Temperature is a key factor influencing plant growth and productivity, however sudden increases in temperature can cause severe consequences in terms of crop performance. We evaluated the influence of elementary sulfur application on the physiology and growth of two tomato genotypes (“Ahmar” and “Roma”) grown in two growth chambers (at 25 and 45 °C). Plants were sprayed with 2, 4, 6, and 8 ppm sulfur 45 days after sowing (untreated plants were kept as control). Plants of the “Roma” cultivar receiving 6 ppm sulfur exhibited maximal shoot and root biomass values followed by those receiving 4 ppm under both temperature conditions. Maximal CO2 index, photosynthetic rate, transpiration rate, and greenness index values (188.1 µmol mol−1, 36.3 µmol CO2 m−2 s−1, 1.8 µmol H2O m−2 s−1, and 95 SPAD, respectively) were observed in plants of “Roma” cultivar grown at 25 °C, indicating positive influences of sulfur on tomato physiology. Similarly, sulfur maximized proline, nitrogen, phosphorus, and potassium contents in leaves of both genotypes at both temperatures. The differences between control and sulfur-treated plants grown under heat stress indicate a possible role of sulfur in mitigating heat stress. Overall, our results suggest that 6 ppm of sulfur is the best dose to alleviate tomato heat stress and enhance the morphological, physiological, and biochemical attributes of tomato plants.
Phytohormones mediate physiological, morphological, and enzymatic responses and are important regulators of plant growth and development at different stages. Even though temperature is one of the most important abiotic stressors for plant development and production, a spike in the temperature may have disastrous repercussions for crop performance. Physiology and growth of two tomato genotypes ('Ahmar' and 'Roma') were studied in two growth chambers (25 and 45 °C) when gibberellic acid (GA3) was applied exogenously. After the 45 days of planting, tomato plants were sprayed with GA3 at concentrations of 25, 50, 75, and 100 mg L−1, whereas untreated plants were kept as control. Under both temperature conditions, shoot and root biomass was greatest in 'Roma' plants receiving 75 mg L−1 GA3, followed by 50 mg L−1 GA3. Maximum CO2 index, photosynthetic rate, transpiration rate, and greenness index were recorded in 'Roma' plants cultivated at 25 °C, demonstrating good effects of GA3 on tomato physiology. Likewise, GA3 enhanced the proline, nitrogen, phosphorus, and potassium levels in the leaves of both genotypes at both temperatures. Foliar-sprayed GA3 up to 100 mg L−1 alleviated the oxidative stress, as inferred from the lower concentrations of MDA and H2O2, and boosted the activities of superoxide dismutase, peroxidase, catalase. The difference between control and GA3-treated heat-stressed plants suggests that GA3 may have a function in mitigating heat stress. Overall, our findings indicate that 75 mg L−1 of GA3 is the optimal dosage to reduce heat stress in tomatoes and improve their morphological, physiological, and biochemical characteristics.
ESRD patients on hemodialysis develop various skin changes during the course of disease process, which contribute to increased morbidity. Different factors affecting skin changes were the cause of ESRD, adequacy and duration of dialysis, employment, financial status, anti HCV positivity, and metabolic factors.
Delicate fruit of strawberry is susceptible to high temperature stress and fungal infection. An extensive spray program is usually adapted to secure yield and fruit quality which sometimes pose a serious threat to consumer health. However, development of eco-friendly, economical and safer strategies has always been in focus of R&D sector. In this study, field-grown strawberry plants cv. Chandler were sprayed with 1, 2 or 3 mM oxalic acid at flowering stage. Interestingly, foliar application of oxalic acid in low doses (1 mM and 2 mM) had more growth-promoting effect on strawberries whereas foliar application of 3 mM oxalic acid either negatively affected or remained ineffective. Low-dose applications of oxalic acid resulted in enhanced nitrogen (1.5-fold), phosphorus (2.5-fold) and potassium (1.75-fold) levels in leaf petioles. Increase in primary macronutrients was also correlated well with enhancement in plant growth indicators including dry biomass (1.5-fold), leaf area (1.7-fold), specific leaf area (2.8-fold) and leaf area ratio (2.6-fold), root weight ratio (1.9-fold), root-to-shoot ratio (1.4-fold). Only, leaf chlorophyll and fresh fruit weight were negatively impacted by oxalic acid. In addition to increase in number of fruits per plant, oxalic acid also improved sensory properties of strawberry fruits mainly due to increase in sugar: acid ratio (1.6-fold), ascorbic acid contents (1.2-fold) and non-reducing sugars (2-fold). Overall, foliar application of 1 mM oxalic acid favoured vegetative growth and enhanced yield and fruit quality of strawberry cv. Chandler.
