Directed Formation of Micro- and Nanoscale Patterns of Functional Light- Harvesting LH2 Complexes

The precision placement of the desired protein components on a suitable substrate is an essential prelude to any hybrid "biochip" device, but a second and equally important condition must also be met: the retention of full biological activity. Here we demonstrate the selective binding of a...

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Veröffentlicht in:	Journal of the American Chemical Society 2007-01, Vol.129 (47), p.14625-14631
Hauptverfasser:	Reynolds, Nicholas P, Janusz, Stefan, Escalante-Marun, Maryana, Timney, John, Ducker, Robert E, Olsen, John D, Otto, Cees, Subramaniam, Vinod, Leggett, Graham J, Hunter, CNeil
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Schlagworte:	Rhodobacter sphaeroides
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creator	Reynolds, Nicholas P Janusz, Stefan Escalante-Marun, Maryana Timney, John Ducker, Robert E Olsen, John D Otto, Cees Subramaniam, Vinod Leggett, Graham J Hunter, CNeil
description	The precision placement of the desired protein components on a suitable substrate is an essential prelude to any hybrid "biochip" device, but a second and equally important condition must also be met: the retention of full biological activity. Here we demonstrate the selective binding of an optically active membrane protein, the light-harvesting LH2 complex from Rhodobacter sphaeroides, to patterned self-assembled monolayers at the micron scale and the fabrication of nanometer-scale patterns of these molecules using near-field photolithographic methods. In contrast to plasma proteins, which are reversibly adsorbed on many surfaces, the LH2 complex is readily patterned simply by spatial control of surface polarity. Near-field photolithography has yielded rows of light-harvesting complexes only 98 nm wide. Retention of the native optical properties of patterned LH2 molecules was demonstrated using in situ fluorescence emission spectroscopy.
doi_str_mv	10.1021/ja073658mPII:S0002-7863(07)03658-X
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title	Directed Formation of Micro- and Nanoscale Patterns of Functional Light- Harvesting LH2 Complexes
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