Iron metabolism of <i>Escherichia coli</i> studied by Mössbauer spectroscopy and biochemical methods

Matzanke, Berthold F.; Ga, Müller; Bill, Eckhard; Trautwein, Alfred X.

doi:10.1111/j.1432-1033.1989.tb14938.x

Cited by 56 publications

(36 citation statements)

References 43 publications

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“…However, in overloaded cells, Bfr iron represents a very low proportion of the total iron content, and low molecular mass molecules carry the bulk of the cellular iron content and fulfill the iron storage function. These results are supported by studies performed on E. coli in which Bfr iron was shown to represent no more than 1% of the total cellular iron, the bulk of iron in the iron-rich cells being in the form of aggregates (42,43).…”

Section: Discussionmentioning

confidence: 58%

Purification, characterization, gene sequence, and significance of a bacterioferritin from Mycobacterium leprae.

Pessolani

Smith

Rivoire

et al. 1994

The Journal of Experimental Medicine

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SummsryThe study of tissue-derived Mycobacterium leprae provides insights to the immunopathology of leprosy and helps identify broad molecular features necessary for mycobacterial parasitism. A major membrane protein (MMP-II) of in vivo-derived M. teprae previously recognized (Hunter, S.W., B. Rivoire, V. Mehra, B.R. Bloom, and P.J. Brennan. 1990. J. Biol. Chem. 265:14065) was purified from extracts of the organism and partial amino acid sequence obtained. This information allowed recognition, within one of the cosmids that encompass the entire M. leprae genome, of a complete gene, bfr, encoding a protein of subunit size 18.2 kD. The amino acid sequence deduced from the major membrane protein II (MMP-II) gene revealed considerable homology to several bacterioferritins. Analysis of the native protein demonstrated the iron content, absorption spectrum, and large native molecular mass (380 kD) of several known bacterioferritins. "][prosy is a chronic disease of the skin and nerves caused by Mycobacterium leprae. Chemotherapy is successful but requires protracted multidrug therapy and the continuing evolution of new drug regimens. The world-wide prevalence of leprosy is now estimated at less than 5 million cases compared with 10-12 million in the mid-1980s (1). Much of this decline is attributed to chemotherapy. Nevertheless, leprosy still represents a major public health problem within regions of Latin America, Africa, and Asia, many of them not amenable to the standard drug regimens. Hence, the development of a vaccine that could contribute to the eradication of the disease remains a goal of some leprosy research programs.The molecular definition of M. leprae is fundamental to an understanding of the physiology and metabolism of the bacillus and the immunoregulatory mechanisms underlying the disease and protection against it. The leprosy bacillus grows intracellularly in cells of the reticuloendothelial system and Schwann cells, and it is so well adapted to this habitat that it has evaded axenic cultivation so far (2). The development of the armadillo as a relatively rich source of the bacillus has allowed extensive study of the physiology of the organism (2) and definition of the chemistry of the highly antigenic glycoconjugates and their roles in pathogenesis (3). Screening of M. leprae genomic libraries with antibodies has also permitted the isolation of genes that encode protein antigens, many of which are related to components of the highly conserved family of stress proteins (4).A landmark in leprosy research that may revolutionize our knowledge of the basis of the obligate parasitism ofM. leprae is the recently initiated "M. leprae genome project" (5). Present achievements from this undertaking include an ordered collection of overlapping clones encompassing the complete chromosome of M. leprae in which 72 loci have been mapped (5) and the complete sequence of 27 cosmids representing approximately one third of the genome (6; Smith, D.R., unpublished data). In an attempt to complement this genetic approac...

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Section: Discussionmentioning

confidence: 58%

Purification, characterization, gene sequence, and significance of a bacterioferritin from Mycobacterium leprae.

Pessolani

Smith

Rivoire

et al. 1994

The Journal of Experimental Medicine

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“…In several studies one of us (B.F.M.) has demonstrated that M6ssbauer spectroscopy of whole cells yields valuable information about the major components of iron metabolism as well as their time-dependent changes [16][17][18]. All of this has been done without the need for interference from any isolation procedure.…”

Section: Introductionmentioning

confidence: 99%

Fungal ferritins: The ferritin from mycelia of Absidia spinosa is a bacterioferritin

Carrano¹,

Böhnke²,

Matzanke³

1996

FEBS Letters

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Two distinct ferritin like iron containing proteins have been identified and isolated from the fungus Absidia spinosa; one from the spores and another from the mycelia. The mycelial protein has been purified and consists of two subunits of approx. 20 kDa. The N-terminal sequences of both subunits have been determined. The holoprotein as isolated contains approx. 750 iron atoms/molecule and exhibits a beme-like UV-Vis spectrum. Based on the beme spectrum and the high degree of sequence homology found, it has been established that the mycelial protein is a bacterioferritin. This is the first example demonstrating the presence of a bacterioferritin in a eukaryotic organism.

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“…and Matzanke et al,6) however, reported that in E. coli, bacterioferritin iron represents no more than 1% of the total iron and most of this metal in cells was the form of aggregates, which could be associated with a novel form of iron-protein. More recently, Laurehere et al 7 ) have shown that most iron in a strain of cyanobacterium was associated with a low-molecular-mass compound « 10 kDa), which fulfilled the storage function.…”

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confidence: 98%

Iron Storage inMycobacterium smegmatisGrown under Iron-sufficient and Iron-overload Conditions

Kikuchi

Fukumoto

1994

Bioscience, Biotechnology, and Biochemistry

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Iron metabolism of Escherichia coli studied by Mössbauer spectroscopy and biochemical methods

Cited by 56 publications

References 43 publications

Purification, characterization, gene sequence, and significance of a bacterioferritin from Mycobacterium leprae.

Purification, characterization, gene sequence, and significance of a bacterioferritin from Mycobacterium leprae.

Fungal ferritins: The ferritin from mycelia of Absidia spinosa is a bacterioferritin

Iron Storage inMycobacterium smegmatisGrown under Iron-sufficient and Iron-overload Conditions

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