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203 Pages·2013·2.74 MB·English
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SOIL MICROBIAL DIVERSITY OF A MANAGED FOREST ECOSYSTEM AND THE POTENTIAL FOR LIGNOCELLULOSE DEGRADATION AND METAL BIOACCUMULATION BY WHITE ROT FUNGI by FRITZ AKUO NTOKO A DISSERTATION Submitted in partial fulfillment of the requirements for the degree of Doctor of Philosophy in the Department of Plant and Soil Science in the School of Graduate Studies Alabama A&M University Normal, Alabama 35762 May 2013 CERTIFICATE OF APPROVAL Submitted by FRITZ AKUO NTOKO in partial fulfillment of the requirement for the degree of DOCTOR OF PHILOSOPHY in PLANT AND SOIL SCIENCE. Accepted on behalf of the Faculty of the Graduate School by the Dissertation Committee: Dr. Veronica Acosta-Martinez Dr. Leopold Nyochembeng Dr. Elica Moss Dr. Zachary Senwo Major Advisor Dean of the Graduate School Date ii Copyright by FRITZ AKUO NTOKO 2013 iii DEDICATION This work is dedicated to my late sister (Victorine Ebude Ntoko), my sons (Chrys and Fritz), and all those who have contributed to my academic success. iv SOIL MICROBIAL DIVERSITY OF A MANAGED FOREST ECOSYSTEM AND THE POTENTIAL FOR LIGNOCELLULOSE DEGRADATION AND METAL BIOACCUMULATION BY WHITE ROT FUNGI Fritz Akuo Ntoko, PhD., Alabama A&M University, 2013. 187 pp. Dissertation Advisor: Dr. Z. N. Senwo, PhD. ABSTRACT This study investigated the impact of forest management practices such as prescribed burning and thinning, on soil microbial community diversity and metabolic function, using ester-linked fatty acid methyl ester (EL-FAME) analysis and DNA pyrosequencing, coupled with enzymatic assays. It also explored the potential of white rot fungi in the forest to degrade plant biomass, as well as bioaccumulate mercury. Results obtained from EL-FAME analysis suggest that the application of prescribed burning without thinning resulted in an overall decrease in total microbial population when compared to the control. However, light thinning with or without prescribed burning resulted in an increase in total microbial population. The bacterial and fungal species diversities, of the various treatments were all greater than that of the control, with the highest species diversities found in the lightly-thinned/9yr burn cycle treatments. The structural and compositional similarities of bacterial species between the different treatments were greater than that of the fungi species, as depicted by the Chao-Jaccard-Raw abundance based similarity indices and shared species. The application of burning without thinning resulted in the lowest metabolic functions, as observed with the no-thin/3yr burn cycle treatments. The lightly-thinned 9yr-burn cycle treatments had the highest metabolic activity based on the geometric mean of enzyme activities (GMea) indices. Evaluation of v biodegradation of woody (red oak) and non woody plant biomass (corn and wheat) with two white rot fungi, Pleurotus floridanus and Perenniporia nanlingensis, suggests that P. floridanus would be a better candidate to pre-treat wheat and wood, while P. nanlingensis would be better for pre-treating corn. The concentration of Hg in the various fruiting bodies ranged from 1.37 to 0.03 µg Hg per gram of fungi tissue, and differed significantly among the species of the various fungi, with the highest bioaccumulation recorded with Metschnikowia sp. Gerronema strombodes, Boletus sp., and Amanita alboverrucosa above the EPA acceptable level of 0.3 ppm. KEY WORDS: metabolic activity, mercury, white rot fungi, pyrosequencing, fatty acid analysis. vi TABLE OF CONTENTS CERTIFICATE OF APPROVAL ................................................................................... ii DEDICATION .............................................................................................................. iv ABSTRACT ....................................................................................................................v LIST OF TABLES ........................................................................................................ ix LIST OF FIGURES ....................................................................................................... xi ACKNOWLEDGMENTS ........................................................................................... xiii INTRODUCTION AND REVIEW OF LITERATURE ...................................................1 1.1 Introduction .......................................................................................................1 1.2 Soil microbial diversities and functions in soils .................................................7 1.2.1 Drivers and concept of diversity ............................................................... 10 1.2.2 Ecological importance of microbial biodiversity ....................................... 14 1.3 Measurement of microbial diversity ................................................................. 17 1.3.1 Dilution plating and culturing methods ..................................................... 18 1.3.2 Community-level physiological profiles .................................................. 20 1.3.3 Fatty acid analysis .................................................................................... 21 1.3.4 Protein based methods ............................................................................. 26 1.3.5 Nucleic acid analyses for soil ecology studies .......................................... 28 1.3.6 Soil microorganisms ................................................................................. 36 1.4 Forest management and soil ecology ............................................................... 43 1.4.1 Effects of thinning and fire on soil properties ........................................... 