Inheritance of C3―C4 Intermediate Photosynthesis in Reciprocal Hybrids Between Moricandia Arvensis (C3―C4) and Brassica Oleracea (C3) That Differ in Their Genome Constitution

Abstract

To Elucidate The Genetic Mechanisms Underlying C₃―C₄ intermediate Photosynthesis, We investigated The Structural and Photosynthetic Characteristics of Leaves of Reciprocal Hybrids Between The C₃―C₄ intermediate Species Moricandia Arvensis (L.) Dc. (Mama) and The C₃ Species Brassica Oleracea L. (Cabbage; Cc), Which Differ in Genome Constitution. Moricandia Arvensis Bundle Sheath (Bs) Cells included Many Centripetally Located Chloroplasts and Mitochondria, Whereas Those of Cabbage Had Few Organelles. Hybrid Leaves Were Structurally intermediate Between Those of The Parents and Showed Stronger intermediate C₃―C₄ Features As The Proportion of The Ma Genome increased. The P-Protein of Glycine Decarboxylase (Gdc) Was Confined Mainly To Bs Mitochondria in M. Arvensis, But Accumulated More in The Mesophyll (M) of Cabbage. in The Hybrids, The Accumulation of Gdc in Bs Cells increased With An increasing Ma:C Ratio. Hybrids Exhibited Gradients in Structural and Biochemical Features, Even in Reciprocal Crosses. The Co₂ Compensation Point of Reciprocal Hybrids With High Ma:C Ratios Was Lower Than That of Cabbage But Higher Than That of M. Arvensis. Thus, The Structural and Biochemical Features in Hybrid Leaves Reduced Photorespiration. Moricandia Arvensis Had A Higher Photosynthetic Rate Than Cabbage, But The Photosynthetic Rates of Hybrids Were intermediate Between Those of The Parents Or Comparable To That of M. Arvensis. Our Results Demonstrate That The C₃―C₄ intermediate Characteristics Are inherited Based On The Ratio of The Parent Genomes, and That There Is No Evidence of Cytoplasmic inheritance in These Characteristics.     

Production of Raphanus sativus (C3)-Moricandia arvensis (C3-C4 intermediate) Monosomic and Disomic Addition Lines with Each Parentl Cytoplasmic Background and their Photorespiratory Characteristics

Abstract

We are maintaining five Moricandia arvensis monosomic addition lines of Raphanus sativus carrying R. sativus cytoplasm (autoplasmic MALs) and twelve M. arvensis MALs of R. sativus carrying M. arvensis cytoplasm (alloplasmic MALs) from BC₆ to BC₈ generation, and newly produced five M. arvensis disomic addition lines of R. sativus (autoplasmic DALs) and seven M. arvensis DALs of R. sativus carrying M. arvensis cytoplasm (alloplasmic DALs) from selfing and sib-crossing of the MALs and DALs in S₃BC₅ and S₂BC₆ generations. The structural, biochemical and physiological characteristics related to photorespiration of these MALs and DALs were compared to study the genetic mechanisms of the C₃-C₄ intermediate photosynthesis in the individual chromosomes of M. arvensis. The CO₂ compensation point of the autoplasmic and alloplasmic DALs (RMa-b and MaR-b DALs) with one pair of M. arvensis ‘b’ chromosome were 29.4 and 30.1 μmol mol-¹, respectively, which were significantly lower than that of other DALs and MALs as well as R. sativus (34.5 𰂼mol mol-¹). An immunogold electron microscopic study of the P-protein of glycine decarboxylase (GDC) in photosynthetic cells of the RMa-b DAL revealed that the bundle sheath cell (BSC) mitochondria were more intensively labeled for the protein than the mesophyll cell (MC) mitochondria. The ratio of the labeling density of the BSC mitochondria to that of the MC mitochondria was 1.13, which lies between values in M. arvensis (2.66) and R. sativus (0.76). These data suggest that the ‘b’ chromosome of M. arvensis genome controls the expression of C₃-C₄ intermediate characteristics.     

