C]Sucrose Uptake and Labeling of Starch in Developing Grains of Normal and segl Barley

Previous work showed that the segl mutant of barley (Hordeum vulgare cv Betzes) did not differ from normal Betzes in plant growth, photosynthesis, or fertility, but it produced only shrunken seeds regardless of pollen source. To determine whether defects in sucrose uptake or starch synthesis resulted in the shrunken condition, developing grains of Betzes and segl were cultured in [¹⁴C]sucrose solutions after slicing transversely to expose the endosperm cavity and free space. In both young grains (before genotypes differed in dry weight) and older grains (17 days after anthesis, when segl grains were smaller than Betzes), sucrose uptake and starch synthesis were similar in both genotypes on a dry weight basis. To determine if sucrose was hydrolyzed during uptake, spikes of Betzes and segl were allowed to take up [fructose-U-¹⁴C]sucrose 14 days after anthesis and the radioactivity of endosperm sugars was examined during 3 hours of incubation. Whereas less total radioactivity entered the endosperm and the endosperm cavity (free space) of segl, in both genotypes over 96% of the label of endosperm sugars was in sucrose, and there was no apparent initial or progressive randomization of label among hexose moieties of sucrose as compared to the free space sampled after 1 hour of incubation. We conclude that segl endosperms are capable of normal sucrose uptake and starch synthesis and that hydrolysis of sucrose is not required for uptake in either genotype. Evidence suggests abnormal development of grain tissue of maternal origin during growth of segl grains.     

Characterization of shrunken endosperm mutants in barley

Despite numerous studies on shrunken endosperm mutants caused by either maternal tissues (seg) or kernel per se (sex) in barley, the molecular mechanism for all of the eight seg mutants (seg1–seg8) and some sex mutants is yet to be uncovered. In this study, we determined the amylose content, characterized granule-binding proteins, analyzed the expression of key genes involved in starch synthesis, and examined starch granule structure of both normal (Bowman and Morex) and shrunken endosperm (seg1, seg3, seg4a, seg4b, seg5, seg6, seg7, and sex1) barley accessions. Our results showed that amylose contents of shrunken endosperm mutants ranged from 8.9% (seg4a) to 25.8% (seg1). SDS-PAGE analysis revealed that 87 kDa proteins corresponding to the starch branching enzyme II (SBEII) and starch synthase II (SSII) were not present in seg1, seg3, seg6, and seg7 mutants. Real-time quantitative PCR (RT-qPCR) analysis indicated that waxy expression levels of seg1, seg3, seg6, and seg7 mutants decreased in varying degrees to lower levels until 27 days after anthesis (DAA) after reaching the peak at 15–21 DAA, which differed from the pattern of normal barley accessions. Further characterization of waxy alleles revealed 7 non-synonymous single nucleotide polymorphisms (SNPs) in the coding sequences and 16 SNPs and 8 indels in the promoter sequences of the mutants. Results from starch granule by scanning electron microscopy (SEM) indicated that, in comparison with normal barley accessions, seg4a, seg4b, and sex1 had fewer starch granules per grain; seg3 and seg6 had less small B-type granules; some large A-type granules in seg7 had a hollow surface. These results improve our understanding about effects of seg and sex mutants on starch biosynthesis and granule structure during endosperm development and provide information for identification of key genes responsible for these shrunken endosperm mutants.     

Growth characteristics, grain filling, and assimilate transport in a shrunken endosperm mutant of barley

The reported inheritance pattern of the seg1 shrunken endosperm mutant of barley (Hordeum vulgare L. cv Betzes) suggests that some defective process in the maternal plant tissues, and not in the endosperm, prevents normal grain filling in the mutant. To identify the physiological mechanism of the mutation, we compared growth, carbon exchange, and assimilate transport of Betzes and seg1 plants. Betzes and seg1 plants did not differ in mean relative growth rate, mean net assimilation rate, or carbon exchange rate. The rate and duration of grain growth of seg1 was lower than Betzes on intact plants and on detached, cultured spikes. Increasing the supply of sucrose in culture media up to 300 mm sucrose did not eliminate differences between normal and mutant grain growth. Translocation of ¹⁴C-labeled assimilates into seg1 grains ceased by 21 days after anthesis, and assimilates were diverted to lower plant parts. In contrast, assimilates were still entering Betzes grains at 29 days after anthesis. Evidence suggests that some maternal spike or grain tissue is affected by the mutation after the onset of grain filling. Identification of the specific seg1 defect may provide information about the cessation of normal grain filling.     

