Phytoplasma Effector SAP54 Hijacks Plant Reproduction by Degrading MADS-box Proteins and Promotes Insect Colonization in a RAD23-Dependent Manner

MacLean, Allyson M.; Orlovskis, Zigmunds; Kowitwanich, Krissana; Zdziarska, Anna Maria; Angenent, Gerco C.; Immink, Richard G. H.; Hogenhout, Saskia A.

doi:10.1371/journal.pbio.1001835

Cited by 200 publications

(245 citation statements)

References 55 publications

(74 reference statements)

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“…One characteristic phenotype ('phyllody') of phytoplasma-infected plants from diverse species, including A. thaliana, resembles the phenotype of class E floral homeotic mutants, with floral organs unable to develop proper floral organ identity. This was recently shown to be due to proteasome-mediated degradation of the class A and E floral homeotic proteins AP1, CAULIFLOWER (CAL) and SEP3, which is initiated by interaction of the floral homeotic proteins with phytoplasma-secreted effector proteins termed SAP54 or PHYL1 (Maejima et al, 2014;MacLean et al, 2014). An in silico study suggests that the PHYL1 structure resembles that of the K domain, thus facilitating dimerization between some floral homeotic proteins and PHYL1 (Rümpler et al, 2015).…”

Section: The Fqm As Guiding Model In Current Researchmentioning

confidence: 99%

MADS-domain transcription factors and the floral quartet model of flower development: linking plant development and evolution

2016

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The floral quartet model of floral organ specification poses that different tetramers of MIKC-type MADS-domain transcription factors control gene expression and hence the identity of floral organs during development. Here, we provide a brief history of the floral quartet model and review several lines of recent evidence that support the model. We also describe how the model has been used in contemporary developmental and evolutionary biology to shed light on enigmatic topics such as the origin of land and flowering plants. Finally, we suggest a novel hypothesis describing how floral quartetlike complexes may interact with chromatin during target gene activation and repression.

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Section: The Fqm As Guiding Model In Current Researchmentioning

confidence: 99%

MADS-domain transcription factors and the floral quartet model of flower development: linking plant development and evolution

2016

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“…Moreover, the miRNA expression patterns of PHYL1 plants (PHYL1 of PnWB) were also consistent with those of SAP54 plants. SAP54 and PHYL1 of onion yellows phytoplasma plants mediate AtAP1, AtSEP3, and AtCAL proteasomal degradation (MacLean et al, 2014;Maejima et al, 2014); therefore, MTF degradation might result in abnormal miRNA expression. These results indicate that these effectors contain common motif(s) for triggering leafy flower formation and altering miRNA expression.…”

Section: The Effectors Of Pnwb Alter Gene and Mirna Expression In Hosmentioning

confidence: 99%

“…These MTFs are key regulators in floral development and were triggered by SAP54/ PHYL1-mediated ubiquitin/26S proteasomal degradation by interacting with the RADIATION SENSITIVE23 (RAD23) family, resulting in interference in floral homeotic gene expression levels (MacLean et al, 2014;Maejima et al, 2014). Consistently, the ap1 mutant, ap1/cal double mutant, and sep1/sep2/sep3/sep4 quadruple mutant manifest various types of leafy flower (e.g.…”

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confidence: 97%

“…PHYL1 and SAP54 interact with MADS domain transcription factors (MTFs) in Arabidopsis, such as SEPALLATA3 (AtSEP3), APETALA1 (AtAP1), and CAULIFLOWER (AtCAL; MacLean et al, 2014;Maejima et al, 2014). These MTFs are key regulators in floral development and were triggered by SAP54/ PHYL1-mediated ubiquitin/26S proteasomal degradation by interacting with the RADIATION SENSITIVE23 (RAD23) family, resulting in interference in floral homeotic gene expression levels (MacLean et al, 2014;Maejima et al, 2014).…”

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confidence: 99%

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MicroRNA396-Targeted SHORT VEGETATIVE PHASE Is Required to Repress Flowering and Is Related to the Development of Abnormal Flower Symptoms by the Phyllody Symptoms1 Effector

Yang

Huang²,

Lin³

et al. 2015

Plant Physiol.

