A critical evaluation of a biophotothermal time scale for barley

The biophotothermal time scale for barley derived previously and based on daily maximum and minimum temperatures and photoperiod was examined and tested further. The threshold temperature of 4.3°C and the optimum of 19 or 20°C found for the planting to emergence phase, and the optimum temperature values of 18.4°C for minimum and 24.8°C for maximum for heading to soft dough were not inconsistent with the results of other authors. For some of the other cardinal points, no meaningful values were found. Tests of the biophotothermal equations with independent data indicated that they could usefully be applied under the environmental conditions prevailing on most of Canada's present or potential farmland. They gave dubious results when applied to very cool marine climates on some exposed coastal parts of Canada, and were unsatisfactory for the short-day regimes that affected early-season plantings at Buenos Aires. The equations for barley seemed much less universally applicable than those for wheat.     

氮、硫肥与灌浆后期高温胁迫对小麦籽粒产量和品质的影响

灌浆期高温胁迫通常导致小麦籽粒产量降低、品质变差.为了探索有效缓解高温胁迫不利影响的有效措施,在大田条件下,以济麦20为试验材料,运用后期高温棚增温的方法,研究了氮、硫肥与灌浆后期高温对小麦籽粒产量和品质的影响.结果表明:高温处理后小麦千粒质量、籽粒产量显著降低(19.7%～28.3%),蛋白质含量升高,蛋白质组分中不溶性谷蛋白含量下降,可溶性谷蛋白含量上升,面团形成时间和稳定时间缩短;氮肥追施比例由50%增加到70%,非高温处理的籽粒产量无显著变化,不溶性谷蛋白质含量和谷蛋白聚合指数(不溶性谷蛋白含量/可溶性谷蛋白含量)升高,面团形成时间和稳定时间延长;高温处理的千粒质量和籽粒产量因氮肥追施比例提高而提高(2.07%～3.58%),面团形成时间和稳定时间缩短;不论高温处理还是非高温处理,与追施硫肥相比,硫肥基施提高籽粒产量、谷蛋白聚合指数,延长面团形成时间和稳定时间;为了有效缓解灌浆后期高温对小麦籽粒产量和品质的不利影响,硫肥基施、氮肥施用基追比50%:50%是较为适宜的施肥模式.     

Identifying the critical period for waterlogging on yield and its components in wheat and barley

Background and aims

Crop tolerance to waterlogging depends on factors such as species sensitivity and the stage of development that waterlogging occurs. The aim of this study was to identify the critical period for waterlogging on grain yield and its components, when applied during different stages of crop development in wheat and barley.

Methods

Two experiments were carried out (E1: early sowing date, under greenhouse; E2: late sowing date, under natural conditions). Waterlogging was imposed during 15–20 days in 5 consecutive periods during the crop cycle (from Leaf 1 emergence to maturity).

Results

The greatest yield penalties occurred when waterlogging was applied from Leaf 7 appearance on the main stem to anthesis (from 34 to 92 % of losses in wheat, and from 40 to 79 % in barley for E1 and E2 respectively). Waterlogging during grain filling reduced yield to a lesser degree. In wheat, reductions in grain number were mostly explained by reduced grain number per spike while in barley, by variations in the number of spikes per plant.

Conclusions

The time around anthesis was identified as the most susceptible period to waterlogging in wheat and barley. Exposing the crop to more stressful conditions, e.g. delaying sowing date, magnified the negative responses to waterlogging, although the most sensitive stage (around anthesis) remained unchanged.     

Distribution of Zinc in Euglena gracilis Wild and Mutant Cells Cultured in Zinc Enriched Medium as Proved by X-Ray Microanalysis

As a part of the study of bubble expansion in wheat flour dough under temperature rise, the critical radius for expansion, and the time course of expansion of an isolated bubble were investigated. As the required physical properties for the calculation of the critical bubble radius for expansion and the time course of bubble expansion, the authors measured the surface tension of the liquid phase of wheat flour batter as a function of concentration and temperature, and the apparent diffusion coefficients of air in wheat flour dough as a function of temperature. The critical radius for expansion and the time course of expansion of the isolated bubble under temperature rise were compared with the theoretical values calculated from the diffusion theory. At constant temperature, the time course of bubble shrinkage in wheat flour dough was described well by diffusion theory with the surface tension and the apparent diffusion coefficient, indicating that the bubble shrinkage would be rate-limited by the diffusion in the liquid phase of wheat flour dough of air out of the bubble. Under temperature rise from 3°C to 43°C, every bubble larger than the critical radius expanded. This result is physically admissible. On the other hand, the calculated time course of the bubble radius under temperature rise was not in agreement with the experimental data.     