Evaluation of the Effect of Photosynthesis on Biomass Production with Simultaneous Analysis of Growth and Continuous Monitoring of CO2 Exchange in the Whole Plants of Radish,cv Kosena under Ambient and Elevated CO2

Abstract

The effects of elevated CO₂ (approximate doubling of atmospheric CO₂ concentration) on the rate of photosynthesis estimated from continuous monitoring of CO₂ exchange in whole plants were investigated in radish cv. Kosena accompanied with simultaneous analysis of growth for 6 days from 15 to 21 days after planting (DAP). The elevated CO₂ increased the dry weights of hydroponically grown radish plants by 59% at 21 DAP.

The increase in dry weight was due to a combined effect of increased leaf area and increased photosynthetic rate per unit leaf area. Leaf area and the photosynthetic rate were increased by elevated CO₂ by 18-43% and 9-20%, respectively, during 15 to 21 DAP. Namely, an increase in the rate of photosynthesis is accompanied by an increase in leaf area, both having a significant effect on biomass production.     

Ultrastructure of Fusion Product between Protoplasts from C3 and C4 Species of Amaranthaceae

Summary

This paper describes the ultrastructure of the electric field-induced fusion products of C₃ and C₄ species of Amaranthaceae at the early developmental stage. Protoplasts of C₃ species were isolated from a Ceiosia cristata L. cell suspension and, those of C₄ species were isolated from an Amaranthus tricolor L. cotyledon. Incompatibility occurred in the C₃/C₄ hybrid. The incompatibility reactions were detected in the newly formed hybrid cells accompanied with significant changes in the nucleolus (segregation of nucleolar components) and plastids (cup-like shape or amoeboid plastid enclosing cytoplasmic materials) of C₃ species parent. The structural changes in the organelles of the C₄ partner were less marked. After 5 days of culture, most organelles showed high cellular activity, and a normal dedifferentiation process of mesophyll chloroplasts was observed. At this stage nucleolar segregation was not detected and the C₃ species plastids were difficult to distinguish from the proplastids formed from mesophyll chloroplasts. In addition, some mitochondria showed bursting-like structure. However, under the culture condition used these somatic incompatibility did not seem to impair further growth of fusion products since they were still proliferating well resulting in callus formation.     

Ultrastructure of Hybrid Callus between C3 and C4 Species of Amaranthaceae

Summary

Unlike the parent line, the hybrid calli between C₃ and C₄ species of Amaranthaceae have poor division capability. Therefore, in this study the fine structures of hybrid callus derived from protoplasts of Celosia cristata L. cv. Pink Charm (C₃ species) cell suspension and Amaranthus tricolor L. cv. Perfecta (C₄ species) cotyledon callus were investigated by light and electron microscopy, and compared with the parental. All callus lines were composed of parenchymatous cells possessing a voluminous vacuole. Parental callus lines contained organelles with a relatively normal structure. The peculiar feature characterizing the C₃/C₄ hybrid callus was the presence of highly lobed nucleus with multinucleoli and numerous small vacuoles having autophagic activity scattered in the cytoplasm. The autophagic activity is apparently related to the existence of several inclusions such as cytoplasmic organelles in the central vacuole. It might also be related to the pronounced expansion of central vacuole and the reduced cytoplasm. The failure to sustain proliferation related to some atypical features of the organelles is discussed.     

小麦光呼吸途径电子流分配的模型研究

为探讨分配到植物光呼吸的光合电子流(J_o)对CO_2浓度(J_o-C_a曲线)的响应规律,以小麦Z39-118为材料,分析了小麦叶片在2%和21%O_2浓度下的光合速率(A_c)和电子传递速率(J)对CO_2浓度的响应曲线。结果表明,光合作用对CO_2浓度的响应新模型(模型I)可很好地拟合小麦的A_c对CO_2浓度响应曲线;同样,基于模型I而构建的J对CO_2的响应模型(模型II),也可很好地拟合小麦在21%和2%O_2条件下的J对CO_2响应曲线。利用模型II分别拟合基于传统公式(J_o=2[J-4(A_c+R_(day))]/3)得到的J_o-C_a曲线(R_(day)为日呼吸速率)及基于光呼吸速率值而计算得到的J_o-C_a曲线,结果显示,两者拟合得到的分配到光呼吸的最大电子传递速率值(分别为86.93和84.17μmol·m~(-2)·s~(-1))与实测值(89.12μmol·m~(-2)·s~(-1))均较为接近(P0.05);但基于前者拟合所得到的饱和CO_2浓度和CO_2为0μmol·mol~(-1)时分配到光呼吸的电子传递速率,均与其对应的测量值之间均存在显著差异(P0.05)。综合分析认为,传统用于计算参与光呼吸途径的光合电子流公式并不能准确地描述J_o对CO_2浓度的响应趋势,本研究构建的新模型可准确地定量研究光呼吸及其电子流分配等问题。     

