Shattil S J, Cooper R A
Biochemistry. 1976 Nov 2;15(22):4832-7. doi: 10.1021/bi00667a012.
An increased sensitivity to epinephrine-induced aggregation has been observed both in platelets obtained from patients with type IIa hyperlipoproteinemia and in normal platelets following incubation with cholesterol-rich lecithin dispersions. We have reported previously that the membrane fraction of platelets is enriched with cholesterol relative to phospholipid under each of these conditions. To further explore the effect of cholesterol on platelet membranes, we have examined the fluidity (microviscosity) of whole platelets and platelet subcellular fractions using a hydrophobic fluorescent probe, 1,6-diphenyl-1,3,5-hexatriene (DPH), under conditions in which the cholesterol-to-phospholipid mole ratio (C/PL) of platelets was varied by incubation with various cholesterol-lecithin sonicated dispersions. The C/PL of platelets directly influenced the rotational diffusion of DPH, as indicated by changes in fluorescence polarization. This was reflected in an increase in microviscosity at 37 degrees C (ETA37) from 2.84 P in normal platelets to 4.06 P in platelets with a 118% increase in C/PL. Conversely, platelets with a 43% decrease in C/PL had a 13% decrease in eta37. A strong correlation (r = 0.94) existed between C/PL and eta37 throughout this entire range. However, C/PL had no effect on the excited-state fluorescence lifetime of DPH. Both C/PL and eta37 were lower in isolated platelet membranes than in the platelet granule fraction. When platelets were incubated for 20 h with cholesterol-rich dispersions, there was an increase in C/PL and eta37 in both the membrane and granule fractions. However, this occurred more rapidly in membranes so that, at 5 h (a time when an increased sensitivity of whole platelets to epinephrine is evident), membrane C/PL had increased 55% and eta37 had increased 42%, whereas granule C/PL and eta37 had changed minimally. Cholesterol-rich platelets and subcellular fractions had a lower fusion (or flow) activation energy for viscosity (deltaE), reflecting a higher degree of order, and the converse was true in cholesterol-poor platelets. Moreover, a strong negative correlation existed between the percent change in deltaE and the percent change in eta37 induced either by cholesterol incorporation or depletion. These data demonstrate that cholesterol influences the fluidity and the degree of order within the hydrophobic core of platelet membranes. Changes induced in these physical properties by an excess of cholesterol relative to phospholipid may underlie the abnormal reception or transmission of the aggregation stimulus in cholesterol-rich platelets.
在从IIa型高脂蛋白血症患者获取的血小板中,以及在与富含胆固醇的卵磷脂分散液孵育后的正常血小板中,均观察到对肾上腺素诱导的聚集敏感性增加。我们之前报道过,在上述每种情况下,血小板的膜部分相对于磷脂富含胆固醇。为了进一步探究胆固醇对血小板膜的影响,我们使用疏水性荧光探针1,6 - 二苯基 - 1,3,5 - 己三烯(DPH),在通过与各种胆固醇 - 卵磷脂超声分散液孵育来改变血小板胆固醇与磷脂摩尔比(C/PL)的条件下,检测了全血小板和血小板亚细胞组分的流动性(微粘度)。血小板的C/PL直接影响DPH的旋转扩散,如荧光偏振变化所示。这表现为37摄氏度时微粘度(ETA37)从正常血小板的2.84泊增加到C/PL增加118%的血小板中的4.06泊。相反,C/PL降低43%的血小板,其eta37降低了13%。在整个这个范围内,C/PL与eta37之间存在强相关性(r = 0.94)。然而,C/PL对DPH的激发态荧光寿命没有影响。分离的血小板膜中的C/PL和eta37均低于血小板颗粒组分。当血小板与富含胆固醇的分散液孵育20小时时,膜和颗粒组分中的C/PL和eta37均增加。然而,这种情况在膜中发生得更快,以至于在5小时(此时全血小板对肾上腺素的敏感性增加明显)时,膜C/PL增加了55%,eta37增加了42%,而颗粒C/PL和eta37变化极小。富含胆固醇的血小板和亚细胞组分对粘度的融合(或流动)活化能较低(deltaE),反映出更高的有序程度,而胆固醇含量低的血小板则相反。此外,由胆固醇掺入或消耗引起的deltaE百分比变化与eta37百分比变化之间存在强负相关性。这些数据表明,胆固醇影响血小板膜疏水核心内的流动性和有序程度。相对于磷脂而言,过量胆固醇引起的这些物理性质变化可能是富含胆固醇的血小板中聚集刺激异常接收或传递的基础。
