Betalains in red and yellow varieties of the Andean tuber crop ulluco (Ullucus tuberosus)

The betalain pigments in ulluco (Ullucus tuberosus), a tuberous crop native to the Andes, have been investigated for the first time using LC-DAD-ESI-MS-MS(2) analyses. Five red, yellow, and red-spotted accessions introduced into New Zealand as a new food crop plus two red tetraploid lines were investigated. Thirty-two different betalains were identified. Both the yellow and red tubers were rich in yellow betaxanthins, and the most prominent among the 20 identified were histidine-betaxanthin, arginine-betaxanthin and glutamine-betaxanthin. Arginine-betaxanthin has been reported to occur naturally only once before and was found in yellow ulluco but not in the red tubers. Twelve betacyanins were found in red tubers, with roughly 50% of this content being betanin/isobetanin. Betacyanin levels were up to 70 microg/g fresh weight in red tubers, but were below quantifiable levels in yellow tubers. Betaxanthin levels were up to 50 microg/g fresh weight in yellow tubers. Interference by betacyanins in measuring levels of betaxanthins by visible spectrophotometry is discussed. Low concentrations of betalains were detected in leaves, whereas stems contained total levels similar to the tubers, with dopamine-betaxanthin and betanin being the major pigments. This is the first report describing both the betacyanin and betaxanthin patterns in a plant from the Basellaceae family.     

Effects of Nitrogen Levels and Nitrate/Ammonium Ratios on Oxalate Concentrations of Different Forms in Edible Parts of Spinach

Two hydroponic experiments were carried out to investigate the effects of nitrogen (N) levels and forms on the oxalate concentrations of different form in edible parts of spinach. Nitrogen was supplied at five levels (4, 8, 12, 16, 20 mM) in Experiment 1 and five ratios of nitrate (NO₃ ^?) to ammonium (NH₄ ⁺) (100/0, 75/25, 50/50, 25/75, 0/100) at a total N of 8 mM in Experiment 2. Biomass of spinach increased markedly from 4 mM to 8 mM N and reached the flat with further increase in N. The total oxalate and soluble oxalate in leaves and shoots (edible parts) increased significantly with increasing N levels from 4 to 12 mM, while the total oxalate and insoluble oxalate decreased markedly when N level was further increased from 12 to 20 mM. Oxalates of different forms in petioles increased first and then decreased and elevated again with increasing nitrogen levels. In the second experiment, decreasing NO₃ ^?/NH₄ ⁺ ratios markedly increased at first and then significantly decreased the biomass of spinach plants and the maximum biomass was recorded in the treatment of the NO₃ ^?/NH₄ ⁺ ratio of 50:50. The oxalate concentrations of different form in leaves and shoots were all decreased obviously as the ratio of NO₃ ^?/NH₄ ⁺ decreased from 100:0 to 0:100. Concentrations of total oxalate and soluble oxalate in petioles could be reduced by increasing ammonium proportion and were the lowest as the ratio of NO₃ ^?/NH₄ ⁺ was 50:50 and insoluble oxalate decreased as nitrate/ammonium ratio decreased. The concentrations of oxalate forms in leaves were all higher than those in petioles and soluble oxalate was predominant form of oxalates in both trials. It is evident that high biomass of spinach can be achieved and oxalate concentrations of different forms can be reduced by modulating N levels and NO₃ ^?/NH₄ ⁺ ratio, so this will benefit for human health especially for those people with a history of calcium oxalate kidney stones.     

Effects of Nitrogen and Calcium Nutrition on Oxalate Contents,Forms, and Distribution in Spinach

ABSTRACT

A hydroponic experiment was conducted to study the effects of nitrogen (N) and calcium (Ca) nutrition on oxalate contents of different forms in spinach tissues. Results showed that leaves were the main locations of oxalates in spinach. Total oxalate, soluble oxalate, and insoluble oxalate contents were highest in leaves, followed by petioles and then roots. Soluble oxalate was the dominant form of oxalate in spinach. Nitrogen and Ca²⁺ (calcium ion) concentrations could markedly affect oxalate contents. Soluble oxalate contents in leaves increased obviously with the increase of N concentration until 8 mmol L^?1, above which oxalate content started to decrease. Supplied with the same amount of N, increasing Ca²⁺ concentration reduced soluble oxalate content in leaves. Total oxalate reached the lowest with 5 mmol L^?1 of Ca²⁺ supply. Leaves and petioles had lower total oxalate and lower proportion of soluble oxalate when N and Ca²⁺ concentrations were 8 and 5 mmol L^?1.     

