Effects of Ammonia, Ph, and Nitrite on the Physiology of Nitrosmonas

Effects of Ammonia, Ph, and Nitrite on the Physiology of Nitrosmonas

AN ABSTRACT OF THE THESIS OF Lisa Yael Stein for the degree of Doctor of Philosophy in Molecular and Cellular Bioloav presented on May 14, 1998. Title: Effects of Ammonia, pH, and Nitrite on the Physioloav of Nitrosomonas europaea, an Obligate Ammonia-Oxidizing Bacterium. Redacted for Privacy Abstract approved: Daniel J. Arp Nitrosomonas europaea is a soil bacterium that derives energy solely from the oxidation of ammonia to nitrite. The first enzyme in ammonia metabolism, ammonia monooxygenase (AMO), is regulated transcriptionally and translationally by NH3. When cells of N. europaea were incubated with 50 mM ammonium, molecules of AMO were synthesized and the ammonia- oxidizing activity doubled over a 3 h period. In the same incubation, the activity decreased over the next 5 h to about the initial level. The decrease in activity was correlated to a decrease in the pH of the medium, from 8 to 5.6, which lowered the availability of the substrate for AMO, NH3, by favoring the formation of NH4+. Approximately half of the ammonium was oxidized in the incubations before reaching the limiting pH for ammonia oxidation. When cells were incubated in concentrations of ammonium that were consumed to completion, 15 mM, about 80% of the total ammonia oxidation activity was lost after 24 h. In cells incubated without ammonium or with a non- limiting amount, 50 mM, that was not consumed to completion due to acidification of the medium, only about 20-30% of the activity was lost after 24 h. The 80% loss of ammonia oxidation activity in the presence of limiting ammonium concentrations was specific and was not due to differences in AMO transcription or protein degradation. The presence of ammonium or short-chain alkanes, alternative substrates for AMO, ameliorated much of the activity loss. Incubations of cells in the presence of up to 20 mM nitrite also resulted in the specific loss of up to 62% of the ammonia oxidation activity. Thus, in the incubations with limiting concentrations of ammonium, the loss of activity was due to both the loss of the protective effects of ammonium and the accumulation of nitrite. The toxic effect of nitrite was more pronounced at alkaline pH, was not dependent on 02, and required copper. These results indicate that AMO is the target for nitrite and nitrite does not fit into previously identified classes of AMO inhibitors. The sensitivity of N. europaea to nitrite may help explain the specialized ecology of ammonia-oxidizing bacteria. Effects of Ammonia, pH, and Nitrite on the Physiology of Nitrosomonas europaea, an Obligate Ammonia-Oxidizing Bacterium by Lisa Yael Stein A THESIS submitted to Oregon State University in partial fulfillment of the requirements for the degree of Doctor of Philosophy Completed May 14, 1998 Commencement June 1998 Doctor of Philosophy thesis of Lisa Yael Stein presented on May 14, 1998 APPROVED: Redacted for Privacy Major Professor, repr sentin o ecular and Cellular Biology Redacted for Privacy Director of Molecular and Cellular Biology Program Redacted for Privacy Dean of G ate School I understand that my thesis will become part of the permanent collection of Oregon State University libraries. My signature below authorizes release of my thesis to any reader upon reyest. Redacted for Privacy Lisa Yael Stein, Author ACKNOWLEDGMENTS The completion of this thesis would not have been possible without the help and encouragement of many people in both my professional and personal life. I would like to thank my advisor, Dan Arp, for his intellectual, financial, and moral support. I would also like to thank Michael Hyman for his encouragement, guidance, and sharp eye. Norman Hommes, Luis Sayavedra- Soto, and Sterling Russell provided much needed and appreciated assistance both technically and personally. All other members of the Arp lab, present and past, I thank for their friendship, encouragement, and interest. I also thank my committee for volunteering their time and energy throughout my graduate career. Thank you to the MCB and CGRB office staff for their friendship highly valued assistance. A large thanks goes to my husband, Brian Lanoil, both for his professional guidance and for getting me through all of the rough spots. Graduate school would have been nearly impossible without you. Lastly, I would not have pursued the sciences without the encouragement and support from my dad, mom, and sister, Fredrick, Claudia, and Mishele Stein. Thank you for my education and for making me believe that I could do it. CONTRIBUTION OF AUTHORS Chapter 2 of this dissertation was published in 1997 in Applied and Environmental Microbiology, Vol. 63: 4588-4592 and is