Carbon dioxide fixation by detached cereal caryopses

Immature detached cereal caryopses from barley (Hordeum vulgare L. var distichum cv Midas) and wheat (Triticum aestivum L. cv Sicco) were shown to be capable of fixing externally supplied ¹⁴CO₂ in the light or dark. Green cross cells and the testa contained the majority of the ¹⁴C-labeled material. Some ¹⁴C-labeled material was also found in the outer, or transparent, layer and in the endosperm/embryo fraction. More ¹⁴C was recovered from caryopses when they were incubated in ¹⁴CO₂ without the transparent layer, thus suggesting that this layer is a barrier to the uptake of CO₂. In all cases, significant amounts of ¹⁴C-labeled material were found in caryopses after dark incubation with ¹⁴CO₂. Interestingly, CO₂ fixation in the chlorophyll-less mutant Albino lemma was significantly greater in the light than in the dark. The results indicate that intact caryopses have the ability to translocate ¹⁴C-labeled assimilate derived from external CO₂ to the endosperm/embryo. Carboxylating activity in the transparent layer appears to be confined to phosphoenolpyruvate carboxylase activity but that in the chloroplast-containing cross-cells may be accounted for by both ribulose-1,5-bisphosphate carboxylase-oxygenase and phosphoenolpyruvate carboxylase activity. Depending on a number of assumptions, the amount of CO₂ fixed is sufficient to account for about 2% of the weight of starch found in the mature caryopsis.     

Photosynthesis in the Pericarp of Developing Wheat Grains

Oxygen exchange in grains of wheat was measured in both lightand dark over the period of grain development. Between 10 dand 30 d after anthesis, the rate of photosynthesis exceededthe rate of respiration. Peak photosynthetic activity was observedat 20 d after anthesis, coinciding with maximum chlorophyllcontent in the pericarp green layer. Removal of the pericarptransparent layer increased rates of oxygen exchange in boththe light and the dark. Attempts to inhibit photosynthesis withDCMU were only successful with the pericarp transparent layerremoved. Key words: Wheat, pericarp, photosynthesis     

Comparison of the photosynthetic characteristics in the pericarp and flag leaves during wheat (Triticum aestivum L.) caryopsis development

The pericarp of cereal crops is considered a photosynthetically active tissue. Although extensive studies have been performed on green leaves, the photosynthetic role of the pericarp in cereal caryopsis development has not been well investigated. In the present study, we investigated the anatomy, ultrastructure, chlorophyll (Chl) fluorescence, and oxygen evolution of the pericarp during caryopsis ontogenesis in field wheat (Triticum aestivum L.). The results showed that wheat pericarp cross-cells contained Chl; the grana stacks and thylakoid membranes in the cross-cells were more distinct in the pericarp than those in the flag leaves as shown by transmission electron microscopy. Chl fluorescence revealed that the photosynthetic efficiency, which was indicated by values of maximum efficiency of PSII photochemistry and effective PSII quantum yield, was lower in the pericarp compared to that of the flag leaf eight days after anthesis (DAA), whereas similar values were subsequently observed. The nonphotochemical quenching values were lower from 8–16 DAA but significantly increased in the pericarp from 24–32 DAA compared to the flag leaf. The oxygen evolution rate of the flag leaves was consistently higher than that of pericarp; notably, isolated pericarps released more oxygen than intact pericarps during caryopsis development. These results suggest that the pericarp plays a key role in caryopsis development by performing photosynthesis as well as by supplying oxygen to the endosperm and dissipating excessive energy during the grain-filling stages.     

Morphology and Ultrastructure of Immature Cereal Grains in Relation to Transport

The surfaces of the pericarps of wheat and barley grains, 15–30days after anthesis, were examined. Stomata were found in thepericarp epidermis on the ventral side at the apical end inone variety of wheat and four varieties of barley. Layers whichstained red with Sudan IV were observed on the pericarp epidermisand on either side of the testa in immature barley grains. Theultrastructure of these layers was investigated. It was concludedthat the cuticular layer inside the testa is derived from thenucellus. The significance of these cuticular layers in relationto the supply of carbon dioxide to the photosynthesizing cellsof the pericarp is discussed. The movement of photosynthateand oxygen produced in the pericarp is also considered. Hordeum vulgare L, Triticum aestivum L, barley, wheat, cereal grain, cuticle, stomata, pericarp     

Effects of Removing Floral Organs, Light Penetration and Physical Constraint on the Development of Wheat Grains

