Gas-filled phospholipid nanoparticles conjugated with gadolinium play a role as a potential theragnostics for MR-guided HIFU ablation

To develop a long-circulating theragnostics, meaning therapeutics and diagnostics for MR-guided HIFU ablation, we designed and prepared Gd-C₅F₁₂-phospholipid nanobubbles (PLNs) 30–100 nm in diameter. The biochemical and physical characterization of Gd-C₅F₁₂-PLNs were performed. Since Gd-C₅F₁₂-PLN-50 (Φ = 50 nm) and Gd-C₅F₁₂-PLN-100 (Φ = 100 nm) enhanced the hyperthermal effect of HIFU size- and concentration-dependently in a tissue-mimicking phantom, its circulation, distribution, tumor accumulation and tumor ablation were examined in tumor-bearing mice. The plasma-half life of Gd-C₅F₁₂-PLNs was longer than 1.5 hrs. Gd-C₅F₁₂-PLNs mainly accumulated in the liver and the spleen, suggesting that they are slowly secreted through the hepatobiliary pathway. Monitored by the T1 signal intensity of MR, Gd-C₅F₁₂-PLNs accumulated in tumor tissues for 8 hours in mice. HIFU with Gd-C₅F₁₂-PLN-100 showed the increased tumor ablation area as compared with HIFU alone. The results suggest that Gd-C₅F₁₂-PLNs exhibit a potential theragnostics for MR-guided HIFU ablation.     

The Influence of Phosphate Uptake on Cation Uptake in Fusarium oxysporum f. sp. vasinfectum

Fusarium oxysporum grown in a low phosphate medium was found to take up several times as much K from KH₂PO₄ as from KCI solutions. Large amounts of phosphate also were taken up from KH₂PO₄. Similar large uptakes of Na and phosphate took place from solutions of NaH₂PO₄. Substantial quanties of phosphate were taken up from solutions of Ca(H₂PO₄)₂ in the absence of any appreciable Ca uptake. When the fungus was grown in a medium containing high phosphate, little or no uptake of phosphate from KH₂PO₄ solutions occured and the K Uptake was at the same level as from KCI solutions. During large phosphate uptake sizable reductions in the organic acid content of the fungal cells were observed. Much, but not all, of the data could be explained on the basis of maintenance of charge balance within the cells. – The respiratory rate of fungus, grown in a low P medium, was markedly increased in KH₂PO₄ solution. Fungus, grown in a medium with high phosphate, had a higher respiratory rate which showed only a slight response to KH₂PO₄ solution. Fungus, grown in a medium with high phosphate, had a higher respiratory rate which showed only a slight response to KH₂PO₄.     

Modulation of epithelial cell proliferation in culture by dissolved oxygen

Modulation of epithelial cell proliferation by the dissolved oxygen concentration (P_O2) of the growth medium was assessed with primary human foreskin epithelium and a continuous monkey kidney epithelial cell line (LLC-MK₂). Direct measurement of the growth medium P_O2 provides the first quantitative evaluation of epithelial cell proliferation as a function of P_O2 provides the first quantitative evaluation of epithelial cell proliferation as a function of P_O2. Sustained proliferation of LLC-MK₂ cells occurs in serum-free medium equilibrated with a gas phase containing 18% or 30% O₂ v/v. Mid-logarithmic phase cultures rapidly consume dissolved oxygen; this results in a 60–70 mm Hg decline in P_O2 and leads to a stable growth medium P_O2 between 70 and 100 mm Hg, well above anoxic values. In contrast, if culture medium is equilibrated with a gas phase containing 0% or 1% O₂ v/v to yield a growth medium P_O2 ～ 20–40 mm Hg, proliferation of LLC-MK₂ and primary foreskin epithelial cells is retarded, and LLC-MK₂ cells use little dissolved oxygen. Gentle, continuous rocking to prevent diffusion gradient formation enhances proliferation slightly at the higher P_O2, but neither periodic fluid renewals nor continued rocking stimulates cells retarded by a lowered oxygen concentration to resume proliferation. The data collectively demonstrate that epithelial cell proliferation requires a P_O2 > 40 mm Hg, and threshold requirements are probably closer to 70 mm Hg. Glycolysis continues at a P_O2 insufficient for proliferation, but more lactic acid accumulates in actively proliferating cultures than in cultures equilibrated with 0% oxygen. We conclude that epithelial cells in vitro both consume more oxygen and require a higher P_O2 for continued proliferation, and that the oxygen requirement for epithelial cell proliferation exceeds that of a comparable population of fibroblasts for which low oxygen may enhance survival and proliferation.     

