Schroeder F, Nemecz G, Gratton E, Barenholz Y, Thompson T E
Division of Pharmacology and Medical Chemistry, College of Pharmacy, University of Cincinnati, Medical Center, O.H. 45267-0004.
Biophys Chem. 1988 Oct;32(1):57-72. doi: 10.1016/0301-4622(88)85034-8.
The fluorescent sterol delta 5,7,9,(11)-cholestatrien-3 beta-ol (cholestatrienol) was incoporated into 1-palmitoyl-2-oleoyl-phosphatidylcholine (POPC) small unilamellar vesicles (SUV) with and without cholesterol in order to monitor sterol-sterol interactions in model membranes. Previously another fluorescent sterol, dehydroergosterol (F. Schroeder, Y. Barenholz, E. Gratton and T.E. Thompson. Biochemistry 26 (1987) 2441), was used for this purpose. However, there is some concern that dehydroergosterol may not be the best analogue for cholesterol. Fluorescence properties of cholestatrienol in POPC SUV were highly sensitive to cholestatrienol purity. The fluorescence decay of cholestatrienol in the POPC SUV was analyzed by assuming either that the decay is comprised of a discrete sum of exponential components or that the decay is made up of one or more component's distribution of lifetimes. The decay for cholestatrienol in POPC SUV analyzed using distributions had a lower chi 2 value and was described by a two-component Lorentzian function with centers near 0.86 and 3.24 ns, and fractional intensities of 0.96 and 0.04, respectively. Both distributions were quite narrow, i.e., 0.05 ns full-width at half-maximum peak height. It is proposed that the two lifetime distributions are generated by separate continua of environments for the cholestatrienol molecule described by different dielectric constants. In the range 0-6 mol% cholestatrienol, the cholestatrienol underwent a concentration-dependent relaxation. This process was characterized by red-shifted absorption and maxima and altered ratios of absorption and fluorescence excitation maxima. Fluorescence quantum yield, lifetime, steady-state anisotropy, limiting anisotropy and rotational rate remained constant. In contrast, in POPC vesicles containing between 6 and 33 mol% cholestatrienol, the fluorescent cholestatrienol partially segregated, resulting in quenching. Thus, below 6 mol% cholestatrienol, the cholestatrienol appeared to behave in part as monomers exposed to some degree to the aqueous solvent in a sterol-poor domain within POPC bilayers. Since the lifetime did not decrease above 6 mol% cholestatrienol, the fluorescence at high mol% values of cholestatrienol was due to cholestatrienol in the sterol-poor domain. The fluorescence intensity, quantum yield, steady-state anisotropy, and limiting anisotropy of cholestatrienol in the sterol-poor domain decreased to limiting, nonzero values while the rotational rate increased to a limiting value. Thus, the sterol-poor domain became more disordered when it coexisted with the sterol-rich domain.(ABSTRACT TRUNCATED AT 400 WORDS)
将荧光甾醇δ5,7,9,(11)-胆甾三烯-3β-醇(胆甾三烯醇)掺入含有和不含有胆固醇的1-棕榈酰-2-油酰-磷脂酰胆碱(POPC)小单层囊泡(SUV)中,以监测模型膜中的甾醇-甾醇相互作用。此前,另一种荧光甾醇脱氢麦角甾醇(F. 施罗德、Y. 巴伦霍尔兹、E. 格拉顿和T.E. 汤普森。《生物化学》26 (1987) 2441)曾用于此目的。然而,有人担心脱氢麦角甾醇可能不是胆固醇的最佳类似物。胆甾三烯醇在POPC SUV中的荧光特性对胆甾三烯醇纯度高度敏感。通过假设衰减由指数成分的离散总和组成或衰减由一个或多个寿命成分的分布组成,分析了胆甾三烯醇在POPC SUV中的荧光衰减。使用分布分析的胆甾三烯醇在POPC SUV中的衰减具有较低的卡方值,并由中心接近0.86和3.24纳秒、分数强度分别为0.96和0.04的双组分洛伦兹函数描述。两种分布都相当窄,即在半峰高处全宽为0.05纳秒。有人提出,两种寿命分布是由具有不同介电常数的胆甾三烯醇分子的不同连续环境产生的。在0 - 6摩尔%胆甾三烯醇范围内,胆甾三烯醇经历了浓度依赖性弛豫。这个过程的特征是吸收峰红移、最大值以及吸收和荧光激发最大值的比率改变。荧光量子产率、寿命、稳态各向异性、极限各向异性和旋转速率保持不变。相比之下,在含有6 - 33摩尔%胆甾三烯醇的POPC囊泡中,荧光胆甾三烯醇部分分离,导致淬灭。因此,在6摩尔%胆甾三烯醇以下,胆甾三烯醇似乎部分表现为在POPC双层内甾醇贫乏区域中一定程度上暴露于水性溶剂的单体。由于在6摩尔%胆甾三烯醇以上寿命没有降低,高摩尔%值的胆甾三烯醇的荧光是由于甾醇贫乏区域中的胆甾三烯醇。甾醇贫乏区域中胆甾三烯醇的荧光强度、量子产率、稳态各向异性和极限各向异性降低到极限非零值,而旋转速率增加到极限值。因此,当甾醇贫乏区域与甾醇丰富区域共存时,它变得更加无序。(摘要截断于400字)
