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Genetic analysis of ectopic growth suppression during planar growth of integuments mediated by the Arabidopsis AGC protein kinase UNICORN.
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PMID:  23281875     Owner:  NLM     Status:  MEDLINE    
BACKGROUND: The coordination of growth within a tissue layer is of critical importance for tissue morphogenesis. For example, cells within the epidermis undergo stereotypic cell divisions that are oriented along the plane of the layer (planar growth), thereby propagating the layered epidermal structure. Little is known about the developmental control that regulates such planar growth in plants. Recent evidence suggested that the Arabidopsis AGC VIII protein kinase UNICORN (UCN) maintains planar growth by suppressing the formation of ectopic multicellular protrusions in several floral tissues including integuments. In the current model UCN controls this process during integument development by directly interacting with the ABERRANT TESTA SHAPE (ATS) protein, a member of the KANADI (KAN) family of transcription factors, thereby repressing its activity. Here we report on the further characterization of the UCN mechanism.
RESULTS: Phenotypic analysis of flowers of ucn-1 plants impaired in floral homeotic gene activity revealed that any of the four floral whorls could produce organs carrying ucn-1 protrusions. The ectopic outgrowths of ucn integuments did not accumulate detectable signals of the auxin and cytokinin reporters DR5rev::GFP and ARR5::GUS, respectively. Furthermore, wild-type and ucn-1 seedlings showed similarly strong callus formation upon in vitro culture on callus-inducing medium. We also show that ovules of ucn-1 plants carrying the dominant ats allele sk21-D exhibited more pronounced protrusion formation. Finally ovules of ucn-1 ett-1 double mutants and ucn-1 ett-1 arf4-1 triple mutants displayed an additive phenotype.
CONCLUSIONS: These data deepen the molecular insight into the UCN-mediated control of planar growth during integument development. The presented evidence indicates that UCN downstream signaling does not involve the control of auxin or cytokinin homeostasis. The results also reveal that UCN interacts with ATS independently of an ATS/ETT complex required for integument initiation and they further emphasize the necessity to balance UCN and ATS proteins during maintenance of planar growth in integuments.
Balaji Enugutti; Kay Schneitz
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Publication Detail:
Type:  Journal Article; Research Support, Non-U.S. Gov't     Date:  2013-01-02
Journal Detail:
Title:  BMC plant biology     Volume:  13     ISSN:  1471-2229     ISO Abbreviation:  BMC Plant Biol.     Publication Date:  2013  
Date Detail:
Created Date:  2013-01-31     Completed Date:  2013-06-21     Revised Date:  2013-07-11    
Medline Journal Info:
Nlm Unique ID:  100967807     Medline TA:  BMC Plant Biol     Country:  England    
Other Details:
Languages:  eng     Pagination:  2     Citation Subset:  IM    
Entwicklungsbiologie der Pflanzen, Wissenschaftszentrum Weihenstephan, Technische Universität München, Emil-Ramann-Strasse 4, 85354 Freising, Germany.
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MeSH Terms
Arabidopsis / genetics,  growth & development*,  metabolism*
Arabidopsis Proteins / genetics,  metabolism*
Gene Expression Regulation, Plant / genetics,  physiology
Protein-Serine-Threonine Kinases / genetics,  metabolism*
Signal Transduction / genetics,  physiology
Reg. No./Substance:
0/Arabidopsis Proteins; EC Kinases; EC protein, Arabidopsis

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Journal ID (nlm-ta): BMC Plant Biol
Journal ID (iso-abbrev): BMC Plant Biol
ISSN: 1471-2229
Publisher: BioMed Central
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Copyright ©2013 Enugutti and Schneitz; licensee BioMed Central Ltd.
Received Day: 18 Month: 10 Year: 2012
Accepted Day: 17 Month: 12 Year: 2012
collection publication date: Year: 2013
Electronic publication date: Day: 2 Month: 1 Year: 2013
Volume: 13First Page: 2 Last Page: 2
PubMed Id: 23281875
ID: 3560232
Publisher Id: 1471-2229-13-2
DOI: 10.1186/1471-2229-13-2

Genetic analysis of ectopic growth suppression during planar growth of integuments mediated by the Arabidopsis AGC protein kinase UNICORN
Balaji Enugutti1 Email:
Kay Schneitz2 Email:
1Present address: Institute of Molecular Biotechnology of the Austrian Academy of Sciences (IMBA), Dr. Bohr-Gasse 3-5, 1030, Vienna, Austria
2Entwicklungsbiologie der Pflanzen, Wissenschaftszentrum Weihenstephan, Technische Universität München, Emil-Ramann-Strasse 4, 85354, Freising, Germany


In plant tissue morphogenesis the control of cell division patterns is crucial for the establishment and propagation of tissue layers. Spatially restricted asymmetric cell divisions frequently generate new cell layers. Subsequently, symmetric cell divisions maintain a cell layer, often by aligning the division planes along the plane of the layer (planar growth). The regulation of asymmetric cell divisions is under intense scrutiny [1-5]. By contrast, the developmental control of planar growth is largely unknown [6].

There is evidence for a link between the control of adaxial-abaxial polarity and the laminar growth of the leaf blade. Leaves are lateral determinate organs and are characterized by a distinct adaxial-abaxial or dorsal-ventral polarity across the whole multi-layered organ. Outgrowth of the developing leaf lamina is believed to require stimulation of cells located at the adaxial-abaxial boundary [7]. The control of adaxial-abaxial leaf polarity relies on the antagonistic interactions between Class III HD-ZIP and KANADI (KAN) transcription factors [8,9]. Class III HD-ZIP genes promote adaxial identity [10-13] and KAN genes, in conjunction with auxin response factor genes ETTIN (ETT) and ARF4, direct abaxial cell fate and lamina outgrowth in leaves [10,14-16]. Interestingly, defects in the control of adaxial identity can result in localized ectopic blade-like outgrowths on adaxial surface of affected leaves [13,17]. Similarly, it has been observed that misregulation of abaxial leaf polarity can lead to ectopic blade-like outgrowths on the abaxial side of leaves and cotyledons [18,19].

