Parasite co-opts a ubiquitin receptor to induce a plethora of developmental changes

Huang, Weijie; MacLean, Allyson M.; Sugio, Akiko; Maqbool, Abbas; Busscher, Marco; Cho, Soyun; Kamoun, Sophien; Kuo, Chih-Horng; Rg, Immink; Sa, Hogenhout

doi:10.1101/2021.02.15.430920

Cited by 6 publications

(12 citation statements)

References 86 publications

(119 reference statements)

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“…An important feature of phytoplasmas is their ability to modulate host plant development through effectors, which are small secreted proteins (Sugio et al, 2011b; Sugio and Hogenhout, 2012). To date, four phytoplasma effectors have been experimentally characterized, including SAP05 (Gamboa et al, 2019; Huang and Hogenhout, 2019; Huang et al, 2021), SAP11/SWP1 (Bai et al, 2009; Sugio et al, 2011a; Lu et al, 2014; Chang et al, 2018; Wang et al, 2018c, 2018b), SAP54/PHYL1 (MacLean et al, 2011; Maejima et al, 2014; Orlovskis and Hogenhout, 2016), and TENGU (Hoshi et al, 2009; Sugawara et al, 2013; Minato et al, 2014). The expanded genome sequence availability allowed us to investigate the phylogenetic distribution of homologous effector genes among diverse phytoplasmas.…”

Section: Resultsmentioning

confidence: 99%

Comparative Genome Analysis of ‘Candidatus Phytoplasma luffae’ Reveals the Influential Roles of Potential Mobile Units in Phytoplasma Evolution

Huang

Cho

et al. 2021

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Phytoplasmas are insect-transmitted plant pathogens that cause substantial losses in agriculture. In addition to economic impact, phytoplasmas induce distinct disease symptoms in infected plants, thus attracting attention for research on molecular plant-microbe interactions and plant developmental processes. Due to the difficulty of establishing an axenic culture of these bacteria, culture-independent genome characterization is a crucial tool for phytoplasma research. However, phytoplasma genomes have strong nucleotide composition biases and are repetitive, which make it challenging to produce complete assemblies. In this study, we utilized Illumina and Oxford Nanopore sequencing technologies to obtain the complete genome sequence of 'Candidatus Phytoplasma luffae' strain NCHU2019 that is associated with witches' broom disease of loofah (Luffa aegyptiaca) in Taiwan. The fully assembled circular chromosome is 769 kb in size and is the first representative genome sequence of group 16SrVIII phytoplasmas. Comparative analysis with other phytoplasmas revealed that NCHU2019 has an exceptionally repetitive genome, possessing a pair of 75 kb repeats and at least 13 potential mobile units (PMUs) that account for ~25% of its chromosome. This level of genome repetitiveness is exceptional for bacteria, particularly among obligate pathogens with reduced genomes. Our genus-level analysis of PMUs demonstrated that these phytoplasma-specific mobile genetic elements can be classified into three major types that differ in gene organization and phylogenetic distribution. Notably, PMU abundance explains nearly 80% of the variance in phytoplasma genome sizes, a finding that provides a quantitative estimate for the importance of PMUs in phytoplasma genome variability. Finally, our investigation found that in addition to horizontal gene transfer, PMUs also contribute to intra-genomic duplications of effector genes, which may provide redundancy for neofunctionalization or subfunctionalization. Taken together, this work improves the taxon sampling for phytoplasma genome research and provides novel information regarding the roles of mobile genetic elements in phytoplasma evolution.

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Section: Resultsmentioning

confidence: 99%

Comparative Genome Analysis of ‘Candidatus Phytoplasma luffae’ Reveals the Influential Roles of Potential Mobile Units in Phytoplasma Evolution

Huang

Cho

et al. 2021

Preprint

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“…S1). For example, the phytoplasma effector SAP11 interacts with and destabilizes multiple TEOSINTE BRANCHED 1-CYCLOIDEA-PROLIFERATING CELL FACTOR (TCP) transcription factors [36][37][38] , SAP54 directly binds and promotes degradation of MADS domain transcription factor (MTF) family proteins, including SEP3, AP1 or SOC1 39 , and SAP05 directly binds the zinc finger domains of SQUAMOSA promoter-binding proteins (SBP) and GATA domain transcription factors and mediates their degradation 35 . Pseudomonas syringae Type III Effector HopBB1 promotes the degradation of TCP14 by direct binding 40 , and HopX1 eliminates JAZ proteins by cleaving the ZIM domain 41 .…”

