马蔺体内主要阳离子含量月变化及分布

在自然盐碱生境下,通过测定不同月份土壤和马蔺体内主要阳离子Na⁺、K⁺、Ca²⁺、Mg²⁺的含量,研究了主要阳离子的吸收、转运变化及其在马蔺体内的分布.结果表明: 不同月份马蔺体内阳离子含量变动很大.在6月以后,随着马蔺的生长, Na⁺、K⁺、Ca²⁺和Mg²⁺4种离子在植物体内累积量逐渐增加.其中,根中Ca²⁺、Na⁺含量峰值出现在7月,分别为2.30%和0.51%,K⁺、Mg²⁺的含量峰值分别出现在9、10月,分别为0.27%和0.28%;叶片中Na⁺含量在7月达到最大值(0.57%);K⁺、Ca²⁺和Mg²⁺在8月分别达到1.30%、2.69%和0.47%.与Na⁺相比, 7、8月时马蔺对K⁺的选择吸收能力较低,但转运能力较强.马蔺对所测离子有很强的富集能力,各种离子在植物体内的含量都明显高于土壤背景值,且不同部位对离子的利用和累积能力不同,马蔺对各阳离子的累积主要集中在地上30 cm到地下40 cm范围内.马蔺地上部分平均单株K⁺、Na⁺、Ca²⁺和Mg²⁺含量分别是地下部分的9.11、4.07、0.98和2.27倍.     

盐胁迫下构树幼苗各器官中K+、Ca2+、Na+和Cl-含量分布及吸收特征

将当年生构树幼苗置于含有不同浓度（04、1、2、3、4 g·kg^-1）NaCl的土壤中,研究其生物量积累、叶片细胞质膜透性和K⁺、Ca²⁺、Na⁺、Cl^-等离子的吸收、分布及运输,并观察盐害症状.结果表明：构树幼苗的叶片质膜透性随着NaCl浓度的增加和胁迫时间的延长而升高,根冠比随NaCl浓度的升高而增加,大于3 g·kg^-1的土壤盐胁迫对构树叶片的质膜透性及植株的生物量积累影响显著.构树幼苗各器官中Na⁺和Cl^-含量随土壤NaCl浓度升高而显著增加,K⁺和Ca²⁺则随之降低,叶片各离子含量均明显高于根和茎.说明盐胁迫影响根系对K⁺和Ca²⁺的吸收,并抑制了它们向地上部分的选择性运输,使叶和茎的K⁺和Ca²⁺含量下降.构树通过吸收积累Na⁺和Cl^-抵御土壤盐分带来的渗透胁迫,但过量的Na⁺和Cl^-积累会造成单盐毒害.作为抗盐性较高的非盐生植物,构树地上部分的拒盐作用不显著.     

盐胁迫对桑树幼苗生长、叶片水分状况和离子分布的影响

以黑龙江省两个桑树品种（秋雨桑和泰来桑）为试验材料,研究了不同盐浓度下桑树幼苗生长、叶片水分关系和不同器官中离子的分布.结果表明：盐胁迫明显降低了桑树幼苗的植株高度和每株干物质量,且对新生叶片干质量的影响大于老叶片.随着盐胁迫的加重,两个品种桑树的叶片水势、渗透势、压力势和相对含水量明显下降,根、茎中Na⁺浓度明显增加,当外界NaCl浓度达到或超过150 mmol·L^-1时,各器官中Na⁺浓度达到饱和.盐胁迫明显降低了两个品种桑树根、茎和叶片中K⁺ 和 Ca²⁺浓度,以及茎和叶片中Mg²⁺浓度,而对根中Mg²⁺浓度影响不大.Na⁺在根、茎和老叶中的区域化分布是两个品种桑树生长过程中表现出耐盐性的机理之一,而盐胁迫使叶片中的Ca²⁺、K⁺和Mg²⁺浓度降低,导致植株体内的离子亏缺,从而限制了植株的生长.     

