cytochrome-c-t and ferrous-sulfate

cytochrome-c-t has been researched along with ferrous-sulfate* in 2 studies

Other Studies

2 other study(ies) available for cytochrome-c-t and ferrous-sulfate

Article	Year
Evolutionary history of redox metal-binding domains across the tree of life. Proceedings of the National Academy of Sciences of the United States of America, 2014, May-13, Volume: 111, Issue:19 Oxidoreductases mediate electron transfer (i.e., redox) reactions across the tree of life and ultimately facilitate the biologically driven fluxes of hydrogen, carbon, nitrogen, oxygen, and sulfur on Earth. The core enzymes responsible for these reactions are ancient, often small in size, and highly diverse in amino acid sequence, and many require specific transition metals in their active sites. Here we reconstruct the evolution of metal-binding domains in extant oxidoreductases using a flexible network approach and permissive profile alignments based on available microbial genome data. Our results suggest there were at least 10 independent origins of redox domain families. However, we also identified multiple ancient connections between Fe2S2- (adrenodoxin-like) and heme- (cytochrome c) binding domains. Our results suggest that these two iron-containing redox families had a single common ancestor that underwent duplication and divergence. The iron-containing protein family constitutes ∼50% of all metal-containing oxidoreductases and potentially catalyzed redox reactions in the Archean oceans. Heme-binding domains seem to be derived via modular evolutionary processes that ultimately form the backbone of redox reactions in both anaerobic and aerobic respiration and photosynthesis. The empirically discovered network allows us to peer into the ancient history of microbial metabolism on our planet. Topics: Adrenodoxin; Amino Acid Sequence; Archaea; Bacteria, Anaerobic; Cytochromes c; Ecosystem; Energy Metabolism; Evolution, Molecular; Ferrous Compounds; Heme; Iron; Molecular Sequence Data; Oxidation-Reduction; Oxidoreductases; Oxygen; Prokaryotic Cells; Protein Structure, Tertiary; Sequence Analysis, Protein	2014
Spectroscopic characterization of (57)Fe-enriched cytochrome c. Analytical biochemistry, 2012, Apr-01, Volume: 423, Issue:1 Investigation of the heme iron dynamics in cytochrome c with Mössbauer spectroscopy and especially nuclear resonance vibrational spectroscopy requires the replacement of the natural abundant heme iron with the (57)Fe isotope. For demetallization, we use a safer and milder ferrous sulfate-hydrochloric acid method in addition to the harsher commonly used hydrofluoric acid-based procedure. The structural integrity of the (57)Fe-reconstituted protein in both oxidation states is confirmed from absorption spectra and a detailed analysis of the rich resonance Raman spectra. These results reinforce the application of metal-substituted heme c proteins as reliable models for the native proteins. Topics: Cytochromes c; Ferrous Compounds; Heme; Hydrochloric Acid; Iron Isotopes; Models, Molecular; Oxidation-Reduction; Spectroscopy, Mossbauer; Spectrum Analysis, Raman; Vibration	2012

Article

Year

Evolutionary history of redox metal-binding domains across the tree of life.

Proceedings of the National Academy of Sciences of the United States of America, 2014, May-13, Volume: 111, Issue:19

Oxidoreductases mediate electron transfer (i.e., redox) reactions across the tree of life and ultimately facilitate the biologically driven fluxes of hydrogen, carbon, nitrogen, oxygen, and sulfur on Earth. The core enzymes responsible for these reactions are ancient, often small in size, and highly diverse in amino acid sequence, and many require specific transition metals in their active sites. Here we reconstruct the evolution of metal-binding domains in extant oxidoreductases using a flexible network approach and permissive profile alignments based on available microbial genome data. Our results suggest there were at least 10 independent origins of redox domain families. However, we also identified multiple ancient connections between Fe2S2- (adrenodoxin-like) and heme- (cytochrome c) binding domains. Our results suggest that these two iron-containing redox families had a single common ancestor that underwent duplication and divergence. The iron-containing protein family constitutes ∼50% of all metal-containing oxidoreductases and potentially catalyzed redox reactions in the Archean oceans. Heme-binding domains seem to be derived via modular evolutionary processes that ultimately form the backbone of redox reactions in both anaerobic and aerobic respiration and photosynthesis. The empirically discovered network allows us to peer into the ancient history of microbial metabolism on our planet.

Topics: Adrenodoxin; Amino Acid Sequence; Archaea; Bacteria, Anaerobic; Cytochromes c; Ecosystem; Energy Metabolism; Evolution, Molecular; Ferrous Compounds; Heme; Iron; Molecular Sequence Data; Oxidation-Reduction; Oxidoreductases; Oxygen; Prokaryotic Cells; Protein Structure, Tertiary; Sequence Analysis, Protein

2014

Spectroscopic characterization of (57)Fe-enriched cytochrome c.

Analytical biochemistry, 2012, Apr-01, Volume: 423, Issue:1

Investigation of the heme iron dynamics in cytochrome c with Mössbauer spectroscopy and especially nuclear resonance vibrational spectroscopy requires the replacement of the natural abundant heme iron with the (57)Fe isotope. For demetallization, we use a safer and milder ferrous sulfate-hydrochloric acid method in addition to the harsher commonly used hydrofluoric acid-based procedure. The structural integrity of the (57)Fe-reconstituted protein in both oxidation states is confirmed from absorption spectra and a detailed analysis of the rich resonance Raman spectra. These results reinforce the application of metal-substituted heme c proteins as reliable models for the native proteins.

Topics: Cytochromes c; Ferrous Compounds; Heme; Hydrochloric Acid; Iron Isotopes; Models, Molecular; Oxidation-Reduction; Spectroscopy, Mossbauer; Spectrum Analysis, Raman; Vibration

2012