Patricia M. Callahan scite author profile

A new method is described for the isolation of subunits of the light-harvesting complex from Rhodospirillum rubrum (wild type and the G-9 mutant) in yields that approach 100%. The procedure involved treating membrane vesicles with ethylenediaminetetraacetic acid-Triton X-100 to remove components other than the light-harvesting complex and reaction center. In the preparation from wild-type cells, a benzene extraction was then employed to remove carotenoid and ubiquinone. The next step involved a careful addition of the detergent n-octyl beta-D-glucopyranoside, which resulted in a quantitative shift of the long-wavelength absorbance maximum from 873 to 820 nm. This latter complex was then separated from reaction centers by gel filtration on Sephadex G-100. The pigment-protein complex, now absorbing at 820 nm, contained two polypeptides of about 6-kilodalton molecular mass (referred to as alpha and beta) in a 1:1 ratio and two molecules of bacteriochlorophyll (BChl) for each alpha beta pair. This complex is much smaller in size than the original complex absorbing at 873 nm but probably is an associated form such as alpha 2 beta 2 X 4BChl or alpha 3 beta 3 X 6BChl. The 820-nm form could be completely shifted back to a form once again having a longer wavelength lambda max near 873 nm by decreasing the octyl glucoside concentration. Thus, the complex absorbing at 820 nm appears to be a subunit form of the original 873-nm complex.

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Assignment of bacteriochlorophyll a ligation state from absorption and resonance Raman spectra

Callahan¹,

Cotton²

1987

J. Am. Chem. Soc.

105

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Spectroscopic characterization of the light-harvesting complex of Rhodospirillum rubrum and its structural subunit

Chang

Callahan²,

Parkes-Loach

et al. 1990

Biochemistry

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The spectroscopic properties of the light-harvesting complex of Rhodospirillum rubrum, B873, and a detergent-isolated subunit form, B820, are presented. Absorption and circular dichroism spectra suggest excitonically interacting bacteriochlorophyll alpha (BChl alpha) molecules give B820 its unique spectroscopic properties. Resonance Raman results indicate that BCHl alpha is 5-coordinate in both B820 and B873 but that the interactions with the BChl C2 acetyl in B820 and B873 are different. The reactivity of BChl alpha in B820 in light and oxygen, or NaBH4, suggests that it is exposed to detergent and the aqueous environment. Excited-state lifetimes of the completely dissociated 777-nm-absorbing form [1.98 ns in 4.5% octyl glucoside (OG)], the intermediate subunit B820 (0.72 ns in 0.8% OG), and the in vivo like reassociated B873 (0.39 ns in 0.3% OG) were measured by single-photon counting. The fluorescence decays were exponential when emission was detected at wavelengths longer than 864 nm. An in vivo like B873 complex, as judged by its spectroscopic properties, can be formed from B820 without the presence of a reaction center.

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Redox-linked hydrogen bond strength changes in cytochrome a: implications for a cytochrome oxidase proton pump

Babcock¹,

Callahan²

1983

Biochemistry

141

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The heme a formyl group of cytochrome a in cytochrome oxidase appears to be involved in a hydrogen-bond interaction with a proton donor associated with the polypeptide backbone [Callahan, P.M., & Babcock, G.T. (1983) Biochemistry 22, 452-461]. Resonance Raman and optical absorption spectroscopies have been applied to the beef heart and Thermus thermophilus proteins and to heme a and copper porphyrin a models in order to assess the spectroscopic manifestations and the energetics of the hydrogen-bond interaction. We find a linear relationship between optical absorption red shift and carbonyl vibrational frequency decrease for a series of hydrogen-bonded model complexes; the magnitude of both changes increases as the hydrogen-bond strength increases. Comparison of the model compound data with analogous data for the proteins indicates that the strength of the formyl hydrogen bond in situ increases by 2-2.5 kcal/mol upon reduction of ferric cytochrome a. The selective stabilization of reduced cytochrome a by the stronger hydrogen bond is expected to increase the redox potential of this center; the energy made available as the hydrogen bond strengthens during reduction may be used to drive redox-coupled events in the protein. Thus, the linkage between cytochrome a redox state and chromophore/protein interaction energy provides a mechanism by which electron-transfer events and protein structure are coupled. Two models, which incorporate this linkage into a redox-driven proton pump centered at cytochrome a in cytochrome oxidase, are presented.

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Coordination geometries and vibrational properties of cytochromes a and a3 in cytochrome oxidase from soret excitation Raman spectroscopy

Babcock¹,

Callahan²,

Ondrias³

et al. 1981

Biochemistry

101

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