钾通道阻断剂所致的蜗内直流电位改变

本实验采用耳蜗外淋巴灌流技术,观察了四氨基吡啶(4-AP)、四乙基铵(TEA)以及奎宁等不同钾通道阻断剂对豚鼠蜗内直流电位(EP)的影响。发现快钾通道阻断剂4-AP对EP无明显影响,但可改变强噪声所致EP改变的形式。TEA与奎宁则可减少负相EP(N-EP)的绝对值。实验结果提示耳蜗内有不同类型的钾离子通道存在并各具有不同的生理意义。     

ABSORPTION OF NUTRIENTS AND PLANT GROWTH IN RELATION TO HYDROGEN ION CONCENTRATION

The absorption of nutrients depends to a large extent on the reaction of the substrate. At maximal growth the intake of salt is at minimum. Different ions are very differently affected. The intake of water is independent of the absorption of salts.     

胞外钙离子以及细胞膜组分参与蓝光诱导拟南芥叶片花色素苷的积累

以野生型和hy4突变体拟南芥为材料,运用药物学方法研究可能参与蓝光诱导叶片花色素苷积累和CHS基因表达的信号组分。培养基中外施Ca2 、钙离子通道剂A23187、螯合剂EGTA、钙通道阻断剂尼群地平(nifedipine,Nif)以及异博定(verapermil)的实验证实,蓝光诱导13d龄叶片花色素苷积累和CHS基因表达需要胞外Ca2 的参与,而蓝光作用是由cry1(cryptochrome1)介导的。此外,质膜黄素蛋白抑制剂DPI(diphenylene iodonium)抑制蓝光诱导的花色素苷积累,质膜H -ATPase激活剂壳梭胞素(fusicoccin,FC)抑制蓝光反应,而抑制剂钒酸钠则起促进作用。CaM拮抗剂W7、Ca2 -ATPase抑制剂EB(erythrosine B)、G蛋白激活剂霍乱霉素(cholera toxin,CTX)以及抑制剂百日咳毒素(pertussis toxin,PTX)对蓝光下野生型与hy4的花色素苷积累都有影响。对药物实验的分析表明,质膜氧化还原系统、H -ATPase可能参与依赖于外源Ca2 的蓝光反应。     

CHLOROPLAST STRUCTURAL CHANGES INDUCED BY WHITE LIGHT IN THE MARINE DIATOM STEPHANOPYXIS TURRIS1,2

The intensity of white tight used for growing Stephanopyxis Turris (Grev.) Ralfs affects the structure of the chloroplasts. In particular, the conformation of the thylakoids, within the bands is altered by increasing the intensity. At low light (100 μW.cm^-2, 12:12 LD cycles) the thylakoids are generally parallel, whereas at 500 μW.cm^-2 the thylakoids tend to be twisted and out of plane. The possible significance of these conformational changes is discussed.     

METABOLIC AND ULTRASTRUCTURAL CHANGES INDUCED IN ADIPOSE TISSUE BY INSULIN

The addition in vitro of insulin to rat adipose tissue (epididymal) produces marked metabolic changes which may be followed by measurement of the net gas exchange of the tissue. Using this method to monitor the metabolic action of insulin, concomitant observations with the electron microscope on the tissue have been made. These reveal that pronounced morphological changes are induced by insulin. The plasma membranes of the adipose cells become invaginated at many sites to form minute finger-like indentations. Numerous tiny, membrane-bounded vesicles are also present and arranged in relationship to the plasma membrane in such a way as to suggest that their formation occurred when a recessed fold was pinched off. Deeper in the cytoplasm, especially in specimens that had been incubated a longer time, numerous large, smooth, membrane-limited vesicles are seen. Finally, in these incubated specimens the cytoplasmic matrix has lost much of its granular nature, small lipid droplets are frequently found in the cytoplasm and suggestive changes have occurred in mitochondria. In control specimens, incubated without insulin for identical periods of time, indentations and vesicles in the plasma membrane are sparse at best and no vesicles or membrane-bound spaces appear deeper in the cytoplasm. The metabolic and morphologic changes induced by insulin seem to be interdependent events. Both changes appear to be initiated rapidly and concomitantly in the tissue. Both processes are initiated by insulin at concentrations considered to be physiological, 0.004 µg. (100 µunits) per ml. Insulin treated with alkali fails to initiate either process. It is concluded that insulin initiates pinocytosis in rat adipose tissue and the possible significance of this process in the mode of action of insulin is discussed.     