Evidence for a connection between the regulation of adaxial-abaxial polarity and planar growth also comes from studies using Arabidopsis integuments as model system [20,21]. Integuments are lateral determinate tissues of ovules and the progenitors of the seed coat. Arabidopsis ovules develop an inner and outer integument of entirely epidermal origin [22,23]. Upon initiation they form laminar extensions of distinct adaxial-abaxial polarity each consisting of two cell layers of anticlinally dividing cells. The outer integument will grow asymmetrically and eventually envelop the inner integument and the developing embryo sac.

Recently it was discovered that maintenance of planar growth of integuments is under control of UNICORN (UCN) [20,21]. UCN encodes a functional protein kinase that belongs to the AGC2 subclass of the plant-specific AGC VIII family [24-27]. Integuments of recessive ucn mutants exhibit local disorganized growth resulting in the formation of one to several multicellular protrusions containing cells with at least partial integument identity. Similar protrusions are also present on stamens and petals. At the cellular level, the earliest detectable defects are local periclinal or oblique cell divisions in individual cell layers. They are clearly distinct from the typical anticlinal cell divisions that maintain planar growth of integuments. In addition, ucn proembryos show altered cell division planes and double mutants carrying null alleles of UCN and its closest homolog UNICORN-LIKE (UCNL) are embryo lethal. These observations indicated that UCN suppresses ectopic growth by influencing division planes in symmetrically dividing cells.

UCN maintains planar growth during integument outgrowth by interacting with ABERRANT TESTA SHAPE (ATS) [21]. ATS is a KAN gene required for several processes of integument development including, integument boundary formation, inner integument outgrowth and the control of adaxial-abaxial polarity [28-31]. In addition, the ATS protein appears to form a functional complex with the auxin response factor ETTIN (ETT) [32] to control early integument development [33]. Protrusion formation in integuments of ucn ats double mutants is strongly diminished indicating that UCN represses ATS[21]. This negative regulation is likely to occur through physical interaction of the two proteins as ATS transcript levels are unaltered in ucn mutants and recombinant UCN protein is able to phosphorylate ATS in in vitro kinase assays. Moreover, bimolecular fluorescence complementation (BiFC) analysis further supports direct physical interaction between UCN and ATS [21]. Thus, by inhibiting ATS UCN appears to prevent misregulation of transcriptional programs that control planar growth in integuments.

Here we further characterize UCN-mediated maintenance of planar growth during integument development. We provide evidence that UCN functions in an organ-specific manner and that UCN does not influence auxin and cytokinin homeostasis. Our data further suggest that UCN and ATS protein levels must be balanced and that repression of ATS by UCN does not involve either ETT or the ATS/ETT complex.

Results and discussion
UCN functions in an organ- not a whorl-specific manner in floral organogenesis

Flowers carry four different types of floral organs arranged in whorls. In Arabidopsis, sepals occupy whorl 1, petals whorl 2, stamens whorl 3 and carpels including the ovules whorl 4 [34]. According to the ABC model floral organ identity is specified at the whorl level by a set of floral homeotic genes, encoding mostly MADS-domain transcription factors, that act in a combinatorial fashion [35-37]. Interestingly, ucn mutants show protrusions in petals, stamen and ovules (Figure 1B, Figure 2B) [21], however, we never observed protrusions on sepals or carpels. This observation raised the question whether UCN acts in an organ- or whorl-specific manner.

To address this issue we generated a set of double mutants between ucn-1 and several floral homeotic mutants (Figure 1). Flowers of apetala3 (ap3) mutants carry sepals in whorl 2 and carpels in whorl 3 [38]. The second whorl sepals of ucn-1 ap3-3 flowers did not show ucn-like protrusions (Figure 1D), although the second-whorl petals of ucn-1 mutants do, providing first evidence that UCN acts in an organ and not a whorl-specific manner. To test this assumption further we analyzed two additional combinations. Plants with a defect in AGAMOUS (AG) exhibit petals in the third whorl and an additional flower in the fourth whorl [38]. Third-whorl petals of ucn-1 ag-1 still showed protrusions (Figure 1F). In apetala2 (ap2) mutants unfused carpels with ovules and stamens develop in the first whorl and second whorl, respectively [38-40]. Flowers of ucn-1 ap2-8 double mutants were characterized by first-whorl carpels devoid of protrusions but that included ucn-like ovules (Figure 1H). Thus, in particular the phenotypes of ucn-1 ap3-3 and ucn-1 ap2-8 flowers suggest that UCN acts in an organ-specific rather than whorl-specific manner in floral organogenesis.

Outgrowths in ucn-1 integuments develop autonomously of auxin and cytokinin

The maintenance of plant tissue morphogenesis and the prevention of aberrant growth and tumor formation is under hormonal and genetic control [41-43]. For example, callus formation can be induced at non-wounding sites in explants by in vitro auxin and cytokinin treatment [44,45] resulting in masses of partially dedifferentiated cells that resemble root meristem tips [46-48]. Furthermore, defects in PROPORZ1 (PRZ1), encoding a putative component of a chromatin-remodeling complex, result in callus formation upon addition of auxin or cytokinin [49]. In addition, ectopic expression of AINTEGUMENTA (ANT), encoding an AP2-class transcription factor involved in the control of cell division and organ initiation [50-57], results in unorganized cell proliferation in wounded or detached ends of fully differentiated leaves [58]. ANT acts downstream of auxin and regulates meristematic competence during organogenesis [58,59].

