Turnover of starch-bound lysophosphatidylcholine in germinating barley

Free and starch-bound lysophosphatidylcholine (LPC) in germinating barley was isolated and quantified during the first 8 days of germination. During the first 4 days the starch-bound LPC remained at a relatively constant level (ca 0.4,μmol/seed) and then declined during the next 2 days to ca 0.1 μmol/seed. There appeared to be no further loss of this starch-bound lipid on further germination. The decrease in the content of starch-bound LPC is not due to the action of phospholipase C and/or D on the starch lipid because there was no corresponding accumulation of starchbound lysophosphatidic acid or monoacylglycerol. The free LPC remained relatively constant at 0.02 to 0.04 μmol/seed during the entire germination period indicating that the LPC released from the starch during days 5 and 6 is further metabolized. Amylase activity was also measured in the germinating seed and increased 20-fold between days 2 and 4 which just precedes the rapid decline in starch-bound LPC. The starch content of the seed however declined to ca one third of the original value by day 5. LPC represents 65–70 % of the starch-bound lipid phosphorus in the dry seed. Through days 5 and 6 when the loss of LPC is most rapid there is no marked change in this percentage. After 8 days, however, the LPC is only ca 30%. of the starch-bound lipid phosphorus. Ofthe two major populations of starch-bound LPC, the one bearing a linoleyl group appears to decline more rapidly during days 4–6 than does that carrying a palmitoyl group. The role of starch-bound LPC in barley development and germination is discussed.     

Lysophosphatidylcholine biosynthesis in developing barley

Acetate-2-[¹⁴C] and choline-Me-[ ¹⁴C], absorbed through the stems of isolated barley heads, were used to label lysophosphatidylcholine (LPC) and phosphatidylcholine (PC) of the endosperm tissue. Labelling of LPC occurred in barley heads at almost all stages of development but was at a maximum when the fr. wt of the seeds had attained ca 60–70% of their maximum wt. In time-course experiments labelling of PC from each substrate reached a maximum after 50 hr and then declined. Label in LPC, however, continued to accumulate throughout 72 hr. Stimulation of labelling of LPC from choline-Me-[¹⁴C] by sucrose was observed. A bound form of LPC (starch lipid) and a free form were distinguished by differential solvent extraction.     

Starch Granule Re-Structuring by Starch Branching Enzyme and Glucan Water Dikinase Modulation Affects Caryopsis Physiology and Metabolism

Starch is of fundamental importance for plant development and reproduction and its optimized molecular assembly is potentially necessary for correct starch metabolism. Re-structuring of starch granules in-planta can therefore potentially affect plant metabolism. Modulation of granule micro-structure was achieved by decreasing starch branching and increasing starch-bound phosphate content in the barley caryopsis starch by RNAi suppression of all three Starch Branching Enzyme (SBE) isoforms or overexpression of potato Glucan Water Dikinase (GWD). The resulting lines displayed Amylose-Only (AO) and Hyper-Phosphorylated (HP) starch chemotypes, respectively. We studied the influence of these alterations on primary metabolism, grain composition, starch structural features and starch granule morphology over caryopsis development at 10, 20 and 30 days after pollination (DAP) and at grain maturity. While HP showed relatively little effect, AO showed significant reduction in starch accumulation with re-direction to protein and β-glucan (BG) accumulation. Metabolite profiling indicated significantly higher sugar accumulation in AO, with re-partitioning of carbon to accumulate amino acids, and interestingly it also had high levels of some important stress-related metabolites and potentially protective metabolites, possibly to elude deleterious effects. Investigations on starch molecular structure revealed significant increase in starch phosphate and amylose content in HP and AO respectively with obvious differences in starch granule morphology at maturity. The results demonstrate that decreasing the storage starch branching resulted in metabolic adjustments and re-directions, tuning to evade deleterious effects on caryopsis physiology and plant performance while only little effect was evident by increasing starch-bound phosphate as a result of overexpressing GWD.     

Genetic dissection of grain beta-glucan and amylose content in barley (Hordeum vulgare L.)