“缺血”引起的绵羊浦肯野纤维跨膜电位与离子流变化

以低氧、高钾、低pH、无能量供应的模拟缺血溶液灌流离体绵羊心脏浦肯野纤维,观察“缺血”对心肌跨膜电位和离子流的影响。实验共24例。跨膜电位的变化过程如下:模拟缺血液灌流后2-3min,首先出现最大舒张电位(MDP)轻度除极,4期舒张除极速率减慢,随后动作电位时程(APD)缩短(n=13)或先缩短、后延长、再缩短的变化(n=11),平台逐渐消失,最后MDP进一步除极,动作电位波幅(APA)减小,兴奋性逐渐降低,以致不能引出动作电位(AP)。其中6例即使MDP高于-60mV时AP已不能引出。以上变化过程历时长短不等,在不同标本为30-160min。跨膜离子流方面,当APD缩短时,在所有膜电位水平即时外向电流都明显增加。稳态电流-电压关系曲线由正常的S形变成直线,内向整流现象消失。慢内向离子流由“缺血”前的6.74±4.48nA减少到0.86±1.39nA,(M±SD,P<0.01,n=8),在多数测试电位水平都有显著减少,其电流-电压关系曲线向较负电位方向移位。以上结果提示:心肌“缺血”时浦肯野细胞起搏功能受抑制,细胞内大量K~+外流,Ca~(2+)内流减少,心肌细胞除极,以上多种变化可能为心肌缺血时心律失常发生的原因。     

A LIGHT AND ELECTRON MICROSCOPE STUDY OF THE MORPHOLOGICAL CHANGES INDUCED IN RAT LIVER CELLS BY THE AZO DYE 2-ME-DAB

The cytological changes induced in rat liver cells by the aminoazo dye 2-Me-DAB have been examined by light and electron microscopy. It is observed that this non-carcinogenic compound duplicates most of the morphological alterations produced by other hepatotoxins, some of which, such as the closely related aminoazo dye 3'-Me-DAB, are potent carcinogens. These non-specific effects involve both the granular and agranular forms of the endoplasmic reticulum as well as the glycogen content of hepatic cells. The arrays of cisternal profiles of the granular reticulum in normal hepatic cells become disorganized and the dispersed cisternae often appear fragmented and irregular. Large cytoplasmic inclusions, consisting of loosely organized tubules and vesicles, are also observed which result from a hypertrophy of the agranular reticulum. The glycogen in the cells progressively decreases in amount. The most specific effect of 2-Me-DAB is to induce an increase in the number of mitochondria per cell. Many of these organelles are characterized by the presence of a median double membrane continuous with the inner limiting membrane of the mitochondrial envelope. Evidence is presented in favor of the view that this partition is directly related to the phenomenon of mitochondrial division. It was noted also in the course of the experiment that an increasing number of cells appear which stain quite intensely with methylene blue and appear denser than normal under electron microscopy. The significance of these cells is not known.     

