外源钙对不同钙敏感型番茄幼苗生理特性的影响

利用钙不敏感型番茄品种(江蔬1号)和钙敏感型番茄品种(L-402)为试材,研究了不同浓度的外源钙对其根系活力、钙调素含量、叶绿素a、b含量和比值及活性氧清除酶系统活性的影响.结果表明,根系钙调素(CaM)含量随介质钙浓度增加而增加,不敏感品种江蔬1号高于敏感品种L-402.根系活力、生长点和真叶chla/b比值在低钙强度下(1和4 mg·L^-1)以江蔬1号显著高于L-402,在充足供钙时(100 mg·L^-1)L-402显著高于江蔬1号,表明江蔬1号品种具有较强的耐低钙和光胁迫的能力.对活性氧清除酶系统活性来说,在三个钙浓度下敏感品种L-402的POD、CAT酶活性均显著高于江蔬1号,降钙使两酶活性升高,SOD酶活性下降,且L-402下降的幅度高于江蔬1号,表明低钙造成的胁迫对L-402品种影响较大,江蔬1号较耐受缺钙胁迫.     

H2O2 pretreated rice seedlings specifically reduces arsenate not arsenite: difference in nutrient uptake and antioxidant defense response in a contrasting pair of rice cultivars

The study investigated the reduction in metalloid uptake at equimolar concentrations (~53.3 μM) of As(III) and As(V) in contrasting pair of rice seedlings by pretreating with H₂O₂ (1.0 μM) and SA (1.0 mM). Results obtained from the contrasting pair (arsenic tolerant vs. sensitive) of rice seedlings (cv. Pant Dhan 11 and MTU 7029, respectively) shows that pretreatment of H₂O₂ and H₂O₂ + SA reduces As(V) uptake significantly in both the cultivars, while no reduction in the As(III) uptake. The higher growth inhibition, higher H₂O₂ and TBARS content in sensitive cultivar against As(III) and As(V) treatments along with higher As accumulation (~1.2 mg g⁻¹ dw) than in cv. P11, unravels the fundamental difference in the response between the sensitive and tolerant cultivar. In the H₂O₂ pretreated plants, the translocation of As increased in tolerant cultivar against AsIII, whereas, it decreased in sensitive cultivar both against AsIII and AsV. In both the cultivars translocation of Mn increased in the H₂O₂ pretreated plants against As(III), whereas, the translocation of Cu increased against As(V). In tolerant cultivar the translocation of Fe increased against As(V) with H₂O₂ pretreatment whereas, it decreased in the sensitive cultivar. In both the cultivars, Zn translocation increased against As(III) and decreased against As(V). The higher level of H₂O₂ and SOD (EC 1.15.1.1) activity in sensitive cultivar whereas, higher, APX (EC 1.11.1.11), GR (EC 1.6.4.2) and GST (EC 1.6.4.2) activity in tolerant cultivar, also demonstrated the differential anti-oxidative defence responses between the contrasting rice cultivars.

Electronic supplementary material

The online version of this article (doi:10.1007/s12298-014-0255-1) contains supplementary material, which is available to authorized users.     

Aluminum Effects on Calcium (45Ca2+) Translocation in Aluminum-Tolerant and Aluminum-Sensitive Wheat (Triticum aestivum L.) Cultivars (Differential Responses of the Root Apex versus Mature Root Regions)