玉米C4光合叶不同部位“花环”结构及叶绿素含量的变化

以玉米进行C4光合的全展第5位叶片为材料,分析从叶基部到顶部的解剖结构和叶绿素含量变化,研究玉米C4光合叶片\"花环\"结构随叶片发育的变化规律。结果表明,玉米第5位叶从基部到顶部都具有完整的典型\"花环\"结构,维管束鞘细胞(BSC)和叶肉细胞(MC)的体积在叶片发育过程中具有渐变性,从叶基部到顶部BSC和MC均呈先增大后变小的趋势,而且叶绿素a、b和a+b含量呈相同的变化趋势,说明BSC和MC细胞体积与叶绿素含量的变化具有相关性。叶绿素a/b总体呈上升趋势,说明玉米第5叶基部到顶部的光合途径存在C3向C4转变的过程。玉米第5叶不同部位C4光合途径发育的渐变性比前3叶更为明显。     

Photosynthetic Characteristics of an Amphibious C4 Plant,Eleocharis retroflexa ssp. chaetaria

Abstract

Eleocharis retroflexa (Poir.) Urban ssp. chaetaria (Roem. & Schult.) T. Koyama, an amphibious leafless sedge, grows not only under terrestrial conditions but also under completely submerged aquatic conditions. We investigated the photosynthetic traits and structural features of the culms, which are the photosynthetic organs, in the terrestrial and submerged forms of this species and compared them with those of other amphibious species of Eleocharis which are known to change the photosynthetic modes. The culms of the terrestrial form had Kranz anatomy with well-developed Kranz (bundle sheath) cells and high levels of C₄ enzyme activity typical of the NAD-malic enzyme (NAD-ME) subtype of C₄ metabolism. They also had a δ ¹³C value typical of C₄ plants, indicating that the terrestrial form fixes carbon through the C₄ pathway. The culms of the submerged form had not only a Kranz-like anatomy but also revealed anatomical traits typical of leaves of submerged aquatic plants. The activities of the C₄ enzymes in the submerged form were lower than those in the terrestrial form, but were still in the range typical of G4 plants, ¹⁴C pulse-¹²C chase experiments with the submerged form indicated that almost all of the fixed ¹⁴C was incorporated into G4 compounds, and subsequently the raioactivity was transferred into C₃ compounds and sucrose. The submerged form showed no diurnal fluctuation in malate level. These data demonstrate that a C₄ metabolism is operative even in the submerged form. This unique amphibious C₄ plant provides an intriguing example of the physiological and ecological adaptability of C₄plants.     

Climate Change and CO2 Effects on Productivity of Danish Agricultural Systems

SUMMARY

Scenarios of climate change for Denmark suggest increases in annual mean temperature of 1 to 4°C by the end of the 21st century with an associated increase in rainfall of approximately 10%. The climatic warming and the associated increase in atmospheric CO₂ concentration will increase the productivity of agricultural crops. The increase may be slightly higher for indeterminate species, such as grass and other fodder crops, compared with cereals and other determinate species, where the duration of growth depends on temperature and daylength. The full benefits of the climatic warming requires adaptation in crop management, which at the individual crop level means changes in sowing dates, i.e., later sowings for winter cereals and earlier sowings for spring cereals. Some crop substitution will probably occur. On dairy farms more cereals will be grown due to higher productivity of the grasslands, which frees up some land for grain production. On sandy loam and loam soils spring cereals may become slightly more favorable and winter cereals slightly less favorable.     

