螫虾腹屈肌的肌球蛋白-副肌球蛋白丝

利用甘油梯度离心方法分离和纯化螯虾腹屈肌粗肌丝,电子显微镜照片显示粗肌丝上有数条纵行条纹,指示其可能由数根亚丝所组成。粗肌丝的 SDS-聚丙烯酰胺凝胶电泳表明其含有肌球蛋白和副肌球蛋白,肌球蛋白仅包含有二种轻链。副肌球蛋白类晶体呈针状,具有14.5nm 和72.5nm 的横纹周期。实验结果表明,螯虾腹屈肌粗肌丝是肌球蛋白-副肌球蛋白丝。     

棉铃虫飞翔肌的超微结构

利用电子显微镜观测表明,棉铃虫Helicoverpa rmigera (Hubner)飞翔肌的肌原纤维由400～800根肌球蛋白丝组成,每根肌球蛋白由6根肌动蛋白丝环绕排列成六角形,肌节长度2.0～3.5μm,线粒体占飞翔肌的体积达42.38%～48.57%,微气管组织较为发达。初羽化棉铃虫肌原纤维和线粒体的发育基本完成,横管系统的发育相对较慢,羽化3日后趋于成熟,至5日龄占飞翔肌的体积达3.31%～3.54%。表明棉铃虫具有适宜飞行的飞翔肌结构。采自渤海海面距海岸线80km的迁飞蛾子飞翔肌基本结构和实验种群无明显的区别,但迁飞过程中的能量代谢导致线粒体内脊疏松而出现大量空洞。     

肌球蛋白微丝在高压力下的解离和重组

高压力下肌球蛋白微丝的解离研究表明,在１－６５０ｂａｒ压力下肌球蛋白微丝的解离是完全可逆的,在５℃时其解离平衡常数的对数ｌｇＫ＝－１２９,解离标准体积变化为２０８８ｍｌ／ｍｏｌ。研究还指出,由肌球蛋白聚合成肌球蛋白微丝的熵是＋１４８．５ｋｃａｌ／ｍｏｌ（２０℃）,表明这是一熵驱动的自发过程,连续二次加压解离动力学研究结果暗示,肌球蛋白二体是肌球蛋白微丝解离过程中的中间体。     

洋葱鳞茎薄壁细胞原生质体胞质肌动蛋白质微丝骨架的形态与结构

使用四甲基罗丹明标记的鬼笔环碱(TRITC-Ph)探针,以新分离的洋葱鳞茎薄壁细胞原生质体为材料,观察了细胞胞质肌动蛋白微丝骨架的结构与形态。研究结果发现洋葱鳞茎内部细胞的细胞质内存在极丰富而精细的肌动蛋白微丝束。这些肌动蛋白微丝束的直径约1.0—4.5μm,有下列四种不同的排列形式:(1)相互平行排列,方向大体与细胞的长轴垂直;(2)从一些结合位点辐射而出,并向四周延伸,然后再相互交织在一起,形成一个非常密集而复杂的网络;(3)细而稀疏,相互交织成网状,两端分别与质膜不同位置上的结合位点相连;(4)粗而稀疏,相互交织成网状,两端都与质膜相连,或一端与质膜相连,另一端与细胞核周围的微丝束网络相连。部分微丝束具有“Y”形分支。     

F-actin慢生长端的盖帽蛋白:红细胞原肌球调节蛋白

红细胞原肌球调节蛋白(erythrocyte tropomodulin,E-Tmod)是从红细胞膜中提取的原肌球蛋白(tropomyosin,TM)的结合蛋白.其N-端有两个TM结合位点和一个TM依赖的actin结合位点,C-端有5个富含亮氨酸的重复序列和一个TM非依赖的actin结合位点.作为F-actin慢生长端唯一的盖帽蛋白,E-Tmod与TM的N-端结合并同时与actin结合,减慢由TM包被的F-actin的解聚速度.E-Tmod编码基因高度保守,在红细胞、心肌细胞等细胞中广泛表达.E-Tmod对于F-actin和细胞骨架的组织以及对细胞力学特性的保持具有至关重要的作用.     