Regulation of Storage Protein Synthesis by Sulphur and Nitrogen Nutrition in Cultured Immature Caryopses of Barley

Techniques are described for the culture of developing barley(Hordeum vulgare L.) caryopses. Over a 7 d period in culturethe dry weights and the amounts of starch and protein increasedby at least twofold. Growth was sustained for at least 20 d.The effects of glutamine and cysteine on the amount and compositionof the hordein storage proteins were also studied. Glutaminestimulated total hordein accumulation but caused a disproportionateincrease in the amount of the S-poor ‘C’ hordeinswhen supplied at 100 mol m^–3. Addition of cysteine at1·0 mol m^–3 did not increase the amount of Srich‘B’ hordeins. The results suggest that althoughisolated caryopses are able to take up sucrose and glutamineand convert them to starch and protein there is some limitationin their ability to convert externally supplied cysteine intoproteins. Key words: Hordeum vulgare L., Caryopses, Glutamine, Cysteine, Storage proteins     

ANATOMY OF IMMATURE GRAINS OF EIGHT MATERNAL EFFECT SHRUNKEN ENDOSPERM BARLEY MUTANTS

The anatomical basis for the shrunken endosperm phenotype of eight recessive maternal effect mutants (seg1-seg8) of barley (Hordeum vulgare L.) is described. Plants which are homozygous recessive for these nuclear genes produce only shrunken seeds regardless of pollen source. Light microscopy revealed that four of the mutants, seg1, seg3, seg6, and seg7, exhibited premature termination of grain filling because of the necrosis and crushing of the chalaza and nucellar projection of the pericarp early in the grain-filling period, resulting in thin, wrinkled seed. Endosperm growth of these mutants before the occurrence of chalazal necrosis seemed normal. The other four mutants exhibited characteristic abnormalities in the endosperm growth pattern but normal development of matemal-origin tissues. Endosperm size was severely reduced in seg2, in which two flat columns of tissue were present with no central endosperm. Seg4 and seg5 developed distorted, disorganized endosperms of variable size. Endosperms of seg8 developed as two well-filled lobes with no central endosperm, resulting in a distinct dorsal crease. We suggest that the mutants are useful as probes to study maternal effects on endosperm development.     

A Comparative Study of Early Seed Development in Genotypes of Barley and Rye

Early seed development was studied in 17 genotypes of barley,Hordeum vulgare L., and 11 genotypes of rye, Secale cerealeL. The numbers of cells and nuclei in the embryos and endospermsof developing seeds were scored daily for 5 days after selfpollination. For embryos, the mean cell doubling times variedfrom 9.2–12.9 h for barley and 15.7–22.7 h for rye.Endosperm mitotic cycle times of both species were shortestover the first 24 h after pollination but then became longer.A non-linear correlation was found between the number of embryocells and the number of endosperm nuclei in barely and rye andis similar to that for other members of the Triticeae. Hordeum vulgare L., Secale cereale L., barley, rye, embryo, endosperm, mean cell doubling time     

Effect of Post-anthesis Drought on Cell Division and Starch Accumulation in Developing Wheat Grains

Wheat plants (Triticum aestivum L., cv. Warigal) were subjectedto 20 d of water deficit during the period of endosperm celldivision. Drought accentuated the differences in final grainweight between spikelets and between grains within spikelets.The distal grains of top spikelets were most affected by drought.The maximum number of endosperm cells was, respectively, 30and 40 per cent lower in basal grains and distal grains of draughtedplants. In basal grains of middle spikelets, the number of largestarch granules per cell was unaffected but the number of smallstarch granules per cell was 45 per cent lower in grains ofdraughted plants. The initiation of small starch granules wasmore affected than cell division because severe water deficitoccurred earlier during the former process than the latter.Final dry weight appeared to correlate well with the maximumnumber of endosperm cells, but depended also on the number ofstarch granules per cell. Consequently, the amount of dry matterper cell was not constant in both treatments. The concentration of sucrose per endosperm cell was lower onlyin the droughted distal grains of top spikelets. The supplyof sucrose to endosperm cells did not regulate the initiationof small starch granules. Triticum aestivum L., wheat, drought, grain growth, cell division, starch     