The effects on grain weight of removing spikelet and floralorgans, other manipulations of the florets or spikelets andcovering intact or treated spikes to reduce the amount of lightwere tested. Removal of organs which exposed the developing grain to increasedlight intensity resulted in a reduction in grain size. The restrictionin grain growth was already apparent 2 weeks after anthesisand was accompanied by a more compact pericarp. Covering thetreated spikes with opaque bags resulted in normal pericarpstructure and restoration of grain weight. Only a small portionof the restoration effect could be attributed to the increaseof humidity under the covers. Treatments which exerted physical constraint on the developinggrain reduced its size and affected its shape. The size of thefloret cavity and the transmission of light through floral bractsare shown to be two of the factors controlling grain growth. Triticum destivum L., Triticum spelta L., wheat, morphogenesis, histogenesis, grain development, glume, lemma, palea     

Light-Dependent CO2 Retrieval in Immature Barley Caryopses

Immature detached caryopses from barley (Hordeum vulgare L.var. distichum cv. Midas) were shown to be capable of light-dependentretrieval of internally-produced CO₂. In the first set of experiments,caryopses were radioactively labelled by supplying (U-14C)-sucroseto detached ears in liquid culture. Caryopses were then removedfrom the ear and given a 12 h chase of non-radioactive sucrosein either the light or dark. More ¹⁴C was recovered in the caryopsesafter the chase in the light than in the dark but the differenceswere not significant. In the second set of experiments, ¹⁴C-labelledcaryopses obtained by a 15 min light incubation in ¹⁴CO₂ weremaintained in either the light or dark for 3 h and any redistributionof label between the tissues recorded. The results show thatunder these conditions, photosynthesis in the Chl-containinggreen layer of the pericarp can prevent losses of internally-producedCO₂, since 3 times as much radiocarbon remained in the caryopsesincubated in the light as in the dark. These differences weresignificant at P=0.001. Experiments with the mutant barley Albinolemma, which has no Chi in the pericarp, showed that there waslittle difference between light and dark treatments. This confirmsthe suggestion that photosynthesis in the pericarp of the normalcultivar Midas may be concerned in the refixation of CO₂. Key words: Barley, pericarp, photosynthesis, carbon dioxide     

禾谷类花器官机械游离小孢子培养研究

以大田及温室生长的植株为材料,成功地建立了直接从禾谷类花器官(大麦穗切段、水稻颖花、小麦小穗)机械游离小孢子的程序及培养系统。从供试的二个大麦材料上重复获得大量游离小孢子再生植株,从一个水稻广亲和品种上得到游离小孢子再生植株,以及从三个小麦品种(系)上获得小孢子形成的多细胞结构(MCS)和早期胚状体(ELS)。相对较长时间的低温预处理有利于提高ELS(大麦)及MCS(小麦)的得率,改善培养物的通气状况,以及提早再分化有利绿色植株再生。     

Starch synthesis in developing wheat grain

The effect of light on the in-vivo rate of starch synthesis in the endosperm of developing wheat (Triticum aestivum cv. Mardler) grain was studied. Individual grains from spikelets grown on the same spike either in darkness or bright light showed no difference in their ability to accumulate radioactivity or to convert this to starch over a 14-h period. Similarly, there was no difference in final grain dry weight between spikes which had been kept in either darkness or normal light from 10 d post anthesis. In contrast, when half-grains (grain which had been bisected longitudinally along the crease region) were incubated by being submerged in culture solution (in vitro) the incorporation of [¹⁴C]sucrose into starch was stimulated by increased irradiance. Further experiments showed that the in-vitro dependence on light could be linked to the availability of oxygen. We suggest that in vitro the diffusion of oxygen into the endosperm cells combined with an increased rate of respiration of the tissue during the incubation causes this limitation. Thus the dependence of starch synthesis on light is an artefact of the in-vitro incubation system. The photosynthetic ability of the green pericarp tissue can be used to prevent the development of anoxia in the endosperm tissue of half-grains incubated in vitro. In conclusion, we propose that starch synthesis in vivo is not dependent on oxygen production by photosynthesis in the green layer of the pericarp.Abbreviations DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - dpa days post anthesis - PCA perchloric acid     

Some enzyme activities associated with the chlorophyll containing layers of the immature barley pericarp

Summary Some photosynthetic and biochemical properties of the chlorophyl containing layers of the pericarp of developing barley have been investigated. The tissue changes from pale green to bright green early in development, chlorophyll disappearing only at the later stages of maturity. It contains chloroplasts and probably amyloplasts and starch bearing chloroplasts. It is capable of high rates of light dependent oxygen evolution. It has been shown that the enzyme phosphoenol pyruvate carboxylase (EC 4.1.1.31) is present in the pericarp and is 100 times as active in carbon dioxide fixation as ribulose diphosphate carboxylase (EC 4.1.1.39). Other enzymes present in the pericarp are phosphoenol pyruvate synthetase, pyrophosphatase (EC 3.6.1.1), malate NAD and NADP dehydrogenases (EC 1.1.1.37), malic enzyme (EC 1.1.1.40), and fructose 1,6 diphosphatase (EC 3.1.3.11).Abbreviations RDP Ribulose 1,5-diphosphate - PEP phosphoenol pyruvate     

