中性红再生紫膜的光化学性质

研究了中性红再生紫膜从先适应状态到暗适应状态的反应及再生紫膜中中性红的光吸收变化。实验结果说明紫膜上的金属离子结合位点可能深入膜内的质子通道,与构成质子通道的一些重要氨基酸残基相互作用。紫膜经去离子化处理变成蓝膜后,带有正电荷的质子化中性红也可以占据此金属离子结合位点,使蓝膜再生为紫膜。但金属离子与结合位点具有更强的亲和力,使蓝膜再生为紫膜的能力比质子化中性红强。     

嗜菌紫膜表面电位和质子泵效率间的关系

本文研究了中性红与紫膜结合,并用直接滴定法和测定结合量法,求得了结合于膜上之中性红本征PK和在不同离子强度时的表观PKa值.从它们的差值中计算得到紫膜表面电位.并得不同盐浓度的表面电位和质子泵效率作了比较.结果说明.阳离子对质子泵效率的影响不能完全用表面电位的变化来说明.这一结果暗示了一定的阳离子对于紫膜质子泵功能的完成有着特殊作用.     

肼对蓝膜的影响

利用紫外可见吸收光谱和动力学光谱法研究了无水肼对蓝膜的影响,研究结果表明:无水肼可以使蓝膜转化为紫膜,同时光循环也得到恢复,但是光循环中间体M412的衰减加快,这与金属阳离子加入到蓝膜溶液中时的现象是完全不同的(这个过程中M412的衰减是减慢的).同时研究了pH和温度对无水肼与蓝膜之间相互作用的影响.在无水肼加入到蓝膜溶液中时,重组反应的灵敏度是pH和温度依赖的.在pH4.8到pH2之间,灵敏度随酸性的增加而降低.在20～40℃之间,无水肼与蓝膜溶液的反应灵敏度随着温度的升高而降低.     

滤光膜对黄檗离体再生能力及其生理生化指标影响

以黄檗（Phellodendron amurense）无菌苗茎段为材料,MS附加1.5 mg·L^-1 BA和0.5 mg·L^-1 NAA为基本培养基,研究了不同滤光膜对黄檗茎段离体再生影响,并对再生过程中生理生化指标变化进行了研究。结果表明,蓝膜对不定芽再生有着明显的促进作用,再生频率达75.4%,平均每个外植体再生的不定芽数为14.7,其次为荧光和黄膜,红膜和绿膜不利于芽的分化。同时发现,蓝膜和荧光有较高的叶绿素含量、较低的chla/b比值。抗氧化酶的活性和可溶性蛋白的含量以蓝膜最高,荧光次之,绿膜最低。     

肼类与蓝膜的相互作用

采用紫外可见光谱、动力学光谱和荧光光谱,研究了肼、甲基肼和偏二甲基肼与蓝膜的相互作用。结果表明这些肼类都可使蓝膜恢复为紫膜,并恢复紫膜原有的光循环方式。但是,中间体(M412)的衰減速率加快,这在金属离子重组紫膜中没有发生。另外,当肼加入蓝膜时,荧光光谱没有明显变化;而去掉金属离子的蓝膜,其荧光強度明显增加。     

表面压与紫膜含量对紫膜LB膜质量的影响

本文报导了用表面轮廓测量仪测量了不同表面压和不同紫膜含量下制备的紫膜LB膜中紫膜碎片的厚度。实验结果表明:单个紫膜碎片在紫脂LB膜中的厚度为50左右,相当数量的紫膜碎片之间有重叠。当表面压为30mN/m或紫膜碎片与大豆磷脂之重量比为20:1时,紫膜碎片容易进入到水相或碎片之间相互重叠变得更加严重。     

温度对紫膜bR结构的影响

温度升高使天然紫膜在可见差分吸收光谱中650nm处出现一吸收峰,这意味着紫膜去离子兰膜的形成,而这在脱氧胆酸处理后的紫膜中并未出现.天然紫膜与脱脂紫膜在630nm处的吸收与温度间的关系进一步表明:只有天然紫膜在温度大于68℃才有膜结合离子的释放,释放的离子结合于移去的膜脂之上.紫膜结合离子的释放改变了天然紫膜中bR的构象.热致离子的释放还受介质pH值及介质中离子的影响.pH5.03时,热致离子释放温度提前至温度46℃,而pH7.00,10mM MgCl_2及pH9.00时都没有观察到紫膜离子释放.温度对紫膜在不同pH值时表面电位影响的不一致性进一步表明这是由于膜表面电荷参与的结果.     