High beta-glucan (BG) barleys (Hordeum vulgare L.) have major potential as food ingredients due to their well-known health benefits. Quantitative trait loci (QTL) associated with BG have been reported in traditional barley varieties with intermediate levels of BG, but no QTL studies have been reported in hull-less barley varieties with high BG levels. In this study, QTL analysis was performed to identify markers linked to high BG and amylose in the hull-less barley varieties Falcon (4–5 % BG) and Azhul (8–9 % BG) using a newly developed recombinant inbred line (RIL) mapping population. The population was grown over 3 years (2007–2009) at sites in Yuma, AZ, USA; Leeston, New Zealand; Aberdeen, ID, USA; and Tetonia, ID, USA. We identified 17 QTL associated with either BG or amylose content. QTL contributing to high BG were located on chromosomes 3H, 4H, 5H, 6H and 7H, while QTL contributing to amylose were located on chromosomes 1H, 5H and 7H. Additionally, we identified QTL affecting both BG and amylose content located on chromosomes 1H and 7H. Transgressive segregation was observed in some of the RILs and exceptions were discovered contradicting an inverse relationship between BG and amylose. This work will provide the basis for gene cloning and marker-assisted selection in combination with traditional field selection to improve barley breeding for high BG content.     

Soluble and particulate lysophospholipase in the aleurone and endosperm of germinating barley

Lysophospholipase was measured in extracts of germinating barley by determining the amount of free [¹⁴C]palmitate released from [1-¹⁴C] 1-palmitoyl-lysophosphatidylcholine (LPC). Soluble and particulate lysophospholipase activity was measured at 1-day intervals in extracts from the aleurone and endosperm of barley seeds germinated for 8 days. The soluble and particulate activities of the aleurone increase approximately in parallel with one another and after 8 days of germination have 20–30 times more activity than at day 1. The activity profiles and the distribution of the activity between the soluble and particulate forms of lysophospholipase in the endosperm are markedly different. With the exception of the first 2 days when the aleurone activity is low, the endosperm activity is less than that associated with the aleurone. The soluble activity increases during the first 3 days and is more active than that of the aleurone. Thereafter it diminishes and remains low. The particulate enzyme, however, increases dramatically between days 4 and 5 and remains moderately high. The fourth and fifth day represent that stage of germination when starch-bound LPC is released in concert with the increase in amylase activity. It is proposed that it is this particulate form of the endosperm activity which may be responsible for maintaining the level of free LPC low in the endosperm of the germinating seed.     

Starch biosynthesis of amylomaize during endosperm development

In an attempt to investigate starch biosynthesis of amylomaize, the endosperm starches from four genotypes with different doses of amylose-extender (ae) between 0 and 3 were isolated at 14, 18, 22, 28, and 36 days after pollination, and their properties were examined. Gene effects of ae on the endosperm starches were found in the apparent amylose content from measurements of iodine binding capacity and in the elution pattern from fractionation of starches debranched by isoamylase on Sephadex G-75. With increasing doses of ae, the lengths of two side-chain fractions of amylopectin in the original starch granule and the carbohydrate content of shorter side-chain fraction both increased. However, the length of each side chain fraction varied little between 14 and 36 days in all genotypes. In addition, the amylose content in ae homozygous at the 14-day stage was ca 24 % lower than the value of amylose and intermediate fractions in the original starch granule.     

Influence of different carbohydrate composition in barley varieties on Salmonella Typhimurium var. Copenhagen colonisation in a "Trojan" challenge model in pigs

Based on previously performed in vitro studies, which showed that hulless barley varieties could reduce large intestinal Salmonella Typhimurium var. Copenhagen proliferation in pigs, two in vivo experiments were conducted to prove these observations. In Experiment (Exp.) 1, 126 weaning piglets were randomly allocated into pens of seven animals each and fed one of six experimental diets. Three diets contained (75% as-fed) one of three hulless barley varieties with beta-glucan (BG) contents ranging from 5 to 11% and amylose from 5 to 40%, and two diets contained a low BG and amylose hulless barley supplemented with isolated barley BG or raw potato starch. A hulled barley diet served as a control. Two piglets per pen ("Trojan" pigs) were orally infected with Salmonella Typhimurium var. Copenhagen (ST). The remaining five pigs per pen were designated "Contact" pigs. The ST shedding was determined over one week after infection. On day 6, the two Trojans and two random Contacts from each pen were euthanised and intestinal contents and mesenteric lymph nodes cultured for ST. Intestinal volatile fatty acids and microbial composition were determined. In Exp. 2, 126 piglets were assigned to one of three diets based on hulled or hulless barleys. The timeline, infection, sampling and analyses were similar as in Exp. 1 except samples were taken from four Contact pigs. Hulless barley varieties with high BG and amylose tended to decrease ST persistence in Exp. 1. Clostridia from cluster I in the colon were reduced with high amylose hulless barley or diets supplemented with potato starch (p < 0.05), whereas other microbial groups were not. Propionate increased (p < 0.05) and acetate decreased (p < 0.05) with hulless barley inclusion. Exp. 2 revealed a reduced ST shedding and reduced number of clostridia for high BG hulless barley as compared to common hulled barley and a low BG variety (p < 0.05). In conclusion, high BG hulless barley do not prevent ST colonisation but might help to reduce transmission in pigs, likely by supporting an intestinal environment limiting growth of this zoopathogen.     