Oxygen and carbon dioxide fluxes from barley shoots depend on nitrate assimilation

A custom oxygen analyzer in conjunction with an infrared carbon dioxide analyzer and humidity sensors permitted simultaneous measurements of oxygen, carbon dioxide, and water vapor fluxes from the shoots of intact barley plants (Hordeum vulgare L. cv Steptoe). The oxygen analyzer is based on a calciazirconium sensor and can resolve concentration differences to within 2 microliters per liter against the normal background of 210,000 microliters per liter. In wild-type plants receiving ammonium as their sole nitrogen source or in nitrate reductase-deficient mutants, photosynthetic and respiratory fluxes of oxygen equaled those of carbon dioxide. By contrast, wild-type plants exposed to nitrate had unequal oxygen and carbon dioxide fluxes: oxygen evolution at high light exceeded carbon dioxide consumption by 26% and carbon dioxide evolution in the dark exceeded oxygen consumption by 25%. These results indicate that a substantial portion of photosynthetic electron transport or respiration generates reductant for nitrate assimilation rather than for carbon fixation or mitochondrial electron transport.     

The Effect of an Oxygen-free Atmosphere on Net Photosynthesis and Transpiration of Barley (Hordeum vulgare L.) and Wheat (Triticum aestivum L.) Leaves

Stomata of barley (Hordeum vulgare L.) and wheat (Triticum aestivum L.) leaves failed to open in the light and close in the dark or respond to changes in the CO₂ concentration of the atmosphere in either light or dark when the leaves were in an O₂-free atmosphere. In contrast, the expected responses to environmental changes were found in atmospheres containing 1.5% O₂. It appears that O₂ is necessary for both opening and closing of wheat and barley stomata.     

Effect of light on abscisic acid‐induced proline accumulation in leaves: comparison between barley and wheat

Light enhanced the abscisic acid‐induced accumulation of proline in barley ( Hordeum vulgare L. cv. Georgie) and wheat ( Triticum durum L. cv. Valnova). In wheat ABA is ineffective in the dark. In both barley and wheat, the accumulation of proline in the light showed the same characteristics as those of the process that occurs in barley in the dark, namely a synergistic interaction between the hormone and K(Na)Cl, an enhancing effect of Cl⁻ anion in excess over K⁺ cation in the incubation medium, and an inhibiting effect of D ‐mannose and monensine. In wheat, furthermore, light is needed during treatment with ABA if proline is to accumulate. Light was effective in both wheat and barley during the second or accumulation phase of the hormonal process, whereas the events occurring in the first (or lag) phase did not require light. The results suggest that in wheat light induces a putative factor(s) involved in the proline accumulation pathway that is lost in the dark, whereas in barley it is present in the dark.     

Barley spikelet culture: An effective tool for the analysis of biochemical events in flower development

Immature detached barley spikelets were cultured in wheat spikelet medium. Fertility of cultured barley spikelets was similar to that of cultured wheat spikelets. Barley anther development within cultured spikelets was retarded relative to in planta, but viability of developing pollen, as determined by a fluorochromatic reaction, was similar in vitro and in planta. Protein synthesis by anthers in developing barley spikelets in vitro was maximal during stage 2, when pollen grains were bicellular, and declined as pollen matured. Barley spikelet culture is an effective tool for the analysis of biochemical events in flower development.Abbreviations FRC fluorochromatic reaction - WSM wheat spikelet medium     

A Study of Floret Development in Wheat (Triticum aestivum L.)

Plants of wheat (Triticum aestlvum L.) cv. Aotea were grownat high or low nitrogen levels and in a natural photoperiodor continuous light. Starting 17–21 days from the double-ridgestage, eight plants from each treatment were sampled every 3days until anthesis, and the two basal, the sixth, and the terminalspikelets were sectioned longitudinally. A developmental scorewas assigned to each floret and rates of development calculated.Continuous light hastened development but reduced the numberof spikelets per ear, while high nitrogen delayed developmentbut increased spikelet numbers. The number of florets initiatedin each spikelet varied within narrow limits, but grain settingdepended strongly on spikelet position and on treatment. Althoughflorets were initiated in acropetal succession, the rate ofdevelopment tended to increase up to floret 4 but then declinedmarkedly. As a result grain setting was confined to basal floretpositions, although the two basal spikelets developed so slowlythat they contributed relatively little to grain yield. Distalflorets degenerated almost simultaneously at or before ear emergence,but those in intermediate positions continued to develop untilafter fertilization in the lower florets. It is argued thatthe spikelet is an integrated system in which correlative mechanismsplay a part throughout the development of the florets.     