The influence of Al exposure on long-distance Ca2+ translocation from specific root zones (root apex or mature root) to the shoot was studied in intact seedlings of winter wheat (Triticum aestivum L.) cultivars (Al-tolerant Atlas 66 and Al-sensitive Scout 66). Seedlings were grown in 100 [mu]M CaCl2 solution (pH 4.5) for 3 d. Subsequently, a divided chamber technique using 45Ca2+-labeled solutions (100 [mu]M CaCl2 with or without 5 or 20 [mu]M AlCl3, pH 4.5) was used to study Ca2+ translocation from either the terminal 5 to 10 mm of the root or a 10-mm region of intact root approximately 50 mm behind the root apex. The Al concentrations used, which were toxic to Scout 66, caused a significant inhibition of Ca2+ translocation from the apical region of Scout 66 roots. The same Al exposures had a much smaller effect on root apical Ca2+ translocation in Atlas 66. When a 10-mm region of the mature root was exposed to 45Ca2+, smaller genotypic differences in the Al effects effects on Ca2+ translocation were observed, because the degree of Al-induced inhibition of Ca2+ translocation was less than that at the root apex. Exposure of the root apex to Al inhibited root elongation by 70 to 99% in Scout 66 but had a lesser effect (less than 40% inhibition) in Atlas 66. When a mature root region was exposed to Al, root elongation was not significantly affected in either cultivar. These results demonstrate that genotypic differences in Al-induced inhibition of Ca2+ translocation and root growth are localized primarily in the root apex. The pattern of Ca2+ translocation within the intact root was mainly basipetal, with most of the absorbed Ca2+ translocated toward the shoot. A small amount of acropetal Ca2+ translocation from the mature root regions to the apex was also observed, which accounted for less than 5% of the total Ca2+ translocation within the entire root. Because Ca2+ translocation toward the root apex is limited, most of the Ca2+ needed for normal cellular function in the apex must be absorbed from the external solution. Thus, continuous Al disruption of Ca2+ absorption into cells of the root apex could alter Ca2+ nutrition and homeostasis in these cells and could play a pivotal role in the mechanisms of Al toxicity in Al-sensitive wheat cultivars.     

Characterization of Zinc Uptake, Binding, and Translocation in Intact Seedlings of Bread and Durum Wheat Cultivars

