The Absorption and Accumulation of Salts by Living Plant Cells: IX The Absorption of Rubidium bromide by Potato Discs

Chemical methods for the quantitative determination of rubidiumin aqueous plant extracts and saps were investigated but abandonedin favour of a spectrographic technique which is fully described. The results of quantitative determinations of the rubidium andbromide absorbed by potato discs from solutions of rubidiumbromide, and the effects upon this absorption of oxygen, oftime, and of the specific surface of the discs are described.The effects of these variables upon the accumulation of bromidewhich were previously described have been confirmed. All thevariables which affect bromide absorption affect the uptakeof rubidium in a similar manner. The absorption of rubidium is of two distinct kinds. The firstphase in the absorption process is a relatively rapid uptakeof rubidium unaccompanied by bromide. This process is unaffectedby oxygen, is not confined to the surface cells, and ceasesafter a short time. The second phase occupies a protracted periodduring which both rubidium and bromide are absorbed in equivalentamounts. During this phase the absorption is confined to a fewlayers of cells at the surface and is determined by oxygen concentrationin the manner already described for the bromide ion. The two types of absorption are described as ‘inducedabsorption’ and as ‘primary absorption’ inthe sense used earlier. The former is merely a property of thesubstances in the tissue, the latter is a process which tendsto increase the free energy of the tissue, therefore demandsthat work should be done, and is a property of the organizedliving cell. The relationships of the two types of absorption process totime have been described and they can be expressed in termsof equations. The effect of the surface and thickness of discs upon the absorptionof bromide and rubidium is interpreted quantitatively. The distance from the surface of the discs at which ‘primaryabsorption’ ceases is the same for rubidium and bromide,and coincides with the values previously determined for thedepth of the layer of tissue which exhibits enhanced respiration. The ‘induced absorption’ of rubidium may be observedin discs killed by alcohol. The effect of concentration uponthis process is similar to the adsorption isotherm. The effectof concentration upon the absorption of bromide by living discsis much less conspicuous and the requirements of the absorptionisotherm are not rigidly met. The effect of concentration alsoinvolves the factor of surface and thickness of disc. Unequal absorption of the bromide and rubidium arises from thesuperimposed effect of two distinct processes one of which causesthe absorption of rubidium only and the other tends to causeequal uptake of rubidium and bromide.     

Chloramphenicol Inhibition of Salt Absorption by Intact Plants

The influence of chloramphenicol on the accumulation of calciumand rubidium by intact barley plants has been investigated.The uptake of both ions during 24 hrs. was reduced by exposureto the inhibitor for 24 hrs. before the uptake period. The maineffect was on the fractions of the ions which reached shootsand on those present in roots in non-exchangeable forms. Chloramphenicolalso reduced transpiration, but to a considerably smaller extent. The primary effect of chloramphenicol on salt uptake appearsto be on the mechanisms of active transport which convey ionsacross the root. Since chloramphenicol does not affect the uptakeof oxygen, it appears that the active accumulation of saltsis not directly mediated by the electron transfer in respiration.The results are compatible with the existence of a linkage betweensalt absorption and protein synthesis; the nature of this linkageis at present unknown.     

The Effects of Aqueous Extracts of Red Beet Root on Salt Accumulation and Respiration of Discs of Red Beet Root

An account is given of the preparation of aqueous extracts ofred beet root which are shown to stimulate potassium uptakein beet discs washed for a short period, but inhibit potassiumuptake in discs washed for four days or more. Analysis of extractsshowed them to contain organic anions (especially citrate andmalate) which affect both the metabolic phase of potassium uptakeand respiration of the tissue. The effects of extracts and organicacids on uptake of manganese by beet discs is described andcompared with effects on potassium absorption. The results arediscussed with respect to current theories of salt accumulationand in relation to the hypothesis relating an inhibitor of saltaccumulation to the lag phase of ion uptake by beet discs.     