Effect of Altered pO(2) in the Aerial Part of Soybean on Symbiotic N(2) Fixation

Dry matter accumulation, nitrogen content and N₂ fixation rates of soybean (Glycine max [L.] Merr. cv. Wye) plants grown in chambers in which the aerial portion was exposed to a pO₂ of 5, 10, 21, or 30% and a pCO₂ of 300 μl CO₂/l or a pO₂ of 21% and a pCO₂ of 1200 μl CO₂/l during the complete growth cycle were measured. Total N₂[C₂H₂] fixed was increased by CO₂/O₂ ratios greater than those in air and was decreased by ratios smaller than those in air; the effects on N₂ fixation of decreased pO₂ or elevated pCO₂ were quantitatively similar during the period of vegetative growth. Decreased pO₂ produced a smaller increase then elevated pCO₂ during the reproductive period, presumably because of the decreased sink activity of the arrested reproductive growth under subambient pO₂. At a pO₂ of 5% and a pCO₂ of 300 μl CO₂/l total N₂ fixed was increased 125% and per cent nitrogen content in the vegetative parts was increased relative to air while that in the seed was decreased. Dry matter production was increased and reproductive growth was arrested as previously reported for plants receiving only fertilizer nitrogen. At a pO₂ of 30% and a pCO₂ of 300 μl CO₂/l total N₂ fixed was decreased 50% and per cent nitrogen content in the vegetative part was increased relative to air while that in the reproductive structures was unaffected. Dry matter production was similarly decreased in both vegetative and reproductive structures. These effects of altered pO₂ in the aerial part on N₂ fixation are consistent with the hypothesis that the amount of photosynthate available to the nodule may be the most significant primary factor limiting N₂ fixation while sink activity of the reproductive structures may be a secondary factor.     

A new chromosomal sex-determining mechanism inMicrotus arvalis pallas

The karyotype in the rodentMicrotus arvalis comprises 21 autosome pairs and two heterosome pairs of the X₁X₂Y₁Y₂/X₁X₁X₂X₂ type. The occurrence of multiple sex chromosomes is thought to be due to a translocation of one arm of a metacentric autosome to the Y chromosome. This translocation would result in an additional acrocentric sex chromosome confined to the(heterogametic) male line, i.e., a Y₂. The original metacentric chromosome thereby turns into an X₂. Because of the translocation mentioned, a trivalent figure of the Y₁Y₂X₂ type occurs in the first meiotic metaphase in the male.     

Increased CaVβ1a expression with aging contributes to skeletal muscle weakness

Ca²⁺ release from the sarcoplasmic reticulum (SR) into the cytosol is a crucial part of excitation–contraction (E‐C) coupling. Excitation–contraction uncoupling, a deficit in Ca²⁺ release from the SR, is thought to be responsible for at least some of the loss in specific force observed in aging skeletal muscle. Excitation–contraction uncoupling may be caused by alterations in expression of the voltage‐dependent calcium channel α_1s (Ca_V1.1) and β_1a (Ca_Vβ_1a) subunits, both of which are necessary for E‐C coupling to occur. While previous studies have found Ca_V1.1 expression declines in old rodents, Ca_Vβ_1a expression has not been previously examined in aging models. Western blot analysis shows a substantial increase of Ca_Vβ_1a expression over the full lifespan of Friend Virus B (FVB) mice. To examine the specific effects of Ca_Vβ_1a overexpression, a Ca_Vβ_1a‐YFP plasmid was electroporated in vivo into young animals. The resulting increase in expression of Ca_Vβ_1a corresponded to decline of Ca_V1.1 over the same time period. YFP fluorescence, used as a measure of Ca_Vβ_1a‐YFP expression in individual fibers, also showed an inverse relationship with charge movement, measured using the whole‐cell patch‐clamp technique. Specific force was significantly reduced in young Ca_Vβ_1a‐YFP electroporated muscle fibers compared with sham‐electroporated, age‐matched controls. siRNA interference of Ca_Vβ_1a in young muscles reduced charge movement, while charge movement in old was restored to young control levels. These studies imply Ca_Vβ_1a serves as both a positive and negative regulator Ca_V1.1 expression, and that endogenous overexpression of Ca_Vβ_1a during old age may play a role in the loss of specific force.     

