Evaluation of effectiveness various seed processing combination technique to produce True Shallot Seed (TSS) with good quality

The seed processing technique is essential to maintain quality and suppress seed deterioration rate as long as processing time. This research aims to evaluate various seed processing combination techniques to produce TSS with good quality. The study was conducted at Indonesian Vegetables Research Institute, Lembang (1,250 m sal) from March until December 2018. The research used a Randomized Complete Block Design (RCBD) with three replications. The treatment consisted of 12 combinations of seed processing, including the technique of drying, capsule breaking, and sorting. The research result showed that the best treatment was a combination technique with umbels drying in the room at RH 50 % and 30-35°C for 72 hours, breaking capsule by hand manually, and seed sorting by winnower followed by hand manually. The produced seed quality in this treatment showed the seed germination was 75%, the moisture content was 7.5%, and the physical purity was 99.9%. This research implies that the availability of TSS processing technology can be carried out by massal, but still can produce good seed quality.

Accelerated Ageing Mediated Seed Longevity Prediction and Assessment of Seed Deterioration Pattern through 2D-Gel Electrophoresis in Chickpea (Cicer arietinum L.)

Background: Accelerated ageing is a method to assess seed storage performance by exposing the seeds to higher temperature and relative humidity to make seeds lose its vigour and viability quickly. The seed physiological parameters are then compared with the natural ageing to derive certain conclusions. But, the molecular pattern of seed deterioration under accelerated ageing varies compared to that of natural ageing.Methods: Chickpea, seed lots of variety JG-11 and Annigeri-1 were subjected to natural ageing in cloth bag with nine per cent initial seed moisture under ambient conditions. Simultaneously, representative sample of same seed lot were also aged at 41oC and 95±2% humidity up to 120 hours.Result: Both the ageing methods had significant negative effect on seed physiological and biochemical quality parameters. The germination potential of seeds tested after 48 hours of accelerated ageing (83.5%) was equal 10 months of natural ageing (85%) in JG-11, while also in Annigeri-1, 48 hours of accelerated ageing (78%) was nearly equal to 10 months of natural ageing (80%). The protein expression analyzed through 2D-PAGE at similar germination potential brought out by two independent ageing methods showed higher protein down regulation ratio (3.4) in accelerated ageing than in natural ageing (3.2) unveiling its rapidity in the seed deterioration process. Therefore, accelerated ageing can be used for predicting chickpea seed longevity.

High Drying Temperature Accelerates Sunflower Seed Deterioration by Regulating the Fatty Acid Metabolism, Glycometabolism, and Abscisic Acid/Gibberellin Balance

Sunflower seed storage is accompanied by the loss of seed vigor. Seed drying is a key link between seed harvest and seed storage; however, to date, the effect of seed drying on sunflower seed deterioration during storage remains unclear. The present study performed hot air drying for sunflower seeds with an initial moisture content of 30% to examine the manner in which drying temperature (35, 40, 45, 50, and 55°C) affects the drying performance and seed vigor following storage process (6 and 12 months). A drying temperature of 40°C was evidently safe for sunflower seeds, whereas the high drying temperatures (HTD, 45, 50, and 55°C) significantly lowered sunflower seed vigor by regulating the fatty acid metabolism, glycometabolism, and abscisic acid (ABA)/gibberellin (GA) balance. HDT significantly increased the seed damage rate and accelerated sunflower seed deterioration during natural and artificial aging process. Further biochemical analysis indicated that HDT significantly increased lipoxygenase and dioxygenase activities, leading to malonaldehyde and reactive oxygen species over-accumulation during storage. During early seed germination, HDT significantly inhibited fatty acid hydrolysis and glycometabolism by decreasing triacylglycerol lipase, CoA-SH oxidase, and invertase activities. Moreover, HDT remarkably increased ABA levels but reduced GA levels by regulating gene expressions and metabolic enzyme activities during early imbibitions. Cumulatively, the seed drying effect on sunflower seed vigor deterioration during the storage process may be strongly related to fatty acid oxidation and hydrolysis metabolism, toxic substance accumulation, and ABA/GA balance.

Óleos essenciais sobre a qualidade de sementes de leucena

<span class="fontstyle0">Leucena (Leucaena leucocephala) is an alternative used for animal feeding in the Northeastern of Brazil due to its resistance to drought and its high nutritional value. They are forest species whose seeds are affected by fungi that cause abnormalities and damage to seedlings, seed deterioration. The objective of this study was to evaluate the efficiency of essential oils in reducing the incidence of fungi associated with L. leucocephala seeds and their interference with physiological quality. The treatments were the following: essential oils of Cymbopogon nardus, Boswellia carteri, Eucalyptus globulus, Helianthus annuus, Vitis vinifera seeds, Eugenia caryophyllata, Melaleuca alternifolia and Rosmarinus officinalis in a concentration of 1 mL · L</span><span class="fontstyle0">-1 </span><span class="fontstyle0">and fungicide, using 100 seeds per treatment.In order to overcome dormancy scarification with sandpaper Nº 100 in the opposite region to the micropile. The sanitary quality of the seeds was made with the incubation method in Petri dishes containing double layer of filter paper moistened with ADE. Seed physiological quality was determined based on seed germination, emergence and vigor tests. The experimental design was completely randomized with ten treatments. Eucalyptus, clove and Melaleuca alternifolia essential oils reduced the incidence percentage of fungi associated with leucena seeds. Melaleuca alternifolia essential oil reduced the physiological quality of leucena seeds.</span> <br /><br />

Biochemical Investigations on Vigour Enhancement in Fresh and Aged Seeds Upon Seed Priming in Cowpea [Vigna unguiculata (L.) Walp.]

