Claudia Canales

Publications (8)75.05 Total impact

• Article: Weeds of change: Cardamine hirsuta as a new model system for studying dissected leaf development.

  Claudia Canales, Michalis Barkoulas, Carla Galinha, Miltos Tsiantis
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  ABSTRACT: Cardamine hirsuta, a small crucifer closely related to the model organism Arabidopsis thaliana, offers high genetic tractability and has emerged as a powerful system for studying the genetic basis for diversification of plant form. Contrary to A. thaliana, which has simple leaves, C. hirsuta produces dissected leaves divided into individual units called leaflets. Leaflet formation requires activity of Class I KNOTTED1-like homeodomain (KNOX) proteins, which also promote function of the shoot apical meristem (SAM). In C. hirsuta, KNOX genes are expressed in the leaves whereas in A. thaliana their expression is confined to the SAM, and differences in expression arise through cis-regulatory divergence of KNOX regulation. KNOX activity in C. hirsuta leaves delays the transition from proliferative growth to differentiation thus facilitating the generation of lateral growth axes that give rise to leaflets. These axes reflect the sequential generation of cell division foci across the leaf proximodistal axis in response to auxin activity maxima, which are generated by the PINFORMED1 (PIN1) auxin efflux carriers in a process that resembles organogenesis at the SAM. Delimitation of C. hirsuta leaflets also requires the activity of CUP SHAPED COTYLEDON (CUC) genes, which direct formation of organ boundaries at the SAM. These observations show how species-specific deployment of fundamental shoot development networks may have sculpted simple versus dissected leaf forms. These studies also illustrate how extending developmental genetic studies to morphologically divergent relatives of model organisms can greatly help elucidate the mechanisms underlying the evolution of form.
  Journal of Plant Research 10/2009; 123(1):25-33. · 1.75 Impact Factor
• Article: Repression of apical homeobox genes is required for embryonic root development in Arabidopsis.

  Stephen P Grigg, Carla Galinha, Noortje Kornet, Claudia Canales, Ben Scheres, Miltos Tsiantis
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  ABSTRACT: Development of seed plant embryos is polarized along the apical-basal axis. This polarization occurs in the absence of cell migration and culminates in the establishment of two distinct pluripotent cell populations: the shoot apical meristem (SAM) and root meristem (RM), which postembryonically give rise to the entire shoot and root systems of the plant. The acquisition of genetic pathways that delimit root from shoot during embryogenesis must have played a pivotal role during land plant evolution because roots evolved after shoots in ancestral vascular plants and may be shoot-derived organs. However, such pathways are very poorly understood. Here we show that RM establishment in the model plant Arabidopsis thaliana requires apical confinement of the Class III HOMEODOMAIN-LEUCINE ZIPPER (HD-ZIP III) proteins PHABULOSA (PHB) and PHAVOLUTA (PHV), which direct both SAM development and shoot lateral organ polarity. Failure to restrict PHB and PHV expression apically via a microRNA-dependent pathway prevents correct elaboration of the embryonic root development program and results in embryo lethality. As such, repression of a fundamental shoot development pathway is essential for correct root development. Additionally, our data suggest that a single patterning process, based on HD-ZIP III repression, mediates both apical-basal and radial polarity in the embryo and lateral organ polarity in the shoot.
  Current biology: CB 08/2009; 19(17):1485-90. · 10.99 Impact Factor
• Article: SERRATE coordinates shoot meristem function and leaf axial patterning in Arabidopsis.

  Stephen P Grigg, Claudia Canales, Angela Hay, Miltos Tsiantis
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  ABSTRACT: Leaves of flowering plants are determinate organs produced by pluripotent structures termed shoot apical meristems. Once specified, leaves differentiate an adaxial (upper) side specialized for light capture, and an abaxial (lower) side specialized for gas exchange. A functional relationship between meristem activity and the differentiation of adaxial leaf fate has been recognized for over fifty years, but the molecular basis of this interaction is unclear. In Arabidopsis thaliana, activity of the class I KNOX (KNOTTED1-like homeobox) genes SHOOTMERISTEMLESS (STM) and BREVIPEDICELLUS (BP) is required for meristem function but excluded from leaves, whereas members of the HD-Zip III (class III homeodomain leucine zipper) protein family function to promote both meristem activity and adaxial leaf fate. Here we show that the zinc-finger protein SERRATE acts in a microRNA (miRNA) gene-silencing pathway to regulate expression of the HD-Zip III gene PHABULOSA (PHB) while also limiting the competence of shoot tissue to respond to KNOX expression. Thus, SERRATE acts to coordinately regulate meristem activity and leaf axial patterning.
  Nature 11/2005; 437(7061):1022-6. · 36.28 Impact Factor
• Article: The formation and patterning of leaves: recent advances.

  Claudia Canales, Stephen Grigg, Miltos Tsiantis
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  ABSTRACT: Leaves, the plant's major photosynthetic organs, form through the activity of groups of pluripotent cells, termed shoot apical meristems (SAMs), located at the growing tips of plants. Leaves develop with a dorso-ventral asymmetry, with the adaxial surface adjacent to the meristem and the abaxial surface developing at a distance from it. Molecular genetic studies have shown that the correct specification of adaxial/abaxial polarity requires communication between the incipient leaf and the meristem, and that the juxtaposition of adaxial/abaxial fates is necessary for lamina outgrowth (Waites and Hudson 1995; McConnell et al. 2001). Over the last few years, a number of factors that control cell fate specification in the apex have been identified. This review will focus on recent advances on distinct but overlapping aspects of leaf development, namely, the transition from meristem to leaf fate and the specification of abaxial/adaxial polarity and its possible role in leaf growth.
  Planta 09/2005; 221(6):752-6. · 3.00 Impact Factor
• Article: VAAMANA--a BEL1-like homeodomain protein, interacts with KNOX proteins BP and STM and regulates inflorescence stem growth in Arabidopsis.

  Anuj M Bhatt, J Peter Etchells, Claudia Canales, Andrey Lagodienko, Hugh Dickinson
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  ABSTRACT: Plant shoot growth depends on the activity of the shoot apical meristem (SAM), where organ primordia are initiated. In turn, the function of the SAM depends on the activities of homeodomain (HD) proteins of the knotted1-like homeobox (KNOX) class [Long et al., Nature 379 (1996) 66; Vollbrecht et al., Development 127 (2000) 3161]. In plants, KNOX proteins have been shown to interact specifically with the BEL1-like (BELL) class of homeodomain proteins [Bellaoui et al., Plant Cell 13 (2001) 2455; Muller et al., Plant 27 (2001) 13; Smith et al., Proc. Natl. Acad. Sci. USA 99 (2002) 9579], through a domain conserved between plants and animals. We have isolated a mutation in a BELL homeobox gene VAAMANA (VAN) that causes a dwarf phenotype. In addition, van inflorescence stems have clusters of cauline leaves; typically three are produced at each node. VAN interacts specifically with the class I KNOX proteins SHOOTMERISTEMLESS (STM), BREVIPEDICELLUS (BP), and KNAT6 (K6), and nuclear localisation of a VAN-GFP fusion depends on co-expression of STM or BP in tobacco leaves. This suggests that localisation of VAN, like that of the animal PBC homeodomain protein [Rieckhof et al., Cell 91 (1997) 171; Berthelsen et al., Genes Dev. 13 (1999) 946], is also regulated by interaction with a partner homeodomain protein.
  Gene 04/2004; 328:103-11. · 2.34 Impact Factor
• Article: EXS, a putative LRR receptor kinase, regulates male germline cell number and tapetal identity and promotes seed development in Arabidopsis.