The characterisation and mapping of a family of LMW-gliadin genes: effects on dough properties and bread volume

Analysis of a cDNA library from wheat cv Wyuna endosperm, indicated a significant size and sequence variation among seed-endosperm protein genes. In this study, a family of low-molecular-weight seed protein genes are analysed that are related to the gliadins and the low-molecular-weight glutenin subunits. Sequence analysis and comparison of these proteins showed that they are closely related to a 17-kDa protein from barley, epsilon hordein, which plays a role in beer foam stability in the brewing industry. Mapping of these genes in wheat shows that they are located on group 7 and 4 chromosomes, as opposed to a group 1 and 6 location for the glutenins and gliadins. It is possible that this family of proteins forms a new class of seed-endosperm proteins important in defining the quality characteristics of wheat flour. Therefore, a representative gene from this family was expressed in Escherichia coli and the purified protein was supplemented into a base wheat flour. Rheological analysis showed that the protein effected dough strength and resistance break down during mixing of the dough, and provided a 20% increase in loaf height after baking.     

Rheological and breadmaking properties of wheat samples infected with<Emphasis Type="Italic">Fusarium spp.</Emphasis>

Rheological and breadmaking properties of untreated and suboptimally stored wheat samples (grain moisture: 20%, temperature: 20°C) and also of wheat which was inoculated withFusarium spp. were investigated. The deoxynivalenol (DON) content of the stored and inoculated wheat samples ranged between 820–12,000 μg/kg. Gluten proteins were isolated with different extraction solutions and the fractions obtained were analysed by means of RP-HPLC. Microextension tests and micro-baking tests were used for the determination of dough properties (maximum resistance (MR) and extensibility (EX)) and bread volume, respectively. In spite of the extremely high DON concentrations of some wheat samples contaminated withFusarium spp. they showed only a slight decrease of the amount of gluten proteins. Extension tests of dough led to a slight decrease of MR, bread volumes stayed almost the same compared with the non-contaminated grain. The contamination of wheat withAspergillus andPenicillium led to a high decrease of gluten proteins, which resulted in an extremely decreased MR of the dough and a very low bread volume.     

Wheat (Triticum aestivum L.) and barley (Hordeum vulgare L.) multiple inositol polyphosphate phosphatases (MINPPs) are phytases expressed during grain filling and germination

At present, little is known about the phytases of plant seeds in spite of the fact that this group of enzymes is the primary determinant for the utilization of the major phosphate storage compound in seeds, phytic acid. We report the cloning and characterization of complementary DNAs (cDNAs) encoding one of the groups of enzymes with phytase activity, the multiple inositol phosphate phosphatases (MINPPs). Four wheat cDNAs (TaPhyIIa1, TaPhyIIa2, TaPhyIIb and TaPhyIIc) and three barley cDNAs (HvPhyIIa1, HvPhyIIa2 and HvPhyIIb) were isolated. The open reading frames ranged from 1548 to 1554 bp and the level of homology between the barley and wheat proteins ranged from 90.5% to 91.9%. All cDNAs contained an N-terminal signal peptide encoding sequence, and a KDEL-like sequence, KTEL, was present at the C-terminal, indicating that the enzyme was targeted to and retained within the endoplasmic reticulum. Expression of TaPhyIIa2 and HvPhyIIb in Escherichia coli revealed that the MINPPs possessed a significant phytase activity with narrow substrate specificity for phytate. The pH and temperature optima for both enzymes were pH 4.5 and 65 degrees C, respectively, and the K(m) values for phytate were 246 and 334 microm for the wheat and barley recombinant enzymes, respectively. The enzymes were inhibited by several metal ions, in particular copper and zinc. The cDNAs showed significantly different temporal and tissue-specific expression patterns during seed development and germination. With the exception of TaPhyIIb, the cDNAs were present during late seed development and germination. We conclude that MINPPs constitute a significant part of the endogenous phytase potential of the developing and germinating barley and wheat seeds.     