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ORCID IDs: 0000-0002-9951-687X (C.-P.L.); 0000-0002-7295-5004 (S.-S.L.).Leafy flowers are the major symptoms of peanut witches' broom (PnWB) phytoplasma infection in Catharanthus roseus. The orthologs of the phyllody symptoms1 (PHYL1) effector of PnWB from other species of phytoplasma can trigger the proteasomal degradation of several MADS box transcription factors, resulting in leafy flower formation. In contrast, the flowering negative regulator gene SHORT VEGETATIVE PHASE (SVP) was up-regulated in PnWB-infected C. roseus plants, but most microRNA (miRNA) genes had repressed expression. Coincidentally, transgenic Arabidopsis (Arabidopsis thaliana) plants expressing the PHYL1 gene of PnWB (PHYL1 plants), which show leafy flower phenotypes, up-regulate SVP of Arabidopsis (AtSVP) but repress a putative regulatory miRNA of AtSVP, miR396. However, the mechanism by which PHYL1 regulates AtSVP and miR396 is unknown, and the evidence of miR396-mediated AtSVP degradation is lacking. Here, we show that miR396 triggers AtSVP messenger RNA (mRNA) decay using genetic approaches, a reporter assay, and high-throughput degradome profiles. Genetic evidence indicates that PHYL1 plants and atmir396a-1 mutants have higher AtSVP accumulation, whereas the transgenic plants overexpressing MIR396 display lower AtSVP expression. The reporter assay indicated that target-site mutation results in decreasing the miR396-mediated repression efficiency. Moreover, degradome profiles revealed that miR396 triggers AtSVP mRNA decay rather than miRNA-mediated cleavage, implying that AtSVP caused miR396-mediated translation inhibition. We hypothesize that PHYL1 directly or indirectly interferes with miR396-mediated AtSVP mRNA decay and synergizes with other effects (e.g. MADS box transcription factor degradation), resulting in abnormal flower formation. We anticipate our findings to be a starting point for studying the posttranscriptional regulation of PHYL1 effectors in symptom development.

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“…12,14,15 Phyllogens interact with and degrade some MADS TFs, including SEP3 of Arabidopsis. 15,16 However, it is unknown whether the other 3 class E proteins (SEP1, SEP2, and SEP4) of Arabidopsis are also degraded by phyllogens, though their interactions with a phyllogen were shown in a yeast 2-hybrid assay. 16 It is also interesting from the perspective of the phylogenetic differences between SEP Keywords: Arabidopsis, floral development, MADS transcription factors, phyllody, phyllogen, phytoplasma, SEPALLATA genes: in an evolutionary analysis of SEP gene sub-family, SEP3 and the other 3 SEP genes of Arabidopsis were divided into 2 different clades.…”

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confidence: 99%

Degradation of class E MADS-domain transcription factors in Arabidopsis by a phytoplasmal effector, phyllogen

Maejima

Kitazawa

Tomomitsu

et al. 2015

Plant Signaling & Behavior

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Phytoplasma Effector SAP54 Hijacks Plant Reproduction by Degrading MADS-box Proteins and Promotes Insect Colonization in a RAD23-Dependent Manner

Abstract: The phytoplasma bacterial plant parasite depends on leafhopper insects to spread and propagate itself. This study reveals how phytoplasma subverts plant development to turn flowers into leaves and thus make its host more attractive to leafhoppers.

Cited by 200 publications

References 55 publications

MADS-domain transcription factors and the floral quartet model of flower development: linking plant development and evolution

MADS-domain transcription factors and the floral quartet model of flower development: linking plant development and evolution

MicroRNA396-Targeted SHORT VEGETATIVE PHASE Is Required to Repress Flowering and Is Related to the Development of Abnormal Flower Symptoms by the Phyllody Symptoms1 Effector

Degradation of class E MADS-domain transcription factors in Arabidopsis by a phytoplasmal effector, phyllogen

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