CEREBRAL METABOLIC AND CIRCULATORY CHANGES INDUCED BY HYPOXIA IN STARVED RATS

In order to study cerebral metabolic and circulatory effects of hypoxia under conditions of restricted glucose supply, the arterial P_o2, was reduced to 25–30mm Hg in artificially ventilated and lightly anaesthetized rats that were starved for 24 or 48 h prior to experiments. Arterial glucose concentrations, that were initially around 6μmol g^-1, were significantly reduced after 15min of hypoxia, and decreased to 50^o of control after 30min. In animals studied after 30min of hypoxia (24 h of starvation), cerebral blood flow had increased 4-fold and there was a moderate (25%) rise in cerebral oxygen consumption. During the course of hypoxia, cerebral cortical concentrations of glucose fell to low values. In spite of this, concentrations of pyruvate and lactate rose with time, and the sum of citric acid cycle intermediates (citrate, α-ketoglutarate, fumarate. malate and oxaloacetate) increased. Changes in amino acids were dominated by a fall in aspartate and a rise in alanine concentration. There was a moderate reduction in phosphocreatine and a slight rise in ADP concentration, but concentrations at ATP and AMP were unchanged. The changes observed are similar to those previously obtained in fed animals. It is concluded that even if blood glucose concentrations fall to 3μmol g^-1, and cerebral energy flux is maintained, substrate supply is sufficient to cover the energy requirements of the tissue. Hypoxia was accompanied by increases in the lactate/pyruvate and β-hydroxybutyrate acetoacetate ratios of blood. In the tissue, NADH/NAD⁺ ratios derived from the lactate, malate and β-hydroxybutyrate dehydrogenase systems rose, while that derived from the glutamate dehydrogenase reaction fell. It is concluded that the latter system is not well suited for estimating mitochondrial redox changes in brain tissue.     

SPACES,BARRIERS, AND ION CARRIERS: ION ABSORPTION BY PLANTS

Epstein , Emanuel . (U. California, Davis.) Spaces, barriers, and ion carriers: ion absorption by plants. Amer. Jour. Bot. 47(5) : 393—399. 1960.—Ions from the external medium initially invade “outer” or “free” spaces of plant cells and tissues, by diffusion and ion exchange. This process is essentially non-metabolic and non-selective, and is readily reversible. The spaces accessible in this manner seem to be confined to the cell walls. From here, ions are selectively transported into “inner” spaces separated from the “outer” space by diffusion barriers. Ion carriers accomplish the selective transfer of the ions across the barriers or membranes, first into the cytoplasm and thence into the vacuole. The second step, into the vacuole, can be by-passed by those ions moving into the xylem elements and up to the shoot, and some transport to the shoot may skirt the active transport mechanisms entirely.     

CHANGES IN THE STABILITY AND POTENTIAL OF CELL SUSPENSIONS : II. THE POTENTIAL OF ERYTHROCYTES.

1. Human and sheep erythrocytes, when placed in 0.01 N buffer solutions at reactions more acid than pH 5.2, undergo a progressive change in potential, becoming less electronegative or more electropositive. This change usually occurs within 2 hours at ordinary room temperatures. It did not occur when rabbit erythrocytes were used. 2. This change is due primarily to the liberation of hemoglobin from some of the cells. 3. Hemoglobin, even in very low concentrations, markedly alters the potential of erythrocytes in the more acid reactions. This is due to a combination between the electropositive hemoglobin and the erythrocytes. The effect of the hemoglobin is most marked in the more acid solutions; it occurs only on the acid side of the isoelectric point of the hemoglobin. 4. The isoelectric point of erythrocytes in the absence of salt, or in the presence of salts having both ions monovalent, occurs at pH 4.7. This confirms the observations of Coulter (1920–21). Divalent anions shift the isoelectric point to the acid side. 5. The effect of salts on the potential of erythrocytes is due to the ions of the salts, and is analogous in every way to the effect of salts on albumin-coated collodion particles, as discussed by Loeb (1922–23).     

CELL POPULATION KINETIC PROFILE OF THE MOUSE THYMUS, AND THE CHANGES INDUCED BY PREDNISOLONE

The cell population kinetic parameters of the thymus in BALB/c mice have been estimated using stathmokinetic and [³H]TdR techniques in both control animals and animals treated with prednisolone. FLM data were analysed by computer using the Gilbert program. The study showed that prednisolone had an inhibitory effect mainly in the DNA synthesis phase and in G₁. Stathmokinetic data also showed a decrease in the cell birth rate and an increase in the apparent cell cycle time (or potential doubling time) after treatment. The labelling index, the mitotic index and the growth fraction were also decreased. The study also shows a good agreement between the data obtained by stathmokinetic and [³H]TdR techniques.     