Effect of awns and drought on the supply of photosynthate and its distribution within wheat ears

The presence of awns doubled the net photosynthetic rate of wheat ears and also increased the proportion of ¹⁴CO₂ assimilated by the ear that moved to the grain. The effect of water supply on photosynthesis and movement of assimilates was greater for leaves than ears, so that drought increased the proportion of assimilate contributed by ear photosynthesis to grain filling from 13% to 24% in the awnless ears, and from 34% to 43% in the awned ears. ¹⁴C assimilated by the ears was most important to the economy of the upper spikelets and to the distal florets in each spikelet, whereas flag leaf assimilate went mainly to the spikelets in the lower half of the ear, and to the proximal florets. Awns increased grain yield in the dry but not in the irrigated treatment, despite the large contribution of awned ears to grain filling. Either the supply of assimilate did not limit grain yield when water supply was not limiting, or there were compensating disadvantages to awns. However, they did not seem to have any adverse effect on the development of the upper florets, nor did they reduce grain number per ear.     

大穗多花种质B46的选育及细胞遗传学鉴定

利用普通小麦(Triticum aestivum L.)7182与华山新麦草(Psathyrostachys huashanica)杂交、回交和自交,经多代选育出能够稳定遗传的大穗多花种质B46.对B46进行形态学观察及其细胞学检测与GISH鉴定.结果表明,B46形态学特征表现大穗多花特性,穗长12 cm左右,小穗达23个,小穗粒数平均6个;其根尖细胞染色体计数为2n=44;根尖原位杂交(GISH)及减数分裂中期Ⅰ染色体的基因组原位杂交(GISH)显示,B46附加1对来自于华山新麦草的同源染色体.由此可以确定B46为小麦-华山新麦草的二体异附加系,其综合农艺性状优于小麦亲本7182,可作为培育高产小麦品种的优良种质材料.     

Identification and Fine Mapping of a White Husk Gene in Barley (Hordeum vulgare L.)

Barley is the only crop in the Poaceae family with adhering husks at maturity. The color of husk at barely development stage could influence the agronomic traits and malting qualities of grains. A barley mutant with a white husk was discovered from the malting barley cultivar Supi 3 and designated wh (white husk). Morphological changes and the genetics of white husk barley were investigated. Husks of the mutant were white at the heading and flowering stages but yellowed at maturity. The diastatic power and α-amino nitrogen contents also significantly increased in wh mutant. Transmission electron microscopy examination showed abnormal chloroplast development in the mutant. Genetic analysis of F₂ and BC₁F₁ populations developed from a cross of wh and Yangnongpi 5 (green husk) showed that the white husk was controlled by a single recessive gene (wh). The wh gene was initially mapped between 49.64 and 51.77 cM on chromosome 3H, which is syntenic with rice chromosome 1 where a white husk gene wlp1 has been isolated. The barley orthologous gene of wlp1 was sequenced from both parents and a 688 bp deletion identified in the wh mutant. We further fine-mapped the wh gene between SSR markers Bmac0067 and Bmag0508a with distances of 0.36 cM and 0.27 cM in an F₂ population with 1115 individuals of white husk. However, the wlp1 orthologous gene was mapped outside the interval. New candidate genes were identified based on the barley genome sequence.     

Level ofFusarium infection in wheat spikelets related to location and number of inoculated spores

The flowering time is the most susceptible period for primary infection of wheat heads byFusarium spp. During this period spores can be deposited into the opened wheat florets where they may later cause infections. We quantitatively explored the relationship between variables related to the flowering process and the infection level byFusarium graminearum in single spikelets. We imitated open (chasmogamous) and closed (cleistogamous) flowering by injecting well-defined amounts of spores into and between wheat florets. Applying the spores between the florets resulted in weaker disease symptoms and significantly lower amounts ofFusarium mycotoxins. With larger numbers of spores, the disease symptoms became more pronounced and the mycotoxin amounts per spikelet increased significantly. Our results indicate that the probability of primary infection is approximately proportional to the number of spores reaching the open florets during the flowering process. The breeding of wheat lines which flower partially or completely cleistogamously might reduce theFusarium susceptibility in wheat.     

Changes in photosynthetic activity in the cyanobacterium Chlorogloea fritschii following transition from dark to light growth

The cyanobacterium Chlorogloea fritschii loses Photosystem II activity, measured by delayed fluorescence and oxygen evolution, during dark heterotrophic growth, but retains Photosystem I, measured as light induced EPR signals. Following transition to the light, Photosystem II recovers in two stages, the first of which does not require protein synthesis. New Photosystem I reaction centres are not synthesised until after net chlorophyll synthesis has commenced. Carbon dioxide fixation recovery commences immediately, the initial rate being unaffected by chloramphenicol. The recovery of carbon dioxide fixation is not directly related to oxygen evolution rate and is only inhibited slightly by 3-(3,4-dichlorophyenyl)-1,1-dimethylurea and 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone.