Growth and Function of Fungal Mycelia in Heterogeneous Environments

Boswell, Graeme P.; Jacobs, Helen; Davidson, Fordyce A.; Gadd, Geoffrey Michael; Ritz, Karl

doi:10.1016/s0092-8240(03)00003-x

Cited by 91 publications

(74 citation statements)

References 55 publications

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“…No ambiente terrestre, os fungos têm um papel importante nos ciclos biogeoquímicos do carbono, nitrogênio ou fósforo (BOSwELL et al, 2003). Como fitopatógenos, estes organismos possuem mecanismos de adesão ao hospedereiro, onde as moléculas de reconhecimento e união são, na maior parte dos casos, de natureza protéica ou glicoprotéica (SUGUI; LEITE; NICHOLSON, 1998;XIAO et al, 1994) e, por isso, a produção de proteínas e polissacarídeos extracelulares têm sido associadas à capacidade do microrganismo causar doenças em plantas (DOSS, 1999;GIL-AD;BAR-NUN;MAYER, 2001;LEITE et al, 2001).…”

Section: Biomassa Fúngicaunclassified

“…O crescimento micelial é dependente do processo de translocação, onde o material celular é direcionado para as regiões em desenvolvimento (BOSWELL et al, 2003), permitindo a formação das estruturas celulares, como a parede, e com isso facilitando a ocupação dos ambientes pelo microrganismo. Em condições normais de desenvolvimento, a estrutura da parede celular é baseada na parede já existente nas células progenitoras, que são extendidas e remodeladas.…”

Section: Parede Celular Fúngicaunclassified

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Polissacarídeos de parede celular fúngica: purificação e caracterização

et al. 2009

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ResumoA parede celular é uma estrutura rígida, essencial para a sobrevivência dos fungos, e o conhecimento de sua composição poderá ser útil para o desenvolvimento de novas drogas antifúngicas. Neste contexto, os polissacarídeos estão entre os seus principais componentes que têm sido alvos de intensa investigação científica. As informações, provenientes do conhecimento da estrutura dessas macromoléculas, poderão ser valiosas para o entendimento dos mecanismos de síntese da parede celular de fungos causadores de patologias, tanto em plantas quanto em animais. A determinação da estrutura química de um endopolissacarídeo deve ser precedida por experimentos de extração e purificação. As extrações, geralmente conduzidas em soluções aquosas neutras e/ou alcalinas, separaram as biomoléculas em grupos, de acordo com suas solubilidades. Os extratos, contendo mistura de polissacarídeos, podem ser purificados pela combinação de métodos químicos e cromatográficos. Após purificação, os polissacarídeos considerados homogêneos são caracterizados estruturalmente com as técnicas convencionais em química de carboidratos tais como hidrólise, metilação, FT-IR e RMN- 13C e 1 H. Esta revisão tem como proposta efetuar um levantamento das principais investigações científicas conduzidas com o objetivo de caracterizar polissacarídeos da parede celular fúngica. Palavras-chave: Biomassa, parede celular fúngica, polissacarídeos, caracterização química AbstractThe cell wall is a rigid structure essential for the survival of fungi. A knowledge of its composition is therefore useful for the development of novel anti-fungal drugs. In this context, polysaccharides as main components of the fungal cell wall have been the subject of intense scientific study over the years. The information gained from the knowledge of the structure of these macrobiomolecules could therefore be valuable in elucidating the mechanisms of their biosynthesis in the cell walls of pathogenic fungi infecting plants and animals alike. Determination of the chemical structures of these polysaccharides (endo) is preceded by their extraction and purification. The extractions, generally lead to neutral and/ or alkaline soluble biopolymers in groups according to their solubilities. Mixtures of polysaccharides in these extracts can then be purified by a combination of chemical and chromatographic methods.

