A neutron solution scattering study of the structure of annexin-V and its binding to lipid vesicles.

Abstract

International audienceLow-angle neutron solution scattering has been used to study the structure of annexin-V and its interaction with small single-bilayer vesicles consisting of phosphatidylserine and phosphatidylcholine at a 33:66 (mol:mol) ratio. There was no evidence for a change in the state of aggregation of annexin-V, which remained as a monomer in the presence of 3 mM-free calcium. The only difference between presence and absence of free calcium was the increase of the radius of gyration, from 19(+/- 0.4) A to 22(+/- 0.4) A in 2H2O buffer and from 19.7(+/- 1.2) A to 22.2(+/- 1.2) A in H2O buffer. The relative molecular weight, outer radius and average surface area per lipid of vesicles alone were respectively 2.5(+/- 0.5) x 10(6), 127 A and 90(+/- 19) A2. These parameters were not modified in the presence of free calcium, which testified to the absence of vesicle coalescence. The calcium-dependent binding of annexin-V was essentially interfacial and therefore did not alter significantly the structural characteristics of the vesicles. At saturation, 80(+/- 10) annexin-V molecules were bound per vesicle, the available area per molecule being 2500(+/- 300) A2 thus covering approximately 28 lipid head groups. The protein shell was approximately 35 A thick. The apparent dissociation constant was probably less than 1 nM. These data contribute to a more accurate definition of annexin-V as a possible probe of those cytodynamic events involving exposure of sequestered membrane aminophospholipids.Low-angle neutron solution scattering has been used to study the structure of annexin-V and its interaction with small single-bilayer vesicles consisting of phosphatidylserine and phosphatidylcholine at a 33:66 (mol:mol) ratio. There was no evidence for a change in the state of aggregation of annexin-V, which remained as a monomer in the presence of 3 mM-free calcium. The only difference between presence and absence of free calcium was the increase of the radius of gyration, from 19(+/- 0.4) A to 22(+/- 0.4) A in 2H2O buffer and from 19.7(+/- 1.2) A to 22.2(+/- 1.2) A in H2O buffer. The relative molecular weight, outer radius and average surface area per lipid of vesicles alone were respectively 2.5(+/- 0.5) x 10(6), 127 A and 90(+/- 19) A2. These parameters were not modified in the presence of free calcium, which testified to the absence of vesicle coalescence. The calcium-dependent binding of annexin-V was essentially interfacial and therefore did not alter significantly the structural characteristics of the vesicles. At saturation, 80(+/- 10) annexin-V molecules were bound per vesicle, the available area per molecule being 2500(+/- 300) A2 thus covering approximately 28 lipid head groups. The protein shell was approximately 35 A thick. The apparent dissociation constant was probably less than 1 nM. These data contribute to a more accurate definition of annexin-V as a possible probe of those cytodynamic events involving exposure of sequestered membrane aminophospholipids