Marigold is one of the commercially exploited flowering crops that belongs to the family Asteraceae. The production of economical yield and better quality of marigold flowers requires proper crop management techniques. Crop regulation is an important technique to make the marigold production profitable. This can be done by adopting application of plant growth regulators (PGRs). The present study was designed to investigate the effect of PGRs on flowering and antioxidant activity of two cultivars of African marigold (Tagetes erecta L.) viz. “Pusa Narangi Gainda” (hereinafter referred to as Narangi) and “Pusa Basanthi Gainda” (hereafter referred to as Basanthi). Plants were sprayed with abscisic acid (ABA), N-acetyl thiazolidine (NAD), gibberellic acid (GA3), salicylic acid (SA), indole-3-butyric acid (IBA) and oxalic acid (OA) at the concentrations of 100, 150, 250, 300 and 800 mg·L−1, each. Results revealed that the plants treated with 500–600 mg·L−1 IBA exhibited maximum increase in floral diameter (34–51%). The use of 500–550 mg·L−1 IBA exhibited maximal enhancement in flower fresh weight (21–92%). The exogenously applied OA significantly (p ≤ 0.05) improved flower dry weight, total phenolic contents, total flavonoid contents and reducing power ability of marigold plants. Overall, “Narangi” performed better than “Basanthi”, in terms of flowering and antioxidant activity. Conclusively, the results suggest that foliar application of PGRs favors flowering and antioxidant activity of African marigold.
Phosphoenolpyruvate carboxylase (PEPC) genes have multiple potential roles in plant metabolism such as regulation and accumulation of organic acids in fruits, movement of guard cells and stress tolerance, etc. However, the systematic identification and characterization of PEPC genes in Rosaceae species i.e., loquat, apple, peach, strawberry, and pear are yet to be performed. In present study, 27 putative PEPC genes (loquat 4, apple 6, peach 3, strawberry 9, and pear 5) were identified. To further investigate the role of those PEPC genes, comprehensive bioinformatics and expression analysis were performed. In bioinformatic analysis, the physiochemical properties, conserved domains, gene structure, conserved motif, phylogenetic and syntenic analysis of PEPC genes were performed. The result revealed that the PEPcase superfamily domain was conserved in all examined PEPC proteins. Most of the PEPC proteins were predicted to be localized in cytonuclear. Genomic structural and motif analysis showed that the exon and motif number of each PEPC gene ranged dramatically, from 8 to 20, and 7 to 10, respectively. Syntenic analysis indicated that the segmental or whole-genome duplication played a vital role in extension of PEPC gene family in Rosacea species. The Ka and Ks values of duplicated genes depicted that PEPC genes have undergone a strong purifying selection. Furthermore, the expression analysis of PEPC genes in root, mature leaf, stem, full-bloom flower, and ripened fruit of loquat, apple, peach, strawberry, and pear was performed. Some genes were differentially expressed in aforementioned plant tissues, signifying their role in plant metabolism. This study provides the first genome-wide identification, characterization, and expression profiling of PEPC gene family in Rosaceae species, and provides the foundation for further functional analysis.