The Control of Flowering in Wheat and Barley: What Recent Advances in Molecular Genetics Can Reveal

The combined forces of developmental biologists, studying primordiuminitiation at the stem apex, and mathematical modellers, developingsimulations of crop growth and development, have brought aboutconsiderable advances in the understanding of the control offlowering in wheat and barley. Nevertheless, there are stillmajor gaps in this understanding including: what determinesthe basic rate of development (magnitude of the phyllochronor plastochron); how temperature and photoperiod interact tobring about the transition from vegetative to reproductive development;and how flowering occurs eventually in the absence of inductiveconditions. Although geneticists have tended to measure cerealflowering in terms of ‘days from sowing or emergence toheading’, results of studies using aneuploids and molecularmarkers are compatible with the roles for photoperiod and low-temperaturevernalization established in purely-physiological or developmentalinvestigations. They have also revealed the existence of ‘earlinessperse’loci, whose detailed roles have yet to be established.Progress towards isolating and characterizing wheat and barleyloci is hampered by the poor resolution of mapping (locationto a precision of tens of thousands of base pairs). Neitherof these broad approaches promises a rapid resolution of thefactors controlling the induction of flowering. Two expandingareas of molecular genetics now provide potential for greaterunderstanding of cereal flowering. First, the extensive homoeologyamong members of the Gramineae can be employed to establishthe existence and location of genes or quantitative trait lociin rice which correspond to controlling loci in wheat or barley.Since the rice genome is 1/30th of the size of the wheat genome,the accuracy of mapping loci can be much higher, and there isgreater potential for precise location of loci using techniquessuch as chromosome walking. With the ultimate cloning of individualgenes, and the isolation of gene products, the relative rolesof the 20 loci apparently involved in the induction of floweringof wheat could be explored. However, progress in the moleculargenetics ofArabidopsis(the second area) may provide a more rapidroute to understanding the control of flowering in cereals forseveral reasons: its small genome (1/4 that of rice); the likelihoodof extensive homoeology with cereals, in spite of differencesin codon usage between monocots and dicots; the existence ofa wide range of flowering-time mutants; and the control of floralinduction by a similar range of environmental factors includingphotoperiod and low temperature. It is likely that the MCDK(Martinez-Zapater, Coupland, Dean and Koornneef, 1994. In: MeyerowitzEM, Somerville CR.Arabidopsis.New York: Cold Spring Harbor Laboratory,403–433) model, formulated to explain the genetic andenvironmental control of flowering inArabidopsis,could be employedusefully in the formulation of experimental work on floweringin wheat and barley. This paper reviews these issues, payingparticular attention to the significance of ‘earlinessperse’ loci and the ‘constitutive floral pathway’for wheat and barley.Copyright 1998 Annals of Botany Company Wheat, barley, rice,Arabidopsis,flowering, photoperiod, vernalization, genetics, development.     

Rates of Shrinkage and Growth of Air Bubbles Entrained in Wheat Flour Dough

The rates of shrinkage at constant temperature, and growth under a temperature rise below 100°C, of bubbles entrained in wheat flour dough were analyzed and compared with those of a bubble in water. The rate of shrinkage of bubbles in flour dough was controlled by the diffusion of dissolved air from the surface of bubbles to the bulk of flour dough. The apparent diffusion coefficient of the dissolved air in wheat flour dough with the water fraction of 0.49 calculated from the shrinkage of bubbles, was (3.2 ± 1.5) × 10^1?1 m²/sec (19°C), and (6.4 ± 2.0) × 10^?11 m²/sec (42°C). However, the growth behavior of bubbles in flour dough under a temperature rise was very different from that predicted from the diffusion theory. The critical radius of bubbles to grow was larger than that estimated from the diffusion theory. The mechanism of growth of bubbles in wheat flour dough, which was different from that of a bubble in water, is a subject that needs to be clarified.     

Evaluation of Barley and Wheat Germplasm for Resistance to Head Blight and Mycotoxin Production by Fusarium asiaticum and F. graminearum

Fusarium head blight (FHB) is one of the most serious diseases in barley and wheat, as it is usually accompanied by the production of harmful mycotoxins in the grains. To identify FHB-resistant breeding resources, we evaluated 60 elite germplasm accessions of barley (24) and wheat (36) for FHB and mycotoxin accumulation. Assessments were performed in a greenhouse and five heads per accession were inoculated with both Fusarium asiaticum (Fa73, nivalenol producer) and F. graminearum (Fg39, deoxynivalenol producer) strains. While the accessions varied in disease severity and mycotoxin production, four wheat and one barley showed <20% FHB severity repeatedly by both strains. Mycotoxin levels in these accessions ranged up to 3.9 mg/kg. FHB severity was generally higher in barley than in wheat, and Fa73 was more aggressive in both crops than Fg39. Fg39 itself, however, was more aggressive toward wheat and produced more mycotoxin in wheat than in barley. FHB severity by Fa73 and Fg39 were moderately correlated in both crops (r = 0.57/0.60 in barley and 0.42/0.58 in wheat). FHB severity and toxin production were also correlated in both crops, with a stronger correlation for Fa73 (r = 0.42/0.82 in barley, 0.70 in wheat) than for Fg39.     