To explore the relationship between UCN and auxin as well as cytokinin we tested whether the integument protrusions of ucn-1 expressed the well-characterized reporters DR5rev::GFP or ARR5::GUS that act as proxies for the presence of auxin and cytokinin, respectively [60,61]. We observed DR5rev::GFP signal distribution as reported previously in developing ovules, such as the tip of the ovule primordium or the micropylar end of the young embryo sac [61,62]. Interestingly, however, no signal could be seen in variably advanced protrusions of ucn-1 integuments (Figure 3A-D). ARR5::GUS expression could be observed in the tip of filaments as noted earlier [63]. During ovule development we could also detect a signal in the developing embryo sac. The latter signal is in accordance with the expression pattern of the IPT1::GUS reporter, using the promoter of a cytokinin biosynthesis enzyme [64,65], and the synthetic cytokinin reporter TCSpro::GFP[65,66]. However, we did not observe ARR5::GUS signal in developing protrusions of ucn-1 integuments (Figure 3E-H). These results suggest that ucn-1 integument protrusions do not accumulate auxin or cytokinin, at least not to a level or in a fashion detectable by these two reporters.

To assess further the relationship between UCN and auxin as well as cytokinin we tested whether UCN influences callus formation in seedlings treated with exogenous auxin and cytokinin. However, when comparing wild-type and ucn-1 seedlings grown on callus inducing medium (CIM) we detected no difference in size or number of formed calli (Figure 3I, J) (n = 25). Thus, it appears that UCN does not affect hormone-induced callus formation in this assay.

The reporter-based experiments described above need to be interpreted with caution. Still, the results are also in accordance with previous genetic data. For example, the additive ovule phenotype of ucn bel1 double mutants [21] further supports the notion that ucn integument protrusions develop autonomously of auxin. BEL1 encodes a homeodomain transcription factor required for chalaza development [20,67-69]. Plants lacking BEL1 activity develop ovules carrying large protrusions emanating from the chalaza. Interestingly, young protrusions of bel1 ovules show ectopic expression of a PIN1::PIN1:GFP reporter [65], used to assess the presence of the polar auxin transport facilitator PIN1 [70,71]. Furthermore, bel1 mutants treated with the polar auxin transport inhibitor N-1-naphthylphthalamic acid (NPA) failed to form protrusions. These results indicate that auxin contributes to the formation of bel1 outgrowths [65]. If auxin would play a major role in the induction of outgrowth formation in ucn-1 integuments one might expect enlarged protrusion formation in ucn bel1 double mutants. However, this is not the case, as ucn bel1 double mutants did not show a noticeable increase in protrusion size [21]. In addition, protrusion formation still occurs on petals and stamen in ucn ant double mutants [21].

Available evidence suggests that cytokinin may be of little importance for the control of integument outgrowth. Signaling mediated by the three cytokinin receptor genes CRE1, AHK2, and AHK3[72] appears to be critical for ovule primordium outgrowth [65] and embryo sac development [65,73]. However, these genes appear to play a minor role if any during integument outgrowth as either no defects in integument development [73] or only a frequency of 10 percent of finger-like ovules lacking integuments [65] were reported in strong cre1 ahk2 ahk3 triple mutants. These affected ovules may have still suffered from defects occurring during prior primordium outgrowth. The absence of detectable ARR5::GUS expression in ucn-1 protrusions, consisting of at least partially differentiated integument cells, may thus reflect the minor role of cytokinin in integument outgrowth.

Taken together the available evidence suggests that processes functioning downstream of UCN growth suppression do not involve the regulation of auxin and cytokinin homeostasis.

Relative levels of UCN and ATS are critical for planar growth of integuments

The current model states that UCN maintains planar growth in integuments by directly repressing the activity of the ATS protein implying that the balance between UCN and ATS proteins may be crucial in this process. Previously we could show that an about 45-fold increase of ATS transcript levels within its normal spatial expression domain in the activation tagging mutant sk21-D[74] is accompanied by ucn-like protrusion formation in integuments [21]. This result supports the genetic model that UCN is a negative regulator of ATS. One interpretation of the sk21-D integument phenotype includes the assumption that elevated ATS transcript levels lead to higher than normal amounts of ATS protein, which may titrate out available UCN. If this notion is correct one might expect that upon reduction of UCN function even more exaggerated protrusion formation should take place in sk21-D plants.

To test this notion we performed a genetic gene dosage assay (Figure 2, Table 1). Ovules of ucn-1/+ plants do not show protrusions [21]. Analysis of ovules of sk21-D/+ heterozygous plants revealed less prominent protrusion formation than in ovules of sk21-D homozygous plants (Figure 2C, D). Furthermore, we generated ucn-1 plants that were either heterozygous or homozygous for sk21-D. Indeed ovules of these mutants showed an increase in protrusion formation, both in terms of protrusion size (Figure 2E) and in number of protrusions formed (Figure 2F, Table 1). Strongest effects were seen in ucn-1 sk21-D double mutants. A dosage effect was discernable as ucn-1 plants heterozygous for sk21-D showed an intermediate phenotype compared to ucn-1 or ucn-1 homozygous for sk21-D (Table 1).

Taken together these data support the model that elevated transcript levels of ATS can ultimately lead to out-titration of functional UCN. In addition, they provide further genetic evidence that it is indeed critical to maintain a proper balance between UCN and ATS protein levels in the regulation of planar integument growth.

UCN acts independently of ETT and ARF4 during integument development

Genetic studies indicated that AUXIN RESPONSE FACTOR (ARF) gene ETTIN (ETT) and its closest homolog ARF4 are required for the control of adaxial-abaxial leaf polarity in conjunction with KAN1 and KAN2[16]. Furthermore, the ETT and ATS proteins may physically interact to form a functional complex required for integument development and polarity [33]. Our previous data suggested that UCN maintains planar growth of integuments by negatively regulating the polarity factor ATS through a physical interaction between the two proteins [21]. If interaction between ATS and ETT proteins is crucial for the formation of a functional complex then impairing either protein should result in similar absence of function. As a consequence ats and ett should show a similar genetic behavior with respect to ucn.

