Analysis of Quantum Mechanics Microscopic Mechanism on Genetic Mutagenesis of Laser

用量子力学研究了激光对ＤＮＡ的键（或链）的局域相互作用及激光对ＤＮＡ分子系统的相互作用的微观机理。研究结果可以解释激光的遗传诱变效应。     

激光的遗传诱变效应的微观机理的量子力学分析

用量子力学研究了激光对ＤＮＡ的键（或链）的局域相互作用及激光对ＤＮＡ分子系统的相互作用的微观机理。研究结果可以解释激光的遗传诱变效应。     

低强度激光生物效应机理研究

结合低强度激光生物效应研究的现状,对低强度激光生物效应机理研究的各种观点进行了归纳分析,提出了对低强度激光生物效应机理研究的一些初步思考,把低强度激光生物效应的一般过程归纳为：激光（辐射)→初始光受体→信号传导与放大→生物效应。并指出探讨低强度激光生物效应机理,应着重于寻找并研究初始光受体与激光的相互作用,以及随后的信号传导与放大过程。     

激光作用DNA的非线性量子遗传突变理论分析

采用Ｗｉｇｎｅｒ表示和Ｈｕｓｉｍｉ表示分析了ＤＮＡ量子系统，并给出了在激光作用下，不同自由度的ＤＮＡ分子的经典和量子系统非线性共振的突变条件。这一研究结果有助于激光对ＤＮＡ的损伤、对生物遗传致突变性诱变以及致癌效应的解释。     

胆酸盐对蟾蜍皮肤静息电位的影响

近年来一些学者研究了胆酸盐对各种组织和细胞作用的理化效应。他们特别感兴趣的是这种物质对细胞透性、离子通道的影响,及胆酸盐同细胞膜蛋白之间的相互作用和溶解过程的分子特性。这类研究在理论和实践上都具有广泛意义。例如,将胆酸盐作为一种微扰探针,以获得有关离子通道和膜脂肪成分,即蛋白-脂肪相互作用的信息;或者用于膜蛋白的分级分离制备程序,借以提取某些受体和Na-     

血红蛋白对人红细胞膜流动性的影响

本文报道了pH7.5时血红蛋白和红细胞膜的结合效应.在10—45℃温度范围内观察到血红蛋白对膜脂质流动性的限制作用.看来这种限制作用不是脂质过氧化所致,而是血红蛋白和红细胞膜直接作用的结果.对流动性大的膜,血红蛋白的效应也随之增大.高铁血红蛋白及红细胞膜去胆固醇皆能修饰血红蛋白和膜的相互作用.     

壳寡糖作用于巨噬细胞的机制初探

研究壳寡糖对免疫系统中巨噬细胞作用的具体机制.结合流式细胞仪和激光共聚焦实验检测壳寡糖与巨噬细胞相互作用,通过凝胶阻滞实验在体外验证壳寡糖的胞内定位.实验结果证明壳寡糖与巨噬细胞相互作用过程如下,先与细胞膜结合,然后进入细胞内,最后定位在细胞核的核酸(DNA/RNA)上.     

极化上皮细胞中转运蛋白的分选

上皮组织细胞必须极化其表面区域以执行其转运生理功能。不同膜转运蛋白定位于细胞膜的不同区域,而细胞与细胞之间则须通过紧密连接复合体紧密连接成极化区域,并调节旁细胞途径的通透性。精密的机体要求上皮细胞具备一个筛选装置,用于将新合成的转运蛋白定位于合适的表面区域;转运蛋白本身也必须内含规定其功能位置的分选信号。目前上皮细胞蛋白分选和蛋白质之间相互作用已被逐渐阐明。上皮细胞通过细胞信号转导途径形成极化初始状态,将自己定位于特定位置,调节细胞与细胞之间、细胞与基质之问的相互作用。最近研究发现其信号转导通路的一个成员是一种AMP激活的蛋白激酶（AMP-stimulated protein kinase．AMPK）,它也是细胞能量感受器。     