《昆虫学报》第49卷第1～6期总目次

生理与生化棉铃虫齿唇姬蜂对植物挥发物和寄主性信息素腺体化合物的EAG反应………………………………………………………………………………………………………颜增光,阎云花,康乐,王琛柱(1)臭腹腺蝗(直翅目:锥头蝗科)中肠内营养物-水分的流动和吸收(英文)…………………………     

急性盐度胁迫对军曹鱼稚鱼渗透压调节的影响

研究了环境盐度急性胁迫对军曹鱼(Rachycentron canadum)稚鱼鳃Na⁺-K⁺ATPase(NKA)活性及血清渗透压、Na⁺、K⁺和Cl^-离子调节的影响.结果表明:将稚鱼从盐度37中直接转移至盐度0、5、15、25、37（对照）和45的水体中,12 h后仅盐度0处理出现死亡(死亡率100％).各处理鳃NKA活性和血清渗透压在最初3 h内出现一定波动,随后变化平稳.试验结束时(12 h), NKA活性与盐度梯度呈“U”型分布,盐度5处理酶活性显著高于其它处理(P<0.05),盐度15处理活性最低,而各处理的血清渗透压大小(293～399 mOsmol·kg^-1)与盐度呈正相关;在3～12 h内稚鱼血清Na⁺和Cl^-浓度随盐度升高而升高,但增幅较小,血清K⁺浓度则与盐度呈负相关;12 h稚鱼的等渗点为328.2 mOsm·kg^-1,相当于盐度11.48,而Na⁺、K⁺和Cl^-等离子点分别为155.2、6.16和137.1 mmol·L^-1,分别相当于盐度10.68、20.44及8.41.军曹鱼在生理上具有广盐性鱼类的“低渗环境高NKA活性”特征,有较强及迅速的渗透压和离子调节与平衡能力.     

辣椒碱对小菜蛾的驱避活性及其体内谷胱甘肽-S-转移酶和Na+，K+-ATP酶活性的影响

采用常规生测方法和酶活力测定方法,初步研究了辣椒碱对小菜蛾Plutella xylostella L.的产卵忌避和拒食作用,及其对小菜蛾体内谷胱甘肽-S-转移酶、Na⁺,K⁺-ATP酶活性的影响,以期阐明辣椒碱对害虫的作用机制。结果表明,辣椒碱对小菜蛾表现出较强的产卵忌避活性和拒食活性。在6.25×10⁴ mg/L浓度下,处理24 h辣椒碱对小菜蛾的非选择性产卵忌避率达96.55%,选择性产卵忌避率为84.30%;在相同浓度下,处理48 h辣椒碱对小菜蛾的非选择性拒食率达81.47%,选择性拒食率为69.69%。 另外,经1.25×10⁵ mg/L辣椒碱不同时间处理后,小菜蛾体内的谷胱甘肽-S-转移酶酶活力和Na⁺,K⁺-ATP酶活力与对照相比均产生了波动,处理18 h时小菜蛾体内GSTs活力最高,为152.01 U·mg^-1pro·min^-1,处理1 h时小菜蛾体内Na⁺,K⁺-ATP酶活力最高,为19.99 U·mg^-1pro·min^-1。结果说明辣椒碱能够影响小菜蛾产卵和取食行为,并且对其体内的酶系也产生了影响。     

不同森林群落类型溪流水化学特征的季节动态

以小兴安岭凉水自然保护区内的阔叶红松林、云冷杉林和落叶松人工林为研究对象, 于2006年3—10月, 分析了其溪流水化学特征的动态变化. 结果表明: 不同月份3种森林群落溪流水的主要阳离子含量均表现为 Ca²⁺>Na⁺>K⁺>Mg²⁺, 主要阴离子含量均为HCO₃^->SO₄^2->NO₃^->Cl^-;不同群落类型的主要离子含量影响显著, 3种森林群落溪流水中Na⁺、Ca²⁺、Mg²⁺、Fe²⁺和Fe³⁺平均含量为云冷杉林>落叶松人工林>阔叶红松林, 而K⁺为落叶松人工林>云冷杉林>阔叶红松林; 主要阴离子平均含量均以落叶松人工林溪流水中为最高.     