To test this hypothesis we generated ucn-1 ett-1 double and ucn-1 ett-1 arf4-1 triple mutants and analyzed their ovule phenotypes (Figure 4). In agreement with a repressive role of UCN on ATS activity ats is epistatic to ucn-1 in ucn-1 ats-3 double mutants [21]. Ovules of ett-1 mutants displayed an ats-like phenotype (Figure 4D) confirming earlier results [33]. Surprisingly, however, ovules of ucn-1 ett-1 double mutants (Figure 4D) or ucn-1 ett-1 arf4-1 triple mutants (Figure 4H) exhibited an additive phenotype. These results suggest that UCN and ETT/ARF4 function in different pathways. They further indicate that UCN does not participate in auxin-related aspects of integument development that involve these two auxin response factors.

Interestingly, the additive ovule phenotype of ucn-1 ett-1 double mutants and ucn-1 ett-1 arf4-1 triple mutants seems not in accordance with the notion of a functional ATS/ETT complex. How can this apparent discrepancy be resolved? At least two models are conceivable. In one scenario the ATS/ETT complex is required throughout integument development and UCN inactivates ATS that is not in a complex with ETT. Alternatively, the ATS/ETT complex is transient and only active during early integument development. Sometime after integument initiation the ATS/ETT complex ceases to be required and dissociates. UCN then interacts with now available free ATS and represses its activity. We favor the latter model as the ATS-dependent protrusions in integuments of ucn-1 or sk21-D mutants first appear once integuments are initiated and continue to outgrow [21].

Both models detailed above imply that ATS protein that is not bound to ETT interferes with the transcriptional programs regulating planar integument growth and must be repressed. Thus, the new genetic data presented above are in agreement with and at the same time refine our current view on the UCN-mediated control of planar integument growth.


Here we provide genetic data that UCN acts in an organ-specific manner during floral development. Furthermore, the repression of ectopic growth by UCN-mediated signaling does not appear to involve a control of auxin or cytokinin homeostasis. UCN-dependent growth suppression is mediated through a repression of ATS and requires a critical balance of both proteins. This repression is independent of a likely earlier-acting ATS/ETT protein complex involved in integument initiation. The presented evidence deepens our understanding of UCN-mediated suppression of ectopic growth. It furthers the link between the control of adaxial-abaxial polarity and planar growth and contributes to a solid experimental and conceptual foundation for further exploration of planar growth control during integument development.

Plant work

Arabidopsis thaliana (L.) Heynh. var. Columbia (Col-0) and var. Landsberg (erecta mutant) (Ler) were used as wild-type strains. Plants were grown essentially as described previously [20]. The following mutants were used: ag-1[38,75]; ap2-8[35], ap3-3[76], arf4-1[16,77,78], ett-1[16,79], sk21-D[74], ucn-1[20,21]. In double-mutant studies respective double mutants were identified based on their phenotypes segregating in a Mendelian fashion. The ucn-1 sk21-D/+ or ucn-1 sk21-D/sk21-D plants were genotyped using primers sk21-D (GT)_F :GAGAATTAGTACAATGTAATG, sk21-D (GT)_R :GTGATTTAACCCTTCTCAAGTGC and pSKI (GT)_F: CCACCCACGAGGAACATCGTG.

In vitro culture and hormone treatment

Seedlings were grown in a growth room under constant light conditions at 23°C. For induction of callus freshly germinated seedlings were grown on MS plates for 6 days. Seedlings were then transferred onto MS plates supplemented with 3 μg/ml each of the auxin 1-naphthalene acetic acid (NAA) (Sigma) and the cytokinin kinetin (Sigma) (callus induction medium, CIM).

Microscopy and art work

Preparation and analysis of samples for light microscopy, scanning electron microscopy, and histochemical localization of β-glucuronidase (GUS) activity in whole-mount tissue was done essentially as described [20,80]. Ovule staining with pseudo-Schiff propidium iodide (mPS-PI) was done as described [81]. Confocal laser scanning microscopy was performed with an Olympus FV1000 setup and FluoView software (Olympus Europa GmbH, Hamburg, Germany) as described previously [21]. Images were adjusted for color and contrast using Adobe Photoshop CS5 (Adobe, San Jose, CA, USA) software.

Authors’ contributions

BE conceived of the study, participated in the design, and carried out experiments. KS conceived of the study, participated in the design and coordination and wrote the manuscript. All authors read and approved the final manuscript.


We thank J. Friml and Alex Christmann for providing the DR5rev::GFP and ARR5::GUS lines, respectively. We also thank J. Lohmann for sending the ett-1 and arf4-1 mutants and members of the Schneitz lab for fruitful discussions. This work was funded by grants SCHN 723/3-1 and SCHN 723/3-2 (KS) from the Deutsche Forschungsgemeinschaft (DFG).