蜜蜂微孢子虫在中国的自然种系构成初探

蜜蜂微孢子虫(Nosema apis及Nosema ceranae)是微孢子虫的典型代表之一,由它寄生蜜蜂所产生的疾病,称为蜜蜂微孢子虫病。通过目前国际上普遍使用的克隆16srRNA基因(16srDNA)的片段并测序的方法来进行蜜蜂微孢子虫在我国主要养蜂地区的分布情况。结果表明,在我国主要养蜂地区,造成大量西方蜜蜂患蜜蜂微孢子虫病的是东方蜜蜂微孢子虫Nosema ceranae,至今为止未发现过去我们广泛认定的西方蜜蜂微孢子虫Nosema apis。     

微丝相关蛋白HSPC300/hHBRK1与肌球蛋白Ⅵ相互作用的鉴定

为鉴定微丝相关蛋白HSPC300/hHBRK1在肝脏组织的功能,采用GST pull-down结合质 谱技术,检测该蛋白在肝脏中的结合蛋白,结果提示,肌球蛋白Ⅵ与HSPC300/hHBRK1共沉降,Western 印迹杂交证实了质谱的结果．构建HSPC300/hHBRK1原核表达载体,诱导并获得了His-hHBRK1融合蛋白．利用免疫共沉淀证实hHBRK1与肌球蛋白Ⅵ存在相互作用,激光共聚焦检测显示hHBRK1与肌球蛋白Ⅵ在肺癌95D细胞的胞浆共定位,提示其相互作用可能是直接结合．肌球蛋白Ⅵ参与细胞迁移、高尔基分泌泡的运输和维持高尔基体稳定性等作用．hHBRK1与肌球蛋白Ⅵ相互作用,为微丝相关蛋白HSPC300/hHBRK1参与细胞迁移和胞内物质运输提供了进一步佐证．     

东方蜜蜂微孢子虫侵染意大利蜜蜂工蜂过程的nce-miR-23928及其靶基因表达谱

【背景】东方蜜蜂微孢子虫(Nosema ceranae)专性侵染成年蜜蜂中肠上皮细胞而导致的微孢子虫病给养蜂业造成严重损失。【目的】检测东方蜜蜂微孢子虫nce-miR-23928及其靶基因在侵染意大利蜜蜂(Apis mellifera ligustica)工蜂过程的表达谱,为深入探究nce-miR-23928在东方蜜蜂微孢子虫侵染中的功能及调控机制提供依据。【方法】通过RNAhybrid、miRanda和TargetScan软件预测nce-miR-23928的靶基因。使用BLAST工具将上述靶基因比对到基因本体论(geneontology,GO)、京都基因和基因组百科全书(Kyoto encyclopedia of genes and genomes, KEGG)、Nr和Swiss-Prot数据库以获得相应注释。采用实时荧光定量PCR(realtimequantitativePCR,RT-qPCR)技术检测nce-miR-23928及其靶基因在东方蜜蜂微孢子虫侵染意蜂工蜂过程中的相对表达量。【结果】相较于接种后1 d (1 day post infection, 1 dpi),nce-...     

蜜蜂飞翔肌收缩蛋白的电子显微镜鉴定

自五十年代肌丝滑行模型建立以来,关于脊椎动物骨胳肌的蛋白质成分,肌丝排列以及肌肉收缩时结构变化的研究取得了很大的进展。骨胳肌肌原纤维由粗、细肌丝有规律地排列所组成。对于肌肉收缩蛋白的选择性抽提,专一性抗体标记以及重组肌丝的研究,证实肌球蛋白存在于粗肌丝;肌动蛋白、原肌球蛋白和原宁蛋白存在于细肌丝(Huxley,A.F.,1957;Huxley,H.E;,1972)。昆虫间接飞翔肌的结构和生理特性有许多不同于脊椎动物骨胳肌的特点。蜜蜂飞翔肌肌原纤维虽然也包含有粗、细两     

意蜂（Apis mellifera）蜂王婚飞交尾机制的初探

通过氯气球悬挂意蜂（Apis mellifera）雌蜂及提取物等方法模拟蜂王婚飞交尾试验,比较不同生理状态的雌蜂及其提取物对雄蜂的性引诱力,结果表明：1．在工峰、处女王与产卵王及其提取物中,以产卵王及其提取物对雄峰性诱最大．平均分别为16只和14．3只雄蜂;2．不同数量的处女王提取物对雄蜂引诱力存在差异．以3只处女王提取物对雄蜂引诱力最大,平均引诱31.3只雄蜂;3．1000烛光以上的光照比400烛光以下的光照更有利于雄蜂的水分,且雄蜂集聚的个性体敏越多,相互激活力越强。     

THE ELONGATION OF MYOFIBRILS FROM THE INDIRECT FLIGHT MUSCLE OF DROSOPHILA

Myofibrils which lengthen by several per cent in the presence of ATP and magnesium ions were prepared by teasing indirect flight muscle of Drosophila in solutions containing ethylenediaminetetraacetate. A study was made of the hydrogen ion, magnesium ion, ATP, and potassium chloride concentrations with which this effect could be observed. The lack of elongation with pyrophosphate and several nucleoside triphosphates suggests that the lengthening is ATP specific. A relaxing factor system comparable to that described for rabbit muscle was not demonstrable, as elongated fibrils did not shorten with calcium ions, carnosine, or digitonin.     