Structural and physiological responses of the C4 grass Sorghum bicolor to nitrogen limitation

Nitrogen (N) is one of the major nutrients influencing photosynthesis and productivity of C₄ plants as well as C₃ plants. C₄ photosynthesis operates through close coordination between mesophyll (M) and bundle sheath (BS) cells. However, how the development of structural and physiological traits in leaves of C₄ plants is regulated under N limitation remains uncertain. We investigated structural and physiological responses of leaves of the NADP-ME-type C₄ grass Sorghum bicolor to N limitation. Plants were grown under four levels of N supply (.05 to .6 g N per 5-L pot). Decreasing N supply resulted in decreases in net photosynthetic rate, stomatal conductance, leaf N and chlorophyll contents, and the activity ratio of phosphoenolpyruvate carboxylase to ribulose 1,5-bisphosphate carboxylase/oxygenase and increases in δ¹³C values and photosynthetic N use efficiency. Low-N leaves were thinner and had smaller photosynthetic cells, especially in M, resulting in lower M/BS tissue area ratio, and contained smaller and fewer chloroplasts. The BS chloroplasts in the low-N leaves accumulated abundant starch grains. The number of thylakoids per granal stack was reduced in M chloroplasts but not in BS chloroplasts. The low-N leaves had thicker cell walls, especially in the BS cells, which might be associated with less negative δ¹³C values, and fewer plasmodesmata in the BS cells. These data reveal structural and physiological responses of C₄ plants to N limitation, most of which would be related to cellular N allocation, light use, CO₂ diffusion and leakiness, and metabolite transport under N limitation.     

玉米作为地质封存CO2泄漏耐受植物的评估

二氧化碳的捕获与储存(CO2capture and storage,CCS)是全球CO_2减排最重要技术战略,其存在CO_2泄漏的风险,会对周围农田生态产生重要影响。深入认识植物对高浓度CO_2的响应并筛选对CO_2的耐受植物,为CCS项目区农业生产决策提供参考数据。本文设置玉米对不同CO_2浓度的响应情形,选择株高、鲜重、干重、净光合速率、蒸腾速率、气孔导度和胞间CO_2浓度作为玉米耐受的观测指标。结果表明,当CO_2浓度为10 000、20 000μmol/mol时,玉米株高增高7%～12%,生物量增加10%～15%,净光合速率增加高达60%左右;当CO_2浓度为40 000、80 000μmol/mol时,玉米株高度减少9%～12%,生物量减少10%～17%,净光合速率减少35%～45%左右。一定程度CO_2浓度的增加,对玉米生长发育具有\"施肥\"效应;在更高CO_2浓度下,会抑制其生长发育,并未出现植株死亡的现象。通过CO_2耐受指数法(LCTI)计算得出,玉米可以作为地质封存CO_2泄漏的耐受植物。     

The Effect of Elevated Atmospheric CO2 Concentration on Two Populus Clones Grown in a FACE System

SUMMARY

Two poplar clones, hybrid Populus deltoides Bartr. Ex Marsh X Populus nigra L. (Populus xeuramericana), clone I-214, and Populus deltoides, clone Lux, were grown from hardwood cuttings for one growing season in either ambient (360 μmol mol^?1) or elevated (560 μmol mol^?1) [CO₂] in FACE-systemrings at Rapolano Terme (Siena, Italy). Both clones I-214 and Lux exhibited a higher aboveground bio-mass, photosynthesis at light saturation and instantaneous transpiration efficiency (ITE) in CO₂-enriched air. The elevated [CO₂]-induced responses of clone I-214 included increased investment in branch and leaf biomass, and enhanced stem volume. The elevated [CO₂]-induced responses of clone Lux included an increase in the number of branches (and foliage area). Indication of photosynthetic acclimation under elevated [CO₂] was found during the early morning, but only in clone I-214. Stomatal conductance decreased under elevated [CO₂] particularly in clone Lux. Clone differences in response to elevated [CO₂] should be taken in account when planning future poplar plantations in forecast warmer and drier Mediterranean sites.     