Sodium and Proton Effects on Inward Proton Transport through Na/K Pumps

The Na/K pump hydrolyzes ATP to export three intracellular Na (Na_i) as it imports two extracellular K (K_o) across animal plasma membranes. Within the protein, two ion-binding sites (sites I and II) can reciprocally bind Na or K, but a third site (site III) exclusively binds Na in a voltage-dependent fashion. In the absence of Na_o and K_o, the pump passively imports protons, generating an inward current (I_H). To elucidate the mechanisms of I_H, we used voltage-clamp techniques to investigate the [H]_o, [Na]_o, and voltage dependence of I_H in Na/K pumps from ventricular myocytes and in ouabain-resistant pumps expressed in Xenopus oocytes. Lowering pH_o revealed that H_o both activates I_H (in a voltage-dependent manner) and inhibits it (in a voltage-independent manner) by binding to different sites. Na_o effects depend on pH_o; at pH_o where no H_o inhibition is observed, Na_o inhibits I_H at all concentrations, but when applied at pH_o that inhibits pump-mediated current, low [Na]_o activates I_H and high [Na]_o inhibits it. Our results demonstrate that I_H is a property inherent to Na/K pumps, not linked to the oocyte expression environment, explains differences in the characteristics of I_H previously reported in the literature, and supports a model in which 1), protons leak through site III; 2), binding of two Na or two protons to sites I and II inhibits proton transport; and 3), pumps with mixed Na/proton occupancy of sites I and II remain permeable to protons.     

A critical appraisal of a combined stomatal-photosynthesis model for C3 plants

Gas-exchange measurements on Eucalyptus grandis leaves and data extracted from the literature were used to test a semi-empirical model of stomatal conductance for CO₂ g_Sc=g_o+a₁A/(c_s-I) (1+D_s/D_o)] where A is the assimilation rate; D_s and c_s are the humidity deficit and the CO₂ concentration at the leaf surface, respectively; g₀ is the conductance as A → 0 when leaf irradiance → 0; and D₀ and a₁ are empirical coefficients. This model is a modified version of g_sc=a₁A h_s/c_s first proposed by Ball, Woodrow & Berry (1987, in Progress in Photosynthesis Research, Martinus Mijhoff, Publ., pp. 221–224), in which h_s is relative humidity. Inclusion of the CO₂ compensation point, τ, improved the behaviour of the model at low values of c_s, while a hyperbolic function of D_s for humidity response correctly accounted for the observed hyperbolic and linear variation of g_sc and c_i/c_s as a function of D_s, where C_i is the intercellular CO₂ concentration. In contrast, use of relative humidity as the humidity variable led to predictions of a linear decrease in g_sc and a hyperbolic variation in c_i/c_s as a function of D_s, contrary to data from E. grandis leaves. The revised model also successfully described the response of stomata to variations in A, D_s and c_s for published responses of the leaves of several other species. Coupling of the revised stomatal model with a biochemical model for photosynthesis of C₃ plants synthesizes many of the observed responses of leaves to light, humidity deficit, leaf temperature and CO₂ concentration. Best results are obtained for well-watered plants.     