Ultrastructural aspects of and observations on the permeability of the rat mesentery to colloidal iron

In works already published, it was made clear that many researches were interested in the absorption phenomena, permeability and structure of the visceral mesothelial tissue. Attention was concentrated on the mesentery and observations were made using the application of lanthanum nitrate and osmium-amine. The penetration of lanthanum nitrate is impeded by the basement membrane situated between the connective and mesothelial tissues. The heavy salt moves through and not between the mesothelial cells by passive diffusion. No reaction was observed in general with osmium-amine, with the exception of a few cases. In those instances, the osmium-amine reacted not only in the outer surface of the mesentery, but also penetrated with no visible reaction all the way to the connective tissue where it was detected in the elastic layer. In this paper, the colloidal iron was employed using different techniques, and depositions were detected in the surface of the mesentery, in the mesothelial cells and also in the connective tissue. A final conclusion that the permeability of different layers of tissues is of great variety and has a definite capacity for selectivity is suggested.     

Induction and development of increased ion absorption in corn root tissue

Washing excised or intact primary roots of corn (Zea mays L., WF9 × M14) in aerated distilled water or dilute salt solutions for 2 hours induced doubling of the rate of accumulation of various nutrient ions and solutes. This response to washing depended upon aerobic metabolism, but involved no increase in aerobic respiration. Excision of root tissue was not required as the effect could be obtained with intact root systems. Increased phosphate absorption followed after a lag period of 30 to 40 minutes and continued for 6 hours before leveling off at about 3.5 times the initial rate. Chloramphenicol was not inhibitory to the development of increased absorption, while inhibitors of RNA and protein synthesis were. Auxins and kinetin were also inhibitory, but so was the antiauxin, 2,4,6-trichlorophenoxyacetic acid.     

Energy state of hepatocytes of fed rats isolated by the means of EDTA and vibration

The energy state of mitochondria in fed rat hepatocytes isolated by the use of non-enzymatic method including liver perfusion with an EDTA-containing solution with a further mild mechanical effect of tissue fragments by vibration has been studied. The isolation procedure used permits to obtain significant amounts of hepatocytes whose viability is not less than 80%. The endogenous respiration rate (10-15 nm O2/min.mln cells) is slightly stimulated by succinate. In the course of incubation in a balanced salt medium, the cells accumulate ATP and the lipophilic cation, tetraphenylphosphonium. Data from the inhibitory analysis testify to the fact that tetraphenylphosphonium accumulation reflects the membrane potential of intact cell mitochondria, which are in a metabolic state similar to state 3.     

Salinity tolerance is related to cyanide‐resistant alternative respiration in Medicago truncatula under sudden severe stress

Salt respiration is defined as the increase of respiration under early salt stress. However, the response of respiration varies depending on the degree of salt tolerance and salt stress. It has been hypothesized that the activity of the alternative pathway may increase preventing over‐reduction of the ubiquinone pool in response to salinity, which in turn can increase respiration. Three genotypes of Medicago truncatula are reputed as differently responsive to salinity: TN1.11, A17 and TN6.18. We used the oxygen‐isotope fractionation technique to study the in vivo respiratory activities of the cytochrome oxidase pathway (COP) and the alternative oxidase pathway (AOP) in leaves and roots of these genotypes treated with severe salt stress (300 mM) during 1 and 3 days. In parallel, AOX capacity, gas exchange measurements, relative water content and metabolomics were determined in control and treated plants. Our study shows for first time that salt respiration is induced by the triggered AOP in response to salinity. Moreover, this phenomenon coincides with increased levels of metabolites such as amino and organic acids, and is shown to be related with higher photosynthetic rate and water content in TN6.18.     