Abrash EB,Bergmann DC,Asymmetric cell divisions: a view from plant developmentDev CellYear: 20091678379610.1016/j.devcel.2009.05.01419531350
Cruz-Ramirez A,Diaz-Trivino S,Blilou I,Grieneisen VA,Sozzani R,Zamioudis C,Miskolczi P,Nieuwland J,Benjamins R,Dhonukshe P,Caballero-Perez J,Horvath B,Long Y,Mahonen AP,Zhang H,Xu J,Murray JA,Benfey PN,Bako L,Maree AF,Scheres B,A bistable circuit involving SCARECROW-RETINOBLASTOMA integrates cues to inform asymmetric stem cell divisionCellYear: 20121501002101510.1016/j.cell.2012.07.01722921914
De Smet I,Beeckman T,Asymmetric cell division in land plants and algae: the driving force for differentiationNat Rev Mol Cell BiolYear: 20111217718810.1038/nrm306421346731
Dhonukshe P,Weits DA,Cruz-Ramirez A,Deinum EE,Tindemans SH,Kakar K,Prasad K,Mahonen AP,Ambrose C,Sasabe M,Wachsmann G,Luijten M,Bennett T,Machida Y,Heidstra R,Wasteneys G,Mulder BM,Scheres B,A PLETHORA-auxin transcription module controls cell division plane rotation through MAP65 and CLASPCellYear: 201214938339610.1016/j.cell.2012.02.05122500804
Petricka JJ,Van Norman JM,Benfey PN,Symmetry breaking in plants: molecular mechanisms regulating asymmetric cell divisions in ArabidopsisCold Spring Harb Perspect BiolYear: 20091a00049710.1101/cshperspect.a00049720066115
Rasmussen CG,Humphries JA,Smith LG,Determination of symmetric and asymmetric division planes in plant cellsAnnu Rev Plant BiolYear: 20116238740910.1146/annurev-arplant-042110-10380221391814
Waites R,Hudson A,phantastica: a gene required for dorsoventrality of leaves in Antirrhinum majusDevelopmentYear: 199512121432154
Husbands AY,Chitwood DH,Plavskin Y,Timmermans MC,Signals and prepatterns: new insights into organ polarity in plantsGenes DevYear: 2009231986199710.1101/gad.181990919723761
Szakonyi D,Moschopoulos A,Byrne ME,Perspectives on leaf dorsoventral polarityJ Plant ResYear: 201012328129010.1007/s10265-010-0336-320369373
Emery JF,Floyd SK,Alvarez J,Eshed Y,Hawker NP,Izhaki A,Baum SF,Bowman JL,Radial patterning of Arabidopsis shoots by class III HD-ZIP and KANADI genesCurr BiolYear: 2003131768177410.1016/j.cub.2003.09.03514561401
McConnell JR,Emery J,Eshed Y,Bao N,Bowman J,Barton MK,Role of PHABULOSA and PHAVOLUTA in determining radial patterning in shootsNatureYear: 200141170971310.1038/3507963511395776
McConnell JR,Barton MK,Leaf polarity and meristem formation in ArabidopsisDevelopmentYear: 1998125293529429655815
Prigge MJ,Otsuga D,Alonso JM,Ecker JR,Drews GN,Clark SE,Class III homeodomain-leucine zipper gene family members have overlapping, antagonistic, and distinct roles in Arabidopsis developmentPlant CellYear: 200517617610.1105/tpc.104.02616115598805
Eshed Y,Baum SF,Perea JV,Bowman J,Establishment of polarity in lateral organs of plantsCurr BiolYear: 2001111251126010.1016/S0960-9822(01)00392-X11525739
Kerstetter RA,Bollman K,Taylor RA,Bomblies K,Poethig RS,KANADI regulates organ polarity in ArabidopsisNatureYear: 200141170670910.1038/3507962911395775
Pekker I,Alvarez JP,Eshed Y,Auxin response factors mediate Arabidopsis organ asymmetry via modulation of KANADI activityPlant CellYear: 2005172899291010.1105/tpc.105.03487616199616
Pinon V,Etchells JP,Rossignol P,Collier SA,Arroyo JM,Martienssen RA,Byrne ME,Three PIGGYBACK genes that specifically influence leaf patterning encode ribosomal proteinsDevelopmentYear: 20081351315132410.1242/dev.01646918305008
Eshed Y,Izhaki A,Baum SF,Floyd SK,Bowman JL,Asymmetric leaf development and blade expansion in Arabidopsis are mediated by KANADI and YABBY activitiesDevelopmentYear: 20041312997300610.1242/dev.0118615169760
Izhaki A,Bowman JL,KANADI and class III HD-Zip gene families regulate embryo patterning and modulate auxin flow during embryogenesis in ArabidopsisPlant CellYear: 20071949550810.1105/tpc.106.04747217307928
Schneitz K,Hülskamp M,Kopczak SD,Pruitt RE,Dissection of sexual organ ontogenesis: a genetic analysis of ovule development in Arabidopsis thalianaDevelopmentYear: 1997124136713769118807
Enugutti B,Kirchhelle C,Oelschner M,Torres Ruiz RA,Schliebner I,Leister D,Schneitz K,Regulation of planar growth by the Arabidopsis AGC protein kinase UNICORNProc Natl Acad Sci USAYear: 2012109150601506510.1073/pnas.120508910922927420
Jenik PD,Irish VF,Regulation of cell proliferation patterns by homeotic genes during Arabidopsis floral developmentDevelopmentYear: 20001271267127610683179
Schneitz K,Hülskamp M,Pruitt RE,Wild-type ovule development in Arabidopsis thaliana: a light microscope study of cleared whole-mount tissue.Plant JYear: 1995773174910.1046/j.1365-313X.1995.07050731.x
Bögre L,Ökrész L,Henriques R,Anthony RG,Growth signalling pathways in Arabidopsis and the AGC protein kinasesTrends Plant SciYear: 2003842443110.1016/S1360-1385(03)00188-213678909
Galván-Ampudia CS,Offringa R,Plant evolution: AGC kinases tell the auxin taleTrends Plant SciYear: 20071254154710.1016/j.tplants.2007.10.00418024140
Hirt H,Garcia AV,Oelmuller R,AGC kinases in plant development and defensePlant Signal BehavYear: 201161030103310.4161/psb.6.7.1558022005000
Zhang Y,McCormick S,AGCVIII kinases: at the crossroads of cellular signalingTrends Plant SciYear: 20091468969510.1016/j.tplants.2009.09.00619818674