Poor crop establishment is one of the major constraints to obtain the higher potential of rice, particularly in areas prone to environmental stresses. Therefore, present study was conducted to evaluate the effects of potassium nitrate on germination dynamics, seedling growth and associated physiological and biochemical events of two rice cultivars. For this purpose, various seed priming treatments were tested in lab and greenhouse. The percent concentrations of potassium nitrate were 0.25, 0.50, 0.75, 1.0 and 1.25 in both lab evaluation and greenhouse experiment. Non-primed seeds were maintained as a control for comparison. The results depicted that soaking rice seeds at higher concentrations of KNO3 could delay emergence time and final emergence (%) in both cultivars under lab and greenhouse conditions. Seed priming with 0.75% KNO3 significantly increased the stand establishment and seedling vigor attributes of both cultivars compared with other concentrations and naked rice seeds both in lab evaluation and greenhouse screening. Similarly, highest values for photosynthesis rate, evaporation rate and CO2 index were observed in experimental units receiving primed seeds with 0.75% KNO3 under greenhouse screening. Interestingly, no variance was observed among both rice cultivars. Overall, higher seed emergence, seedling vigor and associated biochemical attributes due to seed priming with 0.75% KNO3 was associated with decrease in alcohol dehydrogenase (ADH) and pyruvate decarboxylase (PDH) activities in lab and greenhouse screening. Keywords: Seed priming, potassium nitrate, seed quality, stand establishment, vigor Introduction Rice is an important cereal crop that serve as staple food for almost half of the world population (Chun et al. 2020; Zafar et al. 2020). Its germination is affected under various environmental stresses which causes poor yield (Zafar et al. 2015; Zafar et al. 2018). Poor germination is the problem often faced by different farmers of rice, especially when the seed is broadcasted in dry condition. Under unfavorable and harsh environmental condition, seed priming method is the best technique which help the seed to germinate easily. It enhances the germination chances and boost up the process (Ahmed et al., 2019), and is a cheaper solution to overcome poor stand establishment (Farooq et al., 2009; Harris et al., 1999). It has been reported that the seed priming is very helpful in improving germination rate of many crops i.e., rice, wheat, maize and canola (Basra et al., 2005). The germination percentage and dry weight of seedlings of safflower was increased by seed priming (Razaji et al., 2012). It has been reported that the inferior quality of wheat could also grow well after seed priming (Hussian et al., 2013). Increase in germination rate, uniformity in process, improved plant growth and yield, and better physiological performance are included in the beneficial aspects of seed priming (Farooq et al., 2007; Ruan et al., 2002). The seed priming principle is based on the behavior of seed towards water absorption; water is very important factor for seed germination and growth. The water intake of seed is divided into three phases. First phase includes the intake of water by seed and activation of enzymes. In 2nd phase, after activation of enzymes, several processes such as food deprivation, cell membrane restructuring and biosynthesis of starch occur to support seedling and root growth. In final phase, the growth of root and shoot organs i.e., radicle and plumule takes place (Bewley et al., 2013). There are three categories of seed priming techniques; (1) hydro-priming – priming with simple water, (2) solid-matrix priming – priming with solid organic material and (3) osmopriming – priming with priming solutions e.g., potassium nitrate (KNO3), potassium chloride (KCl) and polyethylene glycol (PEG) (McKersie, 2002; Mohammadi, 2009). PEG and KNO3 are commonly used in priming studies, but PEG is more expensive than KNO3. In a previous study, it was demonstrated that the osmopriming of seed of soybean with KNO3 at the concentration of 6 g/L increased the germination percentage and dry weight of seedling (Ahmadvand et al., 2012). Similarly, seed priming with 1.0% KNO3 for 24 h at 20°C enhance the germination rate and improved the physiological quality of soybean (Mohammadi, 2009). Moreover, it has also been reported that the seed priming