外源施钙对盐胁迫下花生营养元素吸收与分配的影响

为解决盐碱地花生养分吸收不畅及分配受阻等问题,研究外源施钙对盐胁迫下花生氮、磷、钾、钙、镁吸收积累、分配特性和产量的影响,为盐碱地花生生产合理、高效施肥提供理论依据.以‘花育25号’为材料,在0.3%盐胁迫浓度下,设置4个Ca浓度梯度[T₁(0)、T₂(75)、T₃(150)和T₄(225) kg·hm^-2 CaO]进行盆栽试验.结果表明: 花生植株内养分含量依次为氮>钾>钙>磷>镁,苗期植株对氮和钙素的吸收中心均在叶片,磷、钾、镁的吸收中心为茎,苗期近一半的营养积累分配在各元素相应的生长中心.成熟期氮、磷、钾吸收中心转移到荚果中,尤以氮、磷在籽仁中的积累量居多,达72.3%～78.9%;钙、镁的吸收中心仍为叶片和茎,其分配比例分别为49.8%、32.6%.盐胁迫明显抑制花生植株各器官对氮、磷、钾、钙和镁各元素的吸收积累与分配,尤以对叶片和籽仁中氮素积累的抑制较为显著,但盐胁迫对荚果中镁的积累有促进作用.外源钙对盐胁迫下花生植株各器官氮、磷、钙和镁的吸收累积有明显的促进作用,尤其对籽仁中磷素积累的调节最为显著,其在籽仁中的积累量提高50%以上.适宜的钙施用量可显著促进盐胁迫下花生养分吸收积累量,提高花生成熟期荚果中氮、磷、钾的分配比,最终提高产量.综合各养分吸收、积累分配和产量结果,在0.3%盐胁迫条件下钙肥适宜施用量为150 kg·hm^-2 CaO.     

等渗的盐分和水分胁迫对芦荟幼苗生长和离子分布的效应

 研究了等渗透势（-0.44、-0.88 MPa）NaCl和PEG 6000处理对六叶龄芦荟(Aloe vera)幼苗叶片生长速率、干物质积累、电解质渗漏和离子吸收、分配的效应。结果表明: -0.44、-0.88 MPa NaCl和PEG处理10 d均明显抑制芦荟幼苗叶片伸长生长,植株干物质积累速率显著降低, 叶片含水量降低,叶片细胞电解质渗漏率上升。NaCl对芦荟幼苗生长的抑制作用显著大于PEG处理的。不同器官离子含量、根系和叶片横切面X-射线微区分析结果表明, NaCl胁迫导致芦荟体内Na+、Cl－含量显著上升,根中增幅明显高于叶片,其中Cl－尤为显著。NaCl胁迫严重抑制芦荟对K+ 和Ca2+ 的吸收及其向叶片的运输,根、叶K+/Na+、Ca2+/Na+ 比率显著下降,而PEG胁迫对离子平衡的干扰较轻,是芦荟对水分胁迫的适应能力高于盐胁迫的主要原因之一。但芦荟对 -0.44～-0.88 MPa NaCl胁迫仍有一定的适应能力,主要原因是：1) 根系对离子的选择性吸收和运输较强,并随着盐胁迫强度增加其选择性增强; 2) 芦荟叶片中的盐分在贮水组织中显著积累,明显高于其它组织细胞。同时,芦荟是CAM（景天酸代谢）途径植物,蒸腾极小,盐分随蒸腾流进入地上部的机会小。     

模拟增温对黄河三角洲滨海湿地非生长季土壤呼吸的影响

冬季土壤呼吸能释放生长季所固存的碳, 因而在陆地碳循环中占有重要地位。随着全球气候变暖, 平均地表温度将升高0.3-4.8 ℃, 且冬季增温更加明显, 而温度的升高会促进更多CO₂的释放。另外, 滨海湿地地下水位浅, 淡咸水交互作用明显, 增温能引起土壤表层盐分升高, 从而影响土壤呼吸。该研究以黄河三角洲滨海湿地为研究对象, 采用红外辐射加热器模拟增温, 研究了该地区非生长季土壤呼吸的日动态及季节动态, 同时探讨了土壤呼吸对环境因子的响应机制。结果显示: 日动态中, 增温与对照的土壤呼吸速率变化趋势一致, 为单峰曲线; 在平均日变化中, 整个非生长季不同处理的土壤呼吸速率无显著差异, 而土壤温度和土壤盐分均为增温大于对照, 并且土壤呼吸峰值时间均比土壤温度提前。季节动态中, 整个研究期分为非盐分限制阶段(2014年11月-2015年2月中旬)和盐分限制阶段(2015年2月中旬-2015年4月)。在整个非生长季, 土壤呼吸速率无显著差异; 在非盐分限制阶段, 当10 cm土壤温度升高4.0 ℃时, 土壤呼吸速率显著提高22.9%, 而土壤呼吸温度敏感性系数(Q₁₀)与对照相比有所降低; 在盐分限制阶段, 尽管土壤温度升高3.3 ℃, 土壤呼吸速率却降低了20.7%, 这可能是由于增温引起了土壤盐分的升高, 同时由增温引起的土壤含水量的升高在一定程度上也限制了土壤呼吸, 而此阶段增温对Q₁₀无显著影响。因此, 在滨海湿地中, 增温除了直接影响土壤温度, 还可通过影响土壤水盐状况来影响土壤呼吸, 进而影响滨海湿地土壤碳库。     

