Jason W. Cooley, PhD

Curriculum Vitae

[17] Lee, D.W., Özturk, Y., Osyczka, A.

Cooley, J. W.

and F. Daldal. Cytochrome

bc

1

-

c

y

fu-

sion complexes reveal the distance constraints for functional electron transfer between

photosynthesis components.

Journal of Biological Chemistry

, 283(20):13973–13982,

2008. doi:

10.1074/jbc.M800091200

[18] Lee, D.W., Özturk, Y., Osyczka, A.

Cooley, J. W.

and F. Daldal. A functional hybrid be-

tween the cytochrome

bc

1

complex and its physiological membrane-anchored electron

acceptor cytochrome

c

y

in

Rhodobacter capsulatus

.

Journal of Biological Chemistry

,

1757(5):346–352, 2006.doi:

10.1016/j.bbabio.2006.04.025

[19]

Cooley, J. W.

, Ohnishi, T. and F. Daldal. Binding dynamics at the quinone reduction

Q

i

site influence the equilibrium interactions of the iron sulfur protein and the hydro-

quinone oxidations Q

o

site of the cytochrome

bc

1

complex.

Biochemistry

, 44(31):10520–

10532, 2005. doi:

10.1021/bi050571

[20] Mather, M. W., Darrouzet, E., Valchova-Valchanova, M.,

Cooley, J. W.

, McIntosh, M.,

Daldal., F. and A. B. Vaida. Uncovering the molecular mode of action of the anti-

malarial drug atovaquone using a bacterial system.

Journal of Biological Chemistry

,

280(29):27458–27465, 2005. doi:

10.1074/jbc.M502319200

[21]

Cooley, J. W.

, Roberts, A. G., Bowman, M. K., Kramer, D. M., and F. Daldal. The raised

midpoint potential of the [2Fe-2S] cluster of the cytochrome

bc

1

is mediated by both

the Q

o

site occupants and the head domain position of the Fe-S protein subunit.

Bio-

chemistry

, 43(8):2217–2227, 2004. doi:

10.1021/bi035938u

[22]

Cooley, J. W.

, Darrouzet, E., and F. Daldal. Bacterial Hydroquinone: Cytochrome c

Oxidoreductases. Physiology, Structure and Function.

In Advances in Photosynthesis

and Respiration

, Ed. Zannoni, D. 15:41–55, 2004.

[23] Darrouzet, E.,

Cooley, J. W.

, and F. Daldal. The cytochrome

bc

1

complex and its homo-

logue the

b

6

f

complex: similarities and differences.

Photosynthesis Research

, 79(1):25–

44, 2004. doi:

10.1023/B:PRES.00

00011926.47778

.4e

[24] Howitt, C. A.,

Cooley, J. W.

, Wiskich, J. T., and W. F. J. Vermaas. A strain of

Synechocys-

tis

sp. PCC 6803 without photosynthetic oxygen evolution and respiratory oxygen con-

sumption: implications for the study of cyclic photosynthetic electron transport.

Planta

,

214(1):46–56, 2001. doi:

10.1007/s004250100578

[25]

Cooley, J. W.

, and W. F. J. Vermaas. Succinate dehydrogenase and other respiratory path-

ways in thylakoid membranes of

Synechocystis

sp. strain PCC 6803: capacity compar-

isons and physiological function.

Journal of Bacteriology

, 183(14):4251–4258, 2001.

doi:

doi: 10.1128/JB.182.3.714-722.2000

[26]

Cooley, J. W.

, Howitt, C. A., and W. F. J. Vermaas. Succinate: quinol oxidoreductases

in the cyanobacterium

Synechocystis

sp. strain PCC 6803: presence and function in

metabolism and electron transport.

Journal of Bacteriology

, 182(3):714–722, 2000.

doi:

doi: 10.1128/JB.182.3.714-722.2000

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