could improve the protein synthesis during early growth of embryo (Xu et al., 2009). Here in this study, the aim was to evaluate the effect of seed priming with different concentrations of KNO3 (0.25%, 0.50%, 0.75%, 1.0% and 1.25% (w/v) KNO3 for 1 day at 25°C) on the stand establishment, seedling vigor, physiological and biochemical attributes of two rice cultivars. Materials and Methods Seed Source: Seed of Indica rice (Oryza sativa L.) cultivars viz., Basmati-515 and Basmati-385 were obtained from Rice Research Institute, Kala Shah Kaku, Punjab, Pakistan. The initial germination and seed moisture content prior to seed treatment was ˃80% and 12% respectively on dry weight basis. Seed Priming Treatments: Rice seeds were primed with 0.25%, 0.50%, 0.75%, 1.0% and 1.25% (w/v) KNO3 for 24 h at 25°C. Pre-weighed seeds (5g) were placed on two blotter papers in 9-cm diameter petri dishes saturated with appropriate concentration of osmotic solutions followed by covering of dishes with aluminum foil. Non-primed rice seeds were maintained as control for comparison. Seeds were stored at -4°C in paper bags, prior to experimentation. Experimental Site and Conditions: Lab experiment was conducted in the growth chamber of Seed Preservation Lab, National Agricultural Research Centre, Islamabad, Pakistan during September 2019 to October 2019. While, greenhouse experiment was conducted at the research station of National Agricultural Research Centre, Islamabad, Pakistan during September 2019 to November 2019. Well pulverized soil was collected from the field of research station and each plastic pot 35cm×25cm×15cm in size was filled with 6kg of soil. After leveling the soil surface in each pot, moisture was applied up to field capacity. In each pot, 40 seeds were equally sown on the soil surface in both experiments. Both experiments were laid out in a completely randomized design with four replications. For lab screening, all the trays were placed in the growth chamber with a constant temperature of 25°C and a light period of 12h. The relative humidity during the complete execution of lab experiment was maintained at 65%. For greenhouse experiment, all the trays were placed in greenhouse under natural environmental conditions. Moisture was applied to each try when declined. Stand Establishment: Emergence was recorded on daily basis until a constant was achieved. Final emergence (%) was taken at the end of experiment (AOSA, 1990). Mean emergence time (days) was recorded as per the equation of ISTA (2015). Seedling Vigor: Seedling length of five randomly selected from each treatment was measured with the help of measuring tape and averaged to get mean length. Similarly, fresh and dry weight of these plants was measured on a weighing balance. For dry weight, plants were dried at 70°C till constant weight in an oven (Zafar et al., 2015). Physiological Parameters: Measurements of CO2 index (µmol mol-1), net photosynthetic rate (µmol CO2 m-2 s-1) and evaporation rate (µmol H2O m-2 s-1) were made on a fully expanded leaf from top by using an open system LCA-4 ADC (USA) portable infrared gas analyzer. Biochemical Attributes: To determine the activities of alcohol dehydrogenase and pyruvate decarboxylase, seedling samples were ground and detected by an alcohol dehydrogenase assay kit and a pyruvate decarboxylase test kit. Statistical Analysis: The data from growth chamber and greenhouse experiments are presented as the mean value ± standard error of four replicates. By using Statistix 9.0, analysis of variance for all the treatments was performed. Graphical presentation of data was performed by using SigmaPlot 14.0. Results Lab Screening Stand Establishment: Seed priming treatments maximally improved the final emergence (%) of both rice cultivars under well-controlled conditions. Highest values for final emergence (%) were recorded in experimental units (Cultivar 1 (V1)=96%, Cultivar 2 (V2)=98%) receiving rice seed primed with 0.75% KNO3 as compared to control. Seed priming with 1% KNO3 was also proved to be beneficial in both cultivars (V1=89%, V2=90%) for improving final emergence (%). No variance in final emergence was observed among experimental units receiving rice seed primed 0.50% and 1% KNO3 in V2 cultivar (Fig. 1a). Similarly, minimum mean emergence time (MET) was recorded in rice seeds primed with 0.75% followed by 1% KNO3. Highest values for MET was recorded in