The molecular basis for the initiation of fruit development and parthenocarpy

Vivian-Smith, Adam

January 2001

Parthenocarpy, or seedless fruit development, has an agronomic importance in many horticultural crops. In most fruit, fertilization or seed set usually determines whether fruit growth is sustained. Naturally occurring parthenocarpy results from a genetic lesion that permits fruit to develop in the absence of fertilization and seed development. Parthenocarpy can also be induced artificially with cytokinin, gibberellin or auxin plant growth regulators applied to anthesis pistils. This thesis describes genetic research using Arabidopsis as a model plant to identify integral mechanisms that control parthenocarpy and the initiation of fruit development. The growth and structure of the Arabidopsis pistil was determined post-fertilization. Experiments were designed to understand how plant growth regulators induce Arabidopsis silique (fruit) development in emasculated anthesis stage pistils. Exogenous gibberellin (GA3) induced growth and cellular differentiation most comparable to pollinated pistils. Dependencies on gibberellins during silique development were examined in mutants defective for gibberellin biosynthesis (ga1, ga4-1, ga5-1) or perception (spy-4, gai-1). Although exogenous GAs are effective at inducing parthenocarpy, mutant studies concluded that GAs are not the sole cue for fruit development in Arabidopsis. Mutants blocked in GA perception could develop siliques in response to pollination, auxin, cytokinin but not to exogenously applied gibberellins. Silique structure in pollinated gai-1 and ga5-1 provided strong evidence for a model supporting evidence of an auxin-like signal regulating structural development and that GAs limit anticlinal cellular division. A specialized function for GAI and related GRAS family members in controlling cellular division during fruit development was uncovered. A mutant that forms parthenocarpic siliques without fertilization (fwf), was also characterized. The presence of surrounding floral whorls reduced the extent of parthenocarpic silique formation in fwf. Silique growth in the fwf background was examined when hormone perception, ovule and carpel identity functions were removed genetically. This established that FWF functions independent of GAI-mediated GA perception. Carpel identity conferred by FUL was critical for parthenocarpic silique elongation and ovule development beyond integument initiation, nucellar specification and subsequent morphogenesis, was essential for parthenocarpic silique development in fwf. Silique elongation occurs over a four-day period post-pollination or post-anthesis. This coincides with a similar time period in which fwf ovules remained receptive to fertilization. These observations are congruent with the hypothesis that FWF potentially represses a signal transduction process initiated within the ovule that mediates subsequent transition from carpel to silique development. Further analysis revealed that aberrant testa shape (ats) a mutant defective in integument formation enhanced parthenocarpic development in fwf, indicating that an ovule located repressor other than fwf can function to affect silique formation. Other studies have shown that ethylene can modulate auxin-dependent growth in both aerial and root tissues by altering both polar and lateral auxin transport. The contribution of ethylene perception to signal transduction between ovule and carpel was also genetically assessed. Constitutive ethylene responses, conferred by ctr1-1, enhanced cellular expansion in fwf and also the autonomous silique development in fis-2, which develops autonomous endosperm. ats ctr1-1 and ino ctr1-1 double mutants were also found to be parthenocarpic. This indicates that ethylene perception and integumentary structure play an important role in autonomous silique development, conceivably by changing the polar and lateral movement of an auxin-like signal within the integumentary tissues of the ovule. fwf and ats were fine mapped on chromosome 5 of Arabidopsis. Candidate genes were identified corresponding to both mutations but only the identity of FWF was established. Auxin Response Factor 8 (ARF8) was cloned and sequenced from the fwf mutant background. The gene encodes a protein with a amino-terminal DNA binding domain and a carboxy-terminal protein binding domain which homo- and hetero- dimerizes with other ARF or Aux / IAA class proteins. ARF8 sequence from fwf mutants encoded a mutation in the translation start site. Complementation of fwf plants by the transformation of wild type copies of ARF8 into fwf plants was hampered by reduced transformation efficiency. However wild type L.er and No.O plants transformed with mutant copies of ARF8 were obtained in higher frequency, and these formed parthenocarpic siliques when primary transformants were emasculated. This indicated that an interfering protein is produced from the mutated ARF8 gene that has altered regulatory activity. Sequence analysis indicated this and found that interference resulted from functional activity of the Q-rich and carboxy-terminal domains of the ARF8 protein. This inference is consistent with other published molecular data, which has demonstrated that the carboxy-terminal domain, together with the Q-rich region of selected ARF members, can activate auxin-responses. Thus the FWF / ARF8 protein may have a dual role, repressing carpel growth development through the DNA binding domain and then ensuring activation of silique development through the carboxy-terminal domain. The combined molecular and genetic data has been used to construct models concerning the genetic control of silique development. The first model considers the role of plant hormones and how signals from floral whorls surrounding the carpel and from within the ovule control silique growth. A model is also presented for the control of adaxial growth and development of the outer integument by the INNER NO OUTER gene. Finally the role of FWF and SPY in controlling floral tissue identity and boundary tissue specification is considered in a third model. Modification of the FWF / ARF8 gene could be used as a tool to improve fruit set and retention in horticultural crops, in addition to creating seedless parthenocarpic fruit. / Thesis (Ph.D.)--Agriculture and Wine, 2001.

