Your search keyword '"plant microbiota"' showing total 5 results

1. Lipopolysaccharide O-antigen molecular and supramolecular modifications of plant root microbiota are pivotal for host recognition

Author

Ministero dell'Istruzione, dell'Università e della Ricerca, European Commission, Science and Technology Facilities Council (UK), Ministerio de Ciencia, Innovación y Universidades (España), Instituto de Salud Carlos III, German Research Foundation, Vanacore, Adele, Vitiello, Giuseppe, Wanke, Alan, Cavasso, Domenico, Clifton, Luke A, Mahdi, Lisa, Campanero-Rhodes, María Asunción, Solís, Dolores, Wuhrer, Manfred, Nicolardi, Simone, Molinaro, Antonio, Marchetti, Roberta, Zuccaro, Alga, Paduano, Luigi, Silipo, Alba, Ministero dell'Istruzione, dell'Università e della Ricerca, European Commission, Science and Technology Facilities Council (UK), Ministerio de Ciencia, Innovación y Universidades (España), Instituto de Salud Carlos III, German Research Foundation, Vanacore, Adele, Vitiello, Giuseppe, Wanke, Alan, Cavasso, Domenico, Clifton, Luke A, Mahdi, Lisa, Campanero-Rhodes, María Asunción, Solís, Dolores, Wuhrer, Manfred, Nicolardi, Simone, Molinaro, Antonio, Marchetti, Roberta, Zuccaro, Alga, Paduano, Luigi, and Silipo, Alba

Abstract

Lipopolysaccharides, the major outer membrane components of Gram-negative bacteria, are crucial actors of the host-microbial dialogue. They can contribute to the establishment of either symbiosis or bacterial virulence, depending on the bacterial lifestyle. Plant microbiota shows great complexity, promotes plant health and growth and assures protection from pathogens. How plants perceive LPS from plant-associated bacteria and discriminate between beneficial and pathogenic microbes is an open and urgent question. Here, we report on the structure, conformation, membrane properties and immune recognition of LPS isolated from the Arabidopsis thaliana root microbiota member Herbaspirillum sp. Root189. The LPS consists of an O-methylated and variously acetylated D-rhamnose containing polysaccharide with a rather hydrophobic surface. Plant immunology studies in A. thaliana demonstrate that the native acetylated O-antigen shields the LPS from immune recognition whereas the O-deacylated one does not. These findings highlight the role of Herbaspirillum LPS within plant-microbial crosstalk, and how O-antigen modifications influence membrane properties and modulate LPS host recognition.

Published

2021

2. Effect of Washing, Waxing and Low-Temperature Storage on the Postharvest Microbiome of Apple

Author

Abdelfattah, Ahmed, Whitehead, Susan R., Macarisin, Dumitru, Liu, Jia, Burchard, Erik, Freilich, Shiri, Dardick, Christopher, Droby, Samir, Wisniewski, Michael, Abdelfattah, Ahmed, Whitehead, Susan R., Macarisin, Dumitru, Liu, Jia, Burchard, Erik, Freilich, Shiri, Dardick, Christopher, Droby, Samir, and Wisniewski, Michael

Abstract

There is growing recognition of the role that the microbiome plays in the health and physiology of many plant species. However, considerably less research has been conducted on the postharvest microbiome of produce and the impact that postharvest processing may have on its composition. Here, amplicon sequencing was used to study the effect of washing, waxing, and low-temperature storage at 2 degrees C for six months on the bacterial and fungal communities of apple calyx-end, stem-end, and peel tissues. The results of the present work reveal that tissue-type is the main factor defining fungal and bacterial diversity and community composition on apple fruit. Both postharvest treatments and low temperature storage had a strong impact on the fungal and bacterial diversity and community composition of these tissue types. Distinct spatial and temporal changes in the composition and diversity of the microbiota were observed in response to various postharvest management practices. The greatest impact was attributed to sanitation practices with major differences among unwashed, washed and washed-waxed apples. The magnitude of the differences, however, was tissue-specific, with the greatest impact occurring on peel tissues. Temporally, the largest shift occurred during the first two months of low-temperature storage, although fungi were more affected by storage time than bacteria. In general, fungi and bacteria were impacted equally by sanitation practices, especially the epiphytic microflora of peel tissues. This research provides a foundation for understanding the impact of postharvest management practices on the microbiome of apple and its potential subsequent effects on postharvest disease management and food safety.

Published

2020

3. Effect of Washing, Waxing and Low-Temperature Storage on the Postharvest Microbiome of Apple

Author

Abdelfattah, Ahmed, Whitehead, Susan R., Macarisin, Dumitru, Liu, Jia, Burchard, Erik, Freilich, Shiri, Dardick, Christopher, Droby, Samir, Wisniewski, Michael, Abdelfattah, Ahmed, Whitehead, Susan R., Macarisin, Dumitru, Liu, Jia, Burchard, Erik, Freilich, Shiri, Dardick, Christopher, Droby, Samir, and Wisniewski, Michael