Léon-Kloosterziel KM,Keijzer CJ,Koornneef M,A seed shape mutant of Arabidopsis that is affected in integument developmentPlant CellYear: 1994638539212244241
Balasubramanian S,Schneitz K,NOZZLE links proximal-distal and adaxial-abaxial pattern formation during ovule development in Arabidopsis thalianaDevelopmentYear: 20021294291430012183381
McAbee JM,Hill TA,Skinner DJ,Izhaki A,Hauser BA,Meister RJ,Venugopala Reddy G,Meyerowitz EM,Bowman JL,Gasser CS,ABERRANT TESTA SHAPE encodes a KANADI family member, linking polarity determination to separation and growth of Arabidopsis ovule integumentsPlant JYear: 20064652253110.1111/j.1365-313X.2006.02717.x16623911
Kelley DR,Skinner DJ,Gasser CS,Roles of polarity determinants in ovule developmentPlant JYear: 2009571054106410.1111/j.1365-313X.2008.03752.x19054366
Sessions A,Nemhauser JL,McColl A,Roe JL,Feldmann KA,Zambryski PC,ETTIN patterns the Arabidopsis floral meristem and reproductive organsDevelopmentYear: 1997124448144919409666
Kelley DR,Arreola A,Gallagher TL,Gasser CS,ETTIN (ARF3) physically interacts with KANADI proteins to form a functional complex essential for integument development and polarity determination in ArabidopsisDevelopmentYear: 20121391105110910.1242/dev.06791822296848
Smyth DR,Bowman JL,Meyerowitz EM,Early flower development in ArabidopsisPlant CellYear: 199027557672152125
Bowman JL,Smyth DR,Meyerowitz EM,Genetic interactions among floral homeotic genes of ArabidopsisDevelopmentYear: 19911121201685111
Coen ES,Meyerowitz EM,The war of the whorls: genetic interactions controlling flower developmentNatureYear: 1991353313710.1038/353031a01715520
Lohmann JU,Weigel D,Building beauty: the genetic control of floral patterningDev CellYear: 2002213514210.1016/S1534-5807(02)00122-311832239
Bowman JL,Smyth DR,Meyerowitz EM,Genes directing flower development in ArabidopsisPlant CellYear: 1989137522535466
Komaki MK,Okada K,Nishino E,Shimura Y,Isolation and characterization of novel mutants of Arabidopsis thaliana defective in flower developmentDevelopmentYear: 1988104195203
Kunst L,Klenz JE,Martinez-Zapater J,Haughn GW,AP2 gene determines the identity of perianth organs in flowers of Arabidopsis thalianaPlant CellYear: 198911195120812359889
Dodueva IE,Frolova NV,Lutova LA,Plant tumorigenesis: different ways for shifting systemic control of plant cell division and differentiationTransgen Plant JYear: 200711738
Doonan JH,Sablowski R,Walls around tumours - why plants do not develop cancerNat Rev CancerYear: 20101079480210.1038/nrc294220966923
Enugutti B,Kirchhelle C,Schneitz K,On the genetic control of planar growth during tissue morphogenesis in plantsProtoplasmaYear: 201210.1007/s00709-012-0452-0
Skoog F,Miller CO,Chemical regulation of growth and organ formation in plant tissues cultured in vitroSymp Soc Exp BiolYear: 19575411813013486467
Valvekens D,Van Montagu M,Lijsebettens M,Agrobacterium tumefaciens mediated transformation of Arabidopsis thaliana root explants by using kanamycin selectionProc Natl Acad Sci USAYear: 1988855536554010.1073/pnas.85.15.553616593964
Atta R,Laurens L,Boucheron-Dubuisson E,Guivarc'h A,Carnero E,Giraudat-Pautot V,Rech P,Chriqui D,Pluripotency of Arabidopsis xylem pericycle underlies shoot regeneration from root and hypocotyl explants grown in vitroPlant JYear: 20095762664410.1111/j.1365-313X.2008.03715.x18980654
Che P,Lall S,Howell SH,Developmental steps in acquiring competence for shoot development in Arabidopsis tissue culturePlantaYear: 20072261183119410.1007/s00425-007-0565-417581762
Sugimoto K,Jiao Y,Meyerowitz EM,Arabidopsis regeneration from multiple tissues occurs via a root development pathwayDev CellYear: 20101846347110.1016/j.devcel.2010.02.00420230752
Sieberer T,Hauser M-T,Seifert GJ,Luschnig C,PROPORZ1, a putative Arabidopsis transcriptional adaptor protein, mediates auxin and cytokinin signals in the control of cell proliferationCurr BiolYear: 20031383784210.1016/S0960-9822(03)00327-012747832
Elliott RC,Betzner AS,Huttner E,Oakes MP,Tucker WQ,Gerentes D,Perez P,Smyth DR,AINTEGUMENTA, an APETALA2-like gene of Arabidopsis with pleiotropic roles in ovule development and floral organ growthPlant CellYear: 199681551688742707
Klucher KM,Chow H,Reiser L,Fischer RL,The AINTEGUMENTA gene of Arabidopsis required for ovule and female gametophyte development is related to the floral homeotic gene APETALA2Plant CellYear: 199681371538742706
Krizek BA,Prost V,Macias A,AINTEGUMENTA promotes petal identity and acts as a negative regulator of AGAMOUSPlant CellYear: 2000121357136610948255
Krizek BA,AINTEGUMENTA utilizes a mode of DNA recognition distinct from that used by proteins containing a single AP2 domainNucleic Acids ResYear: 2003311859186810.1093/nar/gkg29212655002
Liu Z,Franks RG,Klink VP,Regulation of gynoecium marginal tissue formation by LEUNIG and AINTEGUMENTAPlant CellYear: 2000121879189211041883
Long J,Barton MK,Initiation of axillary and floral meristems in ArabidopsisDev BiolYear: 200021834135310.1006/dbio.1999.957210656774
Nole-Wilson S,Krizek BA,DNA binding properties of the Arabidopsis floral development protein AINTEGUMENTANucleic Acids ResesarchYear: 2000284076408210.1093/nar/28.21.4076