农牧交错区不同植物群落土壤呼吸的日动态观测与测定方法比较

 采用动态密闭气室法（IRGA）对农牧交错区10种植物群落最大生物量时期的土壤呼吸日动态进行了测定,并将该方法得到的土壤日呼吸速率与碱液吸收法（AA）进行了比较。结果表明：1）10个群落土壤呼吸的昼夜变化比较明显,均为单峰型曲线,主要受土壤温度的驱动,但同时也受到当日降水情况和云量、风速等气象因子的较大影响。因此,这些群落土壤呼吸日动态的一致性较差,规律性并不明显。2）用碱液吸收法和动态密闭气室法测定的10个群落的土壤呼吸速率变化范围分别为394～894 mg C·m-2·d-1和313～2043 mg C·m-2·d-1,其中碱液吸收法测定结果平均为动态气室法的67.5%,明显低于动态密闭气室法。3）两种测定方法具有很好的相关性,R2为0.873 9。本研究中发现,在土壤呼吸速率低的情况下,两种方法的测定结果十分接近甚至碱液吸收法测定结果稍大于动态密闭气室法,而在土壤呼吸速率较高的情况下,动态密闭气室法测定结果则显著高于碱液吸收法。上述结果与国内外同类研究的结果高度一致,从而为校正以往采用碱液吸收法在该区域的测定结果提供了可靠依据。     

Effects of elevated temperature on soil respiration in a coastal wetland during the non- growing season in the Yellow River Delta,China

Aims Winter soil respiration plays a crucial role in terrestrial carbon cycle, which could lose carbon gained in the growing season. With global warming, the average near-surface air temperatures will rise by 0.3 to 4.8 °C. Winter is expected to be warmer obviously than other seasons. Thus, the elevated temperature can significantly affect soil respiration. The coastal wetland has shallow underground water level and is affected by the fresh water and salt water. Elevated temperature can cause the increase of soil salinity, and as a result high salinity can limit soil respiration. Our objectives were to determine the diurnal and seasonal dynamics of soil respiration in a coastal wetland during the non-growing season, and to explore the responses of soil respiration to environmental factors, especially soil temperature and salinity.
Methods A manipulative warming experiment was conducted in a costal wetland in the Yellow River Delta using the infrared heaters. A complete random block design with two treatments, including control and warming, and each treatment was replicated each treatment four times. Soil respiration was measured twice a month during the non-growing season by a LI-8100 soil CO₂ efflux system. The measurements were taken every 2 h for 24 h at clear days. During each soil respiration measurement, soil environmental parameters were determined simultaneously, including soil temperature, moisture and salinity.
Important findings The diurnal variation of soil respiration in the warming plots was closely coupled with that in the control plots, and both exhibited single-peak curves. The daily soil respiration in the warming was higher than that in the control from November 2014 to January 2015. Contrarily, from March to April 2015. During the non-growing seasons, there were no significant differences in the daily mean soil respiration between the two treatments. However, soil temperature and soil salt content in the warming plots were significantly higher than those in the control plots. The non-growing season was divided into the no salt restriction period (November 2014 to middle February 2015) and salt restriction period (middle February 2015 to April 2015). During non-growing season, soil respiration in the warming had no significant difference compared with that in control. During the no salt restriction period, soil respiration in the warming was 22.9% (p < 0.01) greater than the control when soil temperature at 10 cm depth in warming was elevated by 4.0 °C compared with that in control. However, experimental warming decreased temperature sensitivity of soil respiration (Q₁₀). During salt restriction period, soil warming decreased soil respiration by 20.7% compared with the control although with higher temperature (3.3 °C), which may be attributed to the increased soil salt content (Soil electric conductivity increased from 4.4 ds·m^-1 to 5.3 ds·m^-1). The high water content can limit soil respiration in some extent. In addition, the Q₁₀ value in the warming had no significant difference compared with that in control during this period. Therefore, soil warming can not only increase soil respiration by elevating soil temperature, but also decrease soil respiration by increasing soil salt content due to evaporation, which consequently regulating the soil carbon balance of coastal wetlands.     