《激光与生物组织的相互作用原理及应用》(原书第三版)介绍

本书由MH尼姆兹[德]著,张镇西等译,蒋大宗校。全书系统地描述了激光与生物组织的相互作用原理及在相关领域的应用,详细论述了组织的光和热特性、组织蚀除的各种类型、光致破裂效应的基本概念以及使用的数学工具如MonteCarlo模拟、Kube墩a—Munk理论和光动力学疗法 、激光诱导组织间质热疗法等。     

量子点标记活细胞内GLUT4 蛋白的研究

目的:研究量子点标记活细胞内GLUT4蛋白的方法,用于长时程观察活细胞内GLUT4的转运过程。方法:使用在GLUT4蛋白膜外区构建了myc位点的L6-GLUT4myc细胞系,用胰岛素刺激L6细胞内的GLUT4myc转运到细胞膜上,通过抗体抗原反应先后将一抗9E10和偶联二抗IgG的量子点与特异性位点结合。结果:通过量子点标记固定细胞内GLUT4的实验,证明了标记方法的特异性和灵敏性。量子点能够标记细胞膜表面的GLUT4蛋白并伴随GLUT4的胞吞进入细胞。适当调整实验温度,用量子点标记细胞膜上的GLUT4并且在实验过程结束后将标记了量子点的GLUT4保持在细胞膜表面,能够观察活细胞内GLUT4蛋白内化和胞内循环的过程。结论:发展了量子点标记活细胞内GLUT4的方法,为进一步研究活细胞内GLUT4的转运过程打下了基础。     

Laser induced cell fusion in combination with optical tweezers: the laser cell fusion trap.

A single-beam gradient force optical trap was combined with a pulsed UV laser microbeam in order to perform laser induced cell fusion. This combination offers the possibility to selectively fuse two single cells without critical chemical or electrical treatment. The optical trap was created by directing a Nd:YAG laser, at a wavelength of 1.06 microns, into a microscope and focusing the laser beam with a high numerical aperture objective. The UV laser microbeam, produced by a nitrogen-pumped dye laser (366 nm), was collinear with the trapping beam. Once inside the trap, two cells could be fused with several pulses of the UV laser microbeam, attenuated to an energy of approximately 1 microJ/pulse in the object plane. This method of laser induced cell fusion should provide increased selectivity and efficiency in generating viable hybrid cells.     

激光微束在两种鱼受精卵上打孔技术研究

在埃及胡子鲶和苏氏芒鲶两种鱼受精卵上,用脉冲ＹＡＧ激光微束打孔技术,成功地导入了外源指示剂和用激光微束打过孔的受精卵孵化出了仔鱼,为今后激光微束打孔植入外源基因和针类转基因研究做了一些有意义的探索工作。     

激光微束技术及其在基因转移研究中的应用

本文中介绍了我们设计和安装的一套激光微束系统,该系统分为二部份:激光源和显微镜.工作波长355nm是由电子调Q Nd:YAG激光经KDP倍频和混频后得到的.这束光从显微镜的左边引入45°反射,再经×100物镜聚焦.光束直径小于1μ.这束激光可给细胞打孔,约在1秒内小孔自行修复,在修复之前荧光物质和质粒可以扩散进细胞.我们成功地把GUS基因导入烟草花粉细胞中并得到瞬间表述,还把DAPI-λDNA导入M85胃癌细胞必观察到兰色荧光.从本工作初步表明这种导入方法很有发展前途.     

