Differences in the Endophytic Microbiome of Olive Cultivars Infected by Xylella fastidiosa across Seasons

Giampetruzzi, Annalisa; Baptista, Paula; Morelli, Massimiliano; Cameirão, Cristina; Lino-Neto, Teresa; Costa, Daniela; D’Attoma, Giusy; Kubaa, Raied Abou; Altamura, Giuseppe; Saponari, María; Pereira, José Alberto; Saldarelli, P.

doi:10.3390/pathogens9090723

Cited by 47 publications

(57 citation statements)

References 96 publications

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“…Although assessment and optimization of different DNA extraction protocols should be one of the most important initial steps when developing a protocol for analysis of microbial communities in a new plant niche due to its potential significant influence on the structure and diversity of the recovered community profile (Rubin et al, 2014), for all the studies assessing olive microbiota, this assessment is lacking. Thus, although several studies have described olive endophytic microorganisms either after extraction from xylem woody chips (e.g., Keykhasaber et al, 2017;Anguita-Maeso et al, 2020;Giampetruzzi et al, 2020;Vergine et al, 2020) or from xylem sap when using a pressure chamber (Fausto et al, 2018;Sofo et al, 2019;Anguita-Maeso et al, 2020), none of those studies have examined the influence of DNA extraction kits or choice of primer pairs on microbiota characterization, which might be essential to avoid possible bias on the results.…”

Section: Discussionmentioning

confidence: 99%

Evaluation of Established Methods for DNA Extraction and Primer Pairs Targeting 16S rRNA Gene for Bacterial Microbiota Profiling of Olive Xylem Sap

Haro

Anguita-Maeso

Metsis³

et al. 2021

Front. Plant Sci.

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Next-generation sequencing has revolutionized our ability to investigate the microbiota composition of diverse and complex environments. However, a number of factors can affect the accuracy of microbial community assessment, such as the DNA extraction method, the hypervariable region of 16S rRNA gene targeted, or the PCR primers used for amplification. The aim of this study was to assess the influence of commercially available DNA extraction kits and different primer pairs to provide a non-biased vision of the composition of bacterial communities present in olive xylem sap. For that purpose, branches from “Picual” and “Arbequina” olive cultivars were used for xylem sap extraction using a Scholander chamber device. The DNA extraction protocol significantly affected xylem sap bacterial community assessment. That resulted in significant differences in alpha (Richness) and beta diversity (UniFrac distances) metrics among DNA extraction protocols, with the 12 DNA extraction kits evaluated being clustered in four groups behaving differently. Although the core number of taxa detected by all DNA extraction kits included four phyla, seven classes, 12 orders, 16 or 21 families, and 12 or 14 genera when using the Greengenes or Silva database for taxonomic assignment, respectively, some taxa, particularly those identified at low frequency, were detected by some DNA extraction kits only. The most accurate depiction of a bacterial mock community artificially inoculated on sap samples was generated when using the PowerPlant DNA extraction kit, the combination of 799F/1193R primers amplifying the hypervariable V5–V7 region, and the Silva 132 database for taxonomic assignment. The DESeq2 analysis displayed significant differences among genera abundance between the different PCR primer pairs tested. Thus, Enterobacter, Granulicatella, Prevotella, and Brevibacterium presented a significant higher abundance in all PCR protocols when compared with primer pair 799F/1193R, while the opposite was true for Pseudomonas and Pectobacterium. The methodological approach followed in this study can be useful to optimize plant-associated microbiome analysis, especially when exploring new plant niches. Some of the DNA extraction kits and PCR primers selected in this study will contribute to better characterize bacterial communities inhabiting the xylem sap of olives or other woody crop species.

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Section: Discussionmentioning

confidence: 99%

Evaluation of Established Methods for DNA Extraction and Primer Pairs Targeting 16S rRNA Gene for Bacterial Microbiota Profiling of Olive Xylem Sap

Haro

Anguita-Maeso

Metsis³

et al. 2021

Front. Plant Sci.

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“…In conclusion, the availability of mutants of one of the most virulent strains of X. fastidiosa paves the way for new investigations, aiming to elucidate host–pathogen interactions underpinning the mechanisms of pathogenicity and the differential responses recorded upon the infection of different olive cultivars [ 4 , 88 , 89 , 90 , 91 , 92 ], necessary for the implementation of strategies to mitigate the impact of OQDS.…”

Section: Discussionmentioning

confidence: 99%

Phenotypic Characterization and Transformation Attempts Reveal Peculiar Traits of Xylella fastidiosa Subspecies pauca Strain De Donno

et al. 2020

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Xylella fastidiosa subsp. pauca strain De Donno has been recently identified as the causal agent of a severe disease affecting olive trees in a wide area of the Apulia Region (Italy). While insights on the genetics and epidemiology of this virulent strain have been gained, its phenotypic and biological traits remained to be explored. We investigated in vitro behavior of the strain and compare its relevant biological features (growth rate, biofilm formation, cell–cell aggregation, and twitching motility) with those of the type strain Temecula1. The experiments clearly showed that the strain De Donno did not show fringe on the agar plates, produced larger amounts of biofilm and had a more aggregative behavior than the strain Temecula1. Repeated attempts to transform, by natural competence, the strain De Donno failed to produce a GFP-expressing and a knockout mutant for the rpfF gene. Computational prediction allowed us to identify potentially deleterious sequence variations most likely affecting the natural competence and the lack of fringe formation. GFP and rpfF- mutants were successfully obtained by co-electroporation in the presence of an inhibitor of the type I restriction–modification system. The availability of De Donno mutant strains will open for new explorations of its interactions with hosts and insect vectors.