Effect of High Temperature During Grain-filling on the Structure of Developing and Malted Barley Grains

High temperatures (up to 35 °C) were applied to plants ofmalting barley,Hordeum vulgareL. (‘Schooner’) fora period of 5 d during grain-filling. Heat treatment had a profoundeffect on the structure of the mature barley grain. There wasevidence of degradation of endosperm storage products in heat-treatedgrain. Starch granule development was reduced in sub-aleuronecells following heat treatment and alterations to starch granuledistribution and growth were observed in the endosperms of thesegrains. Endosperm cell wall and crushed cell layer (CCL) developmentwere sensitive to high temperatures, with the reduced thicknessof the CCL and generally patchy Calcofluor fluorescence of endospermcell walls indicative of partial hydrolysis of ß-glucans.Increased growth of the embryo took place in heat-treated grainscompared with control grains. Endosperm texture was generallymore friable in heat-treated grains than in control grains,and these grains overmodified during malting, with considerabledegradation of starch in the form of extensive pitting of A-typestarch granules. Evidence is presented for developmental andgermination events occurring simultaneously within the developinggrain.Copyright 1998 Annals of Botany Company Barley,Hordeum vulgareL., starch granules, crushed cell layer, scutellum, embryo, fluorescence microscopy, scanning electron microscopy, confocal microscopy, malting quality.     

Response of Cultured Embryos of Phaseolus vulgaris and Hordeum vulgare to Farnesol

Excised embryos of Phaseolus vulgaris incubated in a mediumcontaining 10 mg dm^–3 farnesol showed enhanced root growthwhereas the leaves remained rudimentary At lower concentrationsof exogenous farnesol normal leaf development occurred and rootgrowth was comparable to untreated cultures. Enhanced root growthalso occurred when excised embryos of Hordeum vulgare were treatedwith farnesol but only at 10 mg dm^–3 and this treatmentdid not prevent leaf growth X-ray micro-probe analysis of leavesrevealed an increased phosphorus content in P vulgaris and adecreased sulphur content in H vulgare in comparison to untreatedplants. Hordeum vulgare L., barley, Phaseolus vulgaris, bean, embryo culture, farnesol, X-ray microprobe analysis, root growth     

Wild Oat/Barley Interactions: Varietal Differences in Competitiveness in Relation to K+ Supply

Eight cvs of barley (Hordeum vulgare L.) were separately plantedwith Wild Oats (Avena fatua L., genetically pure line CS40)in a sand culture with two external K⁺ concentrations. Substantialdifferences were observed among barley cvs in their abilityto compete with wild oat. The variety Fergus was highly competitiveat both high and low [K⁺]_e, whereas Steptoe was competitiveonly at high [K⁺]_e, and Compana was only weakly competitivewith wild oat. The differences between barley cvs were relatedto their previously reported efficiencies of K⁺ uptake and utilization. Hordeum vulgare L., Avena fatua L., barley, wild oat, competition, K⁺ nutrition, utilization efficiency     

Influence of Genotype and Environment on Growth of Barley Embryos in vitro

Isolated embryos of three contrasting barley genotypes werecultured in vitro on a range of media comprising 16 combinationsof sucrose (3–12 per cent) and 2, 4-D (0–8 mg 1^–1)concentration. Cultures were incubated at a range of temperaturesfrom 5 to 25°C and were examined after 21 days when shootlengths as well as fresh and dry weights were recorded. Therelative influence on growth of increasing concentrations ofsucrose and 2, 4-D was investigated, as was their interactionwith the incubation temperature. The genotypes were found todiffer markedly in their response to these two media components,with each parameter of growth differentially affected. Resultsare discussed in relation to the known dormancy characteristicsof these genotypes. Hordeum vulgare L., barley, embryo, dormancy, 2, 4-dichlorophenoxy acetic acid, sucrose     

Photoperiodically Induced Changes in Seed Growth Rate of Soybean as Related to Endogenous Concentrations of ABA and Sucrose in Seed Tissues