Atmospheric CO2 enrichment changes the wheat grain proteome

Spring wheat (Triticum aestivum L. cv. Triso) was grown in a free-air CO₂ enrichment (FACE) field experiment in order to gain information on CO₂-induced effects on grain composition and quality at maturity. A proteome analysis was performed using two-dimensional gel electrophoresis (2-DE) and protein identification was done with mass spectrometry (MALDI-TOF MS). In elevated CO₂ (526 μl l⁻¹), an increase of 13.5% in grain yield was observed relative to 375 μl l⁻¹ at a low level of significance (P = 0.528). Total grain protein concentration was decreased by 3.5% at a high level of statistical significance. Most importantly, a number of statistically significant changes within the grain proteome were observed, as the levels of 32 proteins were affected by elevated CO₂: 16 proteins were up-regulated and 16 were down-regulated. Our experiment demonstrates that high-CO₂ can markedly affect the proteome of mature wheat grain. The potential role of the proteins, changed in response to CO₂ enrichment, is discussed as some may affect grain quality. For the task of selecting cultivars resistant to CO₂-induced quality loss, we propose to consider the proteins affected by elevated CO₂ identified in this work here.     

小麦旗叶光呼吸对光强和CO2浓度的响应

为给C₃作物光呼吸等光合参数以及光响应模型和CO₂响应模型的研究提供参考,定量研究了小麦花期旗叶光呼吸速率对光强和CO₂浓度的响应。结果表明,在21%和2%O₂下小麦旗叶光饱和点分别为1 960.629和2 030.120 μmol·m^-2·s^-1。在较弱光强(小于800 μmol·m^-2·s^-1)下,小麦的总光呼吸速率(R_pt)与表观光呼吸(R_pa)均随着光强的升高而增大;当光强大于800 μmol·m^-2·s^-1时,R_pt和R_pa趋于稳定;整体上,不同光强下R_pt与R_pa之间差异较小(P>0.05),这主要是由于在380 μmol·mol^-1 CO₂下,光呼吸的CO₂回收利用率较低。饱和光强下,R_pa随着CO₂浓度的增加呈先上升后下降的趋势,R_pa最大值(Rpmax)所对应的外界CO₂浓度为600 μmol·mol^-1,而R_pt则随着CO₂浓度的升高而降低;在低浓度CO₂(小于380 μmol·mol^-1)条件下,R_pt与R_pa之间差异显著(P<0.05)。R_pt与羧化速率的比值(R_pt /Vc)随着胞间CO₂浓度的升高而呈下降的趋势,而不同光强下R_pt /Vc相对稳定,整体上未达到显著水平(P>0.05)。     

Effect of CO2 Concentration,Temperature and N Fertilization on Biomass Production of Soybean Genotypes Differing in N Fixation Capacity

Abstract

We tested the hypothesis that elevated CO₂ concentration [CO₂]-induced enhancement of biomass production of soybean is greater in a genotype that has a higher nitrogen (N) fixation capacity. Furthermore, we analyzed theinteractive effects of N fertilization, temperature and [CO₂] on biomass production. Three genetically related genotypes: Enrei (normally-nodulating genotype), Kanto 100 (supernodulating genotype), and En1282 (non-nodulating genotype) were grown in pots, with or without N fertilizer for two years (2004, 2005). They were then subjected to two different [CO₂] (ambient and elevated (ambient + 200 ?mol mol-¹)) × two temperature regimes (low,high (low + 4~5ºC)). Top dry weight at maturity was the greatest in the elevated [CO₂] × high temperature regime, irrespective of genotype and N fertilization. The [CO₂] elevation generally enhanced N acquisition and dry matter production during the vegetative growth stage, and the enhancement was more pronounced in the nodulating genotypes (Enrei and Kanto 100) than in the non-nodulating genotype (En1282), indicating that N supply through N fixation contributes to elevated [CO₂]-induced biomass production in soybean. However, the relative responsiveness ofbiomass production to elevated [CO₂] was not necessarily higher in the supernodulating genotype than the normally-nodulating genotype. The N utilization efficiency to produce biomass was inferior in the supernodulating genotype than in the normally-nodulating and non-nodulating genotypes. These results did not fully verify the hypothesis that elevated [CO₂]-induced enhancement of biomass production of soybean is greater in a genotype with a higher N fixation capacity.     