Durum wheat (Triticum turgidum L. var durum) cultivars exhibit lower Zn efficiency than comparable bread wheat (Triticum aestivum L.) cultivars. To understand the physiological mechanism(s) that confers Zn efficiency, this study used ⁶⁵Zn to investigate ionic Zn²⁺ root uptake, binding, and translocation to shoots in seedlings of bread and durum wheat cultivars. Time-dependent Zn²⁺ accumulation during 90 min was greater in roots of the bread wheat cultivar. Zn²⁺ cell wall binding was not different in the two cultivars. In each cultivar, concentration-dependent Zn²⁺ influx was characterized by a smooth, saturating curve, suggesting a carrier-mediated uptake system. At very low solution Zn²⁺ activities, Zn²⁺ uptake rates were higher in the bread wheat cultivar. As a result, the Michaelis constant for Zn²⁺ uptake was lower in the bread wheat cultivar (2.3 μm) than in the durum wheat cultivar (3.9 μm). Low temperature decreased the rate of Zn²⁺ influx, suggesting that metabolism plays a role in Zn²⁺ uptake. Ca inhibited Zn²⁺ uptake equally in both cultivars. Translocation of Zn to shoots was greater in the bread wheat cultivar, reflecting the higher root uptake rates. The study suggests that lower root Zn²⁺ uptake rates may contribute to reduced Zn efficiency in durum wheat varieties under Zn-limiting conditions.Soils that contain insufficient levels of the essential plant micronutrient Zn are common throughout the world. As a result, Zn deficiency is a widespread problem in crop plants, especially cereals (Graham et al., 1992). The importance of plant foods as sources of Zn, particularly in the marginal diets of developing countries, is well established (Welch, 1993). The development of crop plants that are efficient Zn accumulators is therefore a potentially important endeavor. In addition to its effects on nutrition, Zn deficiency in crops is relevant to other areas of human health. Another consequence of Zn-deficient soils is the tendency for plants grown in such soils to accumulate heavy metals. For example, in the Great Plains region of North America, where soil Zn levels are low and naturally occurring Cd is present, durum wheat (Triticum turgidum L. var durum) grains accumulate Cd to relatively high concentrations (Wolnik et al., 1983). The presence of Cd in food represents a potential human health hazard and, in response, international trade standards have been proposed to limit the levels of Cd in exported grain (Codex Alimentarius Commission, 1993). Thus, there is a need to understand the physiological processes that control acquisition of Zn from soil solution by roots and mobilization of Zn within plants.It has been demonstrated in recent years that crop plants vary in their ability to take up Zn, particularly when its availability to roots is limited. Zn efficiency, defined as the ability of a plant to grow and yield well in Zn-deficient soils, varies among wheat cultivars (Graham and Rengel, 1993). In field trials, durum wheat cultivars have been shown to be consistently less Zn efficient than bread wheat (Triticum aestivum L.) cultivars (Graham et al., 1992). Similarly, durum wheat varieties were reported to be less Zn efficient than bread wheat varieties when grown in chelate-buffered hydroponic nutrient culture (Rengel and Graham, 1995a).The physiological mechanism(s) that confers Zn efficiency has not been identified. Processes that could influence the ability of a plant to tolerate limited amounts of available Zn include higher root uptake, more efficient utilization of Zn, and enhanced Zn translocation within the plant. Cakmak et al. (1994) showed that a Zn-inefficient durum wheat cultivar exhibited Zn-deficiency symptoms earlier and more intensely than a Zn-efficient bread wheat cultivar even though the Zn tissue concentrations were similar in both lines, suggesting differential utilization of Zn in the two cultivars. Rates of Zn translocation to shoots were shown to vary among sorghum cultivars, although correlations with Zn efficiency were not established (Ramani and Kannan, 1985). Root uptake kinetics have been reported to vary between rice cultivars having different Zn requirements, with high-Zn-requiring cultivars exhibiting consistently higher root uptake rates (Bowen, 1986). In contrast, a correlation between Zn efficiency and rates of root Zn uptake in bread and durum wheat cultivars could not be demonstrated (Rengel and Graham, 1995b).In grasses Zn influx into the root symplasm has been hypothesized to occur as the free Zn²⁺ ion (Halvorson and Lindsay, 1977), as well as in the form of Zn complexes with nonprotein amino acids known as phytosiderophores (Tagaki et al., 1984) or phytometallophores (Welch, 1993). Concentration-dependent uptake of free Zn²⁺ ions has been shown to be saturable in several species, including maize (Mullins and Sommers, 1986), barley (Veltrup, 1978), and wheat (Chaudhry and Loneragan, 1972), suggesting that ionic uptake in grasses occurs via a carrier-mediated system. However, several of these studies have been criticized on the basis that excessively high (and physiologically unrealistic) Zn²⁺ concentrations were used (Kochian, 1993).This study was undertaken to examine unidirectional Zn²⁺ influx and translocation to shoots in Zn-efficient bread wheat lines and Zn-inefficient durum wheat lines. Experiments were performed in the absence of added phytometallophores and results are presumed to represent influx of ionic Zn²⁺. Zn activities in the nanomolar range were used to more closely mimic free Zn²⁺ levels occurring naturally in soil solution. The results presented here indicate that a Zn-efficient bread wheat cultivar maintained higher rates of Zn uptake than a Zn-inefficient durum wheat cultivar, particularly at low (and physiologically relevant) solution Zn²⁺ activities.     

Effects of Salinity on the Extensibility and Ca Availability in the Expanding Region of Growing Barley Leaves

The growth of barley (Hordeum vulgare L.) leaves is reduced by salinity. We used the Instron extensometric technique to measure the reversible and irreversible compliance of the expanding regions of growing barley leaves from plants exposed to 1, 40, 80 and 120 mM NaCl in nutrient solution. Two barley cultivars differing in salinity resistance (cv ‘Arivat’ and cv ‘Briggs’) were compared over 5d of leaf growth. During the period of most active leaf expansion, salinity reduced reversible compliance and increased compliance in the leaf segments, although responses to salinity were complex and changed over the course of leaf expansion. Salinity increased irreversible compliance more in the salt-sensitive cultivar Arivat than in the more salt-tolerant cultivar Briggs. Elemental analysis of the basal leaf segments used for extensometry revealed an accumulation of Na and a depletion of Ca in segments from salinized plants, resulting in very high Na: Ca ratios in salinized expanding tissue. The concentrations of K and Mg in basal leaf tissue were elevated by salinity. Our data do support the hypothesis that the inhibition of leaf expansion by salinity stress is mediated by a decline in irreversible extensibility. We suggest that reduced Ca availability in expanding leaf tissue may contribute to growth reduction in salt-stressed barley seedlings.     