  Claudia Canales, Anuj M Bhatt, Rod Scott, Hugh Dickinson
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  ABSTRACT: Plant germlines arise late in development from archesporial initials in the L2 layer of the anther and ovule primordia. These cells generate a radially symmetrical array of tissues that, in the Arabidopsis anther, comprises a core of sporogenous cells (meiocytes) and the enveloping tapetum, middle cell, and endothecium layers. The putative transcription factor NZZ/SPL is required for the specification of archesporial cells, but nothing is known of how their number is regulated, or what controls cell fate in the lineages they generate. Here, we report detailed characterization of extra sporogenous cells (exs), a male sterile mutant that generates extra meiocytes but lacks tapetal and middle cell layers. We identified the EXS locus by map-based cloning and found it to encode a putative LRR receptor kinase. In the anther, an increased number of L2 layer cells assume an archesporial fate and divide to generate a larger number of sporogenous cells. In seeds, the exs mutation results in smaller embryonic cells, delayed embryo development, and smaller mature embryos. Consistent with the observed phenotype, EXS is expressed in the inflorescence meristem, floral apices, anthers, and in developing seeds. EXS regulates the number of cells that divide in the L2 layer of the anther, and thus the number of functional male archesporial initials. In the young seed, EXS affects cell size in the embryo and the rate at which it develops. The apparently contrasting roles of EXS in the anther and embryo suggest that signaling through the EXS receptor kinase is a feature of a number of regulatory pathways in Arabidopsis.
  Current Biology 11/2002; 12(20):1718-27. · 9.65 Impact Factor
• Article: Plant meiosis: the means to 1N

  Anuj M Bhatt, Claudia Canales, Hugh G Dickinson
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  ABSTRACT: Meiosis is pivotal in the life history of plants. In addition to providing an opportunity for genetic reassortment, it marks the transition from diploid sporophyte to haploid gametophyte. Recent molecular data suggest that, like animals, plants possess a common set of genes (also conserved in eukaryotic microorganisms) responsible for meiotic recombination and chromosome segregation. However, unlike animals, plant meiocytes do not differentiate from a pool of primordial germ cells, but rather arise de novo from a germline formed from sub-epidermal cells in the anthers and ovules. Mutants defective in the specification of these reproductive cell lines and disrupted in different aspects of the meiotic process are beginning to reveal many features unique to plant meiosis.
  Trends in Plant Science 04/2001; · 11.05 Impact Factor
• Article: VAAMANA—a BEL1-like homeodomain protein, interacts with KNOX proteins BP and STM and regulates inflorescence stem growth in Arabidopsis

  Anuj M. Bhatt, J.Peter Etchells, Claudia Canales, Andrey Lagodienko, Hugh Dickinson
  [show abstract] [hide abstract]
  ABSTRACT: Plant shoot growth depends on the activity of the shoot apical meristem (SAM), where organ primordia are initiated. In turn, the function of the SAM depends on the activities of homeodomain (HD) proteins of the knotted1-like homeobox (KNOX) class [Long et al., Nature 379 (1996) 66; Vollbrecht et al., Development 127 (2000) 3161]. In plants, KNOX proteins have been shown to interact specifically with the BEL1-like (BELL) class of homeodomain proteins [Bellaoui et al., Plant Cell 13 (2001) 2455; Muller et al., Plant 27 (2001) 13; Smith et al., Proc. Natl. Acad. Sci. USA 99 (2002) 9579], through a domain conserved between plants and animals. We have isolated a mutation in a BELL homeobox gene VAAMANA (VAN) that causes a dwarf phenotype. In addition, van inflorescence stems have clusters of cauline leaves; typically three are produced at each node. VAN interacts specifically with the class I KNOX proteins SHOOTMERISTEMLESS (STM), BREVIPEDICELLUS (BP), and KNAT6 (K6), and nuclear localisation of a VAN-GFP fusion depends on co-expression of STM or BP in tobacco leaves. This suggests that localisation of VAN, like that of the animal PBC homeodomain protein [Rieckhof et al., Cell 91 (1997) 171; Berthelsen et al., Genes Dev. 13 (1999) 946], is also regulated by interaction with a partner homeodomain protein.
  Gene.