This proposal requests continued support for the PI's long-standing investigation into the mechanical properties of blood cells, and how these properties are altered by abnormalities in the structural components of the membrane. The current proposal focuses on the role of the association between the bilayer and the underlying membrane skeleton. This is a particularly important process in red cells, which must maintain their integrity while undergoing large cyclic deformations. The proposed approach involves direct micromechanical experiments on individual cells with specific abnormalities, making direct measurements of the forces needed to separate the membrane bilayer from the membrane skeleton. These results are analyzed in the framework of specific models, which enable quantitative predictions of how structural changes affect the separation process. The major linkages to be examined are those involving protein 3 and its connections with ankyrin, protein 4.1, and protein 4.2.
Four specific aims are proposed.
In AIM1, he will measure the effects of selected chemical modifications on the strength of the bilayer-skeletal association in red cells. Cells with naturally occurring deficiencies, or mutations introduced by gene knockout and Transgenic strategies will be used in these experiments. The effects of oxidative damage on the separation process will also be investigated. The PI will use fluorescent markers to measure the lateral distribution of membrane components during and after tether formation, a technique in which the force required to extrude a thin finger of membrane from a cell's surface, to obtain a detailed assessment of the molecular events that accompany this process.
In AIM2, the PI seeks to refine quantitative models of the mechanics of bilayer detachment, in order to provide a rational basis for experimental design and interpretation. He hypotheses that the bilayer skeletal detachment force depends critically on the lateral spacing of molecular bonds between the skeleton and the bilayer, and the rigidity of the skeleton.
In AIM3, they extend their studies to consider how the attachment of membrane proteins to a skeleton or substrate affects their distribution between the cell body (with a skeleton) and the tether (which lacks a skeleton). The role of these forces in mediating the lateral distribution of integral membrane proteins will also be examined. Finally, in AIM4, they will apply these techniques to understand the adhesive interactions of lymphocytes, comparing the contributions of skeletal attachment to the adhesion of receptors that mediate rolling (selectin) vs. those that stabilize fixed attachments (LFA-1). Collectively, these studies will provide important new understandings of the forces that shape and stabilize the membrane, and of the role of the membrane skeleton in mediating cell adhesion receptors. These understandings are important to fully comprehend the molecular basis of various hemolytic and inflammatory disorders, and compliment the many biochemical and structural evaluations of this structure.

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Project (R01)
Project #
5R01HL031524-16
Application #
2838910
Study Section
Hematology Subcommittee 2 (HEM)
Project Start
1984-01-01
Project End
2001-11-30
Budget Start
1998-12-01
Budget End
1999-11-30
Support Year
16
Fiscal Year
1999
Total Cost
Indirect Cost
Name
University of Rochester
Department
Pharmacology
Type
Schools of Dentistry
DUNS #
208469486
City
Rochester
State
NY
Country
United States
Zip Code
14627
Butler, James; Mohandas, Narla; Waugh, Richard E (2008) Integral protein linkage and the bilayer-skeletal separation energy in red blood cells. Biophys J 95:1826-36
Raphael, R M; Waugh, R E; Svetina, S et al. (2001) Fractional occurrence of defects in membranes and mechanically driven interleaflet phospholipid transport. Phys Rev E Stat Nonlin Soft Matter Phys 64:051913
Svetina, S; Zeks, B; Waugh, R E et al. (1998) Theoretical analysis of the effect of the transbilayer movement of phospholipid molecules on the dynamic behavior of a microtube pulled out of an aspirated vesicle. Eur Biophys J 27:197-209
Hwang, W C; Waugh, R E (1997) Energy of dissociation of lipid bilayer from the membrane skeleton of red blood cells. Biophys J 72:2669-78
Raphael, R M; Waugh, R E (1996) Accelerated interleaflet transport of phosphatidylcholine molecules in membranes under deformation. Biophys J 71:1374-88
Waugh, R E (1996) Elastic energy of curvature-driven bump formation on red blood cell membrane. Biophys J 70:1027-35
Khodadad, J K; Waugh, R E; Podolski, J L et al. (1996) Remodeling the shape of the skeleton in the intact red cell. Biophys J 70:1036-44
Heinrich, V; Waugh, R E (1996) A piconewton force transducer and its application to measurement of the bending stiffness of phospholipid membranes. Ann Biomed Eng 24:595-605
Waugh, R E; Bauserman, R G (1995) Physical measurements of bilayer-skeletal separation forces. Ann Biomed Eng 23:308-21
Song, J; Waugh, R E (1993) Bending rigidity of SOPC membranes containing cholesterol. Biophys J 64:1967-70

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