The response of two rice cultivars to external Na/Ca ratio

The response of the rice cultivars ‘M9’ and ‘M-201’ to nutrient cultures salinated at −0.4 MPa with varying ratios of Na and Ca was studied. Although the dry matter production of both cultivars was sensitive to the Na/Ca ratio, this correlation was significant only for M-201. Calcium nutrition was severely affected by the composition of the external solution, and the laminae exhibited Ca-deficiency symptoms at Na/Ca molar ratios of 78 and 198. Sodium concentration in the shoot decreased as the Na/Ca ratio in the external solution decreased. Patterns of Na and Cl distribution in the shoot tissues were similar; both ions were accumulated preferentially in the tillers and older leaves. The Na-induced inhibition of Ca uptake and transport appears to be more limiting to shoot growth of M9 and M-201 than Na toxicity per se.     

The development of potential screens based on shoot calcium and iron concentrations for the evaluation of tolerance in Egyptian genotypes of white lupin (Lupinus albus L.) to limed soils

European cultivars of white lupin (Lupinus albus L.) grow poorly in limed or calcareous soils. However, Egyptian genotypes are grown successfully in highly calcareous soil and show no stress symptoms. To examine their physiological responses to alkaline soil and develop potential screens for tolerance, three experiments were conducted in limed and non-limed (neutral pH) soil. Measurements included net CO2 uptake, and the partitioning of Fe2+ and Fe3+ and soluble and insoluble Ca in stem and leaf tissue. Intolerant plants showed clear symptoms of stress, whereas stress in the Egyptian genotypes and in L pilosus Murr. (a tolerant species) was less marked. Only the intolerant plants became chlorotic and this contributed to their reduced net CO2 uptake in the limed soil. In contrast, Egyptian genotypes and L pilosus showed no change in net CO2 uptake between the soils. The partitioning of Ca and Fe either resulted from the stress responses, or was itself a stress response. L pilosus and some Egyptian genotypes differed in soluble Ca concentrations compared with the intolerant cultivars, although no significant difference was apparent in the Ca partitioning of the Egyptian genotype Giza 1. In a limed soil, Giza 1 maintained its stem Fe3+ concentration at a level comparable with that of plants grown in non-limed soil, whereas stem [Fe3+] of an intolerant genotype increased. Gizal increased the percentage of plant Fe that was Fe2+ in its leaf tissue under these conditions; that of the intolerant genotype was reduced. The potential tolerance of the Egyptian genotypes through these mechanisms and the possibility of nutritional-based screens are discussed.     

A relationship between heat load and plasma enzyme concentration

1. 1. The sensitivity of serum enzyme levels as indicators of tissue damage is less well established in the prodromal period of heatstroke, especially for sub-lethal stress conditions.

2. 2. Anaesthetized rats were exposed to two different sets of thermal conditions.

3. 3. Plasma levels of alanine aminotransferase (ALT), aspartate aminotransferase (AST), creatine kinase (CK) and lactate dehydrogenase (LD) were assayed in each group upon termination of stress, 6 h post-stress and 24 h post-stress.

4. 4. The tissue “damage” sustained was mild to moderate and completely reversible.

5. 5. The rate of rise in body temperature may constitute an important factor in the ultimate pathology.

6. 6. CK proved to be the most sensitive parameter of tissue “damage”.