Biochemical and physiological studies of Arabidopsis thaliana Diacylglycerol Kinase 7 (AtDGK7)

Arana-Ceballos, Fernando Alberto

January 2006

A family of diacylglycerol kinases (DGK) phosphorylates the substrate diacylglycerol (DAG) to generate phosphatidic acid (PA) . Both molecules, DAG and PA, are involved in signal transduction pathways. In the model plant Arabidopsis thaliana, seven candidate genes (named AtDGK1 to AtDGK7) code for putative DGK isoforms. Here I report the molecular cloning and characterization of AtDGK7. Biochemical, molecular and physiological experiments of AtDGK7 and their corresponding enzyme are analyzed. Information from Genevestigator says that AtDGK7 gene is expressed in seedlings and adult Arabidopsis plants, especially in flowers. The AtDGK7 gene encodes the smallest functional DGK predicted in higher plants; but also, has an alternative coding sequence containing an extended AtDGK7 open reading frame, confirmed by PCR and submitted to the GenBank database (under the accession number DQ350135). The new cDNA has an extension of 439 nucleotides coding for 118 additional amino acids The former AtDGK7 enzyme has a predicted molecular mass of ~41 kDa and its activity is affected by pH and detergents. The DGK inhibitor R59022 also affects AtDGK7 activity, although at higher concentrations (i.e. IC50 ~380 µM). The AtDGK7 enzyme also shows a Michaelis-Menten type saturation curve for 1,2-DOG. Calculated Km and Vmax were 36 µM 1,2-DOG and 0.18 pmol PA min-1 mg of protein-1, respectively, under the assay conditions. Former protein AtDGK7 are able to phosphorylate different DAG analogs that are typically found in plants. The new deduced AtDGK7 protein harbors the catalytic DGKc and accessory domains DGKa, instead the truncated one as the former AtDGK7 protein (Gomez-Merino et al., 2005). / Wachstum und Entwicklung sind die Kennzeichen lebender Systeme. Diese Prozesse unterliegen einer strengen Regulation im Organismus. Diacylglycerol (DAG) und Phosphatidsäure (PA) sind wesentliche Elemente in der Signalübertragung in Organismen. In Säugetieren kann DAG auf drei verschiedenen Wegen metabolisiert werden, die Entstehung von PA durch Phosphorylierung der freien Hydroxyl-Gruppe von DAG ist jedoch der am häufigsten vorkommende Stoffwechselweg. Die enzymatische Umsetzung dieser Reaktion wird von der Familie der Diacylglycerol-Kinasen (DGKs) katalysiert. Molekulare und biochemische Untersuchungen konnten die Anwesenheit von DGKs in Drosophila melanogaster, Arabidopsis thaliana und jüngst auch in Dictyostelium discoideum zeigen. In der vorliegenden Arbeit wird die Klonierung und Charakterisierung von AtDGK7 aus Arabidopsis thaliana präsentiert, einem Vertreter des pflanzlichen DGK-Clusters II. Das Transkript von AtDGK7 findet sich in der gesamten Pflanze, jedoch sind die Transkriptmengen in Blüten und jungem Gewebe stark erhöht. Rekombinant hergestelltes AtDGK7 ist katalytisch aktiv und akzeptiert DAG-ähnliche Moleküle mit mindestens einer ungesättigten Fettsäure als bevorzugtes Substrat. AtDGK2, ein weiteres Mitglied der DGK-Familie, und AtDGK7 metabolisieren Substrate, welche in Pflanzen physiologisch relevant sind. Das als DGK-Inhibitor beschriebene Molekül 6-{2-{4-[(4-fluorophenyl)phenylmethylene]-1-piperidinyl}ethyl}-7-methyl-5H-thiazolo(3,2-a)pyrimidine-5-one (R59022) inhibiert bei Konzentrationen von 50-100 µM rekombinant hergestelltes AtDGK2 in vitro. In ähnlichen Konzentrationen eingesetzt modifiziert R59022 das Wurzelwachstum. Dies weist darauf hin, dass DGKs in Entwicklungsprozessen eine Rolle spielen. In in vitro Experimenten wurde AtDGK7 von R59022 allerdings erst in Konzentrationen über 100 µM inhibiert. Ferner wird in der vorliegenden Arbeit die erfolgreiche Klonierung einer cDNA beschrieben, die für AtDGK7 aus A. thaliana kodiert und welche im Vergleich zu der bereits bekannten cDNA um 439 bp länger ist. Expressionsanalysen mit Hilfe eines Promotor-ß-glucuronidase (GUS) Fusions-Produktes zeigten die Aktivität von AtDGK7 in vielen Geweben, vor allem aber in Schließzellen, im Konnektiv-Gewebe der Antheren, sowie besonders in den Spitzen der Seitenwurzeln. Physiologische Untersuchungen unter abiotischem Stress (Verwendung verschiedener Konzentrationen von Stickstoff, Saccharose, Auxin und Inhibitoren von Auxin-Transportern) wurden mit AtDGK7 T-DNA-Insertionslinien sowie mit den Promotor-GUS-Linien durchgeführt. AtDGK7 T-DNA-Insertionslinien zeigten eine starke Inhibierung des Seitenwurzel-Wachstums unter limitierenden Stickstoff- und/oder Saccharose-Konzentrationen. In einigen der T-DNA-Insertionslinien inhibierte die Zugabe eines Inhibitors für Auxin-Transport (TIBA; 2,3,5-triiodobenzoic acid) die Bildung von Haupt- und Seitenwurzeln fast vollständig. Die Inhibition des Wurzelwachstums in den T-DNA-Insertionslinien konnte teilweise durch die Zugabe von 50nM NAA (α-naphtalene acetic acid) revertiert werden. Aus den vorliegenden Ergebnissen wird die Hypothese abgeleitet, dass AtDGK7 im Zusammenspiel mit Auxin in Signaltransduktionsprozessen eine Rolle spielt, welche das Wachstum und die Entwicklung in Pflanzen regulieren.