Background: Loss in seed quality that occurs from maturity in the field to storage, leads to seed deterioration. Storage of cowpea seeds under ambient, hot and humid conditions is very problematic since these conditions deteriorate seed quality faster. Seed deterioration is associated with many metabolic defects that occur due to changes in enzyme and protein levels. Method: The present study was performed to verify the effects of cowpea [Vigna unguiculata (L.) Walp.] seed priming (GA3, ammonium molybdate, Ca Cl2, KBr, Mg (NO3)2, ZnSO4, Hydro priming and dry non primed) with fresh and accelerated aged seeds.Result: The deterioration was rectified to the extent possible by the technique of seed priming. SDS PAGE profiling indicated the differential expression of proteins with seed priming. Esterase and peroxidase enzyme which were completely lost as a result of ageing showed reappearance after priming. The band intensity as well as the number of proteins induced by seed priming increased over control. Priming also restored the lost seed vigour in aged seeds due to reactivation of proteins in old seeds and expression of these proteins in priming treatments are related to priming induced proteins in contrast to their absence in the aged seeds which are necessary for germination and longevity of seeds. The present study concluded that priming with GA3 (100 ppm) and Ammonium Molybdate (10-3 M) for 24 hours in aged seeds of cowpea showed increase enzyme activity, restored almost entire protein profile and esterase and peroxidise isozyme profile as it allowed repair system to combat sub-cellular damage and activated synthesis of enzymes and proteins.

Cytoplasmic physical state governs the influence of oxygen on Pinus densiflora seed ageing

During desiccation, the cytoplasm of orthodox seeds solidifies in a glass with highly restricted diffusion and molecular mobility, which extend longevity. Temperature and moisture determine seed cellular physical state, and O2 can promote deteriorative reactions of seed ageing. However, whether seed physical state affects O2-mediated biochemical reactions during ageing remains unknown. Here, we answered this question using oil-rich Pinus densiflora seeds aged by controlled deterioration (CD) at 45 °C and distinct relative humidities (RHs), resulting in a glassy (9 and 33% RH) or fluid (64 and 85% RH) cytoplasm. Regardless of CD regimes, the cellular lipid domain remained always fluid. Hypoxia (0.4% O2) prevented seed deterioration only in the glassy state, limiting non-enzymatic lipid peroxidation, consumption of antioxidants (glutathione, tocopherols) and unsaturated fatty acids, accompanied by decreased lipid melt enthalpy and lower concentrations of aldehydes and reactive electrophile species (RES). In contrast, a fluid cytoplasm promoted faster seed deterioration and enabled the resumption of enzymatic activities implicated in glutathione metabolism and RES detoxification, regardless of O2 availability. Furthermore, seeds stored under dry/cold seed bank conditions showed biochemical profiles similar to those of CD-aged seeds with glassy cytoplasm under normoxia. These findings are discussed in the context of germplasm management.

Physiological Characteristics of Field Bean Seeds (Vicia faba var. minor) Subjected to 30 Years of Storage

Seed vigour and viability, synchronous fluorescence spectroscopy, and proteomic profiles were analysed in field bean (Vicia faba var. minor) (Vicia faba var. minor) seeds (two cultivars) subjected to dry storage at −14 °C or +20 °C for 30 years. The seeds stored at −14 °C retained very high germinability (91–98%) until the end of the experiments, while seeds from the same lots but stored at room temperature completely lost viability. The deterioration of seeds stored at +20 °C was also manifested by a vast (4- to 6-fold) increase in leachate electroconductivity, and the changes in synchronous spectra and proteomic profiles. To carry out detailed analyses of seed proteins, protein extracts were pre-purified and divided into albumin, vicilin, and legumin. Only one protein, superoxide dismutase, was more abundant in deteriorated seeds (of one cultivar) compared to the high vigour seeds. The results show that seed deterioration strongly and specifically affects the contents of some storage proteins. Moreover, the colour of seed coats changes gradually, and seeds stored at −14 °C were light brown, while those constantly exposed to +20 °C turned black. Synchronous fluorescence spectroscopy showed that this change of colour was caused by formation of oxidized and condensed phenols and that the phenol content in seed coats decreased parallel to seed deterioration.

Effect of Seed Ageing in Biochemical and Molecular Changes in Oilseeds: A Review

Seed deterioration is the loss of quality, viability and vigour either due to ageing or effect of adverse environmental factors. The process of deterioration is an irresistible physiological phenomenon. The seeds which are stored under suitable conditions may sometime undergo a series of changes which can ultimately result in the deterioration of the quality of the seed. Hence a thorough study should be done in these deteriorative changes so that proper measures can be adopted to control the variations. Therefore in this article the changes within cellular, biochemical and metabolic aspects of long term stored oilseeds are discussed.

Variation in Seed Metabolites between Two Indica Rice Accessions Differing in Seed Longevity

For a better understanding of germination after seed storage, metabolite profiling was conducted using hybrid triple quadrupole time-of-flight (QTOF) mass spectrometry. After moisture content (MC) equilibration, seeds of “WAS170” (short-lived) and “IR65483” (long-lived) were stored at 10.9% MC and 45 °C. Samples for metabolite analysis were taken after 0 and 20 days of storage. Among 288 metabolites, two flavonoids (kaempferide and quercetin-3-arabinoside), one amino acid (S-sulfocysteine) and one sugar (D-glucose) increased in “IR65483” seeds after storage but were not detected in “WAS170” seeds. Based on the genome sequence database, we identified clear allelic differences with non-synonymous mutations on the six flavonol synthase genes regulating the accumulation of kaempferol- and quercetin-metabolites. On the other hand, two metabolites (thiamine monophosphate and harmaline) increased in short-lived seeds after storage; these metabolites could be potential biochemical indicators of seed deterioration.