Septinus M, Seiffert W, Zimmermann H W
Histochemistry. 1983;79(3):443-56. doi: 10.1007/BF00491779.
10-n-Alkyl-acridine-orange-chlorides (alkyl-AOs) are excellent dyes for fluorescence staining of mitochondria in living cells. The thermodynamic and spectroscopic properties of the series alkyl = methyl to nonyl have been investigated. The dyes form dimers in aqueous solution. The dimerisation is mainly a consequence of the hydrophobic interaction. The dissociation constant K respectively association constant K-1 of the dimers describes the hydrophobic interaction and therefore the hydrophobic properties of the dye cations. The dissociation constant K = K0 at the standard temperature T = 298 K has been determined spectroscopically in aqueous solution. It depends on the length of the alkyl residue n-CmH2m + 1 (m = 1 - 9) (Table 2). In addition the standard dissociation enthalpies (energies) delta H0 and dissociation entropies delta S0 have been determined from the temperature dependence of K (Table 2). With increasing chain length m the thermodynamic parameters K0, delta H0, delta S0 decrease. Therefore with growing m the dimers are stabilized. This stabilization is an entropic effect which is diminished by the energetic effect. The change of the thermodynamic parameters with m is in agreement with the concept of hydrophobic interaction and the stabilization of water structure in the surroundings of hydrophobic residues. As one would expect nonyl-AO is the most hydrophobic dye of the series. As an example the spectroscopic properties of nonyl-AO have been determined. We measured the absorption, luminescence and polarization spectra in rigid ethanol at 77 K. Under these conditions alkyl-AOs associate like dyes in Water at room temperature. The spectra depend on the concentration of the solution. In very dilute solution we observe mainly the spectra of the monomers M, in concentrated solution the spectra of the dimers D. The spectra of M and D are characteristically different. The monomers have one long wave length absorption M1 = 20.000 cm-1 with resonance fluorescence. In addition there is a long living phosphorescence at 16.600 cm-1. Its polarization is nearly perpendicular to the plane of the AO residue. The dimers have two long wave length absorption bands D1 = 18.700 and D2 = 21.200 cm-1 with very different intensities. D1 has very low intensity and is forbitten, D2 is allowed. D1 shows fluorescence. Phosphorescence has not been observed. D1, D2 and also M1 are polarized in the plane of the AO residue. At short wave length absorption and polarization spectra are very similar. From the spectra we constructed the energy level diagram of M and D (Fig. 9). The first excited state of M splits in D in two levels. The level splitting and the transition i
10 - n - 烷基 - 吖啶橙氯化物(烷基 - AO)是用于活细胞中线粒体荧光染色的优良染料。已研究了烷基从甲基到壬基系列的热力学和光谱性质。这些染料在水溶液中形成二聚体。二聚化主要是疏水相互作用的结果。二聚体的解离常数K和缔合常数K - 1描述了疏水相互作用,因此也描述了染料阳离子的疏水性质。在标准温度T = 298 K时,解离常数K = K0已在水溶液中通过光谱法测定。它取决于烷基残基n - CmH2m + 1(m = 1 - 9)的长度(表2)。此外,已根据K的温度依赖性确定了标准解离焓(能量)ΔH0和解离熵ΔS0(表2)。随着链长m的增加,热力学参数K0、ΔH0、ΔS0减小。因此,随着m的增加,二聚体变得更稳定。这种稳定化是一种熵效应,会被能量效应减弱。热力学参数随m的变化与疏水相互作用以及疏水残基周围水结构的稳定化概念一致。正如所预期的,壬基 - AO是该系列中疏水性最强的染料。作为一个例子,已确定了壬基 - AO的光谱性质。我们在77 K的刚性乙醇中测量了吸收、发光和偏振光谱。在这些条件下,烷基 - AO的缔合情况类似于室温下水溶液中的染料。光谱取决于溶液的浓度。在非常稀的溶液中,我们主要观察到单体M的光谱,在浓溶液中观察到二聚体D的光谱。M和D的光谱有明显不同。单体有一个长波长吸收峰M1 = 20000 cm - 1并伴有共振荧光。此外,在16600 cm - 1处有一个长寿命磷光。其偏振几乎垂直于AO残基的平面。二聚体有两个长波长吸收带D1 = 18700和D2 = 21200 cm - 1,强度差异很大。D1强度非常低且是禁阻的,D2是允许的。D1显示荧光。未观察到磷光。D1、D2以及M1在AO残基的平面内偏振。在短波长处,吸收和偏振光谱非常相似。根据光谱我们构建了M和D的能级图(图9)。M的第一激发态在D中分裂为两个能级。能级分裂和跃迁i