AtDGK gene

Diacylglycerol

Phosphatidsäure

Diacylglycerol-Kinasen

Signaltransduktionsprozesse

AtDGK genes

auxin

diacylglycerol

phosphatidic acid

signaling

Life sciences

Optimization Of Mature Embryo Based Regeneration And Genetic Transformation Of Turkish Wheat Cultivars

Battal, Abdulhamit

01 September 2010

The objective of this study was to optimize tissue culture, transformation and regeneration parameters of mature embryo based culture of Triticum durum cv. Mirzabey 2000 and Triticum aestivum cv. Y&uuml / regir 89. The effects of auxin type of hormone at different concentrations and dark incubation periods on regeneration capacity were evaluated. Two different hormone types 2,4- dichlorophenoxyacetic acid and picloram were used at three different concentrations 2, 4 and 8 mg/l. Mature embryo derived calli were incubated in 6 different induction media at dark for 4 and 6 weeks for initiation of primary callus induction. After dark incubation periods, average callus fresh weight and primary callus induction rate were determined. The primary callus induction rates for 4 weeks and 6 weeks old dark adapted Mirzabey calli incubated was found to be 91 % and 93.25 % respectively. Y&uuml / regir primary callus induction rate was 92.5 % for 6 weeks old calli in 6W2D medium and 86.75 % for 4 weeks old calli in 4W8P medium. The primary calli were transferred to embryogenic callus induction medium. The embryogenic callus formation was 94.88 in 6W2D medium for Mirzabey cultivar. The necrosis was observed at high concentration of 2,4-D for both of cultivars. After embryogenic callus induction, embryogenic calli were transferred into hormone free regeneration medium. The maximum regeneration rate (62.31 %) and culture efficiency (44.13 %) were observed in 4W2D medium for Mirzabey. However, the low regeneration rate was observed for Y&uuml / regir (5 %) in 6W2D medium. The transformation studies were performed by using Obitek Biolab Gene Transfer System. The old and the modified loading units were used for optimization of bombardment pressure and distance for mature embryo based calli transformation. After bombardment of pAHC25 coated gold particles, histochemical GUS assay was performed and blue spots were counted. The transformation efficiency increased to 0.65 fold for 30 bar bombardment pressure and 5.5 fold for 35 bar bombardment by the modified loading unit. The modified loading unit could be used for further transformation studies.