紫膜LB膜的结构特性研究

研究了紫膜LB膜中的紫膜碎片的结构特性。扫描电子显微镜观察表明,紫膜LB膜中单个紫膜碎片的直径大约为0.3微米。表面轮廓测量仪(简称台阶仪)观察到紫膜LB膜中的紫膜碎片的厚度为40—50。在不同的表面压和不同紫膜含量时测量了紫膜碎片在紫膜LB膜中的形态学分布,当表面压为30mN/m或紫膜与大豆磷脂的重量比大于20:1时,紫膜碎片容易重叠或凝聚。     

光质对温室甜椒干物质生产和分配指数的影响

为了研究不同光质对甜椒植株干物质生产与分配指数的影响,以甜椒茎有限生长品种"苏椒13号"为试验材料,于2010年计不同种彩色塑料薄膜(红、黄、蓝、绿、紫,白色为对照)试验。结果表明:不同光质处理的甜椒单位面积干物质生产量(Wt)与冠层截获的太阳光合有效辐射日积分(daily photosynthetic active radiation integral,PARi,MJ·m-2)之间的模型为Wt=22.07×e0.0054λPARi;单位面积植株总干重、果实的干物质分配指数、果实采收指数和单位面积果实产量均以红膜最高,紫膜最低;蓝膜的茎干物质分配指数最高,红膜最低;蓝膜、绿膜和紫膜的植株叶片干物质分配指数明显高于红膜和黄膜;不同光质处理对甜椒植株地上部分干物质分配指数的影响差异不显著;研究认为红膜和黄膜能够促进甜椒植株的干物质积累和果实发育,紫膜和蓝膜则有明显的抑制作用,该研究结果可为温室甜椒栽培的光质选择和环境调控提供决策依据。     

紫膜在含水凝胶中的定向和状态

用几种光谱学方法研究了紫膜凝胶的定向度、生色团视黄醛的状态以及其光循环中间产物M的动力学过程。结果表明:用通常采用的制备方法所得到的紫膜凝胶虽然能得到光电响应信号,但其定向度并不理想,生色团视黄醛的构象受到较大扰动,光循环中间产物M的产出及衰减也受到抑制,部分样品甚至由于其视黄醛的脱落而完全失去颜色,其质子泵功能也随之丧失。这说明虽然紫膜凝胶是目前研究紫膜质子泵机理(光电响应测量)和构造分子电子器件较好的和有希望的人工膜系统之一,但由于该系统对紫膜结构和功能的扰动仍然较大,紫膜的定向较难控制,所以,我们仍需在凝胶的形成体系及方法的改进上作大量工作。     

Electrooptical analysis of blue and of cation-regenerated bacteriorhodopsin

Blue bacteriorhodopsin was prepared by electrodialysis, cation-exchange chromatography and acidification. The electrooptical properties of these preparations compared to those of the native purple bacteriorhodopsin suggest that the blue bacteriorhodopsin has a smaller induced dipole moment than the native purple bacteriorhodopsin and that bound cations in the native bacteriorhodopsin stabilize the protein conformation in the membrane.Purple bacteriorhodopsin was regenerated by addition of potassium, magnesium or ferric ions to blue bacteriorhodopsin. Both spectrscopically and electrooptically the potassium- and ferric-regenerated samples are different from the native purple state. Although the magnesium-regenerated sample is spectroscopically similar to the native purple bacteriorhodopsin, the electrooptical properties are rather similar to those of the cation-depleted blue sample, suggesting that it is very difficult to re-stabilize protein structures once cations are depleted.     

Electrooptical studies on proton-binding and -release of bacteriorhodopsin

Electric field induced pH changes of purple membrane suspensions were investigated in the pH range from 4.1 to 7.6 by measuring the absorbance change of pH indicators. In connection with the photocycle and proton pump ability, three different states of bacteriorhodopsin were used: (1) the native purple bacteriorhodopsin (magnesium and calcium ions are bound, the M intermediate exists in the photocycle and protons are pumped), (2) the cation-depleted blue bacteriorhodopsin (no M intermediate), and (3) the regenerated purple bacteriorhodopsin which is produced either by raising the pH or by adding magnesium ions (the M intermediate exists). In the native purple bacteriorhodopsin there are, at least, two types of proton binding sites: one releases protons and the other takes up protons in the presence of the electric field. On the other hand, blue bacteriorhodopsin and the regenerated purple bacteriorhodopsin (pH increase) show neither proton release nor proton uptake. When magnesium ions are added to the suspensions; the field-induced pH change is observed again. Thus, the stability of proton binding depends strongly on the state of bacteriorhodopsin and differences in proton binding are likely to be related to differences in proton pump activity. Furthermore, it is suggested that the appearance of the M intermediate and proton pumping are not necessarily related.     