A preliminary study of the genetic diversity of Bolivian oca (<Emphasis Type="Italic">Oxalis tuberosa</Emphasis> Mol.) varieties maintained<Emphasis Type="Italic"> in situ</Emphasis> and<Emphasis Type="Italic"> ex situ</Emphasis> through the utilization of ISSR molecular markers

ISSR molecular markers have been used to investigate genetic diversity of oca (Oxalis tuberosa Mol.), an Andean neglected tuber crop species. Sampling procedure allowed a preliminary study of the genetic diversity at the intra- and intervarietal levels. Twenty tuber lots conserved in situ in the microcentre of Candelaria and ex situ in the Toralapa Centre (Bolivia) were identified. Four ISSR primers amplified a total of 25 fragments of which 17 (68%) were polymorphic. These experiments show that the structure of oca varieties is mainly based upon vernacular names with a greater differentiation among tuber lots than within them, supporting agromorphological data. ISSR technique enlightened the existence of heterogeneous varieties in oca and divergence between in situ and ex situ conservation strategies. These observations are potentially linked to the different ways of management of tubers in these two conservation systems.     

Evaluation of an anion exchange resin method for plant available molybdenum in New Zealand soils

Abstract

Molybdenum (Mo) extracted from 31 New Zealand soils by an anion exchange resin method (resin Mo) was compared with that extracted by Tamm's oxalate (oxalate Mo). The amounts extracted by the two methods were correlated but, on average, oxalate Mo was 7 times resin Mo. Resin Mo was correlated with relative yield and Mo uptake of lucerne, although correlations were not high. Oxalate Mo was not correlated with plant data. Inclusion of pH in multiple regressions improved correlations with relative yield for both methods but the prediction equations accounted for only 30–35% of the variation. It is concluded that the resin method, although better than the oxalate method, is not sufficiently accurate for diagnosis of Mo deficiency’ in New Zealand pastoral soils.     

氮素形态对菠菜可食部分硝酸盐和草酸累积的影响

采用溶液培养试验研究了营养液中硝态氮/铵态氮比例对菠菜地上部可食部分不同器官硝酸盐以及不同形态草酸累积的影响。结果表明,菠菜地上部生物量随供铵比例从0%提高到50%呈增加趋势而后显著下降。叶片和地上部可食部分的硝酸盐含量和累积量均随供铵比例增加而显著下降;叶柄的硝酸盐含量随供铵比例提高而降低,而硝酸盐积累量则先升高后显著下降。叶片是菠菜积累草酸的主要器官,可溶态草酸与草酸总量分别占地上部的56.3%～89.8%和76.6%～87.4%。可溶态草酸是菠菜体内草酸的主要形态,在叶片、叶柄及地上部中所占草酸总量的比例分别在36.7%～83.5%,79.0%～93.3%以及50.0%～83.0%之间。地上部各器官的可溶态草酸含量、难溶态草酸含量和草酸总量以及积累量均随着供铵比例的增加而显著下降,叶片和地上部的草酸含量和积累量的下降幅度均高于叶柄。可见,调节营养液中硝态氮/铵态氮比例可以有效降低菠菜地上部可食部分硝酸盐和草酸的含量和积累量,50/50是营养液中适宜的硝态氮/铵态氮比例,不仅菠菜的生物量最高,而且硝酸盐和各形态草酸的含量以及累积量较低,从而大大减轻了硝酸盐和草酸对人体健康产生的负面影响。     

Oxalate in grain amaranth

Grain amaranth (Amaranthus spp.) is a widely adaptable C4 pseudo-cereal crop that has interesting nutritional characteristics including high protein and calcium concentrations and a lack of gluten. To date, no antinutrient has been found at problematic levels in grain amaranth; however, oxalate has not been thoroughly studied. Dietary oxalate is a potential risk factor for kidney stone development, and its presence in food lowers calcium and magnesium availability. Oxalate concentration and forms and calcium and magnesium concentrations were determined in 30 field-grown grain amaranth genotypes from the species A. cruentus, A. hybrid, and A. hypochondriacus. The effects of seeding date and fertilization with calcium ammonium nitrate were evaluated in field experiments conducted in multiple environments; the effects of cooking were also evaluated. Mean total oxalate concentration in the 30 genotypes analyzed was 229 mg/100 g, with values ranging between 178 and 278 mg/100 g, the greatest proportion being insoluble (average of 80%). Calcium concentration averaged 186 mg/100 g and ranged between 134 and 370 mg/100 g, whereas magnesium averaged 280 mg/100 g and ranged between 230 and 387 mg/100 g. Fertilization only marginally increased total oxalate concentration and had no effects on other variables. Seeding date had no effects on any of the variables studied. Boiling increased the proportion of soluble oxalate but did not affect total oxalate concentration. Grain amaranth can be considered a high oxalate source, however, as most is in insoluble form, and due to its high calcium and magnesium concentrations, oxalate absorbability could be low. This should be confirmed by bioavailability studies.     

