Lawrence
J. Prochaska, Ph.D., Professor
B.S. - Illinois State University, 1971
Ph.D. - Ohio State University, 1975 (E.L. Gross)
Postdoctorals: Purdue University (R.A. Dilley); University
of Oregon (R.A. Capaldi)
E-mail: lawrence.prochaska@wright.edu
Prochaska Laboratory Group: (top row, left to right) T. Cvetkov,
D. Riegler, M.S., L. Prochaska, Ph.D., S. Salsman, Ph.D., (bottom
row) R.R. Geyer, J. Locke, L. Shroyer, M.S.
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Overview
Our laboratory studies the biochemistry and molecular biology of membrane-bound
enzymes that are crucial in heart and bacterial energy conservation reactions.
Our research focuses on structure/function relationships in heart mitochondrial
and thermophilic bacterial cytochrome c oxidases, using immunological,
biochemical, and recombinant DNA methods. Cytochrome c oxidase is the
terminal member of the respiratory chain of the mitochondrion and some
aerobic bacteria. The enzyme contains hemes and copper atoms that act
as oxidation-reduction centers. In the terminal electron transfer reaction
catalyzed by the enzyme, molecular oxygen is reduced into water and the
energy released by these oxidation-reduction reactions is conserved by
the pumping of protons across the mitochondrial inner or bacterial cell
membrane. The electrochemical gradient generated by the enzyme is subsequently
used to drive the synthesis of ATP. The cytochrome c oxidases are multi-subunit
enzymes containing from 13 subunits in the mammalian mitochondrial form
to 3-4 subunits in the bacterial forms. The three largest subunits are
conserved between the mitochondrial and bacterial forms. The two largest
subunits contain the redox centers of the enzyme and most likely contain
the proton-pumping function of the enzyme.
Research Projects
Our work has focused on the role of the highly conserved, non oxidation-reduction
center containing third subunit (subunit III) in the functioning of bovine
heart mitochondrial cytochrome c oxidase. Toward this goal, we have studied
a preparation of the mitochondrial enzyme that is depleted in subunit
III and found that this enzyme has lost 50% of its energy transducing
or proton pumping function by an unknown mechanism. Addition of purified
subunit III to subunit III-depleted enzyme results in a stimulation of
proton pumping in the enzyme. We also have made site-specific antibodies
to the hydrophilic domains in subunit III and have observed that these
antibodies stimulate electron transfer activity of the enzyme without
affecting proton-pumping. Our results (and those from other laboratories)
suggest that subunit III regulates cytochrome c oxidase activities.
Currently, we are studying the role of critical conserved amino acids
in subunits III and I in the functioning of the bacterial enzyme in Rhodobacter
sphaeroides. In one collaborative project (with J. Hosler), we are
mutating the amino acids at the interface of subunits III and I to investigate
the effect of the mutagenesis on the functioning of the enzyme. In another
collaborative project (with R. Gennis and D. Zaslavsky), we are attempting
to measure the proton-pumping stoichiometries during the enzyme’s
oxidase and peroxidase catalytic activities.
Another interest in our laboratory is whether mitochondrial cytochrome
oxidase functions as a monomeric unit or dimeric form within the mitochondrial
inner membrane in vivo. We have shown by using heterobifunctional chemical
crosslinking reagents that subunit I forms a contact site for two monomers
of the enzyme. Furthermore, our work has shown that the dimeric structure
is preferred in a membrane bilayer environment. We are currently preparing
artificial membranes (liposomes) that contain either one or two cytochrome
oxidase molecules per liposome to explore the possibility that monomers
or dimers of the enzyme have different functional activities.
Other interests in the laboratory include integral membrane protein-lipid
interactions and the interactions of detergents with membrane proteins.
We also focus much of our research efforts on the reconstitution of membrane
proteins into artificial membranes (or liposomes) and the development
of assays to assess protein incorporation into membranes.
We have used a battery of techniques in our investigations, including
membrane protein isolation, preparation and characterization of liposomes,
chemical modification of protein functional groups using group specific
reagents, and production and characterization of site-directed and subunit-specific
antibodies.
Recent Publications
Nguyen, X.-T., Pabarue, H. A., Geyer, R. R., Shroyer, L. A., Estey,
L. A., Parilo, M., Wilson, K.S., and Prochaska, L. Purification of Phospholipid
Vesicles Containing Control and Subunit III-Depleted Beef Heart Cytochrome
c Oxidase, Protein Expression and Purification 26, 122-130 (2002).
Lincoln, A.J., Donat, N., Palmer, G., and Prochaska, L. The Effects
of Site-Specific Polyclonal Antibodies Against Conserved Hydrophilic
Domains of Bovine Heart Cytochrome c Oxidase Subunit III on
the Functioning of the Enzyme. Archives of Biochemistry and Biophysics, 416,
81-91 (2003).
Riegler, D., Shroyer, L.A., Pokalsky, C., Zaslavsky, D., Gennis, R.,
and Prochaska, L.J. Characterization of Steady-state Activities of Cytochrome c Oxidase
at Alkaline pH: Mimicking the Effect of K-channel Mutations in the Bovine
Enzyme. Biochimica Biophysica acta, 1706, 126-133 (2005).
Geyer, R. R, Patli, S. S., Alter, G. M., Hosler, J. P., and Prochaska.
L. J., Cytochrome c Oxidase Subunit I From Rhodobacter sphaeroides Assumes
an Alternative Conformation in the Absence of Subunit III. Submitted
(2006).
Cvetkov, T., Shroyer, L.A., and Prochaska, L. J. Purification of
Phospholipid Vesicles Containing Cytochrome c Oxidase from Rhodobacter
sphaeroides. Submitted (2006).
People
| Lawrence
J. Prochaska, Ph.D. |
Principle
Investigator |
| Lois
A. Shroyer, M.S. |
Research
Associate |
| R. Ryan
Geyer |
Ph.D.
Student |
| Teresa
L. Cvetkov |
Ph.D.
Student |
| Rachel
Omolewu |
M.S.
Student |
| Matthew
Jaruwannakorn |
Undergraduate
Student |
| Dishita
Patel |
Undergraduate
Student |
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