臭腹腺蝗（直翅目：锥头蝗科）消化道对食物储存、消化和吸收相适应的显微结构

显微观察发现臭腹腺蝗Zonocerus variegatus（直翅目：锥头蝗科）嗉囊、中肠和后肠的肠壁结构有所不同。嗉囊为空时纵向折叠。中肠上皮层的厚度随龄期有明显变化,1龄和2龄时明显大于3龄、4龄和5龄。后肠具有帮助消化和吸收的功能。     

9种Na+通道mRNA在5个不同发育阶段大鼠16种组织中表达及变化趋势

电压-门控Na⁺通道由1个可单独发挥作用的α亚单位和2～4个起辅助作用的β亚单位构成,在可兴奋细胞动作电位的产生及传导等过程中起重要作用.采用RT-PCR法对5个不同发育阶段(P1、P9、P40、P80、P120)Wistar大鼠16种不同组织的9种Na⁺通道α亚单位及1种β亚单位的mRNA进行检测发现：同种类型Na⁺通道mRNA在大鼠不同组织中的表达不同,不同类型Na⁺通道mRNA在大鼠同一组织中的表达不同.其中,神经系统和心肌组织中Na⁺通道mRNA的表达最高,随着日龄的增加,Na⁺通道mRNA在不同组织中表达的变化趋势不同.Na⁺通道在全身组织中的广泛分布及随发育周期的不同变化趋势,为离子通道病的研究及治疗提供了理论基础.     

Na+和Cl-在小麦叶肉细胞超微结构中的分布

小麦经200mmol NaCl溶液培养3天后,采用改进的焦锑酸钾方法对叶肉细胞中Na⁺及Cl^-进行超微结构定位。电镜观察及电子探针X-射线显微分析表明,Cl^-主要分布在细胞间隙、细胞壁及细胞质膜中。用电子探针X~-射线能谱仪在这些部位中未探测出Na⁺,提示Cl^-比Na⁺更多地进入小麦的叶肉细胞。此外,在叶肉细胞的细胞核、线粒体及叶绿体中也可见到离子沉淀颗粒。经氯化钠溶液培养的小麦幼苗,其叶肉细胞的叶绿体、线粒体的超微结构受损,植株生长受到抑制。     

POTASSIUM ACCUMULATION IN THE PROXIMAL CONVOLUTED TUBULES OF THE FROG'S KIDNEY

1. In a manner similar to that of the sartorius muscle, the isolated kidney of the frog can accumulate K against a gradient to upwards of three times its normal concentration. 2. The K-accumulating region is identified as the proximal tubule, which in the isolated tissue immersed over 24 hours in the cold (2–3°C.) amounts to about 90 per cent of the nephron minus the glomerulus. In the fresh tissue it constitutes about 70 per cent. The cells of the proximal tubule are impermeable to Na, but freely permeable to K and Cl. 3. The distal tubule in the isolated kidney does not accumulate K over the external concentration. The cells are permeable to Na which they actively extrude. This extrusion of Na goes parallel with a loss of osmotically associated water amounting to about 15 per cent of the weight of the fresh kidney, but varying somewhat with the conditions. 4. The accumulation of K in the proximal tubules is in accordance with the equations established for the sartorius muscle, and, as theoretically expected, there is no volume increase (but rather a small decrease) with the large accumulations, when the external Na concentration is maintained throughout. 5. With K accumulation in isotonic mixtures large volume changes occur as K is progressively substituted for Na. Over the range of external K concentration of 10 to 100 mM per litre the weight of the whole kidney changes to 2.5 times and the water of the cells of the proximal tubules increases to over four times. Up to an external K value of 90 mM per litre the mean weight of the kidney shows a linear relation when plotted against the reciprocal of the Na concentration plus the small glucose and Ca concentration. This relation is interpreted theoretically. 6. The effect of cyanide in the isotonic mixtures is to prevent the contraction of the distal tubules and to cause swelling of the same. It does not affect the volume, volume changes, or differential permeability of the proximal tubule. At the same time the membranes of the proximal tubule cells lose their characteristic permeability at a lower level of distension in the presence of cyanide. 7. The mean Na ratio for the kidney after 24 hours'' immersion in the cold is 0.26 ± 0.014 (giving standard deviation of mean). The ratio is defined as See PDF for Equation. For the fresh kidney the mean ratio is 0.39 ± 0.006. 8. The mean inulin ratio (28 observed in the cold) is 0.23 ± 0.012 and the same value for 10 observed at room temperature. At room temperature—2 hour immersion—the ratio is increased by cyanide to a mean of 0.32 ± 0.028, but only a slight increase is caused by cyanide in the cold. 9. The mean hemoglobin ratio after 24 hours'' immersion in the cold is 0.17 ± 0.004 and is unaffected by cyanide.     

