Your search keyword '"Zuccaro, Alga"' showing total 3 results

1. Root-specific camalexin biosynthesis controls the plant growth-promoting effects of multiple bacterial strains.

Author

Koprivova, Anna, Schuck, Stefan, Jacoby, Richard P., Klinkhammer, Irene, Welter, Bastian, Leson, Lisa, Martyn, Anna, Nauen, Julia, Grabenhorst, Niklas, Mandelkow, Jan F., Zuccaro, Alga, Zeier, Jürgen, and Kopriva, Stanislav

Subjects

BIOSYNTHESIS, WEIGHT gain, CYTOCHROME P-450, SILVER nitrate, PLANT growth

Abstract

Plants in their natural ecosystems interact with numerous microorganisms, but how they influence their microbiota is still elusive. We observed that sulfatase activity in soil, which can be used as a measure of rhizosphere microbial activity, is differently affected by Arabidopsis accessions. Following a genome-wide association analysis of the variation in sulfatase activity we identified a candidate gene encoding an uncharacterized cytochrome P450, CYP71A27. Loss of this gene resulted in 2 different and independent microbiota-specific phenotypes: A lower sulfatase activity in the rhizosphere and a loss of plant growth-promoting effect by Pseudomonas sp. CH267. On the other hand, tolerance to leaf pathogens was not affected, which agreed with prevalent expression of CYP71A27 in the root vasculature. The phenotypes of cyp71A27 mutant were similar to those of cyp71A12and cyp71A13, known mutants in synthesis of camalexin, a sulfur-containing indolic defense compound. Indeed, the cyp71A27 mutant accumulated less camalexin in the roots upon elicitation with silver nitrate or flagellin. Importantly, addition of camalexin complemented both the sulfatase activity and the loss of plant growth promotion by Pseudomonas sp. CH267. Two alleles of CYP71A27 were identified among Arabidopsisaccessions, differing by a substitution of Glu373 by Gln, which correlated with the ability to induce camalexin synthesis and to gain fresh weight in response to Pseudomonas sp. CH267. Thus, CYP71A27 is an additional component in the camalexin synthesis pathway, contributing specifically to the control of plant microbe interactions in the root. [ABSTRACT FROM AUTHOR]

Published

2019

2. Root-associated fungal microbiota of nonmycorrhizal Arabis alpina and its contribution to plant phosphorus nutrition.

Author

Almario, Juliana, Jeenaa, Ganga, Wunder, Jörg, Langen, Gregor, Zuccaro, Alga, Coupland, George, and Bucher, Marcel

Subjects

VESICULAR-arbuscular mycorrhizas, ARABIS, PLANT-fungus relationships, PHOSPHORUS in soils, PLANT nutrition, SYMBIOSIS, HELOTIALES

Abstract

Most land plants live in association with arbuscular mycorrhizal (AM) fungi and rely on this symbiosis to scavenge phosphorus (P) from soil. The ability to establish this partnership has been lost in some plant lineages like the Brassicaceae, which raises the question of what alternative nutrition strategies such plants have to grow in P-impoverished soils. To understand the contribution of plant-microbiota interactions, we studied the root-associated fungal microbiome of Arabis alpina (Brassicaceae) with the hypothesis that some of its components can promote plant P acquisition. Using amplicon sequencing of the fungal internal transcribed spacer 2, we studied the root and rhizosphere fungal communities of A. alpina growing under natural and controlled conditions including low-P soils and identified a set of 15 fungal taxa consistently detected in its roots. This cohort included a Helotiales taxon exhibiting high abundance in roots of wild A. alpina growing in an extremely P-limited soil. Consequently, we isolated and subsequently reintroduced a specimen from this taxon into its native P-poor soil in which it improved plant growth and P uptake. The fungus exhibited mycorrhiza-like traits including colonization of the root endosphere and P transfer to the plant. Genome analysis revealed a link between its endophytic lifestyle and the expansion of its repertoire of carbohydrate-active enzymes. We report the discovery of a plant-fungus interaction facilitating the growth of a nonmycorrhizal plant under native P-limited conditions, thus uncovering a previously underestimated role of root fungal microbiota in P cycling. [ABSTRACT FROM AUTHOR]

Published

2017

3. Host-related metabolic cues affect colonization strategies of a root endophyte.

Author

Lahrmann, Urs, Yi Ding, Banhara, Aline, Rath, Magnus, Hajirezaei, Mohammad R., Döhlemann, Stefanie, von Wirén, Nicolaus, Parniske, Martin, and Zuccaro, Alga

Subjects

HOST-virus relationships, PLANT colonization, ENDOPHYTES, ROOT diseases, PATHOGENIC microorganisms, PLANT viruses in host plants, ARBOVIRUSES

Abstract

A widely held concern is that the pace of infectious disease emergence has been increasing. We have analyzed the rate of discovery of pathogenic viruses, the preeminent source of newly discovered causes of human disease, from 1897 through 2010. The rate was highest during 1950-1969, after which it moderated. This general picture masks two distinct trends: for arthropod-borne viruses, which comprised 39% of pathogenic viruses, the discovery rate peaked at three per year during 1960-1969, but subsequently fell nearly to zero by 1980; however, the rate of discovery of nonarboviruses remained stable at about two per year from 1950 through 2010. The period of highest arbovirus discovery coincided with a comprehensive program supported by The Rockefeller Foundation of isolating viruses from humans, animals, and arthropod vectors at field stations in Latin America, Africa, and India. The productivity of this strategy illustrates the importance of location, approach, long-term commitment, and sponsorship in the discovery of emerging pathogens. [ABSTRACT FROM AUTHOR]

Published

2013