The Cellular Mechanism of Orcadian Rhythms-A View on Evidence, Hypotheses and Problems

A stable period length is a characteristic property of circadian oscillations. The question about whether higher frequency oscillators (0.5-8 hr) contribute to or establish the stable circadian periodicity cannot be answered at present. A sequential coupling of quantal subcycles appears possible on the basis of known “ultradian” oscillations. There is, however, no supporting evidence for such a concept. Phase response curves of the circadian clock derived from various perturbing pulses allow qualitative conclusions concerning the perturbed clock process. Deductions from computer simulations also allow conclusions about the phase of this oscillatory process.

The distinction between processes (a) essential to the clock mechanism, (b) maintaining and controlling the clock (inputs) and (c) depending on the clock (outputs) on the basis of “oscillatory” and “change of φ or τ after perturbation” seems to be useful but not stringent. Protein synthesis may be an essential or input process. Oscillatory changes of this process may be due to periodic translational control or RNA-supply. Circadian changes in protein concentration and/or activity may depend on periodic synthesis, proteolysis, covalent modifications or aggregations. Specific essential proteins have not been identified conclusively. The large overlap between the group of agents and treatments that phase shift the clock and the group that induces stress proteins suggest that the latter may play a role in the controlling (input) or essential domain.

The role of membranes in the clock mechanism is not clear: concepts assuming an essential function are based on circumstantial evidence. The membrane potential as well as Ca²⁺ may be involved in either input or essential function. Ca²⁺ -calmodulin may also be important as concluded from inhibitor experiments. It is tempting to assume that a calmodulin-dependent kinase is part of a periodic protein phosphorylation process, yet it is not clear whether the periodic protein phosphorylation that has been observed is essential or is just another output process.     

Improved salt tolerance of melon (Cucumis melo L.) by the addition of proline and potassium nitrate

A pot experiment was carried out under glasshouse conditions with melon (Cucumis melo) cv. “Tempo F1” in a mixture of peat, perlite and sand (1:1:1) to investigate the effects of external proline and potassium nitrate applications to salinity-treated (150 mM) plants with respect to fruit yield, plant growth, some physiological parameters and ion uptake. Treatments were—(i) control (C): plants receiving nutrient solution, (ii) salinity treatment, as for control plus 150 mM NaCl. Salinity treatment was combined with or without either 5 mM supplementary KNO₃ or 10 mM proline. The salt treatment (150 mM NaCl) led to significant decreases in plant growth, fruit yield, relative water content (RWC), stomatal density, uptake of Ca²⁺, K⁺ and N, and chlorophyll a and b contents, accompanied by significant increases in Na⁺ uptake, proline concentration and membrane permeability. Supplementary KNO₃ and proline treatments significantly ameliorated the adverse effects of salinity on plant growth, fruit yield and the physiological parameters examined. This could be attributed to the effects of all the external supplements in maintaining membrane permeability, and increasing concentrations of Ca²⁺, N and K⁺ in the leaves of plants subjected to salt stress.     

Plasma Concentration of Nine Hormones and Neurotransmitters During Usual Activities or Constant Bed Rest for 34 H

Thyroid-stimulating hormone (TSH), Cortisol, melatonin, prolactin, luteinizing hormone (LH), delta-sleep-inducing peptide (DSIP), its phosphorylated form (P-DSIP), heart rate, and body temperature were measured every half hour during two 24-h periods in five normal men. τ-Amino-butyric acid (GABA) and 3-methoxy-4-hydroxyphenylglycol (MHPG) were measured less frequently. The first period, the “activity” condition, included usual daily activities. The second period, or “rest” condition, consisted of fasting, constant bed rest during 34 h, and partial light deprivation. Compared with the “rest” condition, the “activity” condition increased heart rate, temperature, LH, and TSH in most subjects, and Cortisol in two of five subjects. It retarded the onset of nocturnal Cortisol and melatonin secretion. The temporal pattern and the absolute values of the concentrations of DSIP, P-DSIP, MHPG, GABA, and prolactin showed no or minimal changes during the two conditions. In spite of the influence of the “activity” versus “rest” condition on several hormones, the mean concentrations as well as the temporal organization of their secretion into plasma were quite stable within each subject, whereas they varied much more between individuals. TSH, Cortisol, and melatonin values were also stable within an 8-month period in one subject who was studied on four occasions. The results illustrate that the patterns of hormones rhythms and their reactivity to changes in the environment are, to a large extent, specific to each subject.     