Effects of elevated atmospheric CO2 on grain quality of wheat

Wheat (Triticum aestivum L.) is one of the most important agricultural crops worldwide. Due to its high content of starch and unique gluten proteins, wheat grain is used for many food and non-food applications. Although grain quality is an important topic for food and feed as well as industrial processing, the consequences of future increases in atmospheric carbon dioxide (CO₂) concentrations on quality parameters such as nutritional and bread-making rheological properties are still unclear. Wheat productivity increases under CO₂ enrichment. Concomitantly, the chemical composition of vegetative plant parts is often changed and grain quality is altered. In particular, the decrease in grain protein concentration and changes in protein composition may have serious economic and health implications. Additionally, CO₂ enrichment affects amino acid composition and the concentrations of macro- and micro-elements. However, experimental results are often inconsistent. The present review summarises the results from numerous CO₂ enrichment experiments using different exposure techniques in order to quantify the potential impacts of projected atmospheric CO₂ levels on wheat grain yield and on aspects of grain composition relevant to processing and human nutrition.     

Physicochemical and antioxidant properties of extruded corn grits with corn fiber by CO2 injection extrusion process

Corn grits and corn fiber mixed at different mass ratios (0/100, 15/85 and 30/70) were extruded at different melt temperature (90, 105 and 120 °C) using extrusion with and without CO₂ injection. The L value, reducing sugar content and antioxidant properties decreased after extrusion with or without CO₂ injection. The color and antioxidant properties were relatively stable in the extrusion with CO₂ injection at higher melt temperature (120 °C) in comparison with the extrusion without CO₂ injection. Higher corn fiber content resulted in less loss of total phenolic content. The b, ΔE values and water absorption index increased after extrusion. The increase of the water absorption index was higher after the extrusion process with the CO₂ injection especially at the lower melt temperature. The addition of corn fiber decreased L, b, and ΔE values, but significantly increased antioxidant properties under the same extrusion conditions.     

Simulation of the effects of genotype and N availability on rice growth and yield response to an elevated atmospheric CO2 concentration

The objective of this study was to identify physiological processes that result in genotypic and N fertilization effects on rice yield response to elevated atmospheric CO₂ concentrations ([CO₂]). This study conducted growth and yield simulations for 9 rice genotypes grown at 4 climatically different sites in Asia, assuming the current atmospheric [CO₂] (360 ppm) and elevated [CO₂] (700 ppm) using 5 levels of N fertilizer (4, 8, 12, 16, 20 g m⁻² N fertilizer). A rice growth model that was developed and already validated for 9 different genotypes grown under 7 sites in Asia was used for the simulation, integrating additional components into the model to explain the direct effect of [CO₂] on several physiological processes. The model predicted that the relative yield response to elevated [CO₂] (RY, the ratio of yield under 700 ppm [CO₂] to that under 360 ppm [CO₂]) increased with increasing N fertilizer, ranging from 1.12 at 4 g m⁻² N fertilizer to 1.22 at 20 g m⁻² N fertilizer, averaged overall genotypes and locations. The model also predicted a large genotypic variation in RY at the 20 g N treatment, ranging from 1.08 for ‘WAB450-I-B-P-38-HB’ to 1.41 for ‘Takanari’ averaged overall locations. Combining all genotypes grown at the 5N fertilization conditions, a close 1:1 relationship was predicted between RY and the relative [CO₂] response in spikelet number for crops with a small number of spikelets (less than 30,000 m⁻²) under the current atmospheric [CO₂] (n = 18, r = 0.89^***). In contrast, crops with a large number of spikelets under the current atmospheric [CO₂] showed a significantly larger RY than the relative [CO₂] response for spikelet number per unit area. The model predicted that crops with a larger number of spikelets under the current atmospheric [CO₂] derived great benefit from elevated [CO₂] by directly allocating increased carbohydrate to their large, vacant sink, whereas crops with a smaller number of spikelets primarily required an increased spikelet number to use the increased carbohydrate to fill grains. The simulation analyses suggested that rice with a larger sink capacity relative to source availability under the current atmospheric [CO₂] showed a larger yield response to elevated [CO₂], irrespective of whether genotype or N availability was the major factor for the large sink capacity under the current [CO₂]. The model predicted that the RY response to nitrogen was brought about through the N effects on spikelet number and non-structural carbohydrate accumulation. The genotypic variation in RY was related to differences in spikelet differentiation efficiency per unit plant N content. Further model validation about the effects of [CO₂] on growth processes is required to confirm these findings considering data from experimental studies.