Pulmonary microcirculatory responses to leukotrienes B4, C4 and D4 in sheep

The pulmonary microvascular responses to leukotrienes B₄, C₄ and D₄ (total dosage of 4 μg/kg i.v.) were examined in acutely-prepared halothane anesthetized and awake sheep prepared with lung lymp fistulas. In anesthetized as well as unanesthetized sheep, LTB₄ caused a marked and transient decrease in the circulating leukocyte count. Pulmonary transvascular protein clearance (pulmonary lymph flow x lymph-to-plasma protein concentration ratio) increased transiently in awake sheep, suggesting a small increase in pulmonary vascular permeability. The mean pulmonary artery pressure (P ) also increased. In the acutely-prepared sheep, the LTB₄-induced pulmonary hemodynamic and lymph flow responses were damped. Leukotriene C₄ increased P to a greater extent in awake sheep than in anesthetized sheep, but did not significantly affect the pulmonary lymph flow rate (Q̇_lym) and lmph-to-plasma protein concentration (L/P) ration in either group. LTD₄ increased P and Q̇_lymp in both acute and awake sheep; Q̇_lym increased without a significant change in the L/P ratio. The LTD₄-induced rise in P occurred in association with an increase in plasma thromboxane B₂ (Txb₂) cocentration. The relativity small increase in Q̇_lym with LTD₄ suggests that the increase in the transvascular fluid filtration rate is the result of a rise in the pulmonary capillary hydrostatic pressure. In conclusion, LTB₄ induces a marked neutropenia, pulmonary hypertension, and may transiently increase lung vascular permeability. Both LTC₄ and LTD₄ cause a similar degree of pulmonary hypertension in awake sheep, but had different lymph flow responses which may be due to pulmonary vasoconstriction at different sites, i.e. greather pre-capillary constriction with LTC₄ because Q̇_lym did not change and greater post-capillary constriction with LTD₄ because Q̇ increased with the same rise in P .     

Affinity Purification and Structural Features of the Yeast Vacuolar ATPase Vo Membrane Sector

The membrane sector (V_o) of the proton pumping vacuolar ATPase (V-ATPase, V₁V_o-ATPase) from Saccharomyces cerevisiae was purified to homogeneity, and its structure was characterized by EM of single molecules and two-dimensional crystals. Projection images of negatively stained V_o two-dimensional crystals showed a ring-like structure with a large asymmetric mass at the periphery of the ring. A cryo-EM reconstruction of V_o from single-particle images showed subunits a and d in close contact on the cytoplasmic side of the proton channel. A comparison of three-dimensional reconstructions of free V_o and V_o as part of holo V₁V_o revealed that the cytoplasmic N-terminal domain of subunit a (a_NT) must undergo a large conformational change upon enzyme disassembly or (re)assembly from V_o, V₁, and subunit C. Isothermal titration calorimetry using recombinant subunit d and a_NT revealed that the two proteins bind each other with a K_d of ∼5 μm. Treatment of the purified V_o sector with 1-palmitoyl-2-hydroxy-sn-glycero-3-[phospho-rac-(1-glycerol)] resulted in selective release of subunit d, allowing purification of a V_oΔd complex. Passive proton translocation assays revealed that both V_o and V_oΔd are impermeable to protons. We speculate that the structural change in subunit a upon release of V₁ from V_o during reversible enzyme dissociation plays a role in blocking passive proton translocation across free V_o and that the interaction between a_NT and d seen in free V_o functions to stabilize the V_o sector for efficient reassembly of V₁V_o.     

Acclimation of photosynthesis to increasing atmospheric CO2: The gas exchange perspective

The nature of photosynthetic acclimation to elevated CO₂ is evaluated from the results of over 40 studies focusing on the effect of long-term CO₂ enrichment on the short-term response of photosynthesis to intercellular CO₂ (the A/C_i response). The effect of CO₂ enrichment on the A/C_i response was dependent on growth conditions, with plants grown in small pots (< 5 L) or low nutrients usually exhibiting a reduction of A at a given C_i, while plants grown without nutrient deficiency in large pots or in the field tended to exhibit either little reduction or an enhancement of A at a given C_i following a doubling or tripling of atmospheric CO₂ during growth. Using theoretical interpretations of A/C_i curves to assess acclimation, it was found that when pot size or nutrient deficiency was not a factor, changes in the shape of A/C_i curves which are indicative of a reallocation of resources within the photosynthetic apparatus typically were not observed. Long-term CO₂ enrichment usually had little effect or increased the value of A at all C_i. However, a minority of species grown at elevated CO₂ exhibited gas exchange responses indicative of a reduced amount of Rubisco and an enhanced capacity to metabolize photosynthetic products. This type of response was considered beneficial because it enhanced both photosynthetic capacity at high CO₂ and reduced resource investment in excessive Rubisco capacity. The ratio of intercellular to ambient CO₂ (the C_i/C_a ratio) was used to evaluate stomatal acclimation. Except under water and humidity stress, C_i/C_a exhibited no consistent change in a variety of C₃ species, indicating no stomatal acclimation. Under drought or humidity stress, C_i/C_a declined in high-CO₂ grown plants, indicating stomata will become more conservative during stress episodes in future high CO₂ environments.Abbreviations A net CO₂ assimilation rate - C_i (C_a) intercellular (ambient) partial pressure of CO₂ - operational C_i intercellular partial pressure of CO₂ at a given ambient partial pressure of CO₂ - g_s stomatal conductance - normal CO₂ current atmospheric mole fraction of CO₂ (330 to 355 mol mol^–1) - Rubisco ribulose-1,5-bisphosphate carboxylase/oxygenase     

LCI1, a Chlamydomonas reinhardtii plasma membrane protein,functions in active CO2 uptake under low CO2

In response to high CO₂ environmental variability, green algae, such as Chlamydomonas reinhardtii, have evolved multiple physiological states dictated by external CO₂ concentration. Genetic and physiological studies demonstrated that at least three CO₂ physiological states, a high CO₂ (0.5–5% CO₂), a low CO₂ (0.03–0.4% CO₂) and a very low CO₂ (< 0.02% CO₂) state, exist in Chlamydomonas. To acclimate in the low and very low CO₂ states, Chlamydomonas induces a sophisticated strategy known as a CO₂‐concentrating mechanism (CCM) that enables proliferation and survival in these unfavorable CO₂ environments. Active uptake of C_i from the environment is a fundamental aspect in the Chlamydomonas CCM, and consists of CO₂ and HCO₃^– uptake systems that play distinct roles in low and very low CO₂ acclimation states. LCI1, a putative plasma membrane C_i transporter, has been linked through conditional overexpression to active C_i uptake. However, both the role of LCI1 in various CO₂ acclimation states and the species of C_i, HCO₃^– or CO₂, that LCI1 transports remain obscure. Here we report the impact of an LCI1 loss‐of‐function mutant on growth and photosynthesis in different genetic backgrounds at multiple pH values. These studies show that LCI1 appears to be associated with active CO₂ uptake in low CO₂, especially above air‐level CO₂, and that any LCI1 role in very low CO₂ is minimal.     

H2-CO2-Dependent Anaerobic O-Demethylation Activity in Subsurface Sediments and by an Isolated Bacterium

The ability of microorganisms in sediments from the Atlantic Coastal Plain to biodegrade methoxylated aromatic compounds was examined. O-demethylation activity was detected in deep (121- and 406-m) sediments, as well as in the surface soil. A syringate-demethylating consortium, containing at least three types of bacteria, was enriched from a deep-sediment sample in a medium containing syringate as the sole organic carbon source and with a N₂-CO₂ atmosphere. An isolate which demethylated syringate was obtained from the enrichment on an agar medium incubated under a H₂-CO₂ but not a N₂-CO₂ or N₂ atmosphere. O demethylation of syringate of this isolate was dependent on the presence of both H₂ and CO₂ in the gas phase. The metabolism of syringate occurred in a sequential manner: methylgallate accumulated transiently before it was converted to gallate. Mass balance analysis suggests that the stoichiometry of the reaction in this isolate proceeds in accordance with the following generalized equation: C₇H₃O₃(OCH₃)_n^- + nHCO₃^- + nH₂ → C₇H₃O₃(OH)_n^- + nCH₃COO^- + nH₂O.     