Effect of different cooking methods on vegetable oxalate content

Approximately 75% of all kidney stones are composed primarily of calcium oxalate, and hyperoxaluria is a primary risk factor for this disorder. Nine types of raw and cooked vegetables were analyzed for oxalate using an enzymatic method. There was a high proportion of water-soluble oxalate in most of the tested raw vegetables. Boiling markedly reduced soluble oxalate content by 30-87% and was more effective than steaming (5-53%) and baking (used only for potatoes, no oxalate loss). An assessment of the oxalate content of cooking water used for boiling and steaming revealed an approximately 100% recovery of oxalate losses. The losses of insoluble oxalate during cooking varied greatly, ranging from 0 to 74%. Because soluble sources of oxalate appear to be better absorbed than insoluble sources, employing cooking methods that significantly reduce soluble oxalate may be an effective strategy for decreasing oxaluria in individuals predisposed to the development of kidney stones.     

Root-zone temperature influences the distribution of Cu and Zn in potato-plant organs.

Root-zone temperatures (RZT) in relation to Cu and Zn uptake and tissue accumulation, and to total biomass, in potato plants (Solanum tuberosum L. var. Spunta) were studied. Using five different plastic mulches (no cover, transparent polyethylene, white polyethylene, coextruded white-black polyethylene, and black polyethylene) resulted in significantly different RZT (16, 20, 23, 27, and 30 degrees C, respectively). These RZT significantly influenced Cu and Zn content (concentrated) and the biomass in various potato organs. Root-zone temperature at 20 degrees C resulted in significantly high Cu content in leaflets, and soluble Cu content in leaflets and stems, whereas 23 and 27 degrees C resulted in significantly high Cu content in roots. However, RZT had no effect on Cu content in tubers or stems or on soluble Cu in roots or tubers. The RZT at 20 degrees C resulted in significantly high Zn and soluble Zn in stems, roots, and tubers; whereas, at 27 degrees C Zn and soluble Zn content were significantly highest in leaflets. The most biomass occurred in roots and tubers at 27 degrees C; whereas in leaves and stems, the RZT influence was highly variable. Total accumulation of both Cu forms was affected by RZT at 20 degrees C, with roots and tubers having significantly the least Cu and stems and leaflets having the most. Total accumulation of both Zn forms by RZT in potato organs was highly variable, but tubers consistently accumulated the most.     

Oxalate content of cereals and cereal products

Detailed knowledge of food oxalate content is of essential importance for dietary treatment of recurrent calcium oxalate urolithiasis. Dietary oxalate can contribute considerably to the amount of urinary oxalate excretion. Because cereal foods play an important role in daily nutrition, the soluble and total oxalate contents of various types of cereal grains, milling products, bread, pastries, and pasta were analyzed using an HPLC-enzyme-reactor method. A high total oxalate content (>50 mg/100 g) was found in whole grain wheat species Triticum durum (76.6 mg/100 g), Triticum sativum (71.2 mg/100 g), and Triticum aestivum (53.3 mg/100 g). Total oxalate content was comparably high in whole grain products of T. aestivum, that is, wheat flakes and flour, as well as in whole grain products of T. durum, that is, couscous, bulgur, and pasta. The highest oxalate content was demonstrated for wheat bran (457.4 mg/100 g). The higher oxalate content in whole grain than in refined grain cereals suggests that oxalic acid is primarily located in the outer layers of cereal grains. Cereals and cereal products contribute to the daily oxalate intake to a considerable extent. Vegetarian diets may contain high amounts of oxalate when whole grain wheat and wheat products are ingested. Recommendations for prevention of recurrence of calcium oxalate stone disease have to take into account the oxalate content of these foodstuffs.     

