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Author:
Publisher:
ISBN:
Category : Biomineralization
Languages : en
Pages : 91
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Book Description
Iron is a common cation in biomineral sand; it is present for example in magnetite produced by magnetotactic bacteria and in iron sulfides produced by sulfate reducing microorganisms. The work presented in this thesis focused on two types of microorganisms capable of forming iron biominerals. In the first project I have studied the effect of O2 on the respiratory physiology and the formation of magnetosomes by Magnetospirillum magneticum AMB-1. In the second project I have studied the relationship between olivine and the activity of dissimilatory sulfate reducing (DSR) microorganisms. For the first project, I grew cells of AMB-1 in cultures with various concentrations of O2 and monitored growth and the formation of magnetic mineral particles (MMP). Results have shown that AMB-1 cells grew better at 100-225 uMO2(aq) than at lower [O2], yet the formation of MMP was repressed at ~45 u[mu]M O2(aq) and strongly inhibited at >100 u[mu]M O2(aq).These results have helped better understand the dissimilarity between the optimal growth conditions of magnetotactic bacteria and the conditions needed for the formation of MMPs. My results have also shown that the reaction between H2S produced by DSRs and olivine is abiotic, not catalyzed and exergonic. The pH did not vary significantly during this reaction and pH variation (in the 5-9 range) did not significantly influence this chemical reaction. Bicarbonate inhibited the reaction between H2S and olivine, but not the chemical equilibrium. Phosphate, a weak iron chelator, influenced the equilibrium of the reaction and it is assumed to help increase the rate of olivine weathering in the presence of DSRs. The activity of DSRs was positively influenced by the presence and abundance of olivine. Based on my results I propose that olivine help DSR obtain energy more efficiently, but does not represent a source of energy or nutrients for the cells. These results helped better understand the formation of iron biominerals and signatures of this activity.
Author:
Publisher:
ISBN:
Category : Biomineralization
Languages : en
Pages : 91
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Book Description
Iron is a common cation in biomineral sand; it is present for example in magnetite produced by magnetotactic bacteria and in iron sulfides produced by sulfate reducing microorganisms. The work presented in this thesis focused on two types of microorganisms capable of forming iron biominerals. In the first project I have studied the effect of O2 on the respiratory physiology and the formation of magnetosomes by Magnetospirillum magneticum AMB-1. In the second project I have studied the relationship between olivine and the activity of dissimilatory sulfate reducing (DSR) microorganisms. For the first project, I grew cells of AMB-1 in cultures with various concentrations of O2 and monitored growth and the formation of magnetic mineral particles (MMP). Results have shown that AMB-1 cells grew better at 100-225 uMO2(aq) than at lower [O2], yet the formation of MMP was repressed at ~45 u[mu]M O2(aq) and strongly inhibited at >100 u[mu]M O2(aq).These results have helped better understand the dissimilarity between the optimal growth conditions of magnetotactic bacteria and the conditions needed for the formation of MMPs. My results have also shown that the reaction between H2S produced by DSRs and olivine is abiotic, not catalyzed and exergonic. The pH did not vary significantly during this reaction and pH variation (in the 5-9 range) did not significantly influence this chemical reaction. Bicarbonate inhibited the reaction between H2S and olivine, but not the chemical equilibrium. Phosphate, a weak iron chelator, influenced the equilibrium of the reaction and it is assumed to help increase the rate of olivine weathering in the presence of DSRs. The activity of DSRs was positively influenced by the presence and abundance of olivine. Based on my results I propose that olivine help DSR obtain energy more efficiently, but does not represent a source of energy or nutrients for the cells. These results helped better understand the formation of iron biominerals and signatures of this activity.