Differences in calcium efficiency between cowpea (Vigna unguiculata (L.) Walp.) cultivars

The cowpea (Vigna unguiculata (L.) Walp.) cultivars TVu 354 and Solojo were grown in solution culture at 10 to 1000 M Ca supply. The Ca supply did not vary by more than 10% during the experiment. The pH value was kept constant within 0.1 units at 4.0 by automatic titration. The cultivar TVu 354 proved to be much more Ca-efficient than Solojo. At 10 M Ca supply Solojo died, whereas TVu 354 was hardly affected in dry matter production. The differences in Ca efficiency were independent of the P supply. They could not be explained by differences in Ca uptake or Ca concentrations in the plant tissue. Short-term studies using ⁴⁵Ca, both in the dark and in the light, indicated better transport of Ca from the roots to the shoots and within the shoots to the younger leaves in the Ca-efficient cultivar TVu 354. However, the main reason for the differences between the cultivars in sensitivity to low Ca supply were differences in the Ca requirement of the plant tissue to maintain tissue organization and function. Sequential fractionation of the freeze-dried leaf tissue with hot water, 0.5 M NaCl, 1 M CH₃COOH, and 2 M HCl did not reveal cultivar differences in Ca binding state. The results clearly show that considerable genetic potential in tolerance to low Ca supply exists in cowpea. However, a better understanding of the physiological/biochemical reasons for low internal Ca requirement is needed.     

Seed Treatment with Auxins Modulates Growth and Ion Partitioning in Salt-stressed Wheat Plants

Experiments were performed to determine whether seed priming with different concentrations （100, 150, and 200 mg/L） of auxins （indoleacetic acid （IAA）, indolebutyric acid （IBA）, or their precursor tryptophane （Trp）） could alter salinity induced perturbances in salicylic acid and ion concentrations and, hence, growth in wheat （Triticum aestivum L.） cultivars, namely M.H.-97 （salt intolerant） and tnqtab-91 （salt tolerant）. Primed and non-primed seeds were sown in Petri dishes in a growth room, as well as in a field treated with 15 dS/m NaCl salinity. All priming agents, except IBA, increased the final germination percentage in both cultivars. The seedlings of either cultivar raised from Trp-treated seeds had greater dry biomass when under salt stress. In field experiments, Trp priming was much more effective in mediating the increase in grain yield, irrespective of the cultivar, under salt stress. The alleviatory effect of Trp was found to be associated with reduced uptake of Na^＋ in the roots and subsequent translocation to the shoots, as well as increased partitioning of Ca^＋ in the roots of salt-stressed wheat plants. Plants of both cultivars raised from Trp-and IAA-treated seeds accumulated free salicylic acid in their leaves when under salt stress. Overall, the Trp priming-induced improvement in germination and the subsequent growth of wheat plants could be related to ion homeostasis when under salt stress. The possible involvement of salicylic acid in the Trp priming-induced better growth under Conditions of salt stress is discussed.     

Combination of u.v.-B. and ozone reduces pollen tube growth more than either stress alone

The rate of in vitro Nicotiana tabacum L. “Bel-W3” pollen tube growth was reduced 62 and 44%, respectively, when pollen tubes were exposed to 120 ppb ozone (O₃) for 3 hr or 300 μW/cm² ultraviolet-B (u.v.-B) radiation for 30 min. Petunia hybrida Vilm. “White Cascade” pollen tube growth was reduced 34 and 59%, respectively, upon exposure to O₃ or u.v.-B at the above doses. The combination of u.v.-B at 300 μW/cm² for 30 min, followed by O₃ at 120 ppb for 3 hr, reduced pollen tube growth by 79% for “Bel-W3” and 75% for “White Cascade”. The effect appeared to be additive, implying that different target areas may be affected by the two stressors. In the Northeast, plants are exposed to both u.v.-B and O₃ during the normal growing season. This may result in an unexpectedly higher stress on the reproductive system than had been previously suspected based on these two stressors acting individually.     