Section: Constructing An Rrs1-derived Allele That Represses the Autoactivity Of Rrs1-r Slh1mentioning

confidence: 99%

“…To create this, we selected several effectors and their corresponding targets. SAP05, an effector from insect-transmitted phytopathogenic bacteria, degrades GATA zinc finger domain transcription factor proteins 35 . We fused a GATA SAP05-dependent degron domain to RRS1-R. Co-expression of this fusion protein represses autoimmunity of RRS1-R slh1 ; this is derepressed by coexpression with SAP05, restoring the RRS1-R slh1 -induced-RPS4-dependent hypersensitive response (HR) in transient assays.…”

Section: Introductionmentioning

confidence: 99%

Novel effector recognition capacity engineered into a paired NLR complex

Wang

Huang

Duxbury

et al. 2021

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The Arabidopsis RRS1-R Resistance gene confers recognition of the bacterial acetyltransferase PopP2 and another bacterial effector, AvrRps4. The RRS1-S allele recognizes AvrRps4 but not PopP2. RRS1-R/RRS1-S heterozygotes cannot recognize PopP2. RRS1-R and RRS1-S also suppress the constitutive RPS4-dependent autoactivity of RRS1-Rslh1. Phytoplasmas cause important plant diseases, and their effectors can cause degradation of specific host proteins. We tested whether attaching a pathogen effector-dependent degron to RRS1-R, enabling its degradation by phytoplasma effector SAP05, could derepress RRS1-Rslh1 autoactivity, resulting in SAP05-dependent resistance. In transient assays in tobacco, RRS1-R-derived constructs can confer a hypersensitive response (HR) to SAP05. However, phytoplasma infection assays in transgenic Arabidopsis resulted in delayed disease symptoms but not full resistance. We provide a proof-of-concept strategy utilizing the recessiveness of a plant immune receptor gene to engineer recognition of a pathogen effector that promotes degradation of a specific host protein.

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“…Although the majority of effectors are secreted from salivary glands, effectors may come from other sources as well, including from other organisms. For example, effectors of bacterial plant pathogens such as phytoplasmas promote plant colonization of their insect vectors like leafhoppers, planthoppers, and psyllids (reviewed in Tomkins et al, 2018;Huang et al, 2021). Bemisia tabaci depends on endosymbionts to produce essential amino acids that phloem lacks.…”

Section: Effectors From Other Sourcesmentioning

confidence: 99%

Spotlight on the Roles of Whitefly Effectors in Insect–Plant Interactions

et al. 2021

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The Bemisia tabaci species complex (whitefly) causes enormous agricultural losses. These phloem-feeding insects induce feeding damage and transmit a wide range of dangerous plant viruses. Whiteflies colonize a broad range of plant species that appear to be poorly defended against these insects. Substantial research has begun to unravel how phloem feeders modulate plant processes, such as defense pathways, and the central roles of effector proteins, which are deposited into the plant along with the saliva during feeding. Here, we review the current literature on whitefly effectors in light of what is known about the effectors of phloem-feeding insects in general. Further analysis of these effectors may improve our understanding of how these insects establish compatible interactions with plants, whereas the subsequent identification of plant defense processes could lead to improved crop resistance to insects. We focus on the core concepts that define the effectors of phloem-feeding insects, such as the criteria used to identify candidate effectors in sequence-mining pipelines and screens used to analyze the potential roles of these effectors and their targets in planta. We discuss aspects of whitefly effector research that require further exploration, including where effectors localize when injected into plant tissues, whether the effectors target plant processes beyond defense pathways, and the properties of effectors in other insect excretions such as honeydew. Finally, we provide an overview of open issues and how they might be addressed.

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Parasite co-opts a ubiquitin receptor to induce a plethora of developmental changes

Cited by 6 publications

References 86 publications

Comparative Genome Analysis of ‘Candidatus Phytoplasma luffae’ Reveals the Influential Roles of Potential Mobile Units in Phytoplasma Evolution

Comparative Genome Analysis of ‘Candidatus Phytoplasma luffae’ Reveals the Influential Roles of Potential Mobile Units in Phytoplasma Evolution

Novel effector recognition capacity engineered into a paired NLR complex

Spotlight on the Roles of Whitefly Effectors in Insect–Plant Interactions

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