Author: R. Blakemore
Publisher: Springer Science & Business Media
ISBN: 1461538106
Category : Science
Languages : en
Pages : 426
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Book Description
Author: H. Catherine W. Skinner
Publisher:
ISBN:
Category : Biogeochemistry
Languages : en
Pages : 448
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Book Description
Iron manganese biomineralization; Iron minerals in surface environments; Manganese minerals in surface environments; Crystal structures of manganese oxide minerals; Microbial biomineralization of iron and manganese; Microbial oxidation of organic matter coupled to the reduction of fe (III) and Mn(IV) oxides; Microbial accumulation of iron and manganese in different aquatic environments: an electron optical study; Magnetotactic bacteria: biomineralization, ecology, sediment magnetism, environmental indicator; Production of iron sulfide minerals by magnetotactic bacteria in sulfidic environments; Manganese oxides producec by fungal oxidation of manganese from siderite and rhodochrosite; Biogenic ferrihydrite: effect of B-thalassemia/ hemoglobin E disease onthe structure of ferrihydrite present in ferritins isolated from iron-loaded human heart and spleen tissue; Manganese nodules and microbial oxidation of manganese in the huntley meadows wetland, Virginia, USA; Iron sulfidization in tidal marsh soils; Mineralogy of precipitates formed by the biogeochemical oxidation of Fe(II) in mine drainage; Natural iron precipitates in a mine retention pond near Jabiru, Northern Territory, Australia; Iron deposits and microorganisms in saline sulfidic soils with altered soil water regimes in South Australia; Transformations of iron, manganese and aluminium during oxidation of a sulfidic material from an acid sulfate soil; Deposition and accumulation of biogenic magnetite in low oxygen facies ...
Author: Damien Faivre
Publisher: John Wiley & Sons
ISBN: 3527338829
Category : Science
Languages : en
Pages : 626
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Book Description
Alle relevanten Informationen zu Eisenoxiden, von der Struktur und Transformation über Charakterisierungsverfahren bis hin zu den neuesten AnwendungEN. Ein Muss für alle, die in dem Fachgebiet arbeiten.
Author: Joachim Reitner
Publisher: Springer
ISBN: 9781402092138
Category : Science
Languages : en
Pages : 927
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Book Description
The interplay between Geology and Biology has shaped the Earth from the early Precambrian, 4 billion years ago. Moving beyond the borders of the classical core disciplines, Geobiology strives to identify chains of cause-and-effect and synergisms between the geo- and the biospheres that have been driving the evolution of life in modern and ancient environments. Combining modern methods, geobiological information can be extracted not only from visible remains of organisms, but also from organic molecules, rock fabrics, minerals, isotopes and other tracers. An understanding of these processes and their signatures reveals enormous applied potentials with respect to issues of environment protection, public health, energy and resource management. The Encyclopedia of Geobiology has been designed to act as a key reference for students, researchers, teachers, and the informed public and to provide basic, but comprehensible knowledge on this rapidly expanding discipline that sits at the interface between modern geo- and biosciences.
Author: Aydin Berenjian
Publisher: Springer Nature
ISBN: 3030808076
Category : Science
Languages : en
Pages : 388
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Book Description
This book explains how microorganisms play a pivotal role in the formation of biominerals, including carbonates, silicate minerals and oxides. As readers will learn, these minerals may be produced either intracellularly or extracellularly in order to sustain microbial life. Experienced scientists from the field show that some of these biominerals can be produced in an active form, which involves direct enzymatic intervention to form precipitates. In addition, passive mineral formation can be mediated by the presence of dead cells. Readers from Microbiology and Biochemistry will appreciate the thorough coverage on various types of microbial mineral formation and their roles in microbial domains. Furthermore, they will benefit from the authors’ first-hand knowledge regarding common techniques for studying biomineral-producing microorganisms, factors affecting biomineralization, and the use of this process in biotechnological applications.