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“…In our study, 10 keystone bacterial genera could be considered the core microbiome being transmitted from generation to generation in olive, since they were detected in all samples regardless plant propagation procedure ( in vitro vs nursery) or inoculation with the pathogen; with Cutibacterium, Pseudomonas, Anoxybacillus, Staphylococcus, Methylobacterium-Methylorubrum , and Bradyrhizobium being the most abundant, in that order. These bacterial taxa have also been identified in olive xylem in other works in which olive trees of different ages, belonging to different cultivars or growing under different environments were evaluated (Müller et al 2015; Fausto et al, 2018; Sofo et al, 2019; Anguita-Maeso et al, 2020; Giampetruzzi et al, 2020) which strength the hypothesis that those genera may represent keystone olive xylem bacteria. More interestingly, some of these genera have been already reported or used as plant growth promoting bacteria (Otieno et al, 2015; Subramanian et al, 2015) or as biological control agents against V. dahliae (Berg et al, 2002, 2006).…”

Section: Discussionmentioning

confidence: 64%

“…The role of microorganisms in the biocontrol of Verticillium wilt diseases has been reported mostly on non-woody plant species such as cotton, potato, strawberry or tomato (Azad et al, 1985; Nallanchakravarthula et al, 2014; Cao et al, 2016; Wei et al, 2019; Snelders et al, 2020) with few studies focused on woody hosts including olive (Mercado-Blanco et al, 2004; Aranda et al, 2011; Gómez-Lama Cabanás et al, 2018). However, the characterization of microbial communities inhabiting xylem vessels colonized by Vd has not been studied to date, despite some work done on other tree species or other vascular pathogens (Martín et al, 2015; Pérez-Martínez et al, 2018; Giampetruzzi et al, 2020; Vergine et al, 2020). To the best of our knowledge, this present study is the first to address this knowledge gap, by determining changes in xylem bacterial communities of a resistant olive clone after challenge inoculation with D Vd .…”

Section: Discussionmentioning

confidence: 99%

Verticillium dahliaeinoculation andin vitropropagation modify the xylem microbiome and disease reaction to Verticillium wilt in a wild olive genotype

Anguita-Maeso

Trapero-Casas

Olivares-García

et al. 2020

Preprint

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Host resistance is the most practical, long-term and economically efficient disease control measure for Verticillium wilt in olive caused by the xylem-invading fungus Verticillium dahliae (Vd), and it is at the core of the integrated disease management. Plant’s microbiome at the site of infection may have an influence on the host reaction to pathogens; however, the role of xylem microbial communities in the olive resistance to Vd has been overlooked and remain unexplored to date. This research was focused on elucidating whether in vitro olive propagation may alter the diversity and composition of the xylem-inhabiting microbiome and if those changes may modify the resistance response that a wild olive clone shows to the highly virulent defoliating (D) pathotype of Vd. Results indicated that although there were differences in microbial communities among the different propagation methodologies, most substantial changes occurred when plants were inoculated with Vd, regardless whether the infection process took place, with a significant increase in the diversity of bacterial communities when the pathogen was present in the soil. Furthermore, it was noticeable that olive plants multiplied under in vitro conditions developed a susceptible reaction to D Vd, characterized by severe wilting symptoms and 100% vascular infection. Moreover, those in vitro propagated plants showed an altered xylem microbiome with a decrease in total OTU numbers as compared to that of plants multiplied under non-aseptic conditions. Overall, 10 keystone bacterial genera were detected in olive xylem regardless infection by Vd and the propagation procedure of plants (in vitro vs nursery), with Cutibacterium (36.85%), Pseudomonas (20.93%), Anoxybacillus (6.28%), Staphylococcus (4.95%), Methylobacterium-Methylorubrum (3.91%), and Bradyrhizobium (3.54%) being the most abundant. Pseudomonas spp. appeared as the most predominant bacterial group in micropropagated plants and Anoxybacillus appeared as a keystone bacterium in Vd-inoculated plants irrespective of their propagation process. Our results are first to show a breakdown of resistance to Vd in a wild olive that potentially maybe related to a modification of its xylem microbiome, and will help to expand our knowledge of the role of indigenous xylem microbiome on host resistance which can be of use to fight against main vascular diseases of olive.

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Differences in the Endophytic Microbiome of Olive Cultivars Infected by Xylella fastidiosa across Seasons

Cited by 47 publications

References 96 publications

Evaluation of Established Methods for DNA Extraction and Primer Pairs Targeting 16S rRNA Gene for Bacterial Microbiota Profiling of Olive Xylem Sap

Evaluation of Established Methods for DNA Extraction and Primer Pairs Targeting 16S rRNA Gene for Bacterial Microbiota Profiling of Olive Xylem Sap

Phenotypic Characterization and Transformation Attempts Reveal Peculiar Traits of Xylella fastidiosa Subspecies pauca Strain De Donno

Verticillium dahliaeinoculation andin vitropropagation modify the xylem microbiome and disease reaction to Verticillium wilt in a wild olive genotype

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