Role of intracellular sodium activity in the control of contraction in cardiac purkinje fibers

The role of intracellular sodium activity (a _Na ⁱ ) in the control of force was studied in sheep cardiac Purkinje fibers exposed to norepinephrine (NE) and high [Ca]_o in the absence and presence of overdrive or of a low concentration of strophanthidin. Both NE and high [Ca]_o decrease a _Na ⁱ and increase force, while overdrive increases and low strophanthidin decreases both parameters. In the presence of NE, overdrive increases a _Na ⁱ less than force and is followed by a more pronounced undershoot in a _Na ⁱ and force. In contrast, in high [Ca]_o overdrive increases a _Na ⁱ more than force and is followed by a less pronounced undershoot in a _Na ⁱ and force than in NE. High [Ca]_o increases force to a peak, but then the decreasing a _Na ⁱ reduces force. In all these conditions, a _Na ⁱ determines force changes during recovery from overdrive. NE and high [Ca]_o decrease a _Na ⁱ less and increase force more in low strophanthidin. Thus, changes in a _Na ⁱ modulate the increase in force due to increased Ca influx and control force development when Ca influx is either unchanged (low strophanthidin) or has reached a steady state (high [Ca]_o, recovery from overdrive).     

Arbuscular mycorrhizas alter root system architecture of Citrus tangerine through regulating metabolism of endogenous polyamines

Cadmium (Cd) is readily taken up by the roots of rice seedlings, leading to growth reduction. H₂O₂ is a constituent of oxidative metabolism and is itself a reactive oxygen species. In this study, the participation of H₂O₂ in CdCl₂-inhibited growth of rice roots was investigated. CdCl₂ treatment increased H₂O₂ production in rice roots. CdCl₂ treatment had no effect on the activities of superoxide dismutase, ascorbate peroxidase, and glutathione reductase, but inhibited the activity of catalase (CAT) in rice roots. CdCl₂-inhibited root growth and -increased H₂O₂ content were lessened in the presence of diphenyleneiodonium chloride, an inhibitor of H₂O₂ generating NADPH oxidase. However, this stimulation of root growth in CdCl₂-treated seedlings is small (about 5%). Calcium (Ca) is important in many physiological processes in plants. Attempts were also made to determine whether the action of Ca on CdCl₂-inhibited growth of rice roots is associated with H₂O₂. CaCl₂ application reduced the production of H₂O₂, the decrease in CAT activity, and the inhibition of root growth caused by CdCl₂. The effects of CaCl₂ application could be reversed by exogenous H₂O₂. Our results indicate that the Cd causes a decline in CAT and to a lower extent a stimulation of NADPH oxidase in rice roots, with the subsequent generation of H₂O₂, an agent responsible for growth inhibition.     

Evolutionary implications of C3–C4 intermediates in the grass Alloteropsis semialata

C₄ photosynthesis is a complex trait resulting from a series of anatomical and biochemical modifications to the ancestral C₃ pathway. It is thought to evolve in a stepwise manner, creating intermediates with different combinations of C₄‐like components. Determining the adaptive value of these components is key to understanding how C₄ photosynthesis can gradually assemble through natural selection. Here, we decompose the photosynthetic phenotypes of numerous individuals of the grass Alloteropsis semialata, the only species known to include both C₃ and C₄ genotypes. Analyses of δ¹³C, physiology and leaf anatomy demonstrate for the first time the existence of physiological C₃–C₄ intermediate individuals in the species. Based on previous phylogenetic analyses, the C₃–C₄ individuals are not hybrids between the C₃ and C₄ genotypes analysed, but instead belong to a distinct genetic lineage, and might have given rise to C₄ descendants. C₃ A. semialata, present in colder climates, likely represents a reversal from a C₃–C₄ intermediate state, indicating that, unlike C₄ photosynthesis, evolution of the C₃–C₄ phenotype is not irreversible.     

Phytochrome behaves as a dimer in vivo

Abstract It is well established that phytochrome exists as a dimer in vitro. A comparison of the relative photoequilibrium concentrations of P_rP_r, P_rP_fr and P_frP_fr, with the relative sizes of the P_fr-pools which undergo dark reversion in the intact plant, leads to the hypothesis that phytochrome also exists as a dimer in vivo, This hypothesis is in accordance with kinetic properties of the phytochrome system under continuous irradiation. Additional support for this view is provided by the observation that P_fr-destruction after a red light flash, which should favour the formation of P_rP_fr dimers, is paralleled by a decay of P_r, even if the presence of P_r cycled through P_fr can be excluded. Preliminary observations could indicate an interaction of the subunits of a phytochrome dimer during the process of phototransformation.     