Secretion of a lipolytic protein aggregate by barley aleurone and its dissociation by starchy endosperm

Acidic and basic lysophospholipase activities (LPL) have been separated by ion-exchange chromatography of barley extracts. The basic activity predominates in the starchy endosperm of germinating barley and in the medium of hormone-stimulated half-seeds; the acidic activity is the predominant form in the medium of hormone-stimulated aleurone layers. Addition of either starchy endosperm or EDTA to the acidic activity produces the basic activity. The two activities display the same pH optimum and have similar Km values. Inactivation profiles of LPLs with immunoglobulin G (IgG) prepared against the purified basic LPL are the same. The acidic LPL obtained from the incubation medium from stimulated aleurone layers appears in the void volume on gel filtration with Bio-Gel P100. Acid phosphatase and alpha-amylase in the same incubation medium appear at their expected elution volumes on this column. Gel filtration in the presence of EDTA results in the acidic activity eluting in a volume characteristic of the basic LPL (Mr, 40,000). On Bio-Gel P300 the acidic activity peak is centered at Mr, 160,000. SDS-gel electrophoresis of fractions across this peak shows a simple distribution of proteins eluting with Mr greater than or equal to 160,000. The potential role of an aggregate in the secretion of lipolytic proteins is discussed.     

Ruminal starch digestion characteristics in vitro of barley cultivars with varying amylose content

Three experiments were conducted to study effects of amylose/amylopectin ratios and starch particle size on ruminal digestion characteristics of barley starch using an automated in vitro gas production system. In Experiment 1, starch digestion characteristics were measured in 12 barley cultivars with different amylose/amylopectin ratios, both as milled grain and as purified starch isolated from the original grain samples. The same 12 cultivars, harvested 1 year later from the same locations, were used in Experiment 2. Gas production was measured in milled samples, and in neutral detergent fibre (NDF) extracted from the same samples. The objective of this approach was to estimate gas production from neutral detergent solubles (NDS) as an approximation of starch. This was done by subtracting the NDF gas curve from the total gas production curve. In Experiment 3, starch digestion characteristics were measured for large and small starch granules from nine of the original cultivars used in Experiment 1. The gas curves obtained were fitted to a three-pool Gompertz model, and the effective rate of digestion (kd) was estimated with a two-compartmental rumen model. In Experiment 1, the effective starch kd for milled barley and purified starch were 0.122 and 0.118/h, respectively. Barley cultivars with low amylose (LA) had a higher effective kd (0.148/h) compared with cultivars with normal amylose (NA) (0.115/h) and high amylose (HA) (0.102/h) (P=0.010). Results obtained with milled barley were supported by the purified barley starch sample results, but differences were smaller and only numerically different. In Experiment 2, the ranking of the amylose groups was consistent with those in Experiment 1 (i.e., LA > NA > HA) (P=0.096). However, these differences were not reflected in the effective kd for the NDS fraction (P=0.366). Thus, factors other than those related to starch per se, or other structural features, are apparently important. Barley cultivars in the LA group had a higher effective kd for aNDF (0.098/h) than did NA and HA barley (0.060 and 0.055/h, respectively). Thus, the effect of the amylose group on the effective kd for aNDF corresponded well with the milled barley results. The NDF fraction, directly or indirectly, has a clear impact on the ruminal digestion rate of barley starch. There was no difference in the effective kd for starch between the small (0.126/h) and large (0.129/h) starch granules.     