Short-day photoperiods can increase the partitioning of assimilatesto filling seeds of soybean (Glycine max L. Merr.), resultingin higher seed growth rates. The plant growth substance ABAhas been implicated in the regulation of assimilate transferwithin filling soybean seeds. Thus, we hypothesized that anincreased concentration of endogenous ABA in seeds may enhancesucrose accumulation and seed growth rate of soybeans exposedto short-day photoperiods. Plants of cv. Hood 75 were grownin a greenhouse under an 8-h short-day photoperiod (SD) until11 d after anthesis (DAA) of the first flower, when half ofthe plants were transferred to a night-interruption (NI) treatment(3 h of low-intensity light inserted into the middle of thedark period). Plants remaining in SD throughout seed developmenthad seed growth rates 43% higher than that of plants shiftedto NI (7·6 mg seed^–1 d^–1 vs. 5·3 mgseed^–1 d^–1). On a tissue-water basis, the concentrationof ABA in SD seeds increased rapidly from 7.6 µmol l^–1at 11 DAA to 65·2 µmol l^–1 at 18 DAA, butthen declined to 6·6 µmol l^–1 by 39 DAA.In contrast, the concentration of ABA increased more slowlyin NI seeds, reaching only 47·4 µmol l^–1by 18 DAA, peaking at 57·0 µmol l^–1 on 25DAA, and declining to 10·2 µmol l^–1 by 39DAA. The concentration of sucrose in SD embryos peaked at 73·5mmol l^–1 on 25 DAA and remained relatively constant forthe remainder of the seed-filling period. In NI, the concentrationof sucrose reached only 38·3 mmol 1^–1 by 25 DAA,and peaked at 61·5 µmol l^–1 on 32 DAA. Thusin both SD and NI, sucrose accumulated in embryos only afterthe peak in ABA concentration, suggesting that ABA may havestimulated sucrose movement to the seeds. The earlier accumulationof ABA and sucrose in SD suggests that ABA may have increasedassimilate availability during the critical cell-division period,thus regulating cotyledon cell number and subsequent seed growthrate for the remainder of the seed-filling period. Glycine max L. Merr. cv. Hood 75, soybean, assimilate partitioning, abscisic acid, photoperiod, source-sink     

Effects of Parental Embryo and Endosperm Mitotic Cycle Times on Development of Hybrids Between Barley and Rye

Seven different barley/rye crosses were made using genotypeshaving close (predicted compatible) or dissimilar (predictedincompatible) mean cell doubling times. The relative successof the crosses was determined by a cytological study of earlyhybrid seed development and by the yield of 16-day-old hybridembryos. The results support the hypothesis that parental developmentalrates must be similar for successful hybridization. The degenerationof the hybrid endosperm occurred earlier in the predicted incompatiblecrosses than in the more compatible ones. Fewer hybrid embryoswere harvested at day 16 from predicted incompatible crossesthan from compatible crosses. We conclude that development ofhybrid embryos depends on the early stages of endosperm developmentand that mitotic rates in parental endosperms are more importantthan in embryos. Hordeum vulgare L., Secale cereale L., barley, rye, hybrid, mean cell doubling time, embryo, endosperm     

Histological Observations on Initiation and Morphogenesis in Immature and Mature Embryo Derived Callus of Barley (Hordeum vulgare L.)

Callus was induced from immature and mature embryos of barley(cv. Haruna Nijo) on Murashige and Skoog medium containing 2mg l^-1 2,4-D and 5 mg l^-1 picloram, respectively. Paraffin sections(10 µm thick) were prepared for histology during callusinitiation and plant regeneration. Meristems were regeneratedfrom nodular compact callus (NC) derived from scutellar epidermisin immature embryos, whereas they were regenerated from NC derivedfrom epidermal cells of leaf or coleoptile bases in mature embryos.Regardless of the explant source, regeneration was predominantlythrough organogenesis, although regeneration through somaticembryogenesis infrequently occurred. Thus, the callus inducedfrom immature and mature embryos of barley was regarded as 'nodularcompact' rather than 'embryogenic'.Copyright 1995, 1999 AcademicPress Barley, callus, Hordeum vulgare, histology, immature embryo, mature embryo, regeneration     

Stomata and Mesophyll Characteristics of Barley Leaf as Affected by Light: Stereological Analysis

