Richness of endophytic fungi isolated from Opuntia ficus-indica Mill. (Cactaceae) and preliminary screening for enzyme production

Bezerra, Jadson Diogo Pereira; Santos, Marília G. S.; Svedese, Virgínia Michelle; Lima, Débora María Massa; Fernandes, Maria José; Paiva, Laura Mesquita; Souza-Motta, Cristina Maria de

doi:10.1007/s11274-011-1001-2

Cited by 116 publications

(74 citation statements)

References 56 publications

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“…Endophytic fungi are important producers of enzymes, and have high capability for production of extracellular enzymes such as cellulases, chitinases, laccase, pectinases, xylanases, proteases, amylases, β-galactosidase and other catabolic enzymes (Jordaan et al 2006;Bischoff et al 2009;Borges et al 2009;Rajulu et al 2011;Bezerra et al 2012). Chitinase is applied to the biological control of phytopathogens as it degrades the chitin of the pathogen cell wall.…”

Section: Enzyme Productionmentioning

confidence: 99%

“…Recent studies have revealed a large richness of endophytic fungal species and diverse metabolites with different functions (Zimmerman and Vitousek 2012;Xiao et al 2014;Zhang et al 2014a, b). In some cases, they can enhance plant growth (Waller et al 2005), act as biological control agents (Zhang et al 2014c), and produce enzymes (Bezerra et al 2012). The endophytic fungi are relatively unexplored and could be potential sources of novel natural products for exploitation in medicine, agriculture, and industry (Strobel et al 2004).…”

Section: Introductionmentioning

confidence: 99%

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Diversity, distribution and biotechnological potential of endophytic fungi

et al. 2015

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Endophytic fungi, living in the inner tissues of living plants, have attracted increasing attention among ecologists, taxonomists, chemists and agronomists. They are ubiquitously associated with almost all plants studied to date. Numerous studies have indicated that these fungi have an impressive array of biotechnological potential, such as enzyme production, biocontrol agents, plantgrowth promoting agents, bioremediation, biodegradation, biotransformation, biosynthesis and nutrient cycling. These fungi may represent an underexplored reservoir of novel biological resources for exploitation in the pharmaceutical, industry and agriculture. This review focuses on new findings in isolation methods, biodiversity, ecological distribution and biotechnological potential.

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Section: Enzyme Productionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Diversity, distribution and biotechnological potential of endophytic fungi

et al. 2015

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“…Such work has greatly enhanced our understanding of the geographic-, host-, and tissue-affiliations of fungi that are symbiotic with ecologically important plants in semi-arid grasslands and deserts, especially grasses and sedges [34, 47], gypsophilous plants [69], and selected dicotyledonous plants such as Atriplex spp. [16, 54] and some Cactaceae [17, 83; see also 51]. However, gaps remain with regard to understanding the diversity and composition of fungal communities in above-ground tissues of many woody plants in arid ecosystems, including those non-succulent species that form the dominant cover in some of the world's most biotically rich deserts.…”

Section: Introductionmentioning

confidence: 99%

Fungal Endophytes in Aboveground Tissues of Desert Plants: Infrequent in Culture, but Highly Diverse and Distinctive Symbionts

et al. 2015

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In hot deserts, plants cope with aridity, high temperatures, and nutrient-poor soils with morphological and biochemical adaptations that encompass intimate microbial symbioses. Whereas the root microbiomes of arid-land plants have received increasing attention, factors influencing assemblages of symbionts in above-ground tissues have not been evaluated for many woody plants that flourish in desert environments. We evaluated the diversity, host affiliations, and distributions of endophytic fungi associated with photosynthetic tissues of desert trees and shrubs, focusing on non-succulent woody plants in the species-rich Sonoran Desert. To inform our strength of inference, we evaluated the effects of two different nutrient media, incubation temperatures, and collection seasons on the apparent structure of endophyte assemblages. Analysis of >22,000 tissue segments revealed that endophytes were isolated four times more frequently from photosynthetic stems than leaves. Isolation frequency was lower than expected given the latitude of the study region, and varied among species a function of sampling site and abiotic factors. However, endophytes were very species-rich and phylogenetically diverse, consistent with less-arid sites of a similar latitudinal position. Community composition differed among host species, but not as a function of tissue type, sampling site, sampling month, or exposure. Estimates of abundance, diversity and composition were not influenced by isolation medium or incubation temperature. Phylogenetic analyses of the most commonly isolated genus (Preussia) revealed multiple evolutionary origins of desert-plant endophytism and little phylogenetic structure with regard to seasonality, tissue preference, or optimal temperatures and nutrients for growth in vitro. Together, these results provide insight into endophytic symbioses in desert plant communities, and can be used to optimize strategies for capturing endophyte biodiversity at regional scales.

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“…Additionally, it causes severe diseases in a variety of hosts, including plants and vertebrates (Faisal et al, 2007;Tullio et al, 2010). However, few studies have examined the xylanolytic activity on Phoma species (Bradner et al, 1999;Yang et al, 2005;Bezerra et al, 2012).…”

Section: Discussionmentioning

confidence: 99%