Wheat-yellow pumpkin composite flour: Physico-functional,rheological, antioxidant potential and quality properties of pan and flat bread

The impact of yellow pumpkin powder (YP) substitution (5, 10, and 15%) on wheat flour's physico-functional, pasting, gel texture, and dough rheology was studied. Moreover, the nutritional, organoleptic properties and bioactivity of the composite pan and pita bread were evaluated. An improved water holding capacity was noticed for the blended flour than for control. The pasting parameters were declined significantly (p < 0.05) with increasing YP. Composite flours presented a softer gel texture in the presence of YP. Reduced water absorption, increased dough development time, and lower stability for combined flour dough. The bread with YP depicted increased protein, fat, fiber, and mineral contents, while a reduced volume and specific volume were noticed for pan bread. YP incorporated 5% and did not compromise pan and pita bread's color and overall acceptability. Additionally, composite bread depicted higher total phenolics with enhanced antioxidant activities at the higher substitution of YP.     

Recent biometeorological applications to crops

The paper demonstrates how standard climatological data can effectively be exploited by making use of biometeorological knowledge and modern data processing facilities in studies concerned with the evaluation of crop-weather relationships and the analysis of climatic resources. In analyzing potential biological yield of wheat at Normandin (Quebec), it was found that the potential yield was reduced by approximately 45% because of variations in temperature and radiation whereas the actual yield was reduced by 70%. In mesoscale analyses, the error between soil moisture observations and estimates from a climatological soil moisture budget was in the same order as the standard deviation of 3-times replicated 38 soil moisture samples taken over five years at Swift Current (Sask.). An analysis of crop-weather relationships at Lacombe (Alta.) indicated that the 1957 wheat yield was reduced from the potential 3,300 kg/ha to 2,004 kg/ha or by 40% because of a severe cold spell during the soft dough developing stage resulting in improper filling of the kernels. In macroscale analyses, relative winter hardiness indices for woody ornamental plants together with site suitability indices for winter survival were used in the development of a map of plant hardiness zones in Canada. In the application of this research to forage crops average winter survival percentage of legumes and grasses by classes of hardiness together with selected regional climatic averages were developed for six regions of southern Canada. Long-term research into the relationships between Canadian Prairie crop yields and development (wheat, oats and barley) and selected climatic and soil variables has been used successfully for estimating regional crop production, for determining climatic limitations of the area suitable for the cultivation of these crops, and for assessing the impact of postulated climatic changes on crop production.Contribution No 862 of the Chemistry and Biology Research Institute.     

Phosphorus (P) acquisition of cereal cultivars in the field at three levels of P fertilization

Low phosphorus (P) availability in soils and diminishing P reserves emphasize the need to create plants that are more efficient P users. Knowledge of P efficient germplasm among the existing cereal varieties may serve as the basis for improving soil P use by selection and breeding. We had identified some cereal cultivars (winter wheat: Kosack and Kraka; winter barley: Hamu and Angora; spring barley: Canut, Alexis, Salka, Zita;) which differed (p<0.05) in P depletion from thin slices (0.2 mm) of the rhizosphere soil under controlled conditions. In the present study, the same cultivars were studied under field conditions at three levels of P supply (no-P, 10 and 20 kg P ha^-1) and the differences in P uptake as found in the previous work were confirmed. Under both conditions, the variation between the cultivars was greatest in soil without P fertilizers (no-P) for about 30 years. The variation in P uptake with most cultivars disappeared when 10 kg P ha^-1 was applied. Root development did not differ between the cultivars much, but there was wide, consistent variation in their root hairs, regardless of growth media (solution, soil column and field). Increase in soil P level reduced the length of root hairs. The variation in root hairs between the cultivars was largest in no-P soil. When 10 kg P ha^-1 was applied, the root hair lengths did not differ between the cultivars. Barley cultivars with longer root hairs depleted more P from the rhizosphere soil and also absorbed more P in the field. The relationship between root hairs and phosphorus uptake of the wheat cultivars was less clear. The wide variation in P uptake among the barley cultivars in the field and its relationship to the root hair development confirms that root hair length may be a suitable plant characteristic to use as criterion for selecting barley cultivars for P efficiency, especially in low-P soils. This revised version was published online in June 2006 with corrections to the Cover Date.     