The anatomical structure of the second leaf blade of barley{Hordeum vulgare L. cv. Koral) was studied in plants exposedto a photosynthetic photon flux density (PPFD) of 200 µmolm^–2 s^–1 compared with those grown under 25µmolm^–2–11. Design-based stereological methods wereused for the estimation of various leaf anatomical characteristicssuch as mesophyll volume, proportion of intercellular spaces,number of mesophyll cells, mean mesophyll cell volume, and internalleaf surface area. The structure of the mesophyll was more affectedby different levels of PPFD than were the stomatal characteristics.Increased PPFD produced thicker leaves with a larger mesophyllvolume having a higher number of less elongated mesophyll cellsand a larger internal leaf surface area. Key words: Hordeum vulgare, light effect, mesophyll, stereology, stomata     

Subcellular distribution of β-amylase in developing barley endosperm

Protein bodies were isolated from maturing barley (Hordeum vulgare L. cv. Menuet) endosperm using sucrose density gradient centrifugation. Isolated protein bodies were not contaminated by other organelles such as mitochondria and microbodies, and contained a large amount of the barley storage protein, hordein, indicating that the protein bodies were prepared in high purity and were intact. Enzymatic and immunochemical analysis showed that β-amylase, which was previously thought to be localized in protein bodies, was not detected in the protein body fraction, but was found only in the cytosol fraction. The results show that β-amylase is synthesized as a cytosolic protein in maturing barley endosperm.     

Proton-Chloride Symport in Barley Roots

An increase in the acidity of the incubation medium from pH6 5 to pH 4.0 increased Cl- flux into ATP-depleted Hordeum vulgareL roots more than three times This pH-dependent Cl^– fluxwas inhibited by p-chloromercuriphenyl sulphonic acid. The effectof pH on Cl- influx was eliminated when the pH gradient wasdissipated by addition of salts of permeable weak acids, andin K-loaded roots in the presence of a protonophore togetherwith valinomycin The results support the assumption that a H⁺-Cl^–symportsystem is present in barley root cells Hordeum vulgare L., barley, excised roots, ion transport, proton-chloride symport     

Regulation of K+ Uptake and Transport to the Xylem in Barley Roots; K+ Distribution Determined by Electron Probe X-ray Microanalysis of Frozen-Hydrated Cells

Intact roots of young barley plants (Hordeum vulgare L. cv.Proctor) were induced to transport K⁺ to the xylem at rapidor slow rates. Roots were then rapidly frozen in liquid nitrogenand fractured in the zone 70 mm behind the root tip to givetransverse faces for electron probe microanalysis. With SEMvisualization, analyses were made over the cytoplasm and vacuole(or lumen) of 14 cells types along the root radius between theouter cortex and stele, with particular emphasis on the xylem,xylem parenchyma, and phloem. Data were recorded in the formof colour-coded maps and also quantitatively. For both typesof roots, K⁺ concentration was lower over the xylem and phloemthan in the remainder of the root. The concentration of K⁺ wasgreater in the vacuole than in the cytoplasm, while for P itwas the reverse. Significantly, in roots induced to transportK⁺ rapidly the concentration of K⁺ was low in the early maturingmetaxylem and protoxylem, and in the sieve tubes of the metaphloemand protophloem. The concentrations of K⁺ in various cell typesare discussed in relation to regulation of K⁺ loading of thexylem in long-distance ion transport. Key words: Ion transport, nutrient deficiency     

Effects of Far-red Light on the Labelling of Acyl Lipids during the Greening of Barley (Hordeum vulgare)

Etiolated Hordeum vulgare (barley) Plants were greened underwhite light or far-red (> 700 nm) light. Exposure to far-redlight inhibited chlorophyll synthesis (especially chlorophyllb) and the development of photosystem II which were seen whengreening took place under white light. Primary leaves were detachedand the labelling of their acyl lipids from [¹⁴C]acetate wasstudied under white light or far-red light illumination. Greeningwith far-red light caused a reduction in the radiolabellingof polyunsaturated fatty acids and diacylgalactosylglycerol.Total fatty acid labelling rates were unaffected. Phosphatidylethanolamine,which was normally poorly labelled, accounted for up to 15 percent of the total radioactivity in acyl moieties of lipids inleaves greened with far-red light. The results are discussedin connection with the role that acyl lipids may play in normalthylakoid structure and function. Hordeum vulgare, barley, acyl lipids, white light, far-red light, chloroplasts, thylakoids