entitled, "Regulation of the synthesis and activity of ammonia monooxygenase in Nitrosomonas europaea by altering pH to affect NH3 availability." Chapter 3 was published in 1998 in Applied and Environmental Microbiology Vol. 64: 1514-1521 and is entitled, "Ammonium limitation results in the loss of ammonia-oxidizing activity in Nitrosomonas europaea." Chapter 4 has been submitted to Applied and Environmental Microbiology for publication and is entitled, "Loss of ammonia monooxygenase activity in Nitrosomonas europaea by exposure to nitrite." I, Lisa Stein, am the primary author on all three of the manuscripts, Dr. Daniel J. Arp is an author on all three manuscripts, and Dr. Michael R. Hyman is an author on the manuscript from Chapter 2. The experiments for all of these manuscripts were financially supported and conducted in the laboratory of Dr. Daniel J. Arp at Oregon State University. Dr. Arp contributed to the design of the experiments and the writing of all three of the manuscripts. Dr. Hyman contributed to the design, experimental execution, and writing of the manuscript from Chapter 2. TABLE OF CONTENTS Page 1. Introduction 1 1.1. Isolation of Nitrifying Bacteria 1 1.2. Ecology of Nitrifying Bacteria 2 1.2.1. Processes 2 1.2.2. Diversity and Ecology of Ammonia-Oxidizers 4 1.3. Nitrosomonas europaea 7 1.4. Metabolism of N. europaea 7 1.4.1. Energy Generation 10 1.4.2. Autolithotrophy 12 1.5. Ammonia Monooxygenase 14 1.5.1. Catalytic Active-Site 14 1.5.2. Substrate Range .16 1.5.3. Inhibitors 18 1.5.4. Regulation 21 1.6. Hydroxylamine Oxidoreductase 23 1.6.1. Structure and Function 23 1.6.2. Inhibitors and Inactivators 25 1.6.3. Genes 26 1.7. Regulation of Ammonia-Oxidizing Activity in the Environment 27 1.7.1. pH 28 1.7.2. Ammonia Limitation and Starvation 30 1.7.3. Oxygen 32 1.7.4. Nitrite 35 1.8. Summary 37 TABLE OF CONTENTS (Continued) Pacie 2. Regulation of the Synthesis and Activity of Ammonia Monooxygenase in Nitrosomonas europaea by pH-Mediated Effects on NH3 Availability 39 2.1. Abstract 39 2.2. Introduction 40 2.3. Materials and Methods 41 2.3.1. Materials 41 2.3.2. Growth of N. europaea 42 2.3.3. Batch incubations 42 2.3.4. 02 uptake measurements 43 2.3.5. Na214CO3 labeling reactions 44 2.3.6. 14C2H2-labeling incubations 44 2.3.7. Nitrite analysis 45 2.3.8. Protein determinations 45 2.4. Results 46 2.4.1. Changes in AMO and HAO activities in cells incubated in batch cultures 46 2.4.2. Effect of pH on AMO activity 48 2.4.3. Analysis of de novo polypeptide synthesis 50 2.4.4. Effects of pH changes on AMO activity in 02-limited incubations 53 2.5. Discussion 57 3. Ammonium Limitation Results in the Loss of Ammonia-Oxidizing Activity in Nitrosomonas europaea 60 3.1. Abstract 60 TABLE OF CONTENTS (Continued) Page 3.2. Introduction 61 3.3. Materials and Methods 63 3.3.1. Materials 63 3.3.2. Growth of N. europaea 63 3.3.3. Batch incubations 64 3.3.4. Analysis of amoA gene expression 65 3.3.5. Na214CO3 labeling reactions 66 3.4. Results 67 3.4.1. Time-dependent changes in ammonia oxidation activity from cells incubated in batch cultures containing different amounts of ammonium 67 3.4.2. Expression of the amoA gene in response to changing levels of ammonium 69 3.4.3. Stability of AmoA protein 72 3.4.4. Influence of remaining ammonium on ammonia oxidation activity 74 3.4.5. Effect of short-chain alkanes on ammonia oxidation activity 76 3.5. Discussion 81 4. Loss of Ammonia Monooxygenase Activity In Nitrosomonas europaea by Exposure to Nitrite 85 4.1. Abstract 85 4.2. Introduction 86 4.3. Materials and Methods 89 4.3.1. Growth of N. europaea and batch incubations 89 4.3.2. Labeling of polypeptides with 14C2H2 90 TABLE OF CONTENTS (Continued) Page 4.4. Results 91 4.4.1. Ammonia and hydroxylamine oxidation activities for cells incubated with different concentrations of ammonium 91 4.4.2. Effect of nitrite on ammonia and hydroxylamine oxidation activities 93 4.4.3. The effect of 02 and CH4 on the loss of ammonia oxidation activity 95 4.4.4. Effect of pH on nitrite-mediated loss of ammonia oxidation activity 96 4.4.5. Quantification of the active AMO polypeptide pool by 14c2H2 98 4.4.6. The role of copper in mediating the toxicity of nitrite 100 4.4.7. The effects of nitric oxide, nitrous oxide and nitrate on ammonia and hydroxylamine oxidation activity 102 4.5. Discussion 104 5. Summary 110 5.1. Introduction 110 5.2. Biochemical Significance 111 5.2.1. Regulation of AMO by the Concentration of NH3 111 5.2.2. Protection of AMO from Nitrite by Substrates 112 5.3. Physiological Significance 114 5.4. Ecological Significance 115 5.5. Concluding Statement 116 BIBLIOGRAPHY 118 LIST OF FIGURES Figure Page 2.1 Time course of changes in enzyme activities and culture conditions for cells of N.

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