Abstract

There is growing recognition of the role that the microbiome plays in the health and physiology of many plant species. However, considerably less research has been conducted on the postharvest microbiome of produce and the impact that postharvest processing may have on its composition. Here, amplicon sequencing was used to study the effect of washing, waxing, and low-temperature storage at 2 °C for six months on the bacterial and fungal communities of apple calyx-end, stem-end, and peel tissues. The results of the present work reveal that tissue-type is the main factor defining fungal and bacterial diversity and community composition on apple fruit. Both postharvest treatments and low temperature storage had a strong impact on the fungal and bacterial diversity and community composition of these tissue types. Distinct spatial and temporal changes in the composition and diversity of the microbiota were observed in response to various postharvest management practices. The greatest impact was attributed to sanitation practices with major differences among unwashed, washed and washed-waxed apples. The magnitude of the differences, however, was tissue-specific, with the greatest impact occurring on peel tissues. Temporally, the largest shift occurred during the first two months of low-temperature storage, although fungi were more affected by storage time than bacteria. In general, fungi and bacteria were impacted equally by sanitation practices, especially the epiphytic microflora of peel tissues. This research provides a foundation for understanding the impact of postharvest management practices on the microbiome of apple and its potential subsequent effects on postharvest disease management and food safety.

Published

2020

4. Effect of Washing, Waxing and Low-Temperature Storage on the Postharvest Microbiome of Apple

Author

Biological Sciences, Abdelfattah, Ahmed, Whitehead, Susan R., Macarisin, Dumitru, Liu, Jia, Burchard, Erik, Freilich, Shiri, Dardick, Christopher, Droby, Samir, Wisniewski, Michael, Biological Sciences, Abdelfattah, Ahmed, Whitehead, Susan R., Macarisin, Dumitru, Liu, Jia, Burchard, Erik, Freilich, Shiri, Dardick, Christopher, Droby, Samir, and Wisniewski, Michael

Abstract

There is growing recognition of the role that the microbiome plays in the health and physiology of many plant species. However, considerably less research has been conducted on the postharvest microbiome of produce and the impact that postharvest processing may have on its composition. Here, amplicon sequencing was used to study the effect of washing, waxing, and low-temperature storage at 2 °C for six months on the bacterial and fungal communities of apple calyx-end, stem-end, and peel tissues. The results of the present work reveal that tissue-type is the main factor defining fungal and bacterial diversity and community composition on apple fruit. Both postharvest treatments and low temperature storage had a strong impact on the fungal and bacterial diversity and community composition of these tissue types. Distinct spatial and temporal changes in the composition and diversity of the microbiota were observed in response to various postharvest management practices. The greatest impact was attributed to sanitation practices with major differences among unwashed, washed and washed-waxed apples. The magnitude of the differences, however, was tissue-specific, with the greatest impact occurring on peel tissues. Temporally, the largest shift occurred during the first two months of low-temperature storage, although fungi were more affected by storage time than bacteria. In general, fungi and bacteria were impacted equally by sanitation practices, especially the epiphytic microflora of peel tissues. This research provides a foundation for understanding the impact of postharvest management practices on the microbiome of apple and its potential subsequent effects on postharvest disease management and food safety.

Published

2020

5. The seed endosphere of Anadenanthera colubrina is inhabited by a complex microbiota, including Methylobacteriumspp. and Staphylococcus spp. with potential plant-growth promoting activities

Author

Alibrandi, P, Cardinale, M, Rahman, M, Strati, F, Ciná, P, de Viana, M, Giamminola, E, Gallo, G, Schnell, S, De Filippo, C, Ciaccio, M, Puglia, A, Alibrandi, P., Cardinale, M., Rahman, M. M., Strati, F., Ciná, P., de Viana, M. L., Giamminola, E. M., Gallo, G., Schnell, S., De Filippo, C., Ciaccio, M., Puglia, A. M., Alibrandi, P, Cardinale, M, Rahman, M, Strati, F, Ciná, P, de Viana, M, Giamminola, E, Gallo, G, Schnell, S, De Filippo, C, Ciaccio, M, Puglia, A, Alibrandi, P., Cardinale, M., Rahman, M. M., Strati, F., Ciná, P., de Viana, M. L., Giamminola, E. M., Gallo, G., Schnell, S., De Filippo, C., Ciaccio, M., and Puglia, A. M.

Abstract

Background and aims: Plant seeds are emerging micro–habitats, whose importance as reservoir and vector of beneficial microbes just begins to be recognized. Here we aimed to characterize the bacterial microbiota of the Anadenanthera colubrina seed endosphere, with special focus to beneficial traits and to the colonization pattern. Methods: Cultivation–dependent (isolation from surface–sterilized seeds) and cultivation–independent (pyrosequencing of 16S rRNA gene from metagenomic seed DNA) analyses, functional tests and microscopical investigations (fluorescence in situ hybridization coupled with confocal laser scanning microscopy (FISH-CLSM) were performed. Results: We isolated several Methylobacterium and Staphylococcus spp., exhibiting both plant growth promotion and antimicrobial activities. The two taxonomic groups showed complementary traits, which supports a functional selection. Both genera were detected also by pyrosequencing, together with further taxa. The genera Friedmaniella, Bifidobacterium, Delftia, Anaerococcus and Actinomyces appeared here for the first time as seed endophytes. We detected bacterial cells and micro–colonies in seed cryosections by FISH-CLSM. Alphaproteobacteria, Firmicutes and other bacteria colonized intercellular spaces of the parenchyma and associated to transport vessels. Conclusions: This work sheds light onto the diversity, functions and colonization pattern of the Anadenanthera colubrina seed endophytes, and strongly suggest a role as beneficial partners for seed-associated microbiota.

Published

2018