The effects of sodium ions and potassium ions of glycine uptake by mouse ascites-tumour cells in the presence and absence of selected metabolic inhibitors

1. The initial rate, v, of glycine uptake by ascites-tumour cells respiring their endogenous nutrient reserves was studied as a function of the respective extracellular concentrations of glycine, Na(+) and K(+). With the extracellular concentration of Na(+)+K(+) constant at 158m-equiv./l. and that of glycine either 4 or 12mm, v tended to zero as the extracellular concentration of Na(+) approached zero. Glycine appeared to enter the cells as a ternary complex with a carrier and Na(+). K(+) competed with Na(+) for one of the carrier sites, whereas glycine was bound at a second site. The values of the five relevant binding constants showed that the two sites interacted. 2. The glycine uptake rate at various extracellular concentrations of glycine and Na(+) was scarcely affected by starving the cells for 30min. in the presence of 2mm-sodium cyanide provided that cellular Na(+) and K(+) contents were kept at the normal values. When the cells took up Na(+), however, v decreased approximately threefold. 3. When their Na(+) content was relatively small and the extracellular concentration of Na(+) was large, the starved cells accumulated glycine in the presence of cyanide for about 15min. Glycine then tended to leave the cells. An average of about 5mumoles of glycine/ml. of cell water was taken up from a 1mm solution, representing about 20% of the accumulation observed during respiration. Studies with fluoride, 2,4-dinitrophenol and other metabolic inhibitors supported the view that ATP and similar compounds were not implicated. The relation between the transient accumulation of glycine that occurred in these circumstances and the normal mode of active transport was not established.     

Cytochemical characterization of microvillar and perimicrovillar membranes in the posterior midgut epithelium of Rhodnius prolixus

Perimicrovillar membranes (PMM) are structures present on the surface of midgut epithelial cells of the hematophagous insect, Rhodnius prolixus. They cover the microvilli and are especially evident 10 days after blood meal, providing the compartmentalization of the enzymatic processes in the intestinal microenvironment. Using an enzyme cytochemical approach, Mg2+-ATPase and ouabain-sensitive Na+K+-ATPase activities were observed in the plasma (or microvillar) membrane (MM) of midgut cells and in the PMM. In contrast, alkaline phosphatase was only detected in MM. Using cationized ferritin and colloidal iron hydroxide particles, anionic sites were found only on the luminal surface of the PMM. Using fluorescein isothiocyanate (FITC)-labeled lectins, residues of alpha-d-galactose, mannose, N-acetyl-neuraminic acid, N-acetyl-d-galactosamine and N-acetyl-galactosamine-alpha-1,3-galactose were detected on the apical surface of posterior midgut epithelial cells. On the other hand, using FITC-labeled neoglycoproteins (NGP) it was possible to detect the presence of carbohydrate binding molecules (CBM) recognizing N-acetyl-d-galactosamine, alpha-d-mannose, alpha-l-fucose and alpha-d-glucose in the posterior midgut epithelium. The use of digitonin showed the presence of sterols in the MM and PMM. These results have led the authors to suggest that for some components the PMM resembles the MM lining the midgut cells of R. prolixus, composing a system which covers the microvilli and stretches to the luminal space.     

Investigations on the midgut caeca of mosquito larvae-II. Functional aspects

Fluorescent dyes were used to observe antiperistaltic movements of the midgut which cause an anteriorly directed flow which provides the caeca with midgut fluid. Aminopeptidases could be demonstrated histochemically in the cells and lumen of the caeca. This would suggest that the caeca of mosquito larvae take part in the final degradation, resorption and storage of nutrients. The caecal membrane acts as a permeability barrier. Particulate material and substances which cannot be degraded or resorbed accumulate in the caeca. Moreover, the caeca are involved in osmoregulation. Changes in the number of mitochondria present in the microvilli of ion transporting cells occur. The number of mitochondria in the microvilli depends on the salinity of the culture medium of these larvae.     