Immunofluorescent and ultrastructural studies of “sarcomeric” units in stress fibers of cultured non-muscle cells

Immunofluorescence and electron microscopy were used to study the organization of actin, myosin and α-actinin in the “sarcomeric” units of the stress fibers of a selected non-muscle cell type. The results of indirect immunofluorescence confirm that myosin and α-actinin are periodically distributed in discrete units along stress fibers and demonstrate that they are alternately spaced. This relationship is required by a sarcomere model of stress fiber construction. A comparison between immunofluorescent and EM images of stress fibers confirms that α-actinin is confined to Z line-like dense bodies, myosin to the spaces in between. The most intriguing result is that by immunofluorescence a periodic distribution of actin can be detected in some fibers. This may indicate that even actin is periodically distributed in non-muscle “sarcomeres”.     

Detectability and criterion measures in temporal generalization

Computer simulation of performance on “normal” and “episodic” temporal generalization tasks was used to examine the relations between the theoretical parameters of models which fit temporal generalization data (“timing sensitivity” and “threshold”), and the d′ (detectability) and beta (decision criterion) measures of signal-detection theory. In general, changes in timing sensitivity altered d′, whereas threshold changes affected beta, supporting the assertion that the two sorts of variables (“sensitivity/detectability” and “threshold/criterion”) were psychologically equivalent. Cases where temporal generalization gradients were apparently contaminated by “random responding” could be treated by changes in beta, but cases in which temporal generalization gradients were not peaked at the standard posed severe problems for a simple signal-detection account, although existing models of temporal generalization performance could deal with them.     

An Update on Connexin Genes and their Nomenclature in Mouse and Man

Gap junctions, composed of connexin protein subunits, allow direct communication through conduits between neighboring cells. Twenty and twenty-one members of the connexin gene family are likely to be expressed in the mouse and human genome, respectively, 19 of which can be grouped into sequence-orthologous pairs. Their gene structure appears to be relatively simple. In most cases, an untranslated exon1 is separated by an intron of different lengh from exon2 that includes the uninterrupted coding region and the 3'-untranslated region. However, there are several exceptions to this scheme, since some mouse connexin genes contain different 5'-untranslated regions spliced either in an alternative and/or consecutive manner. Additionally, in at least 3 mouse and human connexin genes (mCx36, mCx39, mCx57 and hCx31.3, hCx36, as well as hCx40.1) the reading frame is spliced together from 2 different exons. So far, there are two nomenclatures to classify the known connexin genes: The “Gja/Gjb” nomenclature, as it is currently adopted by the NCBI data base, contains some inconsistencies compared to the “Cx” nomenclature. Here we suggest some minor corrections to co-ordinate the “Gja/Gjb” nomenclature with the “Cx” nomenclature. Furthermore, this short review contains an update on phenotypic correlations between connexin deficient mice and patients bearing mutations in their orthologous connexin genes.     

Inhibitory effect of high oxygen pressure on potassiuminduced activation of pyruvate dehydrogenase and glucose metabolism in rat brain slices

The effects of high oxygen pressure on pyruvate dehydrogenase (pyruvate: lipoate oxidoreductase (decarboxylating and acceptor-acylating), EC 1.2.4.1) activity, tissue concentration of ATP, and CO₂ production from glucose were studied in rat brain cortical slices. The increase in pyruvate dehydrogenase activity and the lowering of cellular ATP, occurring during potassium-induced depolarization at 1 atm of oxygen, were reversed by increasing the oxygen pressure to 5 atm. When brain slices were incubated at 1 atm oxygen with [U-¹⁴C]glucose, a high potassium medium approximately doubled the production of ¹⁴CO₂. Oxygen at 5 atm abolished this potassium-dependent increase in ¹⁴CO₂ production with no significant effect on glucose oxidation in normal Krebs-Ringer phosphate medium. Adding 4 atm helium to 1 atm oxygen did not interfere with the ability of potassium ions to activate pyruvate dehydrogenase, lower ATP, or increase glucose oxidation. The results show that toxic effects of hyperbaric oxygen, not manifest in “resting” tissue, may be revealed during stress such as potassium depolarization. The site of the toxic effects of oxygen is probably the cell membrane where excess oxygen appears to interfere with the action of the sodium pump, calcium transport or other processes stimulated by increased concentrations of extracellular potassium.     