Digestibility of whole-crop barley and oat silages in dairy heifers

This study evaluated the digestibility of whole-crop cereal silage (WCCS) made from oats and six-rowed barley harvested at the heading, early milk and early dough stages, and two-rowed barley harvested at the early milk and early dough stages of maturity. The eight WCCSs were fed to 32 Swedish Red heifers in a changeover design over three periods of 28 days each. The heifers were first fed ad libitum for 17 days and then at 0.95 of ad libitum for 11 days of each period. During the last 5 days all faeces and orts were collected to determine the digestibility of the silages. Only the maturity stage effect was significant for the WCCS organic matter (OM) digestibility and the average OM digestibility was higher at the heading stage (698 g/kg) than at early milk (647 g/kg) and early dough (652 g/kg) stages of maturity. For neutral detergent fibre (NDF) digestibility the crop × maturity stage effect was significant. The NDF digestibility decreased from the heading to the early milk stage for both six-rowed barley (746 to 607 g/kg) and oats (698 to 596 g/kg). There was no further significant decrease in NDF digestibility for six-rowed barley at the early dough stage (577 g/kg), but for two-rowed barley it decreased from the early milk (682 g/kg) to the early dough (573 g/kg) stage, and also for oats the NDF digestibility was lowest at the early dough stage (507 g/kg). The decrease in NDF digestibility during maturation was to a large extent compensated by an increase in starch concentration in the crops. The starch digestibility was lower for six-rowed barley at early dough stage (948 g/kg) than at early milk stage (977 g/kg), and was also lower compared with oats (979 g/kg) at early dough stage. The average crude protein (CP) digestibility was higher at the heading (646 g/kg) and the early milk (642 g/kg) stages than at the early dough stage (599 g/kg), and oats had higher average CP digestibility (650 g/kg) than six-rowed (613 g/kg) and two-rowed (624 g/kg) barley. Delaying the harvest of WCCS from the heading to the early milk and dough stage of maturity will decrease the OM digestibility; as a result there is a decreased NDF digestibility.     

Proteins in intercellular washing fluid from noninoculated and rust-affected leaves of wheat and barley

Proteins in intercellular washing fluid (IWF) from wheat (Triticum aestivum) and barley (Hordeum vulgare) leaves were separated by two-dimensional isoelectric focusing-polyacrylamide gel electrophoresis and stained with Coomassie brilliant blue (CBB) or silver. Intracellular protein from the cut ends of leaves accounted for only a small proportion of total protein in IWF from wheat leaves. When these were heavily infected with the stem rust fungus (Puccinia graminis f. sp. tritici) and grown at 19°C, four infection-related CBB-stainable proteins were detected in IWF.

To compare IWF proteins from wheat and barley leaves infected with the same pathogen, conditions were established that permitted luxuriant growth of stem rust of wheat in barley (exposure to chloroform before inoculation and maintenance at 25°C thereafter). Under these conditions, at least 10 infection-related silver-stainable proteins were detected in IWF from infected wheat in addition to the more than 50 that were of host origin. The electrophoretic properties of 8 of the infection-related proteins were the same as those of 8 infection-related proteins in IWF from barley.

IWF from wheat and barley grown under these conditions was analyzed for Concanavalin A-binding glycoproteins immobilized on nitrocellulose membrane replicas made from gels. Of the many infection-related glycoproteins that were detected in IWF from stem rust-affected wheat, approximately 20 occupied the same positions as those from stem rust-affected barley. The glycoprotein pattern of IWF prepared from wheat leaves grown at 19°C and infected with the leaf rust fungus (P. recondita f. sp. tritici) was markedly different to that of IWF from the same host infected with the stem rust fungus. We conclude that IWF from rust-affected cereal leaves may be a useful source of surface or extracellular proteins from the parasitic mycelium.