LIGHT ABSORPTION BY PLANTS AND ITS IMPLICATIONS FOR PHOTOSYNTHESIS

The preceding account has attempted to examine the interactions between light absorption and photosynthesis, with reference to both unicellular and multicellular terrestrial and aquatic plants. There are, however, some notable plant groups to which no direct reference has been made, e.g. mosses, liverworts and lichens. Although many have similar optical properties to terrestrial vascular plants (Gates, 1980) and apparently similar photosynthetic responses (see Green & Snelgar, 1982; Kershaw, 1984) they may possess subtle, as yet unknown differences. For instance, the lichen thallus has a high surface reflectance although the transmittance is virtually zero (Gates, 1980; Osborne, unpublished results). It is envisaged, however, that differences in optical properties between species will reflect differences in degree not kind. Although not all variation in photosynthesis is due to differences in light absorption a number of accounts suggest that this is a contributing factor. Variations in leaf absorptance have been found to account for most of the variation in leaf photosynthesis at low J_is (see Ehleringer & Björkman, 1978a; Osborne & Garrett, 1983). There is, however, little direct experimental evidence on light absorption and photosynthesis in either microalgal species or aquatic macrophytes. We also do not know over what range of incident photon flux densities photosynthesis is determined largely by changes in light absorption. Plants growing under natural conditions also experience large diurnal and seasonal fluctuations in J_i, unlike species grown under laboratory conditions. The occurrence of transitory peaks in J_i tends to overshadow the fact that the average J_i is often lower than the J₁ required to saturate photosynthesis, i.e. 1500–2000 μmol m^-2 s^-1, depending on the growth treatment. Using the data of Monteith (1977) and I W m²= 5 μmol m^-2 s^-1, and with photosynthetically active radiation 50% of total solar radiation, the daily mean value for Britain is approximately 450 μmol m^-2 s^-1, with a maximum in June of 1000μmol m^-2 s^-1 and a minimum during the winter of 75 μmol m^-2 s^-1. Such values could be even lower on shaded understory leaves and considerably lower for aquatic species. Based on average values of net photosynthesis for a terrestrial plant leaf, light saturation would only be expected in June while for most of the year the average values would lie largely on the light-limited portion of the photosynthesis light response curve. Although the daily average values in tropical climates may be higher during the winter months, they are remarkably similar throughout the world for the respective summers in the northern and southern hemispheres, because the increased daylength at high latitudes compensates for the lower J_is. The expected lower dark respiration rates during the winter may also partially offset the effects of a lower light level. There is therefore a trade-off between high J_is for a short period of time against a lower J_i for a longer period of time. We might expect different photosynthetic responses to these two very different conditions. Importantly, a low J_i with a long daylength may enable a plant to photosynthesize at or near its maximum photon efficiency for most of the day. Although the response of the plant to fluctuations in J_i is complicated because it is affected by the previous environmental conditions, this may indicate that light absorption has a much greater significance under natural conditions, particularly for perennial species. The bias in many laboratories towards research on terrestrial vascular plants also tends to ignore the fact that a number of multicellular and unicellular aquatic species survive in very low light environments. Furthermore, the direct extrapolation of photosynthetic responses from measurements on single leaves to those of whole plants is clearly erroneous. Although this is obvious, many physiological ecologists have attributed all manner of things to the photosynthetic responses of ‘primary’ leaves. Most researchers have ignored problems associated with composite plant tissues and internal light gradients. Clearly caution is required in interpreting the photosynthesis light-response curve of multicellular tissues based on biochemical features alone. Also, the importance of cell structure on light absorption and photosynthesis has generally been ignored and attributed solely to the effects of structural features on CO₂ diffusion. In doing so the work of two or three generations of plant physiologists has been ignored. Haberlandt (1914) at the turn of the century probably first implicated the role of cell structure in leaf optics, and Heath (1970) stressed that in order to completely understand the role of light in photosynthesis we need to know the flux incident on the chloroplast itself. Even this suggestion may need modification because of the capacity of the internal chloroplast membranes for scattering light. It is worth emphasizing the importance of light gradients within tissues and their role in regulating photosynthesis, particularly at light saturation. Measurements of light gradients are fraught with problems because of experimental difficulties and the majority (few) are based on reflectance and transmittance measurements. Seyfried & Fukshansky (1983) have shown that light incident on the lower surface of a Cucurbita cotyledon produced a larger light gradient than light incident from above, indicating the importance of the spatial arrangement of the tissues with respect to the light source. Also, light incident on the lower surface of leaves of Picea sitchensis was less ‘effective’ in photosynthesis than light from above (Leverenz & Jarvis, 1979). Clearly, two tissues could have the same gross absorptance but different photosynthetic rates because of differences in the internal light environment. Fisher & Fisher (1983) have recently found asymmetries in the light distribution within leaves, which they related to asymmetries in photosynthetic products due to differences in solar elevation. Such modifications in light distribution could be important for a number of solar-tracking species. Changes in light absorption are brought about by a whole gamut of physiological, morphological and behavioural responses which serve to optimize the amount of light absorbed. Perhaps the simplest way of regulating the amount of light absorbed is by restricting growth either to particular times of the year or to conditions when the light climate is favourable. We are still largely ignorant of many details of these modifications. In particular, differences in tissue structure such as the size and number of vacuoles or the effects of organelles on the scattering component of the internal light environment of photosynthetic tissues are not understood. A better understanding of the interaction of light with plants in aquatic systems is also required. It is unfortunate that light-absorptance measurements are not routinely made in photosynthetic studies, and this is quite clearly a neglected area of study. That these measurements are not made is even more surprising, since techniques have been available for over sixty years (Ulbricht, 1920). Absorptance measurements are of particular importance in the photosynthetic adaptation of microalgae, where only a small proportion of the incident photon flux density is absorbed. For multicellular species more detailed information is required on internal light gradients and their variability. Light-absorptance measurements are also important in any study relating kinetic data on CO₂ fixation to in vivo photosynthesis, especially when there are large variations in the morphology and structure of the photosynthetic organ.     