SB Plant Culture 1-668

Auxin-cytokinin interactions in the control of shoot branching

Shimizu-Sato, Sae, Tanaka, Mina, Mori, Hitoshi, 森, 仁志

03 1900

Open Access Article

Apical dominance

Basipetal auxin flow

Cytokinin oxidase

Pea

PIN1

Shoot branching

Evaluation of auxinic herbicides for broadleaf weed control, tolerance of forage bermudagrass hybrids [Cynodon dactylon (L.) Pers.], and absorption and translocation in common ragweed (Ambrosia artemisiifolia L.)

Moore, Frederick Thomas

29 August 2005

These studies were conducted on several central Texas agricultural producers?? properties, the Stiles Farm Foundation, the Texas Agricultural Experiment Station, and the Texas A&M University campus. First, an experimental herbicide from Dow AgroSciences, GF-884, was evaluated for effectiveness in controlling three annual and three perennial weed species in production pasture lands and hay meadows. Several rates of GF-884 were examined and evaluated against three registered pasture products and one non-selective herbicide. Next, GF-884 was assessed for tolerance on two common bermudagrass hybrids (Cynodon dactylon (L.) Pers.) at three progressive rates with and without adjuvant. Finally, the herbicides, picloram and fluroxypyr, were applied to common ragweed (Ambrosia artemisiifolia L.) to characterize their individual absorption and translocation and assess any influence one might have on the other. GF-884 applied at rates of 0.91 and 1.14 kg a.e./ha provided >85% and >75% control of the annual and perennial weed species evaluated, respectively. These same rates of GF-884 consistently provided control that was equivalent or better than thatachieved with the registered products. No differences were observed among treatments when shoots from the perennial species were evaluated 12 months following treatment application. The tolerance experiments utilized GF-884 at rates twice that used to evaluate weed control efficacy. These elevated rates did not result in discernable influences on yield or forage quality for either hybrid forage grass when compared to untreated areas. The efficacy and tolerance observations suggest that GF-884 applied at the highest recommended weed control rate can effectively control several annual and perennial weed species without imparting detrimental effects to the hybrid bermudagrass being produced. Finally, in the presence of fluroxypyr, 14C picloram absorption was maintained throughout all sampling intervals. Picloram applied alone, maximized 14C absorption at 6 HAT then declined significantly. At the final sampling, 14C from picloram applied alone was in greater concentration in the treated leaf and the root. Picloram significantly decreased absorption of 14C fluroxypyr. Fluroxypyr alone maintained 14C absorption throughout all samplings, whereas the combination maximized at 12 HAT. Initially, picloram limited 14C translocation, however at 6, 12, and 24 HAT this was not evident.

GF-884

aminopyralid

2,4-D

herbicide

auxin

weed control

forage tolerance

absorption

translocation

picloram

fluroxypyr

Studies on submerged cotton fiber growth : induction and characterization, effects of Congo Red and auxin

Feng, Rong

13 May 2015

Induction of growth of submerged cotton (Gossypium hirsutum L.) fibers from cultured ovules has been investigated for the first time. Both exogenous plant hormone levels and the age of the ovules at induction play important roles in induction of submerged cotton fiber growth. The diameter of submerged fibers was about same as that of air-grown fibers but was smaller than that of fibers grown in vivo. Submerged fibers were shorter in the fiber length, stronger in the tensile strength, and they had thicker secondary cell walls and smaller crystallite sizes compared with air-grown fibers and fibers in vivo. Helical secondary cell wall thickenings were exclusively found in submerged fibers. Congo Red is a natural dye that has a high affinity for the biopolymer cellulose. The addition of Congo Red to the culture medium had an influence only on submerged cotton fibers and not on air-grown cotton fibers. When Congo Red was applied in the early primary wall stage, fiber cell elongation was inhibited, but amyloplast production was induced. When Congo Red was applied in late primary wall or early secondary wall stage (about 14-16 DPA), the effects were less severe, but a significant increase in birefringence of secondary cell walls was observed. In both conditions of treatment with Congo Red in the primary wall and the secondary wall stages, a "nodulation" occurred on the wall surface. Neither cellobiohydrolase CBH I or CBH II had affinity for the external wall materials, implying that there was no cellulose present or binding sites for CBH had been occupied by Congo Red. X-ray diffraction data showed that Congo Red decreased the crystallite size of cellulose in submerged cotton fibers. The preliminary investigation with auxin (indole-3-acetic acid) depletion in the culture medium was to study whether or not amyloplasts were produced under this condition. No amyloplasts were observed in submerged fibers grown in the auxindepleted medium, but cellulose microfibrils in the secondary cell wall were greatly disorganized. Possibly, indole-3-acetic acid might play an important role in regulating the arrays of microtubules, which, in turn, may help to organize the patterns of cellulose deposition. / text

