Fractal analysis in studies of mycelium in soil

Abstract Like many naturally irregular structures mycelia are approximately fractal; thus fractal dimension can be used to quantify the extent to which mycelia permeate space in relation to the extent of the system. Since it is important to be able to quantify both space filling at mycelial margins, i.e., `search fronts', and within systems, both surface/border and mass fractal dimensions are appropriate. The value of employing fractal geometry to describe mycelia is examined by comparison with information from other descriptors, in experiments examining the effects of extracellular concentration of the macronutrients NPK, and endogenous nutrient status of inocula, on development of mycelia of Hypholoma fasciculare , Phanerochaete velutina and Phallus impudicus . Mycelial morphology differed between species and was altered by both soil and inoculum nutrient status. Sensitivity to treatment effects was a major benefit of using fractal dimension (determined by box-counting) as a descriptor. However, complementary descriptors, including mycelial extent and total hyphal cover provided different information and all three should be used in combination. Further, though quantitative measures are attractive because of their objectivity they cannot describe all features of branching pattern, thus visual observation is also essential.

[1]  M. Obert,et al.  The fractal dimension of young colonies of Macrophomina phaseolina produced from microsclerotia , 1994 .

[2]  Damian P. Donnelly,et al.  Development of mycelial systems of Stropharia caerulea and Phanerochaete velutina on soil: effect of temperature and water potential , 1997 .

[3]  L. Boddy,et al.  Resource acquisition by the mycelial-cord-former Stropharia caerulea: effect of resource quantity and quality , 1997 .

[4]  L. Boddy,et al.  Characterization of the spatial aspects of foraging mycelial cord systems using fractal geometry , 1993 .

[5]  T. Kuyper,et al.  Performance of four ectomycorrhizal fungi on organic and inorganic nitrogen sources. , 1997 .

[6]  J. Wells,et al.  Patch formation and developmental polarity in mycelial cord systems of Phanerochaete velutina on a nutrient-depleted soil. , 1997, The New phytologist.

[7]  Johann N. Bruhn,et al.  Fractal geometry of diffuse mycelia and rhizomorphs of Armillaria species , 1995 .

[8]  J. Wells,et al.  Carbon translocation in mycelial cord systems of Phanerochaete velutina (DC: Pers.) Parmasto , 1995 .

[9]  J. Wells,et al.  The fate of soil-derived phosphorus in mycelial cord systems of Phanerochaete velutina and Phallus impudicus. , 1990 .

[10]  R. Campbell,et al.  The ecology and physiology of the fungal mycelium , 1985 .

[11]  W. Thompson,et al.  Extent, development and function of mycelial cord systems in soil , 1983 .

[12]  Lynne Boddy,et al.  Fungal decomposition of wood. Its biology and ecology. , 1988 .

[13]  R. Cooke,et al.  Ecology of saprotrophic fungi , 1985 .

[14]  L. Boddy,et al.  Resource relationships of foraging mycelial systems of Phanerochaete velutina and Hypholoma fasciculare in soil. , 1989, The New phytologist.

[15]  D. Wood,et al.  Developmental Biology of Higher Fungi. , 1986 .

[16]  P. Pfeifer,et al.  Microbial growth patterns described by fractal geometry , 1990, Journal of bacteriology.

[17]  Lynne Boddy,et al.  Spatial dynamics and interactions of the woodland fairy ring fungus, Clitocybe nebularis. , 1989, The New phytologist.

[18]  D B Patankar,et al.  A fractal model for the characterization of mycelial morphology , 1993, Biotechnology and bioengineering.

[19]  J. Lawton,et al.  Fractal dimension of vegetation and the distribution of arthropod body lengths , 1985, Nature.

[20]  L. Boddy,et al.  Inoculation of mycelial cord‐forming basidiomycetes into woodland soil and litter II. Resource capture and persistence , 1988 .

[21]  Johann N. Bruhn,et al.  The fungus Armillaria bulbosa is among the largest and oldest living organisms , 1992, Nature.

[22]  N. Collis-george,et al.  A filter-paper method for determining the moisture characteristics of soil , 1967 .

[23]  J. Crawford,et al.  Quantification of the fractal nature of colonies of Trichoderma viride. , 1990 .

[24]  L. Boddy,et al.  Foraging patterns of Phallus impudicus, Phanerochaete laevis and Steccherinum fimbriatum between discontinuous resource units in soil , 1988 .

[25]  John W. Crawford,et al.  Quantification of fungal morphology, gaseous transport and microbial dynamics in soil: an integrated framework utilising fractal geometry , 1993 .

[26]  John L. Harper,et al.  Clonal growth in grassland perennials. I: Density and pattern-dependent competition between plants with different growth forms , 1985 .

[27]  A. Rayner,et al.  The challenge of individualistic mycelium , 1991 .

[28]  J. M. Cook,et al.  The fractal approach to heterogeneous chemistry , 1990 .

[29]  L. Boddy,et al.  Outgrowth Patterns of Mycelial Cord-forming Basidiomycetes from and between Woody Resource Units in Soil , 1986 .

[30]  L. Boddy Saprotrophic cord-forming fungi: warfare strategies and other ecological aspects , 1993 .

[31]  C. A. Glasbey,et al.  Image analysis of space-filling by networks: Application to a fungal mycelium , 1996 .

[32]  L. Sander,et al.  Diffusion-limited aggregation, a kinetic critical phenomenon , 1981 .

[33]  B. Sleeman,et al.  The origins of spatial heterogeneity in vegetative mycelia: a reaction-diffusion model , 1996 .