Structural insights into the interaction between phytoplasmal effector causing phyllody 1 and <scp>MADS</scp> transcription factors

Liao, Yi; Lin, Shih Shun; Lin, San‐Yih; Sun, Wan; Shen, Bo; Cheng, Han Pin; Lin, Chan Pin; Ko, Tzu Ping; Chen, Yi Fan; Wang, Hao Ching

doi:10.1111/tpj.14463

Cited by 19 publications

(31 citation statements)

References 46 publications

(75 reference statements)

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“…The conditions during analytical ultracentrifugation thus may have promoted the dissociation of protein complexes. In line with this view, dimers seemed to be present in the crystals assessed by Liao et al (2019). In fact, employing dynamic light scattering, we found complexes with an apparent molecular mass of ~20 kDa, suggesting that SAP54 predominantly formed homodimers under our experimental conditions (Figure 5a, Table 2).…”

Section: Discussionsupporting

confidence: 83%

“…Taken all three studies together, and considering the high sequence similarity also to other homologous proteins (Figure 1), we have now a pretty good impression about the structure of SAP54-like proteins: it comprises about 90 amino acids that fold into two α-helices connected by a small, unstructured loop. SAP54-like proteins may not have a rigid structure, however; to a certain degree it may depend on environmental conditions, and it may undergo conformational changes upon binding to and release from K-domain (Liao et al 2019). Also the functional relevance of the structure for interaction with target proteins and for causing disease phenotypes is now well documented (this study; Iwabuchi et al, 2019).…”

Section: Discussionmentioning

confidence: 86%

“…While insertions in either the first or second helix abolished the interaction with some MIKC-type MTFs (SEP1 -SEP4), the degradation of SEP3, and the ability to induce disease symptoms (phyllody), insertion in the linker region had no such effects. Likewise, Liao et al (2019) reported that some double amino acid substitutions in both either the first or second helix of PHYL1PnWB abolished the interaction with the K-domain of SEP3 in Y2H experiments. These findings, summarized in Figure 6 strongly corroborate all structure-function relationships involving SAP54 outlined above.…”

Section: Discussionmentioning

confidence: 88%

“…While this manuscript was in preparation, Iwabuchi et al (2019) PHYL1OY shares about 87 % sequence identity with SAP54 ( Figure 1a) and generates similar symptoms in planta, suggesting that both proteins work in very similar ways (Maejima et al, 2014). In contrast, PHYL1PnWB shares only about 53% sequence identity with SAP54 and is hence probably more distantly related than PHYL1OY (Figure 1a; Liao et al, 2019).…”

Section: Discussionmentioning

confidence: 97%

“…It is well known, however, that Y2H experiments are biased against the detection of homodimer formation (Newman et al, 2000;Smirnova et al, 1999), so this conclusion does not appear to be cogent. Liao et al (2019) concluded from sedimentation rates during analytical ultracentrifugation that native PHYL1PnWB exist as a monomer. However, in their kind of experiment they also found monomers (and tetramers) of K-domain fragments of SEP3, whereas in other experiments only dimers and tetramers had been detected (Puranik et al, 2014).…”

Section: Discussionmentioning

confidence: 99%

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Structural requirements of the phytoplasma effector protein SAP54 for causing homeotic transformation of floral organs

Aurin¹,

Haupt

Goerlach

et al. 2019

Preprint

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SIGNIFICANCE STATEMENTPhytoplasmas are bacterial plant pathogens that cause devastating diseases in crops and ornamental plants by the secretion of effector proteins such as SAP54, which leads to the degradation of some floral homeotic proteins. Our study clarifies the structural requirements of SAP54 function and illuminates the molecular mode of interaction and thus may ultimately help to develop treatments against some devastating plant diseases. SummaryPhytoplasmas are intracellular bacterial plant pathogens that cause devastating diseases in crops and ornamental plants by the secretion of effector proteins. One of these effector proteins, termed SECRETED ASTER YELLOWS-WITCHES' BROOM PROTEIN 54 (SAP54), leads to the degradation of a specific subset of floral homeotic proteins of the MIKC-type MADSdomain family via the ubiquitin-proteasome pathway. In consequence, the developing flowers show the homeotic transformation of floral organs into vegetative leaf-like structures. The molecular mechanism of SAP54 action involves physical binding to the keratin-like K-domain of MIKC-type proteins, and to some RAD23 proteins, which translocate ubiquitylated substrates to the proteasome. The structural requirements and specificity of SAP54 function are poorly understood, however. Here we report, based on biophysical and molecular biological analyses, that SAP54 folds into α-helical structures. We also show that the insertion of helixbreaking mutations disrupts correct folding of SAP54, which interferes with the ability of SAP54 to bind to its target proteins and to cause disease phenotypes in vivo. Surprisingly, dynamic light scattering data together with electrophoretic mobility shift assays suggest that SAP54 preferentially binds to multimeric complexes of MIKC-type proteins rather than to dimers or monomers of these proteins. Together with literature data this finding suggests that MIKC-type proteins and SAP54 constitute multimeric α-helical coiled-coils, possibly also involving other partners such as RAD23 proteins. Our investigations clarify the structurefunction relationship of an important phytoplasma effector protein and thus may ultimately help to develop treatments against some devastating plant diseases.

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Section: Discussionsupporting

confidence: 83%

Section: Discussionmentioning

confidence: 86%

Section: Discussionmentioning

confidence: 88%