control in both cultivars (Fig. 1b). Collectively, statistical analysis of data revealed that seed primed with KNO3 proved better in improving stand establishment of both rice cultivars as compared to control. Seedling Vigor: Seedling length of both rice cultivars is graphically presented in Fig. 2a and data revealed that maximum seedling vigor in both cultivars was achieved in rice seeds primed with 0.75% (V1=8.10cm, V2=8.24cm) followed by 1% (V1=7.88cm, V2=7.91cm) and 0.50% (V1=7.43cm, V2=7.69cm) KNO3 solutions as compared to control (V1=6.83cm, V2=6.71cm) (Fig. 2a). Seed priming with KNO3 also proved effective in improving the seedling fresh and dry weight, nonetheless effect of different cultivars was not pronounced. Plants in both cultivars raised from seeds treated with 0.75% KNO3 depicted highest values for seedling fresh (V1=34.45mg, V2=37.67mg) (Fig. 2b) and dry weight (V1=18.12mg, V2=19.01mg) as compared to other treatments and control (Fig. 2c). No apparent difference in seedling fresh and dry weight was observed among rice seed treated with 0.50% and 1.0% KNO3 in both cultivars. Greenhouse Screening Stand Establishment: A variable trend of primed and non-primed final emergence (%) was observed in both cultivars under greenhouse screening. Rice seed in both cultivars treated with 0.75% KNO3 steadily depicted highest values for final emergence (V1=95%, V2=98%), while an opposite drift was examined in control (V1=77%, V2=80%). Rice seeds treated with 1% KNO3 also proved to be successful in both cultivars (V1=88%, V2=91%) for improving final emergence (%) under greenhouse conditions. No variance in final emergence was observed among experimental units receiving rice seed primed 0.50% and 1% KNO3 in both cultivars (Fig. 3a). However, minimum mean emergence time (MET) was recorded in rice seeds primed with 0.75% followed by 1% KNO3 in both cultivars compared to other treatments and control. In addition, both cultivars showed highest values for MET in experimental units receiving control (Fig. 3b). Seedling Vigor: Statistical analysis of data pertaining to seedling vigor depicted that the effect of seed priming treatments was significant in both cultivars. However, both cultivars did not exhibit pronounced effect on seedling vigor. All priming treatments significantly improved the seedling length in both cultivars, whereas maximum seedling was achieved in rice seed primed with 0.75% (V1=7.90cm, V2=8.09cm) followed by 1% (V1=7.65cm, V2=7.74cm) KNO3 solutions. Furthermore, lowest vales for seedling length in both cultivars was observed in control (V1=6.41cm, V2=6.51cm) (Fig. 3a). Plants in both cultivars raised from seeds treated with 0.75% KNO3 depicted highest values for seedling fresh (V1=33.45mg, V2=36.54mg) (Fig. 3b) and dry weight (V1=16.78mg, V2=19.99mg) as compared to other treatments and control (Fig. 3c). Overall, statistical analysis of data revealed that seed priming with 0.75% KNO3 proved successful in improving seedling vigor of both rice cultivars as compared to other treatments and control. Physiological and Biochemical Attributes: Analysis of variance of data showed that seed priming treatments significantly improved the physiological and biochemical attributes of both cultivars, while effect of cultivars was not significant. Highest photosynthesis rate, evaporation rate and CO2 were observed in rice seeds treated with 0.75% KNO3, whereas lowest values were examined in non-treated control. Statistical analysis of data demonstrated that PDH and ADH activities were significantly influenced by seed priming treatments. Though all the seed priming treatments proved successful for improving the biochemical attributes however lowest values were observed in experimental units receiving rice seed treated with 0.75% KNO3 under greenhouse screening. Highest values for PDH and ADH activities were observed in control (Table 1). Figure 3. Effect of seed priming with KNO3 on stand establishment of two rice cultivars in greenhouse. V1=Basmati-515, V2=Basmati=385: T0=Control, T1=0.25% KNO3, T2=0.50% KNO3, T3=0.75% KNO3, T4=1.0% KNO3, T5=1.25% KNO3. Seedling Vigor: Statistical analysis of data pertaining to seedling vigor depicted that the effect of seed priming treatments was significant in both cultivars. However, both cultivars did not exhibit pronounced effect on seedling vigor. All priming treatments significantly improved the seedling length