供氮水平对菠菜产量、硝酸盐和草酸累积的影响

采用溶液培养方法研究了不同供氮水平对菠菜生物量、硝酸盐和不同形态草酸含量的影响。结果表明,供氮水平由4.mmol/L增加到8.mmol/L,菠菜产量显著增加,继续提高氮水平对产量没有显著影响。叶片中的维生素C(Vc)含量随着供氮浓度从4.mmol/L提高到8.mmol/L而显著增加,再增加氮水平,叶片中的Vc含量明显下降;而菠菜叶柄Vc的含量则随供氮水平的提高显著下降。叶片硝酸盐含量随着氮浓度的提高而增加,当供氮水平由4mmol/L增加到8.mmol/L时,叶柄硝酸盐含量显著下降,而氮水平由8.mmol/L提高到20.mmol/L时,叶柄硝酸盐含量则随之升高。供氮浓度从4.mmol/L增加到8.mmol/L,叶片可溶态草酸含量略有下降,再提高供氮水平则明显上升,供氮水平低于12.mmol/L时,叶柄中的可溶态草酸和菠菜叶片和叶柄中的草酸总量则随着氮水平的提高而升高,高于12.mmol/L草酸含量反而降低。由此可见,菠菜在供氮浓度为8mmol/L(N2)时能够获得较高的产量和Vc含量,较低的硝酸盐和草酸含量,表明适宜的供氮水平下可获得高产优质的菠菜。     

Oxalate content of soybean seeds (Glycine max: Leguminosae), soyfoods, and other edible legumes

Consumption of soybeans and food products made from them is increasing because of their desirable nutritional value. However, the oxalate content of seeds from 11 cultivars of soybean showed relatively high levels of total oxalate from 0.67 to 3.5 g/100 g of dry weight. Oxalate primarily was found as calcium oxalate crystals. Thirteen tested commercial soyfoods contained between 16 and 638 mg of total oxalate per serving. These values compare to those of three other legume foods, peanut butter, refried beans, and lentils, which contained 197, 193, and 100 mg of total oxalate per serving, respectively. After oxalate has been absorbed from the diet, it cannot be metabolized and is excreted by the kidney into urine, where it binds to calcium forming an insoluble salt that may precipitate to form kidney stones. The amounts of total oxalate in soybean seeds, soy foods, and other common legume foods exceed current recommendations for oxalate consumption by individuals who have a history of calcium oxalate kidney/urinary stones. This study serves as the basis to find soybean cultivars lower in oxalate, which will have lower risk for kidney stone formation after human consumption.     

Identification of podzols and podzolised soils in New Zealand by relative absorbance of oxalate extracts of A and B horizons

A method for separating podzols and podzolised soils from other New Zealand soils is proposed. The method is based on measurement of the optical density of acid oxalate extracts of soils. A number of soil leaching sequences and some individual soils are examined.It is assumed that the optical density of the oxalate extracts is due mainly to extracted fulvic acid and that detection of appreciable quantities of this material in the B horizon indicates that podzolisation is an active process in the soil.The technique separated the soils of the leaching sequences well, following the observable increase of podzolic characteristics with increased leaching.When the B horizon/A horizon ODOE (optical density of the oxalate extracts) ratios were compared with the criteria for the spodic horizon in “Soil Taxonomy” (Soil Survey Staff, 1975), it was found that all soils with a ratio of less than 1.0 did not satisfy spodic horizon criteria and were not classified as podzol/podzolised. All the soils examined with ratios > 1.0 satisfied spodic horizon criteria or were classified as podzol/podzolised, usually both.     

Biodegradation of oxalic acid from spinach using cereal radicles

A high level of oxalate intake constitutes a health risk for infants and metabolically disposed adults. Spinach, acclaimed for its many health benefits, is among the vegetables richest in oxalate. Blanching reduces oxalate unsatisfactorily and unspecifically. An alternative, biological method is proposed on the basis of rye seedlings or radicles (also barley and wheat) containing an oxalate-specific oxalate oxidase by nature. Dissolved oxalate (0.25 mM) was rapidly degraded in the presence of radicles (e.g., 70% within 100 min). With commercial deep-frozen spinach, near-complete degradation of soluble oxalate was achieved at pH 3.5. The total level of oxalate was reduced by half. Similarly high rates occurred from 18 to 35 degrees C. Even at 55 degrees C appreciable rates were observed. The seedling as a whole is effective, too, and enrichment with cereal-specific healthy components would occur. Removal of oxalate from other vegetables, juices, cycled process waters, or feeds is conceivable with fresh or heat-dried cereal seedlings or radicles.     