Electric field induced conformational changes of bacteriorhodopsin in purple membrane films

Electric field-induced absorption changes of bacteriorhodopsin were studied with different samples of purple membranes which were prepared as randomly oriented and electrically oriented films of purple as well as cation-depleted blue bacteriorhodopsin. The absorption changes were proportional to the square of the field strength up to 300 kV/cm. The electric field from the intracellular side to the extracellular side of the purple bacteriorhodopsin induces a spectrum change, resulting in a spectrum similar to that of the cation-depleted blue bacteriorhodopsin. When the field was removed, the purple state was regenerated. The blue state was mainly affected by an electric field in the opposite direction, suggesting a reversible interaction with the Schiff's base bond of the retinal. Since the field-induced reaction of bacteriorhodopsin was observed in the presence of a concomitant steady ion flux, it is assumed that the generation of a local diffusion potential may play an important role in these spectral reactions. Although the fragments were fixed in the dried film, electric dichroism was observed. The dichroic contribution of the total absorbance change was about 15%. The angular displacement of the retinal transition moment was calculated to be 1.5° toward the membrane normal.     

Romanowsky dyes and Romanowsky-Giemsa effect. 5. Structural investigations of the purple DNA-AB-EY dye complexes of Romanowsky-Giemsa staining.

A reproducible Romanowsky-Giemsa staining (RGS) can be carried out with standardized staining solutions containing the two dyes azure B (AB) and eosin Y (EY). After staining, cell nuclei have a purple coloration generated by DNA-AB-EY complexes. The microspectra of cell nuclei have a sharp and intense absorption band at 18,100 cm-1 (552 nm), the so called Romanowsky band (RB), which is due to the EY chromophore of the dye complexes. Other absorption bands can be assigned to the DNA-bound AB cations. Artificial DNA-AB-EY complexes can be prepared outside the cell by subsequent staining of DNA with AB and EY. In the first step of our staining experiments we prepared thin films of blue DNA-AB complexes on microslides with 1:1 composition: each anionic phosphodiester residue of the nucleic acid was occupied by one AB cation. Microspectrophotometric investigations of the dye preparations demonstrated that, besides monomers and dimers, mainly higher AB aggregates are bound to DNA by electrostatic and hydrophobic interactions. These DNA-AB complexes are insoluble in water. Therefore it was possible to stain the DNA-AB films with aqueous EY solutions and also to prepare insoluble DNA-AB-EY films in the second step of the staining experiments. After the reaction with EY, thin sites within the dye preparations were purple. The microspectra of the purple spots show a strong Romanowsky band at 18,100 cm-1. Using a special technique it was possible to estimate the composition of the purple dye complexes. The ratio of the two dyes was approximately EY:AB approximately 1:3. The EY anions are mainly bound by hydrophobic interaction to the AB framework of the electrical neutral DNA-AB complexes. The EY absorption is red shifted by the interaction of EY with the AB framework of DNA-AB-EY. We suppose that this red shift is caused by a dielectric polarization of the bound EY dianions. The DNA chains in the DNA-AB complexes can mechanically be aligned in a preferred direction k. Highly oriented dye complexes prepared on microslides were birefringent and dichroic. The orientation is maintained during subsequent staining with aqueous EY solutions. In this way we also prepared highly orientated purple DNA-AB-EY complexes on microslides. The light absorption of both types of dye complexes was studied by means of a microspectrophotometer equipped with a polarizer and an analyser. The sites of best orientation within the dye preparations were selected under crossed nicols according to the quality of birefringence.(ABSTRACT TRUNCATED AT 400 WORDS)     