     

花后灌水次数对强筋小麦籽粒产量和品质的影响

在防雨池栽培条件下,以2个优质强筋小麦品种（济麦20和藁城8901）为试验材料,研究了花后不同水分供应状况对籽粒产量、籽粒品质（粉质仪参数和面包体积）及其蛋白质组分的影响.结果表明：2个品种的籽粒产量、面粉的面团形成时间、面团稳定时间和制成面包体积均随花后灌水次数的增加呈先升高后降低的趋势;其中,花后灌1水（花后7 d）时藁城8901的籽粒产量最高,花后灌2水（花后7 d+花后14 d）时济麦20的籽粒产量最高;2个品种面粉的面团形成时间、面团稳定时间和制成面包体积均以花后灌1水时最优.单体蛋白含量、不溶性谷蛋白含量、谷蛋白总含量、蛋白质含量以及湿面筋含量也呈现类似的变化趋势.逐步回归分析表明,花后不同水分供应状况下,不溶性谷蛋白含量是影响面团稳定时间的关键因素,谷蛋白总含量与面包体积的变化密切相关.因此,为了保持优质强筋小麦品质的稳定性,水分管理应以改善籽粒蛋白质特别是谷蛋白组分的构成为目标.     

Stable Carbon Isotope Evidence for Neolithic and Bronze Age Crop Water Management in the Eastern Mediterranean and Southwest Asia

In a large study on early crop water management, stable carbon isotope discrimination was determined for 275 charred grain samples from nine archaeological sites, dating primarily to the Neolithic and Bronze Age, from the Eastern Mediterranean and Western Asia. This has revealed that wheat (Triticum spp.) was regularly grown in wetter conditions than barley (Hordeum sp.), indicating systematic preferential treatment of wheat that may reflect a cultural preference for wheat over barley. Isotopic analysis of pulse crops (Lens culinaris, Pisum sativum and Vicia ervilia) indicates cultivation in highly varied water conditions at some sites, possibly as a result of opportunistic watering practices. The results have also provided evidence for local land-use and changing agricultural practices.     

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     

High night temperatures during grain number determination reduce wheat and barley grain yield: a field study

Warm nights are a widespread predicted feature of climate change. This study investigated the impact of high night temperatures during the critical period for grain yield determination in wheat and barley crops under field conditions, assessing the effects on development, growth and partitioning crop‐level processes driving grain number per unit area (GN). Experiments combined: (i) two contrasting radiation and temperature environments: late sowing in 2011 and early sowing in 2013, (ii) two well‐adapted crops with similar phenology: bread wheat and two‐row malting barley and (iii) two temperature regimes: ambient and high night temperatures. The night temperature increase (ca. 3.9 °C in both crops and growing seasons) was achieved using purpose‐built heating chambers placed on the crop at 19:000 hours and removed at 7:00 hours every day from the third detectable stem node to 10 days post‐flowering. Across growing seasons and crops, the average minimum temperature during the critical period ranged from 11.2 to 17.2 °C. Wheat and barley grain yield were similarly reduced under warm nights (ca. 7% °C^?1), due to GN reductions (ca. 6% °C^?1) linked to a lower number of spikes per m². An accelerated development under high night temperatures led to a shorter critical period duration, reducing solar radiation capture with negative consequences for biomass production, GN and therefore, grain yield. The information generated could be used as a starting point to design management and/or breeding strategies to improve crop adaptation facing climate change.     

Metabolic acclimation to hypoxia in winter cereals : low temperature flooding increases adenylates and survival in ice encasement

Cold hardened seedlings of winter wheat (Triticum aestivum L. em Thell) show an hypoxic hardening response: an exposure to low temperature flooding increases the tolerance of plants to a subsequent ice encasement exposure. Seedlings of winter barley (Hordeum vulgare L.) do not show such a response in similar experimental conditions. During ice encasement, there are general declines in adenylate energy charge (AEC), total adenylates and ATP:ADP ratios in the crown tissues of two winter wheat cultivars, and a winter barley, but rates of decline are faster in the barley. When the ice period is preceded by low temperature flooding of the whole plant, levels of the adenylate components are raised significantly in the wheats, and to a lesser extent in the barley. The survival of plants in ice preceded by flooding is related to the increased initial level of adenylates at the onset of the ice encasement stress, and the maintenance of higher levels of adenylates and ATP in the early stages of ice encasement as a result of accelerated rates of glycolysis. Higher survival of both winter wheat and barley plants during ice encasement in the light is also associated with significantly higher levels of AEC and adenylates in the early stages of ice encasement.