施氮对块茎形成期高温胁迫后马铃薯块茎产量、淀粉含量和相关酶代谢活性的影响

为了明确不同施氮量对高温胁迫后马铃薯块茎淀粉合成酶、淀粉含量及产量的影响,本研究于2019-2020年在宁南山区海原县进行田间试验.供试品种为青薯9号,通过搭建高温棚构建高温环境,设2个温度处理(T1:块茎形成初期高温胁迫,T2:自然温度),4个氮肥水平(不施氮N0:0 kg·hm-2,低氮水平N1:75 kg·hm-...     

Oxalate-metabolizing microorganisms in sagebrush steppe soil

Oxalate metabolization by soil microorganisms was assessed using a calcium oxalate clearing medium and¹⁴CO₂ release from [¹⁴C]-oxalate. Three saprophytic fungi, two bacteria, and one actinomycete tested produced¹⁴CO₂ when grown in culture with [¹⁴C]-oxalate, yet failed to test positive for oxalate degradation using a calcium-clearing medium. A field plot was then established to determine the effects of oxalate inputs on oxalate metabolism. The amount of [¹⁴C]-oxalate metabolized by soil microorganisms and the number of bacteria metabolizing oxalate increased within 24 h after the addition of oxalic acid at a concentration of 11.1 mol g^-1 soil. Oxalate metabolism and bacterial numbers returned to the baseline within 84 days. Soil phosphate concentrations increased significantly above baseline 7 days after the addition of oxalate and did not return to prespike levels. Fungi, bacteria, and actinomycetes were able to metabolize oxalate. Therefore, while oxalate can influence P cycles by increasing the amount of available phosphates, that increase is mediated by microbes that metabolize the oxalates.     

Effect of selenate supplementation on glycoalkaloid content of potato (Solanum tuberosum L.)

Potatoes (Solanum tuberosum L.) supplemented with increasing amounts of sodium selenate were analyzed for glycoalkaloid (GA) content. GAs were extracted with 5% acetic acid from freeze-dried tubers of two potato cultivars, Satu and Sini, harvested 10 weeks after planting as immature. The GAs alpha-solanine and alpha-chaconine were quantified by reverse-phase high-performance liquid chromatography (RP-HPLC) with diode array detection. Two independent experiments were performed. In the first experiment, the total GA concentration +/- standard error of the tubers ranged between 105 +/- 9 and 124 +/- 10 mg kg(-1) fresh weight in Satu and between 194 +/- 26 and 228 +/- 10 mg kg(-1) fresh weight in Sini. The ratio of alpha-solanine to alpha-chaconine was 0.2 in Satu and 0.5-0.6 in Sini. In the second experiment, the total GA concentration +/- standard error was 75 +/- 4 to 96 +/- 11 mg kg(-1) fresh weight, and the ratio of alpha-solanine to alpha-chaconine was 0.3-0.4 in Satu. A high sodium selenate supplementation (0.9 mg of Se kg(-1) quartz sand) slightly decreased the GA content in Satu, but this decrease was not statistically significant. Furthermore, at this addition level the Se concentration increased to a very high level of 20 microg g(-1) dry weight, which cannot be recommended for human consumption. In both experiments, the Se concentration in tubers increased with increasing sodium selenate application levels. Our results show that acceptable application levels of selenate did not have an effect on the GA concentration in immature potato tubers.     

Distribution of selenium in different biochemical fractions and raw darkening degree of potato (Solanum tuberosum L.) tubers supplemented with selenate

Effects of Se fertilization on potato processing quality, possible changes in Se concentration and form in tubers during storage, and retransfer of Se from seed tubers were examined. Potato plants were grown at five selenate (SeO4(2-)) concentrations. Tubers were harvested 16 weeks after planting and were stored at 3-4 degrees C prior to analysis. The results showed that the Se concentration did not decrease during storage for 1-12 months. In tubers, 49-65% of total Se was allocated in protein fraction, which is less than found in plant leaves in a previous study. The next-generation tubers produced by the Se-enriched seed tubers had increased Se concentrations, which evidenced the relocation of Se from the seed tubers. At low levels, Se improved the processing quality of potato tubers by diminishing and retarding their raw darkening. The value of Se-enriched potato tubers as a Se source in the human diet was discussed.