Author: Damien Faivre
Publisher: Frontiers E-books
ISBN: 2889192725
Category : Microbiology
Languages : en
Pages : 136
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Book Description
Bacteria can sequester metals and other ions intracellularly in various forms ranging from poorly ordered deposits to well- ordered mineral crystals. Magnetotactic bacteria provide one example of such intracellular deposits. They synthesize intracellular magnetic minerals of magnetite (Fe3O4) and/or greigite (Fe3S4) magnetosomes which are generally less than 150 nm and organized into one or multiple chain structures. The magnetosome chain(s) act like a compass needle to facilitate the navigation of magnetotactic bacteria by using the Earth’s magnetic field. Due to their ubiquitous distribution in aquatic and sedimentary environments, magnetotactic bacteria play important roles in global iron cycling. Other intracellular mineral phases have been evidenced in bacteria such as As2S3, CaCO3, CdS, Se(0) or various metal phosphates which may play as well a significant role in the geochemical cycle of these elements. However, in contrast to magnetotactic bacteria, the biological and environmental function of these particles remains a matter of debate. In recent years, such intracellularly biomineralizaing bacteria have become an attractive model system for investigating the molecular mechanisms of organelle-like structure formation in prokaryotic cells. The geological significance of intracellular biomineralization is important; spectacular examples are fossil magnetosomes that may significantly contribute to the bulk magnetization of sediments and act as potential archives of paleoenvironmental changes. In addition, intracellular mineral deposits formed by bacteria have potentially versatile applications in biotechnological and biomedical fields. After more than four decades of research, the knowledge on intracellularly biomineralizing bacteria has greatly improved. The aim of this Research Topic is to highlight recent advances in our understanding of intracellular biomineralization by bacteria. Magnetotactic bacteria are a system of choice for that topic but other intracellularly biomineralizing bacteria may bring a unique perspective on that process. Research papers, reviews, perspectives, and opinion papers on (i) the diversity and ecology of intracellularly biomineralizing bacteria, (ii) the molecular mechanisms of intracellular biomineralization, (iii) the chemo- and magneto-taxis behaviors of magnetotactic bacteria, (iv) the involvement of intracellularly biomineralizing bacteria in local or global biogeochemical cycling, (v) the paleoenvironmental reconstructions and paleomagnetic signals based on fossil magnetosomes, (vi) and the applications of intracellular minerals in biomaterial and biotechnology were welcomed.
Author: Joseph L. Kirschvink
Publisher: Springer Science & Business Media
ISBN: 1461303133
Category : Science
Languages : en
Pages : 679
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Book Description
The mystery of how migrating animals find their way over unfamiliar terrain has intrigued people for centuries, and has been the focus of productive research in the biological sci ences for several decades. Whether or not the earth's magnetic field had anything to do with their navigational abilities has sufaced and been dismissed several times, beginning at least in the mid to late 1800s. This topic generally remained out of the mainstream of scientific research for two reasons: (1) The apparent irreproducibility of many of the be havioral experiments which were supposed to demonstrate the existence of the magnetic sense; and (2) Perceived theoretical difficulties which were encountered when biophysi cists tried to understand how such a sensory system might operate. However, during the mid to late 1960s as the science of ethology (animal behavior) grew, it became clear from studies on bees and birds that the geomagnetic field is used under a variety of conditions. As more and more organisms were found to have similar abilities, the problem shifted back to the question as to the basis of this perception. Of the various schemes for trans ducing the geomagnetic field to the nervous system which have been proposed, the hy pothesis of magnetite-based magnetoreception discussed at length in this volume has per haps the best potential for explaining a wide range of these effects, even though this link is as yet clear only in the case of magnetotactic bacteria.
Author: Edmund Bäuerlein
Publisher: Wiley-VCH
ISBN:
Category : Medical
Languages : en
Pages : 328
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Book Description
Teeth, bones, kidney stones, and skeletons of algae, mussels, and grasses: all examples of biomineralization. Whole mountains owe their existence to the ability of organisms to mineralize in their cells inorganic compounds from solutions. Those minerals made by organisms are used for various purposes. Some of these minerals are magnetic and therefore of interest to nanotechnology. Thus there is a rapidly growing number of research groups and journals worldwide dealing with biomineralization. This book provides a much-needed up-to-date account of the important developments in biomineralization, focusing on investigations of unicellular organisms. An international and interdisciplinary team of authors, under the direction of a leading expert in the field, presents research results from first-hand experience as well as general information and a full list of references. Specific applications, such as the use of biominerals as contrast agents in cancer therapy, the templated crystallization of colloids, and in nanotechnology are highlights of this book.
Author: Mahendra Rai
Publisher: CRC Press
ISBN: 1000196488
Category : Science
Languages : en
Pages : 353
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Book Description
This book provides an account of the biogenic synthesis of nanomaterials by using different microorganisms. The chapters are focused on the biosynthesis of various metal and metal oxide nanosized materials by using bacteria, actinomycetes, fungi, and algae, including mechanisms of microbial synthesis. Other chapters summarize recent developments of microbial-based nanostructures for the management of food-borne pathogens, plant pathogenic fungi, as nutrients, and biomedical applications. Microorganisms are discussed not only as biofactories for the synthesis of nanomaterials but also as removal agents of toxic metals from the environment. Exposure sources and ecotoxicity of microbially synthesized nanoparticles are also discussed.