48 1.5 Rationale and research objectives .................................................................... 51 METHODOLOGY ........................................................................................................ 56 2.1 Study site description....................................................................................... 56 2.2 Soil sampling and analyses .............................................................................. 60 2.3 Microbial communities sizes and structures ..................................................... 60 vii 2.4 Bacterial and fungal diversity by pyrosequencing techniques ........................... 62 2.5 Metabolic capacity of the forest ecosystem via enzyme activities..................... 65 2.6 Collection and screening and identification of fungi fruiting bodies ................. 66 2.7 Molecular identification of fungi fruiting bodies .............................................. 67 2.8 Characterization of biomass and compositional analysis of biomass ................ 68 2.9 Pretreatment of substrate and estimation of enzyme production ....................... 69 2.10 Analysis of mercury in fungi tissue .................................................................. 70 2.11 Statistical analyses ........................................................................................... 71 RESULTS AND DISCUSSION .................................................................................... 73 3.1 Microbial community size and structure by EL-FAME .................................... 73 3.2 Microbial community diversity, and richness, according to pyrosequencing .... 83 3.2.1 Bacterial community richness and diversity .............................................. 83 3.2.2 Shared species richness and similarity in the bacterial community structure ................................................................................................... 98 3.2.3 Fungal community richness and diversity ............................................... 101 3.2.5 Shared species richness and similarity in the fungal community structure ................................................................................................. 117 3.3 Metabolic capacity of the forest ecosystem by enzymatic assays .................... 121 3.4 Additional soil properties............................................................................... 132 3.5 Evaluating biodegradation of plant biomass ............................................ 136 3.6 Bioaccumulation of mercury in fungi tissue ............................................ 154 CONCLUSION ........................................................................................................... 158 REFERENCES ............................................................................................................ 163 APPENDIX ................................................................................................................. 176 viii LIST OF TABLES Table Page 2 1. Treatment applications at the Bankhead National Forest ............................... 58 3.1. Principal Component Analysis (PCA) factor loadings and percent contributions of variables to relationships between soil microbial community compositions, and enzymatic activities with treatments, at 0 - 10cm soil depth. ...................................................................................... 78 3.2. Changes in microbial community compositions and size at 0 - 10 depth, relative to the control site. .................................................................. 81 3.3. Analysis of variance for abundance of microbial groups and biomass of the different treatments at 0 - 10 cm, and with depth (0 - 10cm and 10 – 20cm). .................................................................................................. 82 3.4. Analysis of variance for relative abundance of bacterial classes with different treatments. ..................................................................................... 93 3.5. Bacterial species diversity indices of various treatments. .............................. 95 3.6. Pearson’s correlation matrix between bacterial classes and soil properties. .................................................................................................... 96 3.7. Pearson’s correlation matrix between bacterial classes and soil enzymatic activities. ..................................................................................... 97 3.8 Observed and estimated shared bacterial species between treatments. ........... 99 3.9. Chao-Jaccard-Raw abundance-based similarities between pairs of treatments, calculated from shared OTUs. .................................................. 100 3.10. Analysis of variance for relative abundance of fungal phyla with different treatments. ................................................................................... 109 3.11 Analysis of variance for relative abundance of fungal classes with respect to thinning, burning, and combined treatments................................ 110 3.12. Diversity indices of fungal species in the different treatments. .................... 114 3.13. Pearson’s correlation matrix between fungal classes and soil properties. .................................................................................................. 115 ix

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algae, bacteria, fungi, protists and viruses (Prescott et al., 1996) define. In addition to richness, OTUs have been used to characterize the . would include: the suspension of a soil sample in sterile phosphate solution; a series “big four”), Proteobacteria, Firmicutes, Bacteroidetes, and Act
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