THE VISUAL ACUITY OF THE HONEY BEE

1. Bees respond by a characteristic reflex to a movement in their visual field. By confining the field to a series of parallel dark and luminous bars it is possible to determine the size of bar to which the bees respond under different conditions and in this way to measure the resolving power or visual acuity of the eye. The maximum visual acuity of the bee is lower than the lowest human visual acuity. Under similar, maximal conditions the fineness of resolution of the human eye is about 100 times that of the bee. 2. The eye of the bee is a mosaic composed of hexagonal pyramids of variable apical angle. The size of this angle determines the angular separation between adjacent ommatidia and therefore sets the structural limits to the resolving power of the eye. It is found that the visual angle corresponding to the maximum visual acuity as found experimentally is identical with the structural angular separation of adjacent ommatidia in the region of maximum density of ommatidia population. When this region of maximum ommatidia population is rendered non-functional by being covered with an opaque paint, the maximum visual acuity then corresponds to the angular separation of those remaining ommatidia which now constitute the maximum density of population. 3. The angular separation of adjacent ommatidia is much smaller in the vertical (dorso-ventral) axis than in the horizontal (anterio-posterior) axis. The experimentally found visual acuity varies correspondingly. From this and other experiments as well as from the shape of the eye itself, it is shown that the bee''s eye is essentially an instrument for uni-directional visual resolution, functional along the dorso-ventral axis. The resolution of the visual pattern is therefore determined by the vertical angular separation of those ocular elements situated in the region of maximum density of ommatidia population. 4. The visual acuity of the bee varies with the illumination in much the same way that it does for the human eye. It is low at low illuminations; as the intensity of illumination increases it increases at first slowly and then rapidly; and finally at high intensities it becomes constant. The resolving power of a structure like the bee''s eye depends on the distance which separates the discrete receiving elements. The data then mean that at low illuminations the distance between receiving elements is large and that this distance decreases as the illumination increases. Since such a moving system cannot be true anatomically it must be interpreted functionally. It is therefore proposed that the threshold of the various ommatidia are not the same but that they vary as any other characteristic of a population. The visual acuity will then depend on the distance apart of those elements whose thresholds are such that they are functional at the particular illumination under investigation. Taking due consideration of the angular separation of ommatidia it is possible to derive a distribution curve for the thresholds of the ommatidia which resembles the usual probability curves, and which describes the data with complete fidelity.     

CELL STRUCTURE AND THE METABOLISM OF INSECT FLIGHT MUSCLE

The biochemical properties of insect flight muscle were investigated to ascertain the mechanisms whereby energy is made available for the contractile processes. It was found: 1. The endogenous respiration of muscle homogenates was diminished by starving the flies. The substrate for this respiration was probably glycogen. 2. To obtain the maximal rate of oxidation of glucose, the homogenate had to be fortified with inorganic phosphate, Mg ions, ATP, and cytochrome c. The nucleotides, AMP and ADP, were not as effective as ATP. The addition of DPN or TPN was not necessary for this system. 3. Flight muscle homogenates oxidized glycogen, some sugars, and amino acids, as well as the intermediates of the glycolytic and tricarboxylic acid cycles. Other evidence demonstrated the substrate specificity of the muscle. 4. By centrifugation, the muscle homogenate was divided into two fractions: one, a soluble fraction representing the sarcoplasm; the other, the particulate fraction which contained the fibrils and the sarcosomes. 5. The particulate fraction, alone, oxidized all the citric acid cycle intermediates, α-glycerophosphate, phosphopyruvate, and the amino acids, glutamic, proline, and cysteine. Regardless of the substrate, no oxygen uptake was found with the sarcoplasm by itself. 6. A recombination of the sarcoplasm and the particulate component was required for the oxidation of glycogen, the hexoses, and all the phosphorylated intermediates of glycolysis, except phosphopyruvate. 7. Isolated mitochondria accounted for all the enzymatic activity of the particulate fraction. These results demonstrate that the enzymes of intermediate metabolism are localized in the sarcoplasm or sarcosomes. The third cytological entity, the myofibrils, plays no role in the energy-providing scheme. From a functional viewpoint, the sarcoplasm and the mitochondria, in combination, furnish the energy for the actomyosin contraction. The results are discussed in relation to analogous findings in other insects and vertebrates.     