in both cultivars, whereas maximum seedling was achieved in rice seed primed with 0.75% (V1=7.90cm, V2=8.09cm) followed by 1% (V1=7.65cm, V2=7.74cm) KNO3 solutions. Furthermore, lowest vales for seedling length in both cultivars was observed in control (V1=6.41cm, V2=6.51cm) (Fig. 4a). Plants in both cultivars raised from seeds treated with 0.75% KNO3 depicted highest values for seedling fresh (V1=33.45mg, V2=36.54mg) (Fig. 4b) and dry weight (V1=16.78mg, V2=19.99mg) as compared to other treatments and control (Fig. 4c). Overall, statistical analysis of data revealed that seed priming with 0.75% KNO3 proved successful in improving seedling vigor of both rice cultivars as compared to other treatments and control. Figure 4. Seedling vigor attributes of two cultivars of rice under the influence of seed priming with KNO3 in greenhouse. V1=Basmati-515, V2=Basmati=385: T0=Control, T1=0.25% KNO3, T2=0.50% KNO3, T3=0.75% KNO3, T4=1.0% KNO3, T5=1.25% KNO3. Table 1. Variations in physiological and biochemical attributes of two rice cultivars under the influence of seed priming with KNO3 in lab. Cultivars Treatments Physiological attributes Biochemical attributes Photosynthesis rate (µmol CO2 m-2 s-1) Evaporation rate (µmol H2O m-2 s-1) CO2 index (µmol mol-1) Alcohol dehydrogenase (Ug-1 FW) Pyruvate decarboxylase (U g -1 FW) Basmati-515 T0 10.67±0.05 c 0.91±0.09 c 120.33±5.5 d 1.72±0.09 a 1.62±0.09 a T1 12.67±0.08 bc 1.09±0.09 bc 131.33±6.2 cd 1.44±0.07 ab 1.33±0.05 ab T2 14.83±0.06 abc 1.31±0.08 b 148.33±5.2 bc 1.29±0.06 bc 1.17±0.08 bc T3 17.67±0.04 a 1.72±0.06 a 172.00±5.3 a 1.11±0.08 c 1.02±0.04 c T4 15.83±0.06 ab 1.40±0.06 ab 154.33±4.8 ab 1.33±0.06 bc 1.24±0.07 bc T5 14.00±0.07 abc 1.33±0.08 b 142.67±4.8 bc 1.54±0.09 ab 1.43±0.06 ab LSD at p≤0.05 1.23 0.31 18.71 0.31 0.29 Basmati-385 T0 9.69±0.05 c 1.02±0.08 c 122.33±5.12 c 1.82±0.08 a 1.73±0.08 a T1 11.63±0.08 bc 1.19±0.06 bc 132.67±5.98 bc 1.51±0.09 abc 1.42±0.09 abc T2 13.89±0.06 abc 1.39±0.09 b 152.33±4.82 ab 1.40±0.08 bc 1.29±0.08 bc T3 16.64±0.04 a 1.81±0.05 a 174.00±5.83 a 1.22±0.05 c 1.10±0.05 c T4 14.88±0.06 ab 1.51±0.07 ab 155.33±4.89 ab 1.43±0.06 bc 1.31±0.06 bc T5 13.01±0.07 abc 1.40±0.05 b 144.00±5.01 bc 1.65±0.07 ab 1.56±0.07 ab LSD at p≤0.05 1.03 0.34 28.00 0.32 0.31 Discussion Osmopriming of seed by KNO3 affected the seed emergence and the speed of seed germination. Osmopriming induces the reduction in intake of water in phase-I of germination, causing prolonged duration of phase-2, resulting commencement of major event before the emergence of radicle (Nonogaki and Nonogaki, 2016). This major event includes metabolic changes such as repair of DNA and increase in biosynthesis of RNA (Bray, 2017), and enhancement in the respiration process of seed (Singh et al., 2013). It indicates that the time of seed imbibition is very important for osmopriming. For the study of osmopriming of rice (Oryza sativa L.) seed with different levels of KNO3, therefore it is important to know about the emergence percentage and mean emergence time (MET). The results of present study indicate that the performance of osmopriming of both cultivars of rice with 0.75% KNO3 was appreciable in lab screening as well as greenhouse (Fig. 1 and 3). The pattern of seedling emergence (%) and MET was almost same in both cultivars as well as both sites (lab and greenhouse). The time of water intake by the seed during priming can very within the cultivars which can affect the performance of osmoticum (KNO3) (Kiers et al., 2008), but in our study the difference between the performance of both cultivars was non-significant. Emergence of the seed is the stage where it is determined that either the seedling will further grow or not. The emergence percentage is calculated from the number of emerged seedlings from number of primed seeds sown (International Seed Testing Association, 2015). The data shown in figure 1 and 3 depicts that the osmopriming of rice seed with 0.75% KNO3 is better than all other treatments in term of emergence percentage and MET. Our study is in correspondence with another study who revealed that emergence percentage of wheat seed was decreased with the increase in KNO3 concentration (Shafiei Abnavi and Ghobadi, 2012). This indicates that the KNO3 concentration above than a certain level may not be appropriate for cereals. Osmopriming with 1% KNO3 was found useful in term of emergence percentage in sorghum (Shehzad et al., 2012). Besides, soybean seed priming with 1% KNO3 for 1 day enhanced the emergence percentage as compared to untreated seeds, both in lab and field experiments (Mohammadi, 2009). Seedling vigor is the combine result of the emerged seeds in a wide range of biotic and abiotic factors (International Seed Testing Association, 2015). Seedling vigor is not a single measurable entity, but it is a sum of many growth parameters such as seedling length, seedling fresh weight and seedling dry weight (International Seed Testing Association, 2015). Maximum vigor was observed when seed priming with 0.75% KNO3 was done (Fig. 2 and 4). Our study is in line with another study in which seedling vigor of wheat was improved by the priming with KNO3 (Shafiei Abnavi and Ghobadi, 2012). Similar results were found in corn when the osmopriming of seed was done with 1% KNO3 (Hadinezhad et al., 2013). Our findings are similar with other studies, in which the shoot length of tomato and watermelon was increased by the osmopriming with KNO3 (Demir and Van De Venter, 1999; Mirabi & Hasanabadi, 2012). Seed priming with KNO3 can cause significant increase in seedling vigor of wheat crop as compared to hydro-priming or dry broadcasting (Basra et al., 2003). The growth and development of plant is based upon a process; photosynthesis. While its performance is mostly dependent on the opening/closing of stomata, causing decrease in photosynthetic rate, respiration rate and CO2 index (Shu et al., 2016). The results of present study revealed that the maximum photosynthesis rate, evaporation rate and CO2 index was observed in the rice seeds which were primed with 0.75% KNO3 (Table 1). Whereas the seedlings of control treatments showed inferior results as compared to other osmopriming treatments. Our study is in corroboration with another study in which the increased photosynthetic rate, respiration rate and CO2 index of cucumber seedlings as the result of seed priming with KNO3 was reported (Anwar et al., 2020). Photosynthesis rate of the seedlings has a positive correlation with the growth of seedling (Anwar et al., 2020). A previous study indicated that the leaf nitrogen and chlorophyll contents have a positive correlation, and can derive the photosynthesis rate being a key molecule for photosynthesis (De Castro et al., 2014). The results of present study revealed that the biochemical attributes e.g. alcohol dehydrogenase (Ug-1 FW) and pyruvate decarboxylase (Ug-1 FW) of rice were suppressed by osmopriming of seed with KNO3. Maximum suppression was observed in those seedlings who were treated with 0.75%% KNO3, while minimum suppression was seen in non-primed seedlings. A previous study expressed that seed priming with potassium nitrate (KNO3) improved the biochemical indices of Chicory (Cichorium intybus L.) (Dehkordi et al., 2012). Conclusion Good quality seed is always in demand by the farmers and seed industry. Therefore, present study was conducted to improve the rice seed quality by seed priming with KNO3. The results depicted that seed priming with 0.75% KNO3 proved successful in improving stand establishment, vigor and physiological attributes. The improved performance might by linked with better activities of ADH and PDH. Therefore, present research provides basis for further transcriptomics/metabolomics/proteomics basis of primed seeds with KNO3
Current postharvest activities in the sesame value chain are prompting colossal losses, which reduce overall global productivity. This review portrays losses in sesame during various processing stages, from grain harvesting to marketing and transformation of crop seed into oil. Such losses in sesame not only reduce yield but also have an impact on the economy of its production territories. The loss in productivity is because the majority of farmers don't use adequate harvesting, packaging, or handling technologies to manage on-farm produce. Also, there is a lack of knack for minimizing postharvest losses. Therefore, the study penlights the inevitability of increasing production by raising productivity and quality while giving mitigation strategies to reduce postharvest losses. Elevating standardized productivity with accurate postharvest management is the only substitute for the gap between the global productivity average and the overall production potential of sesame.
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