Identification of Membrane Proteins imaged by Atomic force microscopy using a template matching algorithm

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Original languageEnglish
Pages (from-to)100-107
Number of pages8
JournalCONDENSED MATTER: STRUCTURAL, MECHANICAL, AND THERMAL PROPERTIES
Volume2001
Issue numberVol.10(13)
Publication statusPublished - 19 Mar 2001

Abstract

The atomic force microscope allows to image biological samples in their native environment. But the identification and the topography of individual randomly distributed membrane proteins is still a challenge. We used membranes of isolated vacuoles of barley mesophyll cells. Images at low resolution indicate that vacuoles spontaneously attach, rupture and finally adsorb completely as planar membrane to mica. Height profiles indicate that the membrane at the peripheral boundary exposes the extravacuolar surface to the scanning tip. At molecular resolution a template matching correlation algorithm was used to identify the most abundant membrane protein, the vacuolar H+-ATPase by the characteristic extravacuolar head of the transport molecule. The data indicate the possibility to analyse single randomly distributed membrane proteins in their native environment with the knowledge of a suitable template.

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Identification of Membrane Proteins imaged by Atomic force microscopy using a template matching algorithm. / Zeilinger, Carsten; Enders, Oliver; Kolb, Hans-Albert.
In: CONDENSED MATTER: STRUCTURAL, MECHANICAL, AND THERMAL PROPERTIES, Vol. 2001, No. Vol.10(13), 19.03.2001, p. 100-107.

Research output: Contribution to journalArticleResearchpeer review

Zeilinger, C, Enders, O & Kolb, H-A 2001, 'Identification of Membrane Proteins imaged by Atomic force microscopy using a template matching algorithm', CONDENSED MATTER: STRUCTURAL, MECHANICAL, AND THERMAL PROPERTIES, vol. 2001, no. Vol.10(13), pp. 100-107.
Zeilinger, C., Enders, O., & Kolb, H.-A. (2001). Identification of Membrane Proteins imaged by Atomic force microscopy using a template matching algorithm. CONDENSED MATTER: STRUCTURAL, MECHANICAL, AND THERMAL PROPERTIES, 2001(Vol.10(13)), 100-107.
Zeilinger C, Enders O, Kolb HA. Identification of Membrane Proteins imaged by Atomic force microscopy using a template matching algorithm. CONDENSED MATTER: STRUCTURAL, MECHANICAL, AND THERMAL PROPERTIES. 2001 Mar 19;2001(Vol.10(13)):100-107.
Zeilinger, Carsten ; Enders, Oliver ; Kolb, Hans-Albert. / Identification of Membrane Proteins imaged by Atomic force microscopy using a template matching algorithm. In: CONDENSED MATTER: STRUCTURAL, MECHANICAL, AND THERMAL PROPERTIES. 2001 ; Vol. 2001, No. Vol.10(13). pp. 100-107.
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abstract = "The atomic force microscope allows to image biological samples in their native environment. But the identification and the topography of individual randomly distributed membrane proteins is still a challenge. We used membranes of isolated vacuoles of barley mesophyll cells. Images at low resolution indicate that vacuoles spontaneously attach, rupture and finally adsorb completely as planar membrane to mica. Height profiles indicate that the membrane at the peripheral boundary exposes the extravacuolar surface to the scanning tip. At molecular resolution a template matching correlation algorithm was used to identify the most abundant membrane protein, the vacuolar H+-ATPase by the characteristic extravacuolar head of the transport molecule. The data indicate the possibility to analyse single randomly distributed membrane proteins in their native environment with the knowledge of a suitable template.",
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AU - Zeilinger, Carsten

AU - Enders, Oliver

AU - Kolb, Hans-Albert

PY - 2001/3/19

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N2 - The atomic force microscope allows to image biological samples in their native environment. But the identification and the topography of individual randomly distributed membrane proteins is still a challenge. We used membranes of isolated vacuoles of barley mesophyll cells. Images at low resolution indicate that vacuoles spontaneously attach, rupture and finally adsorb completely as planar membrane to mica. Height profiles indicate that the membrane at the peripheral boundary exposes the extravacuolar surface to the scanning tip. At molecular resolution a template matching correlation algorithm was used to identify the most abundant membrane protein, the vacuolar H+-ATPase by the characteristic extravacuolar head of the transport molecule. The data indicate the possibility to analyse single randomly distributed membrane proteins in their native environment with the knowledge of a suitable template.

AB - The atomic force microscope allows to image biological samples in their native environment. But the identification and the topography of individual randomly distributed membrane proteins is still a challenge. We used membranes of isolated vacuoles of barley mesophyll cells. Images at low resolution indicate that vacuoles spontaneously attach, rupture and finally adsorb completely as planar membrane to mica. Height profiles indicate that the membrane at the peripheral boundary exposes the extravacuolar surface to the scanning tip. At molecular resolution a template matching correlation algorithm was used to identify the most abundant membrane protein, the vacuolar H+-ATPase by the characteristic extravacuolar head of the transport molecule. The data indicate the possibility to analyse single randomly distributed membrane proteins in their native environment with the knowledge of a suitable template.

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JO - CONDENSED MATTER: STRUCTURAL, MECHANICAL, AND THERMAL PROPERTIES

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IS - Vol.10(13)

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