Submerged cotton fiber growth

Cotton fiber

Induction

Characterization

Congo Red

Auxin

Effects of extracellular ATP and ADP on growth and development of Arabidopsis seedlings

Tang, Wen-qiang

28 August 2008

Not available / text

Arabidopsis

Auxin--Physiological effect

Identification and Characterization of Pseudomonas syringae Type Three Effectors that Alter Auxin Responses.

Nievas, Maria Soledad

13 January 2014

Plant hormones act in a complex network where their pathways regulate and interact to control different mechanisms, such as development and stress responses. This crosstalk between hormones can be exploited by pathogens to suppress plant defense responses and thereby increase pathogen growth. Pseudomonas syringae pathogenicity is reliant on a Type III secretion system (TTSS) that acts as a specialized injection apparatus to deliver virulence proteins, known as type III effectors (TTEs), into the plant cell cytosol. In my work, I have screened hormone inducible promoter::GUS transgenic Arabidopsis thaliana lines against a P. syringae TTE library in order to identify TTEs involved in the perturbation of hormone signaling in planta. Through this screen I identified two P. syringae TTEs, HopAK1 and HopAL1, both belonging to the same bacterial strain P. syringae pv. maculicola ES4326. I found that HopAK1 can sensitize A. thaliana plants to auxin. On the other hand, HopAL1 activates auxin signaling. Monitoring of auxin signaling was done using transgenic DR5::GUS plants. Both TTEs render the plant susceptible to bacterial infection, highlighting a potential relationship between increased auxin signaling and virulence.

auxin

type three effector

plant hormones

Pseudomonas syringae

high-throughput screening

0480

Identification and Characterization of Pseudomonas syringae Type Three Effectors that Alter Auxin Responses.

Nievas, Maria Soledad

13 January 2014

Plant hormones act in a complex network where their pathways regulate and interact to control different mechanisms, such as development and stress responses. This crosstalk between hormones can be exploited by pathogens to suppress plant defense responses and thereby increase pathogen growth. Pseudomonas syringae pathogenicity is reliant on a Type III secretion system (TTSS) that acts as a specialized injection apparatus to deliver virulence proteins, known as type III effectors (TTEs), into the plant cell cytosol. In my work, I have screened hormone inducible promoter::GUS transgenic Arabidopsis thaliana lines against a P. syringae TTE library in order to identify TTEs involved in the perturbation of hormone signaling in planta. Through this screen I identified two P. syringae TTEs, HopAK1 and HopAL1, both belonging to the same bacterial strain P. syringae pv. maculicola ES4326. I found that HopAK1 can sensitize A. thaliana plants to auxin. On the other hand, HopAL1 activates auxin signaling. Monitoring of auxin signaling was done using transgenic DR5::GUS plants. Both TTEs render the plant susceptible to bacterial infection, highlighting a potential relationship between increased auxin signaling and virulence.