激光微束在遗传操作上的应用

本文概述了近年来激光微束在染色体微切割和微分离、分子细胞生物学、去除细胞壁、诱导原生质体融合等方面的应用,并对其今后的应用前景作了展望。     

激光诱导金盏菊原生质体融合方法初探

本文简述运用激光微束诱导金盏菊(Calendula Officinali L.)叶肉细胞原生质体融合的方法和初步结果,并就激光诱导植物原生质体融合的条件进行初步讨论。     

In-depth activation of channelrhodopsin 2-sensitized excitable cells with high spatial resolution using two-photon excitation with a near-infrared laser microbeam

We used two-photon excitation with a near-infrared (NIR) laser microbeam to investigate activation of channelrhodopsin 2 (ChR2) in excitable cells for the first time to our knowledge. By measuring the fluorescence intensity of the calcium (Ca) indicator dye, Ca orange, at different wavelengths as a function of power of the two-photon excitation microbeam, we determined the activation potential of the NIR microbeam as a function of wavelength. The two-photon activation spectrum is found to match measurements carried out with single-photon activation. However, two-photon activation is found to increase in a nonlinear manner with the power density of the two-photon laser microbeam. This approach allowed us to activate different regions of ChR2-sensitized excitable cells with high spatial resolution. Further, in-depth activation of ChR2 in a spheroid cellular model as well as in mouse brain slices was demonstrated by the use of the two-photon NIR microbeam, which was not possible using single-photon activation. This all-optical method of identification, activation, and detection of ChR2-induced cellular activation in genetically targeted cells with high spatial and temporal resolution will provide a new method of performing minimally invasive in-depth activation of specific target areas of tissues or organisms that have been rendered photosensitive by genetic targeting of ChR2 or similar photo-excitable molecules.     

Microdissection of human chromosomes by a laser microbeam

A laser microbeam apparatus, based on an excimer laser pumped dye laser is used to microdissect human chromosomes and to isolate a single chromosome slice.     

激光微束切割小冰麦异附加系染色体的研究

利用激光微束,并选用适当的功率密度可将小冰麦异附加系花粉细胞染色体切割成2～3个片段,这个技术的建立为激光微束应用于染色体片段DNA微克隆及基因定位提供可能。     

Poleward force at the kinetochore in metaphase depends on the number of kinetochore microtubules

To examine the dependence of poleward force at a kinetochore on the number of kinetochore microtubules (kMTs), we altered the normal balance in the number of microtubules at opposing homologous kinetochores in meiosis I grasshopper spermatocytes at metaphase with a focused laser microbeam. Observations were made with light and electron microscopy. Irradiations that partially damaged one homologous kinetochore caused the bivalent chromosome to shift to a new equilibrium position closer to the pole to which the unirradiated kinetochore was tethered; the greater the dose of irradiation, the farther the chromosome moved. The number of kMTs on the irradiated kinetochore decreased with severity of irradiation, while the number of kMTs on the unirradiated kinetochore remained constant and independent of chromosome-to-pole distance. Assuming a balance of forces on the chromosome at congression equilibrium, our results demonstrate that the net poleward force on a chromosome depends on the number of kMTs and the distance from the pole. In contrast, the velocity of chromosome movement showed little dependence on the number of kMTs. Possible mechanisms which explain the relationship between the poleward force at a kinetochore, the number of kinetochore microtubules, and the lengths of the kinetochore fibers at congression equilibrium include a "traction fiber model" in which poleward force producers are distributed along the length of the kinetochore fibers, or a "kinetochore motor-polar ejection model" in which force producers located at or near the kinetochore pull the chromosomes poleward along the kMTs and against an ejection force that is produced by the polar microtubule array and increases in strength toward the pole.     

Telomeric sequences derived from laser-microdissected polytene chromosomes

Telomeric fragments from salivary gland squashes of Drosophila melanogaster Oregon R. were produced by a new microdissection technique, UV laser microbeam dissection. Microdissection, an essential step in microcloning procedures, is usually performed using micromanipulators and microneedles. Recently it has been shown that microdissection can be improved to very high precision if a laser coupled into a microscope is used. A laser microbeam, generated by an excimer pumped dye laser, allows chromosomes to be cut into slices of less than 0.5 m. Here it is shown, that single copy DNA probes prepared from Drosophila chromosomes by laser microdissection and microcloning relocalize to the chromosomal regions from which they are derived. The combination of laser technique and microcloning provides an advantageous approach for rapid genetic analysis with potential for the study of genetic diseases and genome mapping.