Synthesis and characterisation of a trinuclear uranyl complex: Crystal structure of (CN3H6)5[(UO2)3O(OH)2(CH3COO)(C2O4)3]

The reaction of uranyl oxalate trihydrate with guanidinium acetate at room temperature in water yields known uranyl complex with composition (CN₃H₆)₂[UO₂(C₂O₄)₂(H₂O)]·H₂O as a first phase and a novel complex (CN₃H₆)₅[(UO₂)₃O(OH)₂(CH₃COO)(C₂O₄)₃] as a second. The second phase was investigated by means of IR spectroscopy and X-ray diffraction. The trinuclear discrete complex contains two symmetrically independent uranyl ions with a pentagonal bipyramid structure and has a nonplanar geometry. The distortion of its equatorial plane is caused by substitution of a monodentate bridge hydroxide anion by a bidentate bridge acetate-anion. The acidic ligands found in the complex are usually in competition for a place in coordination sphere of an uranyl ion, thus peculiarities of the complex formation are discussed in terms of ‘crystallochemical analysis’.     

Stomatal response to blue light: water use efficiency in sugarcane and soybean*

Abstract. The significance of blue light-stimulated stomatal conductance for carbon assimilation (A), stomatal conductance (g), intercellular CO₂ (C_i), stomatal limitation of A (L), transpiration (E) and water use efficiency (W = A/E), was determined in a C₄ and a C₃ species. W and L were evaluated for steady-state gas exchange with constant, saturating red light (A_s, g_s, E_s), and for the integrated gas exchange above the steady state baseline induced by a single, brief pulse of blue light (A_p, g_p, E_p). Sugarcane (Saccharum spp. hybrid), a C₄ grass, and soybean (Glycine max) a C₃ dicot, were compared. Sugarcane exhibited typical C₄ behaviour, with A saturing at C_i of ca. 200 μmol mol^?1, compared to >500 μmol mol^?1 in soybean. Steady-state W was also considerably higher in sugarcane. The extent of stomatal opening in response to a blue light pulse, from baseline (g_s) to the maximum value of conductance during the opening response (g_m), was similar in the two species. More rapid opening and closing of stomata in sugarcane resulted in a smaller integrated magnitude of the conductance response (g_p) than in soybean. At the peak of the blue light response, both species exhibited similar levels of L. During the response to the pulse of blue light, A and C_i increased and L decreased to a greater extent in sugarcane than in soybean. As a result, the gas exchange attributed to the stomatal response to blue light exhibited a higher ratio of A_p to E_p (W_p) in sugarcane than in soybean. This W_p was lower in both species than was the W_s associated with the steady state gas exchange. The two species did not differ in the rate of induction of photosynthetic utilization of elevated C_i. The greater stimulation of A in sugarcane was attributed to its C₄ attributes of greater carboxylation efficiency (slope of the A versus C_i relationship), lower g_s and prevailing C_i,s, and greater L_s under steady-state red illumination. Despite saturation of A at low levels of C_i in C₄ species, the gas exchange attributed to the stomatal response to blue light decreased L and contributed considerably to carbon acquisition, while maintaining the high level of W associated with C₄ metabolism.     

采伐对小兴安岭落叶松-泥炭藓沼泽温室气体排放的影响

利用静态箱-气相色谱法,研究了择伐和皆伐对小兴安岭落叶松-泥炭藓沼泽CH4、CO2、N2O排放的影响.结果表明:采伐改变了落叶松-泥炭藓沼泽CH4和N2O的季节排放规律,其中对照样地的CH4为夏季吸收、秋季排放,N2O夏秋季吸收;择伐样地的CH4和N2O在夏季集中排放;皆伐样地的CH4在夏秋季排放,N2O则在夏季吸收、秋季排放.但采伐对CO2季节排放规律的影响,均为夏季春季秋季.采伐改变了CH4、CO2和N2O的源汇功能,对照样地为CO2的排放源、CH4和N2O的弱吸收汇;采伐地的CO2排放量下降了1/4,并转化为N2O弱排放源,为CH4的弱排放源或强排放源.择伐样地温室效应贡献潜力较对照样地下降了24.5%,皆伐地则提高了3.2%.