THE VISUAL INTENSITY DISCRIMINATION OF THE HONEY BEE

1. Bees respond by a characteristic reflex to a movement in their visual field. By confining the field to a series of parallel stripes of different brightness it is possible to determine at any brightness of one of the two stripe systems the brightness of the second at which the bee will first respond to a displacement of the field. Thus intensity discrimination can be determined. 2. The discriminating power of the bee''s eye varies with illumination in much the same way that it does for the human eye. The discrimination is poor at low illumination; as the intensity of illumination increases the discrimination increases and seems to reach a constant level at high illuminations. 3. The probable error of See PDF for Equation decreases with increasing I exactly in the same way as does See PDF for Equation itself. The logarithm of the probable error of ΔI is a rectilinear function of log I for all but the very lowest intensities. Such relationships show that the measurements exhibit an internal self-consistency which is beyond accident. 4. A comparison of the efficiency of the bee''s eye with that of the human eye shows that the range over which the human eye can perceive and discriminate different brightnesses is very much greater than for the bee''s eye. When the discrimination power of the human eye has reached almost a constant maximal level the bee''s discrimination is still very poor, and at an illumination where as well the discrimination power of the human eye and the bee''s eye are at their best, the intensity discrimination of the bee is twenty times worse than in the human eye.     

THE DARK ADAPTATION OF THE EYE OF THE HONEY BEE

Bees which are held in a fixed position so that only head movements can be made, respond to a moving stripe system in their visual field by a characteristic motion of the antennae. This reflex can be used to measure the bee''s state of photic adaptation. A curve describing the course of dark adaptation is obtained, which shows that the sensitivity of the light adapted bee''s eye increases rapidly during the first few minutes in darkness, then more slowly until it reaches a maximum level after 25 to 30 minutes. The total increase in sensitivity is about 1000 fold. The adaptive range of the human eye is about 10 times greater than for the bee''s eye. The range covered by the bee''s eye corresponds closely to the adapting range which is covered by the rods of the human eye.     

感染囊幼病的工蜂咽下腺细胞的超微结构的变化

前言 中华蜜蜂囊幼病是我国养蜂业的一种重要病毒病,发病率很高,有的地区造成大量的幼虫死亡,给我国养蜂生产带来一定的危害,为了对防治病害提供科学的依据,我们首先对该病病原进行了分离、提纯及电子显微镜的研究等工作。发现该病毒对幼虫和成蜂,尤其对工蜂体内各个器官都有程度不同的影响。在幼虫发病期症状特别明显,病幼虫身体松软多水,其表皮容易破裂,当悬挂幼虫时其幼虫末端积聚有透明的液滴,在巢房内幼虫头部尖并变成黑色,头部稍微向上抬起呈船形。死后的幼虫干涸变为褐色的外壳留于巢房内,当感染的幼虫全部封盖后,巢房盖的中央有一小孔,这些异常的变化都是囊幼病的典型症状。幼虫症状虽很明显,但工蜂感染病毒后在外部形态上却没有明显     

副肌球蛋白在意大利蜜蜂间接飞翔肌中的定位

肌肉收缩是由于肌原纤维中粗、细肌丝相互滑行的结果(Huxley,1988;Huxley,1983;Squire,1986)。许多无脊椎动物肌肉粗肌丝中除含有肌球蛋白外,还存在着含量不同的副肌球蛋白(陈明等,1984、1985)。我们曾经进行过一系列关于意大利蜜蜂(Apis mellifera ligustica Spin)间接飞翔肌原纤维排列及其粗肌丝亚丝结构的研究。间接飞翔肌的粗肌丝从Z-线延伸至另一Z-线(范世藩等,1966),分离的天然粗肌丝经变性剂(脲、胍)处理,可以散开成直径约为5nm的数根亚丝,在一些亚丝上     

THE FINE STRUCTURE OF STRIATED MUSCLE : A COMPARISON OF INSECT FLIGHT MUSCLE WITH VERTEBRATE AND INVERTEBRATE SKELETAL MUSCLE

The available evidence from phase contrast, polarization optical, and electron microscopic studies on vertebrate skeletal muscle, insect skeletal muscle, and dipteran flight muscle is interpreted as favoring the following general structure of striated muscle. A continuous array of filaments (actin) runs through all bands of the sarcomere. These are linked by an axially periodic system of transverse filamentous bridges. Myosin (and probably other substances) are localized in the A bands. The system of transverse bridges compensates the birefringence of actin and is thus responsible for the isotropy of the I band. Myosin is responsible for the birefringence of the A bands. On strong contraction, A band material migrates to the Z bands to form contraction bands. It is not yet certain whether this migration involves myosin or another A band component.