Morphology and ultrastructure of the alimentary canal of the cicada Platypleura kaempferi (Hemiptera: Cicadidae)

The alimentary canal of cicada Platypleura kaempferi is described. It comprises the oesophagus, filter chamber, external midgut section and hindgut. The elongate oesophagus expands posteriorly, with its posterior end constricting to become a bulb. The filter chamber consists of two parts: a very thin sheath and a filter organ. The filter organ is composed of the anterior and posterior ends of the midgut (internal midgut section), and the internal proximal ends of the Malpighian tubules. The external midgut section differentiates into a collapsed sac and a midgut loop. The latter is divided into three distinct segments. The hindgut contains a dilated rectum and a long narrow ileum. The distal portions of the four Malpighian tubules are enclosed in a peritoneal sheath together with the distal ileum before reaching to the rectum. Ultrastructurally, the oesophagus and the hindgut are lined with a cuticle. The filter chamber sheath consists of cells with large irregular nuclei. Filamentous substances coat the microvilli of the cells of the internal midgut section. The posterior end of the midgut comprises two types of cells, with the first type of cells containing many vesicles and scattered elements of rough endoplasmic reticulum. The anterior and posterior segments of the midgut loop cells have ferritin‐like granules. The ileum cells have well‐developed apical leaflets associated with mitochondria. Accumulations of virus‐like particles enclosed in the membrane are observed in the esophagus, conical segment, mid‐ and posterior segments of the midgut loop.     

Ionic basis of volume regulation in mammalian cells following osmotic shock

Previous studies with mammalian cultured cells have shown that volume regulation in hypotonic medium requires active Na transport. In the present study, determinations of intracellular Na and K content were made in cultured mouse lymphoblasts during the process of swelling and subsequent shrinking (volume regulation) in hypotonic medium. Na and K content were measured in cells in which the shrinking phase was inhibited by the cardiac glycoside, ouabain. In osmotically-shocked cells, an initial permeability increase to K, and not Na, was observed, which allowed K to diffuse out rapidly, down its gradient. Na, meanwhile, rapidly flowed inward with water entry during the swelling process, and was later lost with the same kinetics as the cell shrinkage. This loss of Na was prevented in the presence of ouabain. The results imply that volume regulation is achieved by pumping Na gained during swelling out of the cells, while any K taken up by the pump is rapidly lost through a more permeable membrane. The loss of osmotically active Na, presumably with accompanying anions, allows water to passively diffuse down its osmotic gradient, reducing cell volume subsequent to the initial passive swelling, during which K was rapidly lost.     

雷公藤的杀虫作用研究与应用

卫矛科植物雷公藤(Tripterygium wilfordli Hook)是我国著名的杀虫植物。文章对雷公藤的杀虫活性、主要有效成分、作用机理及田间药效4个方面的研究与应用进行综述。雷公藤对多种昆虫有毒杀、拒食、麻醉、生长发育抑制和种群抑制作用;雷公藤定碱、雷公藤次碱、雷公藤春碱、雷公藤吉碱、雷公藤嗪碱、雷公藤新碱和雷公藤甲素、雷公藤内酯酮是其主要杀虫活性成分;雷公藤生物碱作用于昆虫的神经系统和中肠肠壁细胞,Na+,K+-ATP酶可能是雷公藤甲素的靶标之一;雷公藤还具有较好的田间防效。最后,对雷公藤作为杀虫植物资源的开发利用前景和今后的研究方向作了展望。     

Iodoacetate action on endocytic uptake of different fluid-phase markers by OK renal epithelial cells

When grown in monolayer culture, OK cells display endocytic uptake of soluble fluid-phase markers such as lucifer yellow (LY) and horseradish peroxidase (HRP). The response of this process to metabolic inhibitors was characterized in the present study. Inhibition of cell metabolism by cyanide produced a decrease in cell ATP content which was accompanied by a decrease in uptake of both LY and HRP, confirming the energy-dependence of fluid-phase endocytosis in OK cells. Use of iodoacetate also decreased cell ATP content but its action on endocytosis was unexpected. Cell uptake of HRP was decreased by iodoacetate, similar to the effect of cyanide, but there was a marked increase in LY uptake. Additional studies showed that cyanide did not change intracellular Na+ or intracellular K+ and did not interfere with the Na(+)-dependency of Pi uptake. In contrast, iodoacetate produced a marked increase in Na+, a decrease in K+, and abolished the Na(+)-dependency of Pi transport. The latter was due primarily to a 10-fold increase in Na(+)-independent uptake of Pi. These findings suggest, indirectly, that plasma membrane permeability to Na+, K+, Pi, and small molecules such as LY, may be increased by iodoacetate, possibly through its action as an alkylating agent. This mechanism may allow increased cell uptake of LY through a non-endocytic pathway, and may mask the inhibitory action of iodoacetate on endocytic uptake of LY. These additional effects complicate the use of iodoacetate to interrupt endocytosis.     

