Cooper R A, Arner E C, Wiley J S, Shattil S J
J Clin Invest. 1975 Jan;55(1):115-26. doi: 10.1172/JCI107901.
Cholesterol-rich membranes are the hallmark of "spur" red cells. Spur cells accumulate cholesterol from cholesterol-rich serum lipoproteins. Previous studies suggested that this added cholesterol is responsible for both the altered morphology and the destruction of spur cells. To examine this process in the absence of other serum factors, cholesterol-lecithin dispersions with varying amounts of unesterified cholesterol (C) relative to phospholipid (P) were prepared, and their influence on normal human red cells was studied. Cholesterol-rich lipid dispersions (C/P mole ration greater 1.0) transferred cholesterol to both red cell membranes and serum lipoproteins, and cholesterol-poor dispersions (C/P mole ration less 1.0) depleted red cells of cholesterol. Changes in membrane cholesterol paralleled changes in membrane surface area, as calculated from osmotic fragility, with a 0.22 percent variation in surface area per 1.0 percent variation in cholesterol content. Cold-induced compression of membrane surface area was increased in cholesterol-poor red cells (C/P equals 0.4), whereas the surface area of cholesterol-rich membranes (C/P equals 1.80) underwent no compression. Although the Na and K permeability of red cells severely depleted of cholesterol was increased, lesser degrees of depletion had no effect, and the permeability of cholesterol-rich cells was normal. However, increasing membrane cholesterol caused a progressive decrease in red cell deformability, as measured by filtration. Cholesterol-poor red cells were spherocytic in appearance and cholesterol-rich cells were broad and flat, indicative of their surface areas. In addition, cholesterol-rich cells had an irregular contour due to folding of the periphery of the cell. This shape abnormality was identical to that of both spur cells after splenectomy and normal red cells incubated in spur serum. Normalization of the C/P of spur serum by added phospholipid prevented the increase in membrane cholesterol and surface area and the transformation of cell shape. These studies establish that the cholesterol content of red cells is dependent on the C/P of their milieu, either lipoproteins or cholesterol-lecithin dispersions. Moreover, the surface area, deformability, and contour of cholesterol-rich red cells are a direct function of their increased membrane C/P. Although cholesterol-rich spur cells are further modified in the circulation of patients with spleens, this abnormality of the membrane lipid bilayer, induced by cholesterol-rich cholesterol-lecithin dispersions, represents the primary spur cell defect.
富含胆固醇的膜是“棘刺”红细胞的标志。棘刺细胞从富含胆固醇的血清脂蛋白中积累胆固醇。先前的研究表明,这种额外添加的胆固醇是棘刺细胞形态改变和破坏的原因。为了在没有其他血清因子的情况下研究这一过程,制备了相对于磷脂(P)含有不同量未酯化胆固醇(C)的胆固醇 - 卵磷脂分散体,并研究了它们对正常人红细胞的影响。富含胆固醇的脂质分散体(C/P摩尔比大于1.0)将胆固醇转移到红细胞膜和血清脂蛋白中,而胆固醇含量低的分散体(C/P摩尔比小于1.0)使红细胞中的胆固醇减少。根据渗透脆性计算,膜胆固醇的变化与膜表面积的变化平行,胆固醇含量每变化1.0%,表面积变化0.22%。胆固醇含量低的红细胞(C/P等于0.4)中,冷诱导的膜表面积压缩增加,而富含胆固醇的膜(C/P等于1.80)的表面积没有压缩。尽管严重缺乏胆固醇的红细胞的钠和钾通透性增加,但程度较轻的缺乏则没有影响,富含胆固醇的细胞的通透性正常。然而,通过过滤测量,增加膜胆固醇会导致红细胞变形性逐渐降低。胆固醇含量低的红细胞外观呈球形,富含胆固醇的细胞则宽而扁平,这与其表面积相符。此外,富含胆固醇的细胞由于细胞周边折叠而轮廓不规则。这种形状异常与脾切除术后的棘刺细胞以及在棘刺血清中孵育的正常红细胞的形状异常相同。通过添加磷脂使棘刺血清的C/P正常化可防止膜胆固醇和表面积增加以及细胞形状转变。这些研究表明,红细胞的胆固醇含量取决于其所处环境的C/P,该环境可以是脂蛋白或胆固醇 - 卵磷脂分散体。此外,富含胆固醇的红细胞的表面积、变形性和轮廓是其膜C/P增加的直接函数。尽管富含胆固醇的棘刺细胞在有脾患者的循环中会进一步发生改变,但由富含胆固醇的胆固醇 - 卵磷脂分散体诱导的这种膜脂质双层异常代表了棘刺细胞的主要缺陷。