Solid-state 13C and 15N NMR study of the low pH forms of bacteriorhodopsin

The visible absorption of bacteriorhodopsin (bR) is highly sensitive to pH, the maximum shifting from 568 nm (pH 7) to approximately 600 nm (pH 2) and back to 565 nm (pH 0) as the pH is decreased further with HCl. Blue membrane (lambda max greater than 600 nm) is also formed by deionization of neutral purple membrane suspensions. Low-temperature, magic angle spinning 13C and 15N NMR was used to investigate the transitions to the blue and acid purple states. The 15N NMR studies involved [epsilon-15N]lysine bR, allowing a detailed investigation of effects at the Schiff base nitrogen. The 15N resonance shifts approximately 16 ppm upfield in the neutral purple to blue transition and returns to its original value in the blue to acid purple transition. Thus, the 15N shift correlates directly with the color changes, suggesting an important contribution of the Schiff base counterion to the "opsin shift". The results indicate weaker hydrogen bonding in the blue form than in the two purple forms and permit a determination of the contribution of the weak hydrogen bonding to the opsin shift at a neutral pH of approximately 2000 cm-1. An explanation of the mechanism of the purple to blue to purple transition is given in terms of the complex counterion model. The 13C NMR experiments were performed on samples specifically 13C labeled at the C-5, C-12, C-13, C-14, or C-15 positions in the retinylidene chromophore. The effects of the purple to blue to purple transitions on the isotropic chemical shifts for the various 13C resonances are relatively small. It appears that bR600 consists of at least four different species. The data confirm the presence of 13-cis- and all-trans-retinal in the blue form, as in neutral purple dark-adapted bR. All spectra of the blue and acid purple bR show substantial inhomogeneous broadening which indicates additional irregular distortions of the protein lattice. The amount of distortion correlates with the variation of the pH, and not with the color change.     

On the molecular mechanism of the blue to purple transition of bacteriorhodopsin. UV-difference spectroscopy and electron spin resonance studies

Conformational changes in the bacteriorhodopsin molecule related to the blue to purple transition have been monitored using UV-difference spectrophotometry. Mn2+ binding to the deionized blue membrane, which restores the purple form, promotes the appearance of a difference spectrum that can be interpreted as arising from tryptophan perturbation. Similar difference spectra were found upon pH increase of the blue membrane suspensions. Such pH increase yields the deionized purple membrane and shows an apparent pK of 5.4. Binding of Hg2+ to the blue membrane does not induce any UV-difference spectrum or change the apparent pK of the transition. ESR studies of Mn2+ binding show that in the pink membrane several high and medium affinity binding sites have been converted to low affinity ones. In the NaBH4-reduced membrane, a medium affinity site has been converted to a low affinity site. Upon Mn2+ binding to the reduced membrane or pH increase, absorption changes were found in the visible region which showed a dependence upon bound Mn2+ as well as an apparent pK similar to those of the nonreduced membrane. It is proposed that the functional form of the membrane depends primarily on the deprotonated state of a control group and that cation binding only affects the pK of this deprotonation through changes in the membrane surface potential.     

The relationship between the chromophore moiety and the cation binding sites in bacteriorhodopsin

Bleaching of the purple membrane strongly reduces the number of divalent cation binding sites as well as their affinities. Conversely, deionization of the bleached membrane drastically inhibits the chromophore regeneration. Proteolysis experiments using bromelain show that the bleached membrane has an additional cleavage site probably located at the fifth loop, whereas in the blue membrane, the C-terminal tail is no longer susceptible to proteolysis. It is suggested that there exists a close relationship between the retinal environment and one or more of the cation binding sites.     

Electric field induced conformational changes of bacteriorhodopsin in purple membrane films

Electric field induced conformational changes of bacteriorhodopsin were studied in six types of dried film (randomly and electrically oriented membranes of purple as well as cation-depleted blue bacteriorhodopsin) by measuring the frequency dependence of the optical absorbance change and the dielectric dispersion and absorption. For the purple bacteriorhodopsin the optical absorbance change induced by alternating rectangular electric fields of ±300 kV/cm altered the sign twice in the frequency range from 0.001 Hz to 100 kHz (around 0.03 Hz and 100 kHz), indicating that the electric field induced conformational change in these samples consists of, at least, three steps. Similarly, it was found for the blue bacteriorhodopsin that at least two steps are involved. In accord with optical measurements, the dielectric behaviour due to alternating sinusoidal electric fields of±6kV/cm in the frequency range from 10 Hz to 10 MHz showed two broad dispersion/absorption regions, one below 1 kHz and the other around 10–100 kHz. This suggests that the conformational change of bacteriorhodopsin is also reflected by its dielectrical properties and that it is partially induced at 6 kV/cm. Including previous results obtained by analysis of the action of DC fields on purple membrane films, a model for a field-induced cyclic reaction for purple as well as blue bacteriorhodopsin is proposed. In addition it was found that there are electrical interactions among purple membrane fragments in dried films.