The passage and absorption of dietary and endogenous nitrogen in different regions of the digestive tract of rats given a single meal of 15N-labelled barley

Based on previously performed in vitro studies, which showed that hulless barley varieties could reduce large intestinal Salmonella Typhimurium var. Copenhagen proliferation in pigs, two in vivo experiments were conducted to prove these observations. In Experiment (Exp.) 1, 126 weaning piglets were randomly allocated into pens of seven animals each and fed one of six experimental diets. Three diets contained (75% as-fed) one of three hulless barley varieties with β-glucan (BG) contents ranging from 5 to 11% and amylose from 5 to 40%, and two diets contained a low BG and amylose hulless barley supplemented with isolated barley BG or raw potato starch. A hulled barley diet served as a control. Two piglets per pen (“Trojan” pigs) were orally infected with Salmonella Typhimurium var. Copenhagen (ST). The remaining five pigs per pen were designated “Contact” pigs. The ST shedding was determined over one week after infection. On day 6, the two Trojans and two random Contacts from each pen were euthanised and intestinal contents and mesenteric lymph nodes cultured for ST. Intestinal volatile fatty acids and microbial composition were determined. In Exp. 2, 126 piglets were assigned to one of three diets based on hulled or hulless barleys. The timeline, infection, sampling and analyses were similar as in Exp. 1 except samples were taken from four Contact pigs. Hulless barley varieties with high BG and amylose tended to decrease ST persistence in Exp. 1. Clostridia from cluster I in the colon were reduced with high amylose hulless barley or diets supplemented with potato starch (p < 0.05), whereas other microbial groups were not. Propionate increased (p < 0.05) and acetate decreased (p < 0.05) with hulless barley inclusion. Exp. 2 revealed a reduced ST shedding and reduced number of clostridia for high BG hulless barley as compared to common hulled barley and a low BG variety (p < 0.05). In conclusion, high BG hulless barley do not prevent ST colonisation but might help to reduce transmission in pigs, likely by supporting an intestinal environment limiting growth of this zoopathogen.     

Effect of phytase supplementation on phosphorus digestibility in low-phytate barley fed to finishing pigs

Forty crossbred barrows (Camborough 15 Line female x Canabred sire) weighing an average of 79.6 +/- 8.0 kg were used in a factorial design experiment (5 barleys x 2 enzyme levels) conducted to determine the effects of phytase supplementation on nutrient digestibility in low-phytate barleys fed to finishing pigs. The pigs were assigned to one of 10 dietary treatments comprised of a normal 2-rowed, hulled variety of barley (CDC Fleet, 0.26% phytate) or 2 low-phytate hulled genotypes designated as LP422 (0.14% phytate) and LP635 (0.09% phytate). A normal, hulless barley (CDC Dawn, 0.26% phytate) and a hulless genotype designated as LP422H (0.14% phytate) were also included. All barleys were fed with and without phytase (Natuphos 5000 FTU/kg). The diets fed contained 98% barley, 0.5% vitamin premix, 0.5% trace mineral premix, 0.5% NaCl and 0.5% chromic oxide but no supplemental phosphorus. The marked feed was provided for a 7-day acclimatization period, followed by a 3-day faecal collection. In the absence of phytase, phosphorus digestibility increased substantially (P < 0.05) as the level of phytate in the barley declined. For the hulled varieties, phosphorus digestibility increased from 12.9% for the normal barley (0.26% phytate) to 35.3 and 39.8% for the two low-phytate genotypes (0.14 and 0.09% phytate respectively). For the hulless varieties, phosphorus digestibility increased from 9.2% for the normal barley (0.26% phytate) to 34.7% for the hulless variety with 54% of the normal level of phytate (0.14% phytate). In contrast, when phytase was added to the diet, there was little difference in phosphorus digestibility between pigs fed normal barley and those fed the low-phytate genotypes (significant barley x enzyme interaction, P = 0.01). For the hulled varieties, phosphorus digestibility was 50.1% for the barley with the normal level of phytate (0.26% phytate) compared with 51.1 and 52.4% for the varieties with 54 and 35% of the normal level of phytate (0.14 and 0.09% phytate respectively). For the hulless varieties, phosphorus digestibility increased from 47.1% for the normal barley (0.26% phytate) to 54.4% for the hulless variety with 54% of the normal level of phytate (0.14% phytate). In conclusion, both supplementation with phytase and selection for low-phytate genotypes of barley were successful in increasing the digestibility of phosphorus for pigs. Unfortunately, the effects did not appear to be additive. Whether or not swine producers will choose low-phytate barley or supplementation with phytase as a means to improve phosphorus utilization, will likely depend on the yield potential of low-phytate barley and the additional costs associated with supplementation with phytase.     