Schneitz K,Baker SC,Gasser CS,Redweik A,Pattern formation and growth during floral organogenesis: HUELLENLOS and AINTEGUMENTA are required for the formation of the proximal region of the ovule primordium in Arabidopsis thalianaDevelopmentYear: 1998125255525639636071
Mizukami Y,Fischer RL,Plant organ size control: AINTEGUMENTA regulates growth and cell numbers during organogenesisProc Natl Acad Sci USAYear: 20009794294710.1073/pnas.97.2.94210639184
Hu Y,Xie Q,Chua NH,The Arabidopsis auxin-inducible gene ARGOS controls lateral organ sizePlant CellYear: 2003151951196110.1105/tpc.01355712953103
Hwang I,Sheen J,Two-component circuitry in Arabidopsis cytokinin signal transductionNatureYear: 200141338338910.1038/3509650011574878
Friml J,Vieten A,Sauer M,Weijers D,Schwarz H,Hamann T,Offringa R,Jürgens G,Efflux-dependent auxin gradients establish the apical-basal axis of ArabidopsisNatureYear: 200342614715310.1038/nature0208514614497
Pagnussat GC,Alandete-Saez M,Bowman JL,Sundaresan V,Auxin-dependent patterning and gamete specification in the Arabidopsis female gametophyteScienceYear: 20093241684168910.1126/science.116732419498110
Baliji S,Lacatus G,Sunter G,The interaction between geminivirus pathogenicity proteins and adenosine kinase leads to increased expression of primary cytokinin-responsive genesVirologyYear: 201040223824710.1016/j.virol.2010.03.02320399479
Miyawaki K,Matsumoto-Kitano M,Kakimoto T,Expression of cytokinin biosynthetic isopentenyltransferase genes in Arabidopsis: tissue specificity and regulation by auxin, cytokinin, and nitratePlant JYear: 20043712813810.1046/j.1365-313X.2003.01945.x14675438
Bencivenga S,Simonini S,Benkova E,Colombo L,The transcription factors BEL1 and SPL are required for cytokinin and auxin signaling during ovule development in ArabidopsisPlant CellYear: 2012242886289710.1105/tpc.112.10016422786869
Müller B,Sheen J,Cytokinin and auxin interaction in root stem-cell specification during early embryogenesisNatureYear: 20084531094109710.1038/nature0694318463635
Robinson-Beers K,Pruitt RE,Gasser CS,Ovule development in wild-type Arabidopsis and two female-sterile mutantsPlant CellYear: 199241237124912297633
Modrusan Z,Reiser L,Feldmann KA,Fischer RL,Haughn GW,Homeotic transformation of ovules into carpel-like structures in ArabidopsisPlant CellYear: 1994633334912244239
Reiser L,Modrusan Z,Margossian L,Samach A,Ohad N,Haughn GW,Fischer RL,The BELL1 gene encodes a homeodomain protein involved in pattern formation in the Arabidopsis ovule primordiumCellYear: 19958373574210.1016/0092-8674(95)90186-88521490
Gälweiler L,Guan C,Müller A,Wisman E,Mendgen K,Yephremov A,Palme K,Regulation of polar auxin transport by AtPIN1 in Arabidopsis vascular tissueScienceYear: 1998282222622309856939
Petrasek J,Mravec J,Bouchard R,Blakeslee JJ,Abas M,Seifertova D,Wisniewska J,Tadele Z,Kubes M,Covanova M,Dhonukshe P,Skupa P,Benkova E,Perry L,Krecek P,Lee OR,Fink GR,Geisler M,Murphy AS,Luschnig C,Zazimalova E,Friml J,PIN proteins ferform a rate-limiting function in cellular auxin effluxScienceYear: 200631291491810.1126/science.112354216601150
Higuchi M,Pischke MS,Mahonen AP,Miyawaki K,Hashimoto Y,Seki M,Kobayashi M,Shinozaki K,Kato T,Tabata S,Helariutta Y,Sussman MR,Kakimoto T,In planta functions of the Arabidopsis cytokinin receptor familyProc Natl Acad Sci USAYear: 20041018821882610.1073/pnas.040288710115166290
Kinoshita-Tsujimura K,Kakimoto T,Cytokinin receptors in sporophytes are essential for male and female functions in Arabidopsis thalianaPlant Signal BehavYear: 20116667110.4161/psb.6.1.1399921301212
Gao P,Li X,Cui D,Wu L,Parkin I,Gruber MY,A new dominant Arabidopsis transparent testa mutant, sk21-D, and modulation of seed flavonoid biosynthesis by KAN4Plant Biotechnol JYear: 2010897999310.1111/j.1467-7652.2010.00525.x20444210
Yanofsky MF,Ma H,Bowman JL,Drews GN,Feldmann KA,Meyerowitz EM,The protein encoded by the Arabidopsis homeotic gene agamous resembles transcription factorsNatureYear: 1990346353910.1038/346035a01973265
Jack T,Brockman LL,Meyerowitz EM,The homeotic gene APETALA3 of Arabidopsis thaliana encodes a MADS box and is expressed in petals and stamensCellYear: 19926868369710.1016/0092-8674(92)90144-21346756
Parinov S,Sevugan M,Ye D,Yang WC,Kumaran M,Sundaresan V,Analysis of flanking sequences from dissociation insertion lines: a database for reverse genetics in ArabidopsisPlant CellYear: 1999112263227010590156
Sundaresan V,Springer P,Volpe T,Haward S,Jones JD,Dean C,Ma H,Martienssen R,Patterns of gene action in plant development revealed by enhancer trap and gene trap transposable elementsGenes DevYear: 199591797181010.1101/gad.9.14.17977622040
Sessions RA,Zambryski PC,Arabidopsis gynoecium structure in the wild and in ettin mutantsDevelopmentYear: 1995121151915327789281
Gross-Hardt R,Lenhard M,Laux T,WUSCHEL signaling functions in interregional communication during Arabidopsis ovule developmentGenes DevYear: 2002161129113810.1101/gad.22520212000795
Truernit E,Bauby H,Dubreucq B,Grandjean O,Runions J,Barthelemy J,Palauqui JC,High-resolution whole-mount imaging of three-dimensional tissue organization and gene expression enables the study of phloem development and structure in ArabidopsisPlant CellYear: 2008201494150310.1105/tpc.107.05606918523061


[Figure ID: F1]
Figure 1 

Phenotypic analysis of ap3 ucn, ag ucn and ap2 ucn flowers. Light micrographs of stage 14 flowers. Arrows indicate protrusions, arrowheads indicate absence of protrusions. (A) Wild-type (Ler). (B) ucn-1. Note the presence of protrusions on petals and stamens but their absence on sepals. (C) ap3-3. One first-whorl sepal was removed to reveal the inner second-whorl sepal. The star indicates a first-whorl sepal. (D) ap3-3 ucn-1 double mutant. Similar setup as in (C). Note the absence of protrusions on the second-whorl sepal. Serrations at the tip of the second-whorl sepal regularly occur in ap3-3 single mutants. (E) ag-1 flower. Star indicates a fourth-whorl sepal. (F) ag-1 ucn-1 double mutant. Protrusions are found on second- and third-whorl petals. (G) ap2-8. First-whorl unfused carpels with ovules are visible. (H) ap2-8 ucn-1. The first-whorl ovules carry protrusions. Scale bars: 0.5 mm.

[Figure ID: F2]
Figure 2 

Ovules of ucn-1 sk21-D mutants show enhanced protrusion formation. Confocal micrographs of early stage 4 ovules stained with pseudo-Schiff propidium iodide (mPS PI) are shown. Arrows indicate protrusions. (A) Wild-type ovule (Ler). (B) ucn-1 ovule. Note the presence of a protrusion. (C) sk21-D/+ ovule. A small protrusion is indicated. (D) sk21-D ovule. (E, F) ucn-1 sk21-D ovules. (E) Note the prominently enlarged protrusion (compare with B, D). (F) Multiple protrusions are detectable. Scale bars: 20 μm.

[Figure ID: F3]
Figure 3 

Hormone-induced callus formation is not affected in ucn-1 seedlings and ucn-1 protrusions do not accumulate detectable DR5rev::GFP and ARR5::GUS reporter signals. (A-D) Confocal micrographs of live wild-type (Ler) and ucn-1 plants carrying the DR5rev::GFP reporter. Overlays of GFP and bright-field channels. No difference in signal detected between wild-type and ucn-1. (A, B) Stage 2-III ovules. (C, D) Stage 3-III ovules. Note the absence of detectable signal in the ucn-1 protrusions (arrows). (E-H) Plants carrying the ARR5::GUS reporter. No difference in signal detected between wild-type and ucn-1. (E, F) Light micrographs of fixed stage 14 flowers (4 h incubation in GUS staining solution). Arrowheads indicate signal at the junction between filament and anther. (G, H) Differential interference contrast micrographs of fixed stage 3-IV ovules (16 h incubation in GUS staining solution). Note the absence of signal in the ucn-1 protrusion (outlined). (I) Light micrograph of a 30-days-old callus grown from germinated wild-type (Ler) seedling grown on callus induction medium (CIM). (J) Light micrograph of a 30-days-old callus grown from germinated ucn-1 seedling grown on CIM. Callus is of comparable size than the one in (I). Scale bars: (A-D): 20 μm, (G, H) 30 μm, (E, F, I, J) 0.5 mm.

[Figure ID: F4]
Figure 4 

Ovules of ucn-1 ett-1 and ucn-1 ett-1 arf4-1 mutants show additive phenotypes. Scanning electron micrographs of early stage 4 ovules are depicted with the exception of (C, F) which show gynoecia of stage 14 flowers. (A) Wild-type ovule. (B) ucn-1 ovule. Arrows highlight protrusions. (C) Typical gynoecium of an ett-1 flower. (D) ett-1 ovule. (E) Additive phenotype of a ucn-1 ett-1 double mutant ovule. Note the protrusions (arrows). (F) Typical gynoecium of an ett-1 arf4-1 flower. (G) ett-1 arf4-1 ovule. Not noticeably different from an ett-1 ovule (compare with D). (H) Additive phenotype of a ucn-1 ett-1 arf4-1 triple mutant ovule. Not noticeably different from a ucn-1 ett-1 double mutant ovule (compare with E). Arrows mark protrusions. Scale bars: 20 μm.

[TableWrap ID: T1] Table 1 

Quantification of protrusion number on ovules of wild-type, ucn-1, sk21-D, and ucn-1 sk21-D mutants

Genotype No. of ovules analyzed No. of ovules with only one protrusion No. of ovules with >1 protrusions % of ovules with protrusions
ucn-1 sk21-D/+
ucn-1 sk21-D 200 34 158 96

Article Categories:
  • Research Article

Keywords: Arabidopsis, Auxin, ABERRANT TESTA SHAPE, AGC protein kinase, AUXIN RESPONSE FACTOR 4, Cell division, Cytokinin, ETTIN, Growth regulation, KANADI, Planar growth, Ovule, Signal transduction, UNICORN.

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