Cation distributions across the larval and pupal midgut of the lepidopteran, Hyalophora cecropia, in vivo.

1. The levels of potassium, sodium, magnesium and calcium in leaves, midgut contents, midgut tissue, and blood were analysed in seven developmental stages between feeding, fourth-instar larvae and new pupae of the Cecropia silkworm. 2. Three dramatic changes in cation levels were found: the K level in the contents drops from 284 /+- 51 mEquiv./1 tissue water in the fifth-instar larva to 51 +/- 6 mEquiv./1 in the new pupa; the Mg level in the midgut tissue increases from 28 +/- 3 mEquiv./1 at the time of gut evacuation to 1093 +/- 104 mEquiv./1 in the new pupa; and the Ca level in the contents drops temporarily from 56 +/- 12 mEquiv./1 in the feeding fourth instar larva to 17 +/- 5 mEquiv./1 in the new fifth instar larva. The Na level was nerve higher than 2.8 +/- 0.5 mEquiv./1. 3. The relative levels of the four cations were different for each tissue studied, but each tissue maintained the same relative levels during the developmental stages studied. The sequences are: leaf, Ca greater than K GREATEr than Mg greater than Na; midgut contents, K greater than Ca greater than Mg greater than Na; midgut tissue, K GREATEr than Mg greater than Ca greater than Na; and blood, Mg greater than K greater than Ca greater than Na. 4. There were three large concentration gradients across the midgut; the K level in the midgut contents is approximately 10 times the level in blood; the Mg level in contents is one-half to one-sixth the level in blood; and the Ca level in contents is 3-4 times the level in blood. The K gradient and the Ca gradient are opposed and the Mg gradient is favoured by the electrical gradient across the larval midgut, the contents being 100 mV positive with respect to the blood. The K gradient and the electrical gradient are not present across the pupal midgut while the Mg gradient and the Ca gradient persist. 5. The K gradient is presumably maintained by the midgut K pump, the Mg gradient is aided by the midgut Mg pump, and the Ca gradient suggests that the midgut may possess a Ca pump.     

Potassium transmembrane fluxes in anoxic hepatocytes from goldfish (Carassius auratus L.)

Despite the fact that anoxic goldfish hepatocytes can maintain the transmembrane gradients of Na(+), H(+) and Ca(2+), cyanide (CN) intoxication leads to a rapid breakdown of K(+) homeostasis. In this study, [(86)Rb(+)] K(+) fluxes across the plasma membrane of goldfish hepatocytes were studied in order to identify the possible causes of this imbalance. Four minutes of cyanide incubation induced an acute and stable 61% decrease of K(+) influx (mostly driven by Na,K-ATPase activity), whereas K(+) efflux increased by 24.3%, this imbalance yielding a net K(+) efflux of 0.279+/-0.024 nmol 10(-6) cells(-1) min(-1). This uncoupling was not observed when glycolytic ATP production was inhibited with iodoacetic acid. Although the CN-induced decrease of K(+) influx was fully reversible upon washout of the inhibitor, it could not be prevented by any of the following treatments: (1) addition of 2% bovine serum albumin, which binds extracellular fatty acids known to activate specific K(+) channels; (2) addition of ascorbate, which acts as a radical scavenger; (3) inclusion of 5 mM glucose as an extracellular carbon source; and (4) removal of medium oxygen (obtained by nitrogen bubbling). Regarding the elevation of K(+) efflux in the presence of CN, neither ATP-dependent K(+) channels nor the KCl cotransporter appeared to be activated, whereas BaCl(2), an inhibitor of voltage-gated K(+) channels, decreased K(+) efflux of CN-intoxicated cells to control levels. In summary, these results indicate that, in goldfish hepatocytes, the CN-induced K(+) imbalance results from acute Na,K-ATPase inhibition together with the activation of voltage-dependent K(+) channels, the latter probably resulting from transient membrane depolarization.