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Section: Biomassa Fúngicaunclassified

Section: Parede Celular Fúngicaunclassified

Polissacarídeos de parede celular fúngica: purificação e caracterização

et al. 2009

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“…Using the process of dichotomous and lateral branching [5], hyphae create the mycelial network, in which the older branches eventually collides with existing braches and annihilated by the process of anastomosis [6]. The nutrients are internalized by the hyphae [7][8][9][10] and are sent through the mycelial network to the area of high nutrient demand, using a process called translocation [8,11,12].As hyphae propagate, they leave behind a stationary biomass [13]that consists of older cells, which are structurally stable and promote further growth of the hyphae. Earlier studies with mycotoxin producers suggest that mycotoxin production promoteshyphal growth and vice-versa.…”

Section: Introductionmentioning

confidence: 99%

Uncertainty Quantification Driven Predictive Multi-Scale Model for Synthesis of Mycotoxins

Banerjee¹,

Terejanu

Chanda

2014

CBB

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Abstract:Many toxic molds synthesize and release an array of poisons, termed mycotoxins that have an enormous impact on human health, agriculture and economy [1]. These molds contaminate our buildings, indoor air and crops, cause life threatening human and animal diseases and reduce agricultural output [2]. In order to design appropriate approaches to minimize the detrimental effects of these fungi, it is essential to develop diagnostic methodologies that can rapidly and accurately determine based on fungal strains and their growth patterns, the extent of mycotoxin mediated damage caused to the environment.Here we developed a novel multi-scale predictive mathematical model that could reliably estimate aflatoxin synthesis from growth features extracted from Aspergillusparasiticus, a well-characterized model for studying mycotoxin biosynthesis. We conducted acoustic imaging experiments to observe and extract the growth features from the biomass profiles of the growing Aspergillus colony growing on an aflatoxin-inducing solid growth medium. We employed the probability-based representation of uncertainty and used Bayes' theorem to infer the uncertain parameters in our mathematical model using biomass observations of the colony at 24h (aflatoxin is not synthesized yet at this time-point) and 48 hours (aflatoxin synthesis occurs at peak levels). We demonstrate that our model could successfully predict with quantified uncertainties the levels of aflatoxin secreted to the environment by the fungus.

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“…This is mainly because changes in the physiological state of individual fungal cells, as well as nutrient translocation inside the hyphae and in the growth substrate, respectively, are processes that are extremely hard to monitor which leaves considerable uncertainties in the interpretation of the experimental data. In this context, the use of mathematical models for the investigation of mycelial growth gains increasing attention [9][10][11][12][13]. Using the abstractive power of these models, it is not only possible to simulate the complex behaviour of fungal mycelia based on rather simple fundamental mechanisms or rules [14][15][16].…”

Section: Introductionmentioning

confidence: 99%

Applying dimorphic yeasts as model organisms to study mycelial growth: Part 1. Experimental investigation of the spatio-temporal development of filamentous yeast colonies

Walther

Reinsch

Weber

et al. 2010

Bioprocess Biosyst Eng

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Colony development of the dimorphic yeasts Yarrowia lipolytica and Candida boidinii on solid agar substrates under glucose limitation served as a model system for mycelial development of higher filamentous fungi. Strong differences were observed in the behaviour of both yeasts: C. boidinii colonies reached a final colony extension which was small compared to the size of the growth field. They formed cell-density profiles which steeply declined along the colony radius and no biomass decay processes could be detected. The stop of colony extension coincided with the depletion of glucose from the growth substrate. These findings supported the hypothesis that glucose-limited C. boidinii colonies can be regarded as populations of single cells which grow according to a diffusion-limited growth mechanism. Y. lipolytica colonies continued to extend after the depletion of the primary nutrient resource, glucose, until the populations covered the entire growth field which was accomplished by utilization of mycelial biomass.

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Growth and Function of Fungal Mycelia in Heterogeneous Environments

Cited by 91 publications

References 55 publications

Polissacarídeos de parede celular fúngica: purificação e caracterização

Polissacarídeos de parede celular fúngica: purificação e caracterização

Uncertainty Quantification Driven Predictive Multi-Scale Model for Synthesis of Mycotoxins

Applying dimorphic yeasts as model organisms to study mycelial growth: Part 1. Experimental investigation of the spatio-temporal development of filamentous yeast colonies

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