Influence of ionic environment of the stress relaxation behavior of an invertebrate connective tissue

The rheological properties of an invertebrate connective tissue were measured in three different ionic environments. Short-term stress relaxation tests were conducted on sections of holothurian (Echinodermata) body wall immersed in isotonic monovalent and divalent salt solutions and deionized water. Using a reduced modulus format, the viscoelastic behavior over the experimental time scale was described by a two term Maxwell equation with empirically determined spring constants and relaxation times. In addition, equilibrium relaxation moduli (Ge) were estimated from the empirical relationship of Chasset and Thirion (1965, in Physics of Non Crystalline Solids, ed. Prins, North Holland). The experiments indicated that both relaxation times and equilibrium moduli decreased in the presence of monovalent and divalent inorganic ions whereby the effect of the Na+ was greater than that of the Ca++. The present findings are compared with those reported for vertebrate connective tissue.     

Macular pigment optical density and its relationship with serum and dietary levels of lutein and zeaxanthin

Observational evidence is accumulating that the onset of age-related maculopathy, the leading cause of legal blindness in the Western World, could be delayed, or even averted, with antioxidant supplements. Lutein (L) and zeaxanthin (Z) are two hydroxy-carotenoids with antioxidant activity which accumulate at the macula, where they are collectively known as macular pigment (MP). It has been shown that MP is entirely of dietary origin, and that L and Z levels in serum, diet, and retina correlate. However, the nature of the relationships between L and Z in foodstuffs, blood, and macula is confounded by many variables including processes which influence digestion, absorption, and transport of the compounds in question, and accumulation and stabilization of the carotenoids in the tissues. If macular pigment is protective for age-related maculopathy, a clear understanding of the mechanisms whereby L and Z arrive at the target tissue (retina) from their source (foodstuff) is essential. In this paper, we review the literature germane to this growing area of interest.     

Inhibition of intestinal sugar transport by phenformin.

The effect of phenformin on the absorption of D-glucose and D-galactose by hamster and rat intestine, was studied. Phenformin did not affect D-glucose absorption by rat intestine, but it inhibited at 10(-3) to 10(-2) M the absorption of D-glucose and D-galactose by hamster intestine. The inhibition was higher when D-glucose was tested. Phenformin also inhibited active accumulation of these sugars by rings of hamster small intestine, in vitro; this effect was greater when D-glucose was utilized. The drug inhibits the oxygen uptake in the tissue in the absence or in the presence of added substrate. Phenformin, as previously suggested, does not seem to act as a specific inhibitor on D-glucose transport, but most likely by its inhibitory effect on mitochondrial respiration.     

Does night-time transpiration provide any benefit to wheat (Triticum aestivum L.) plants which are exposed to salt stress?

The study aimed to test whether night-time transpiration provides any potential benefit to wheat plants which are subjected to salt stress. Hydroponically grown wheat plants were grown at four levels of salt stress (50, 100, 150, and 200 mM NaCl) for 5–8 days prior to harvest (day 14–18). Salt stress caused large decreases in transpiration and leaf elongation rates during day and night. The quantitative relation between the diurnal use of water for transpiration and leaf growth was comparatively little affected by salt. Night-time transpirational water loss occurred predominantly through stomata in support of respiration. Diurnal gas exchange and leaf growth were functionally linked to each other through the provision of resources (carbon, energy) and an increase in leaf surface area. Diurnal rates of water use associated with leaf cell expansive growth were highly correlated with the water potential of the xylem, which was dominated by the tension component. The tissue-specific expression level of nine candidate aquaporin genes in elongating and mature leaf tissue was little affected by salt stress or day/night changes. Growing plants under conditions of reduced night-time transpirational water loss by increasing the relative humidity (RH) during the night to 95% had little effect on the growth response to salt stress, nor was the accumulation of Na⁺ and Cl⁻ in shoot tissue altered. We conclude that night-time gas exchange supports the growth in leaf area over a 24 h day/night period. Night-time transpirational water loss neither decreases nor increases the tolerance to salt stress in wheat.     