CHANGES IN THE STABILITY AND POTENTIAL OF CELL SUSPENSIONS : I. THE STABILITY AND POTENTIAL OF BACTERIUM COLI.

1. Stability and potential of Bacterium coli suspensions depend, not only on the strain of the organism and the medium in which it is suspended, but also on the previous treatment of the suspension, and the length of time it has been in the medium. 2. When treated at acid reactions, the negative charge on the bacteria is diminished; with some strains, a positive charge is acquired. Changes in stability accompany the changes in potential. 3. Washing acid-treated bacteria at neutral or slightly alkaline reactions does not restore the original potential; the zone of flocculation is moved toward the alkaline side. 4. These changes are due to two factors: the extraction of a soluble protein which combines with the surfaces of the cells, and a further irreversible change of the cell or its membrane.     

无机盐诱导蓝藻细胞液泡化

选用NaCl、KNO3、(NH4)2SO4、MgSO4、CaCl2五种常用无机盐对分属三科的六种蓝藻进行液泡化诱导,不同蓝藻其盐敏感性不同。鱼腥藻sp.595最为敏感,五种盐均诱导其液泡化;颤藻284和极大螺旋藻438最不敏感,所试验盐类均不能诱导其液光化;念珠藻sp.96、织线藻246和伪枝藻248液泡化程度居中,少数盐类如NaC1、KNO3、(NH4)2SO4对其有诱导作用。采用压片法观察到诱导形成的液泡,液泡在相差显微镜下显示为圆球形,基本透明。     

植物吸收离子动力学综合型模型探讨

本文在前人工作基础上提出了一个离子吸收动力学新模型（综合型抑制作用模型）,并推导出其速率方程．该模型能将现有的离子吸收相互作用模型（竞争性抑制作用模型,反竞争性抑制模型和非竞争性抑制作用模型）统一在该模型之中．笔者用该模型很好地解释了七例有关离子吸收相互作用试验结果．