Anthroyl stearate as a fluorescent probe of chloroplast membranes

1. A reversible light-induced enhancement of the fluorescence of a “hydrophobic fluorophore”, 12-(9-anthroyl)-stearic acid (anthroyl stearate), is observed with chloroplasts supporting phenazine methosulfate, cyclic or 1,1′-ethylene-2,2′-dipyridylium dibromide (Diquat) pseudo-cyclic electron flow; no fluorescence change is observed when methyl viologen or ferricyanide are used as electron acceptors. The stearic acid moiety of anthroyl stearate is important for its localization and fluorescence response in the thylakoid membrane, since structural analogs of anthroyl stearate lacking this group do not show the same response.

2. This effect is decreased under phosphorylating conditions (presence of ADP, P_i, Mg²⁺), and completely inhibited by the uncoupler of phosphorylation NH₄Cl (5–10 mM), as well as the ionophores nigericin and gramicidin-D (both at 5 · 10⁻⁸ M). The MgCl₂ concentration dependence of the anthroyl stearate enhancement effect is identical to that previously observed for cyclic photophosphorylation, as well as for the formation of a “high energy intermediate”. The anthroyl stearate fluorescence enhancement is inhibited by increasing concentrations of ionophores in parallel with the decrease in ATP synthesis, but is essentially unaffected by specific inhibitors (Dio-9 and phlorizin) of photophosphorylation; thus, it appears that anthroyl stearate monitors a component of the “high energy state” of the thylakoid membrane rather than a terminal phosphorylation step.

3. The light-induced anthroyl stearate fluorescence enhancement is suggested to monitor a proton gradient in the energized chloroplast because (a) similar enhancement can be produced by sudden injection of hydrogen ions in a solution of anthroyl stearate; (b) when the proton gradient is dissipated by gramicidin or nigericin light-induced anthroyl stearate fluorescence is eliminated; (c) when the proton gradient is dissipated by tetraphenylboron, light-induced anthroyl stearate fluorescence decreases, and (d) light-induced anthroyl stearate fluorescence change as a function of pH is qualitatively similar to that observed with other probes for a proton gradient (e.g. 9-aminoacridine). Furthermore, anthroyl stearate does not monitor H⁺ uptake per se because (a) the pH dependence of H⁺ transport is different from that of the anthroyl stearate fluorescence change, and (b) tetraphenylboron, which does not inhibit H⁺ uptake, reduces anthroyl stearate fluorescence.

Thus, anthroyl stearate appears to be a useful probe of a proton gradient supported by phenazine methosulfate or Diquat catalyzed electron flow and is the first “non-amine” fluorescence probe utilized for this purpose in chloroplasts.     

Bongkrekic acid sensitivity of respiration-deficient mutants and of petite-negative species of yeasts

1. Growth on glucose of cytoplasmic respiration-deficient (ρ⁻) mutants isolated from five strains of Saccharomyces cerevisiae and one strain of Saccharomyces carlsbergensis were arrested by the inhibitor of mitochondrial adenine nucleotide translocation, bongkrekic acid. This indicates that the mitochondrial adenine nucleotide translocation system is preserved and necessary for growth in a number of independent ρ⁻ mutants.

2. Growth of three “petite-negative” yeast species was arrested by a combined inhibition of respiration by antimycin A and of adenine nucleotide translocation by bongkrekic acid. Thus, the arrest of growth upon inhibition of adenine nucleotide translocation in non-respiring cells is not specific for ρ⁻ mutants and may be a general characteristic of eucaryotic cells.