Mitochondrial calcium flux in temperature-sensitive mutants of Drosophila

The mechanisms of mitochondrial calcium flux in normal and temperature-sensitive mutants of $\text{Drosophila}$ were investigated. Adult mitochondria from all stocks, when analysed with an oxygen electrode, gave respiration rates which exhibited normal responses to adenosine diphosphate and uncoupling agents but no stimulation by calcium. In contrast, calcium stimulates the respiration rate of normal larval mitochondria particularly those of the second instar. This is not evident in second instar mitochondria from the temperature sensitive mutants. There is a rapid accumulation of mitochondrial calcium during normal larval ontogenesis. The levels in temperature-sensitive second instar mitochondria are higher than those of any of the normal larval stages. Adult mitochondria in all cases contain very low levels of calcium. The amount of calcium taken up by mitochondria of second instar temperature-sensitive mutants is lower than that of normal. This may reflect the higher endogenous levels already present in the former. The implications of these variations in calcium metabolism for the behavioural defects of the temperature sensitive mutants is discussed.     

Inhibitory effects of 2,3,5-triiodobenzoic Acid on ion absorption, respiration, and carbon metabolism in excised barley roots

The ability of 2,3,5-triiodobenzoic acid (TIBA) to alter ion absorption, respiration, carbon metabolism, and the permeability of the cell membranes of excised barley roots has been examined. Roots pretreated in either H₂O, KCl, or TIBA followed by treatment in KCl, TIBA, or KCl and TIBA demonstrated that inhibition of ion uptake due to TIBA was reversible. These studies also suggest that ions already accumulated within the vacuole remain sequestered after the addition of TIBA, whereas cytoplasmic ions leak out into the external medium. A 20-minute lag period was present prior to the onset of inhibition of O₂ consumption by TIBA. A b-type cytochrome from corn that is apparently associated with the plasmalemma and possibly involved in respiration or ion uptake, or both, was unaffected by TIBA. The addition of TIBA to treatment solutions resulted in the synthesis and accumulation of ethanol. Analysis of organic acids showed that only the malate concentration was affected by treatment with TIBA. A reduction of 26% was noted for malate in the presence of 2 micromolar TIBA. These combined results suggest that the inhibitory action of TIBA in barley roots involves an alteration of mitochondrial respiration and not a direct depolarization of the plasmalemma.     

Inhibition of intestinal copper absorption by divalent cations and low-molecular-weight ligands in the rat

l-histidine (His) has been shown to enhance the inhibitory effect of zinc on intestinal copper absorption. This study was aimed at examining whether this effect of His was also extended to the interactions of other divalent cations: ferrous iron, tin, and cobalt, using an in vivo perfusion system in rats. Copper absorption and intestinal content of this element significantly decreased in the presence of 2 mM His and ferrous iron. Iron accumulation was greater when His was present than when omitted. A fivefold excess of tin inhibited copper absorption only when His was present. Citrate, at the same concentration as His, had no effect on copper absorption, but hepatic copper levels were increased, as compared to the absence of either His or citrate. Addition of 0.5 or 1.0 mM cobaltous salt plus His resulted in a sharp decrease in copper intestinal absorption, with an increase in intestinal tissue retention. These results confirm earlier findings with zinc and His, and suggest that a general phenomenon, either accelerating the removal of copper from the intestinal lumen or increasing, the retention of this element by the intestinal tissue, is a common feature of the interaction between cations of similar electronic configuration to copper and a high-affinity ligand, such as His.