Developmental Changes in the Amylose Content of Endosperm Starch of Barley (Hordeum vulgare L.) during the Grain Filling Period after Anthesis

Large and small starch granules were isolated and characterized from kernels of non-waxy (Bozu) and waxy (Yatomi mochi) barleys at their developmental stages of 8, 16, 28 and 40 days after flowering. The amylose content of the large and small granules of the non-waxy barley starch, as determined by the blue value and enzyme-chromatography, increased with the increasing age of the endosperm. Large granules of the non-waxy barley at any given developmental stage contained more amylose than small granules at the same stage, as in the case of mature non-waxy barley starches. Large granules of either the non-waxy or waxy barleys at any given developmental stage had a lower fraction III: fraction II ratio, one of the structural characteristics of amylopectin, than did small granules of the same cultivar at the same developmental stage. The amylose content in large granules of the waxy barley appeared to increase with the increasing age of the endosperm. The amylose content in small granules of the waxy barley at 8 days after flowering was 10%, although that at 16 and 28 days after flowering and at maturity was only 0~1%.     

Characterization of barley starches of waxy, normal, and high amylose varieties

Four varieties of barley starches, W.B. Merlin, glacier, high amylose glacier, and high amylose hull-less glacier, were isolated from barley seeds. Apparent and absolute amylose contents, molecular size distributions of amylose and amylopectin, amylopectin branch-chain-length distributions, and Naegeli dextrin structures of the starches were analyzed. W.B. Merlin amylopectin had the longest detectable chain length of DP 67, whereas glacier, high amylose glacier and high amylose hull-less glacier amylopectins had the longest detectable chain length of DP 82, 79, and 78, respectively. All the four starches displayed a substantially reduced proportion of chains at DP 18–21. Amylopectins of high amylose varieties did not show significantly larger proportions of long chains than that of normal and waxy barley starch. Onset gelatinization temperatures of all four barley starches ranged from 55.0 to 56.5°C. Absolute amylose contents of W.B. Merlin, glacier, high amylose glacier, and high amylose hull-less glacier were 9.1, 29.5, 44.7, and 43.4%, respectively; phospholipid contents were 0.36, 0.78, 0.79, and 0.97%, respectively.     

Effect of phytase supplementation on phosphorus digestibility in low-phytate barley fed to finishing pigs

Forty crossbred barrows (Camborough 15 Line female×Canabred sire) weighing an average of 79.6±8.0?kg were used in a factorial design experiment (5 barleys×2 enzyme levels) conducted to determine the effects of phytase supplementation on nutrient digestibility in low-phytate barleys fed to finishing pigs. The pigs were assigned to one of 10 dietary treatments comprised of a normal 2-rowed, hulled variety of barley (CDC Fleet, 0.26% phytate) or 2 low-phytate hulled genotypes designated as LP422 (0.14% phytate) and LP635 (0.09% phytate). A normal, hulless barley (CDC Dawn, 0.26% phytate) and a hulless genotype designated as LP422H (0.14% phytate) were also included. All barleys were fed with and without phytase (Natuphos 5000 FTU/kg). The diets fed contained 98% barley, 0.5% vitamin premix, 0.5% trace mineral premix, 0.5% NaCl and 0.5% chromic oxide but no supplemental phosphorus. The marked feed was provided for a 7-day acclimatization period, followed by a 3-day faecal collection. In the absence of phytase, phosphorus digestibility increased substantially (P<0.05) as the level of phytate in the barley declined. For the hulled varieties, phosphorus digestibility increased from 12.9% for the normal barley (0.26% phytate) to 35.3 and 39.8% for the two low-phytate genotypes (0.14 and 0.09% phytate respectively). For the hulless varieties, phosphorus digestibility increased from 9.2% for the normal barley (0.26% phytate) to 34.7% for the hulless variety with 54% of the normal level of phytate (0.14% phytate). In contrast, when phytase was added to the diet, there was little difference in phosphorus digestibility between pigs fed normal barley and those fed the low-phytate genotypes (significant barley×enzyme interaction, P=0.01). For the hulled varieties, phosphorus digestibility was 50.1% for the barley with the normal level of phytate (0.26% phytate) compared with 51.1 and 52.4% for the varieties with 54 and 35% of the normal level of phytate (0.14 and 0.09% phytate respectively). For the hulless varieties, phosphorus digestibility increased from 47.1% for the normal barley (0.26% phytate) to 54.4% for the hulless variety with 54% of the normal level of phytate (0.14% phytate). In conclusion, both supplementation with phytase and selection for low-phytate genotypes of barley were successful in increasing the digestibility of phosphorus for pigs. Unfortunately, the effects did not appear to be additive. Whether or not swine producers will choose low-phytate barley or supplementation with phytase as a means to improve phosphorus utilization, will likely depend on the yield potential of low-phytate barley and the additional costs associated with supplementation with phytase.     