auxin

type three effector

plant hormones

Pseudomonas syringae

high-throughput screening

0480

INTERACTIONS BETWEEN AUXIN AND STRIGOLACTONE IN THE CONTROL OF ARABIDOPSIS SHOOT BRANCHING

Alice Hayward

Unknown Date

Diversity in plant architecture is largely generated by the post-embryonic regulation of meristem initiation and activity. In a phenomenon known as apical dominance, the active growth of the shoot apical meristem (SAM) exerts significant inhibitory force on the outgrowth of axillary meristems (AMs) into shoot branches. The degree of branching in plants is a determinant of yield in many crop species and is carefully regulated to ensure that plants only branch at specific stages of development or in response to their environment. Apical dominance has been attributed to the action of the hormone auxin, produced in SAM tissues and transported downwards. A second hormone, cytokinin, acts antagonistically to auxin to promote branching. Nonetheless, the exact mechanism by which these hormones operate is still being elucidated and continued research suggested that novel signals are involved. The recent discovery that strigolactones, previously implicated in parasitic weed germination and mycorrhizal associations, are branching inhibitors supports the existence of additional signals controlling branching in plants. In garden pea (Pisum sativum) strigolactones are synthesised by the coordinated action of the carotenoid cleavage dioxygenase (CCD) family enzymes, RMS1 (RAMOSUS1) and RMS5. These are encoded by MAX4 (MORE AXILLARY GROWTH4) and MAX3 in Arabidopsis thaliana respectively. Mutants for MAX genes have increased amounts of auxin travelling in the polar auxin transport stream (PATS) of inflorescence stems but exhibit increased branching that is insensitive to inhibition by this auxin. Two hypotheses for the action of strigolactones have been presented. The first is that strigolactones modulate the levels of auxin transport proteins, preventing axillary buds from establishing an active auxin transport flow into the primary stem, which inhibits growth. The second is that strigolactones act downstream of auxin signalling to inhibit the action of outgrowth-promoters. Consistent with this latter hypothesis, in pea, rice (Oryza sativa) and petunia (Petunia hybrida), the expression of RMS1/MAX4 orthologues is auxin regulated. These genes are also regulated by feedback signalling in strigolactone pathway mutants and this is proposed to involve an additional novel signal. In Arabidopsis, however, research showed that MAX4 is not regulated by feedback or auxin in the shoot and placed doubt on the importance of this regulation for branching control. The strigolactone biosynthetic pathway offers a novel target for the manipulation of plant architecture and yield while controlling the germination of parasitic weed species that are detrimental to agriculture. Therefore, a greater understanding of the pathway and its regulators is beneficial. The majority of the research in this thesis pre-dates the discovery of strigolactones as the RMS/MAX-derived branching inhibitor, yet aimed to clarify the evolutionary conservation and functional importance of the regulation of strigolactone biosynthetic genes by auxin and feedback signalling in Arabidopsis. Quantitative real-time PCR analysis demonstrated that MAX3 and MAX4 are co-ordinately and systemically regulated by auxin and by feedback throughout development. Both auxin and feedback regulation required the AXR1/TIR1 auxin response pathway, which targets Aux/IAA transcriptional repressors for proteasomal degradation. In particular, correct degradation of the Aux/IAA protein IAA12 appears to be necessary for optimal MAX3 and MAX4 expression. Moreover this regulation affects strigolactone-dependent branching inhibition. Therefore it is proposed that auxin inhibits branching, in part, by positively regulating strigolactone synthesis. As feedback requires AXR1, this also suggests that increased auxin level and/or signalling in the PATS in conditions of reduced strigolactone signalling mediates feedback regulation of the strigolactone pathway. Consistent with this, microarray analysis revealed that in addition to the inflorescence, max mutants have increased global auxin-responsive gene expression associated with the PATS in the vegetative stage. The pea RMS1 gene was the first strigolactone pathway gene demonstrated to be auxin-regulated. Sequencing of the RMS1 promoter and comparative bioinformatic analysis with promoters of other strigolactone synthesis genes revealed a number of conserved, putative regulatory cis-elements that could mediate this regulation and cross-talk with additional branching cues. However a 2.5 kb fragment of the RMS1 promoter was not sufficient to drive transcriptional and translational fusions with GFP and the RMS1 coding region in Arabidopsis. The RMS1 coding region driven by the CAMV 35S promoter complemented the max4 mutant but did not affect branching induced by auxin-depleting treatments. Grafting studies with axr1 and iaa12 mutants, and decapitation and auxin-transport inhibition in max4 mutants, demonstrated that auxin signalling has a function in branching control independent from the regulation of strigolactone synthesis genes. Overall, data obtained herein was incorporated into current models for the interaction of the strigolactone pathway with auxin and cytokinin in the control of shoot branching. It is suggested that both strigolactone and auxin have the capacity to regulate the levels or distribution of each other in interlocking feedback loop that intersects with additional developmental, physiological and environmental cues for the precise control of axillary branching in plants.

MAX

RMS

BODENLOS/IAA12

Branching

Auxin

Strigolactone

Cytokinin

Pea

Arabidopsis

Transcription