doi.org/10.1242/dev.135327 SN - 0950-1991 SN - 1477-9129 VL - 143 SP - 3394 EP - 3406 PB - Company of Biologists Limited CY - Cambridge ER - TY - GEN A1 - Eldridge, Tilly A1 - Łangowski, Łukasz A1 - Stacey, Nicola A1 - Jantzen, Friederike A1 - Moubayidin, Laila A1 - Sicard, Adrien A1 - Southam, Paul A1 - Kennaway, Richard A1 - Lenhard, Michael A1 - Coen, Enrico S. A1 - Østergaard, Lars T1 - Fruit shape diversity in the Brassicaceae is generated by varying patterns of anisotropy T2 - Postprints der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe N2 - Fruits exhibit a vast array of different 3D shapes, from simple spheres and cylinders to more complex curved forms; however, the mechanism by which growth is oriented and coordinated to generate this diversity of forms is unclear. Here, we compare the growth patterns and orientations for two very different fruit shapes in the Brassicaceae: the heart-shaped Capsella rubella silicle and the near-cylindrical Arabidopsis thaliana silique. We show, through a combination of clonal and morphological analyses, that the different shapes involve different patterns of anisotropic growth during three phases. These experimental data can be accounted for by a tissue level model in which specified growth rates vary in space and time and are oriented by a proximodistal polarity field. The resulting tissue conflicts lead to deformation of the tissue as it grows. The model allows us to identify tissue-specific and temporally specific activities required to obtain the individual shapes. One such activity may be provided by the valve-identity gene FRUITFULL, which we show through comparative mutant analysis to modulate fruit shape during post-fertilisation growth of both species. Simple modulations of the model presented here can also broadly account for the variety of shapes in other Brassicaceae species, thus providing a simplified framework for fruit development and shape diversity. T3 - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 986 KW - Brassicaceae KW - Capsella KW - arabidopsis KW - fruit shape KW - modelling KW - anisotropic growth Y1 - 2020 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-438041 SN - 1866-8372 IS - 986 SP - 3394 EP - 3406 ER -