Gibberellin-like Substances in Developing Barley Grain and Their Relation to Dry Weight Increase

Gibberellin-like activity of two varieties of barley (Hordeum vulgare L.) at different stages of grain development was determined by barley endosperm bioassay (acid phosphatase bioassay). Activity of the acidic ethyl-acetate fraction (“free” GAs) in both varieties displayed two maxima, a first maximum at the 9th day and a second one 20 to 21 days after pollination. Activity of the n-butanol fraction (“bound” GAs) first dropped to a minimum level at the 9th day, then increased to reach a maximum 32 days after pollination, and finally decreased again towards maturity. From the 9th day after pollination, a conversion of “free” GAs to “bound” GAs has probably occurred. From the 12th day after pollination, the curves of rate of dry weight increase and of “free” GAs run nearly parallel, but the latter reached its maximum about 2–4 days earlier than the former. The results indicate that gibberellins may participate in the regulation of the accumulation processes into the barley grain.     

Lipase Activities in Castor Bean Endosperm during Germination

Two lipases were found in extracts from castor bean (Ricinus communis L.) endosperm. One, with optimal activity at pH 5.0 (acid lipase), was present in dry seeds and displayed high activity during the first 2 days of germination. The second, with an alkaline pH optimum (alkaline lipase), was particularly active during days 3 to 5. When total homogenates of endosperm were fractionated into fat layer, supernatant, and particulate fractions, the acid lipase was recovered in the fat layer, and the alkaline lipase was located primarily in the particulate fraction. Sucrose density gradient centrifugation showed that the alkaline lipase was located mainly in glyoxysomes, with some 30% of the activity in the endoplasmic reticulum. When glyoxysomes were broken by osmotic shock and exposed to KCl, which solubilizes most of the enzymes, the alkaline lipase remained particulate and was recovered with the glyoxysomal “ghosts” at equilibrium density 1.21 g/cm³ on the sucrose gradient. Association of the lipase with the gly-oxysomal membrane was supported by the responses to detergents and to butanol. The alkaline lipase hydrolyzed only monosubstituted glycerols. The roles of the two lipases in lipid utilization during germination of castor bean are discussed.     

Production of very-high-amylose potato starch by inhibition of SBE A and B

High-amylose starch is in great demand by the starch industry for its unique functional properties. However, very few high-amylose crop varieties are commercially available. In this paper we describe the generation of very-high-amylose potato starch by genetic modification. We achieved this by simultaneously inhibiting two isoforms of starch branching enzyme to below 1% of the wild-type activities. Starch granule morphology and composition were noticeably altered. Normal, high-molecular-weight amylopectin was absent, whereas the amylose content was increased to levels comparable to the highest commercially available maize starches. In addition, the phosphorus content of the starch was increased more than fivefold. This unique starch, with its high amylose, low amylopectin, and high phosphorus levels, offers novel properties for food and industrial applications.     

Phospholipid changes in wheat and barley leaves under water stress

Total phospholipid content of leaves of wheat and barley increased and phospholipid components changed under water stress. Notable among these were the absence of phosphatidyl serine in barley varieties, decrease in phosphatidyl glycerol content in a less drought-tolerant variety of wheat (S-308) and barley (BG-25), and appearance of phosphatidic acid in both crops. The phospholipid content and its components did not return to normal upon release of the stress by subsequent irrigations. Such observations are indicative of water stress effected alterations in membranes.     

Enzymes of starch metabolism in the developing rice grain

The levels of starch, soluble sugars, protein, and enzymes involved in starch metabolism—α-amylase, β-amylase, phosphorylase, Q-enzyme, R-enzyme, and starch synthetase —were assayed in dehulled developing rice grains (Oryzasativa L., variety IR8). Phosphorylase, Q-enzyme, and R-enzyme had peak activities 10 days after flowering, whereas α- and β-amylases had maximal activities 14 days after flowering. Starch synthetase bound to the starch granule increased in activity up to 21 days after flowering. These enzymes (except the starch synthetases) were also detected by polyacrylamide gel electrophoresis. Their activity in grains at the midmilky stage (8-10 days after flowering) was determined in five pairs of lines with low and high amylose content from different crosses. The samples had similar levels of amylases, phosphorylase, R-enzyme, and Q-enzyme. The samples consistently differed in their levels of starch synthetase bound to the starch granule, which was proportional to amylose content. Granule-bound starch synthetase may be responsible for the integrity of amylose in the developing starch granule.