Abstract
An extremely important oil crop in the world, Helianthus annuus L. is one of the world's most significant members of the Asteraceae family. The rate and extent of seed germination and agronomic features are consistently affecting by temperature (T) and changes in water potential (ψ). A broad hydrothermal time model with T and ψ components could explain sunflower responses over suboptimal T and ψ. A lab experiment was performed using the HTT model to discover both T and ψ and their interactive effects on sunflower germination and also to figure out the cardinal Ts values. The sunflower seeds were germinated at temperatures (15 °C, 20 °C, 25 °C and 30 °C); each Ts had five constant ψs of 0, 0.3, 0.6, 0.9, and 1.2 MPa via PEG 6000 as osmotic stress inducer. The results revealed that highest germination index was found in seed grown at 20 °C in distilled water (0 MPa) and the lowest at 30 °C with osmotic stress of (− 1.2 MPa). The highest value of germination rate index was found in seed grown at 20 °C in distilled water (0 MPa) and the lowest at 15 °C with an osmotic stress of (− 1.2 MPa). In conclusion, water potential, temperature, and their interactions have a considerable impact on seed germination rate, and other metrics (GI, SVI-I, GRI, GE, SVI-II, and MGT). Seeds sown at 20 °C with zero water potential showed high germination metrics such as GE, GP, GRI, and T50%. The maximum value to TTsub noted at 30 °C in − 0.9 MPa osmotic stress and the minimum value was calculated at 15 °C in − 1.2 MPa osmotic stress. The result of TTsupra recorded highest at 15 °C in controlled group (0 MPa). Moreover, θH was highest at 30 °C in controlled condition (0 MPa) and minimum value was observed at 20 °C under − 1.2 MPa osmotic stress. The value of θHTT were maximum at 30 °C in controlled group (0 MPa) and minimum value was recorded at 15 °C under − 1.2 MPa osmotic potential. The base, optimum and ceiling temperatures for sunflower germination metrics in this experiment were noted 6.8, 20 and 30 °C respectively.
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Introduction
The Helianthus annuus L. (Sunflower) is a member of the Asteraceae family. It is one of the world's most important oil crops1. Helianthus annuus L. is the world's fourth-major producer of oil seeds. The English name Sunflower, which was given to these flowers in reference to the idea that they move with the sun during the day, always turning in the direction of its rays, shares the same meaning as the Greek name Helianthus, which combines the words helios (the sun) and anthos (flower). Sunflower (Helianthus annuus L.) plant stalks that have dried up are burned as fuel2,3. Sunflower plant is a wonder oil seed crop that is grown all over the world for its seeds. Researchers have discovered that sunflower seeds, a nutrient-rich meal, may help prevent chronic inflammatory disorders, fungus and bacteria infestations, cardiovascular diseases, skin issues, and possibly cancer. The occurrence of proteins, unsaturated fatty acid, phytosterols and varieties of vitamins are responsible for these advantages of sunflower seeds. Numerous studies have shown that sunflower seeds are effective in treating a range of clinical problems4.
The key factor impacting seed dormancy and germination is temperature, which controls dormancy and influences how quickly non-dormant seeds germinate. Three cardinal temperatures; maximum optimal, and minimum, have been acknowledged as defining the temperature array across which a specific specie germination of seed occur5. The optimal temperature (To) be the temperature at which germination occurs most quickly, the minimum or base temperature (Tb), and the maximum or ceiling temperature (Tc), at which seeds can germinate. When seeds are dormant, temperature array between Tc and Tb is sensitive to their level of dormancy; it is frequently small in inactive seeds and widens when dormancy is lost. Low Tc values, in particular, are frequently linked to seed dormancy. Seeds whose germination is impeded by warm temperatures demonstrate thermo-inhibition or relative dormancy.6. The ideal soil temperature for seed germination is that temperature where a seed population experiences the highest percentage of germination in the short length of time (To)7. At temperatures above the optimum range (T > To), physiological changes take place in seeds that slow down germination8,9. Thermos inhibition describes this gradual loss in seedling growth in a seed population when soil temperature rise above To. The water potentials and temperatures of the seedbed play a significant role in non-dormant seeds' complex physiological process of germination. In order to accurately explain the time, supra and sub-optimal temperatures have been efficiently incorporated in hydrothermal time (HTT) models for a number of plant species at both sub- and supra-optimal temperatures. The hydrothermal time model is a threshold model that takes germination rates and seed population percentages into account at the same time10,11.
Thermal time or heat units can be used to define the timing of germination for temperatures below ideal (between Tb and To). That is, for a particular germination percentage tg, the time multiplied by the T in excess of Tb is a fixed for that portion, θT (g). According to this model, the germination rate (GRg or 1/tg) for a specific seed percentage or fraction is a linear function of Temperature above Tb. The maximum temperature at which seeds can grow is known as the ceiling temperature. In many instances, GRg decreases linearly as T between Tc and To rises. To account for this difference in Tc value, Ellis and Horvitz12, Covell, et al.13 and Hardegree14 proposed this model. Germination rate rates are inversely connected to how much water potential there is, according to the HTT and temperature (T) are over their base or threshold values. The mathematical basis of the HTT, certain applications in modelling seed dormancy and sprouting behaviour, and prospective future directions are discussed. Temperature is the main environmental cue that governs both germination and dormancy15. The TT model can take into account changing temperatures by adding the thermal times determined at each T16. In order to represent seed germination patterns, the HTT model was created by combining the aforementioned thermal time and hydro-time models.
This study will investigate mathematical model (based on the temperatures and the osmotic potentials) which would predict the germination responses of seeds of Helianthus annus. Therefore, the current study aimed; (1) to estimate the effectiveness of the HTT model to examine seed germination of Sunflower at different Ts and Ψs, (2) To calculate SG at cardinal Ts and various osmotic potentials.
Materials and methods
Seeds sowing and treatments
Sunflower (Helianthus annuus L. var. S1-278) seeds with a 90% viability rate were gathered from the Nuclear Institute for Food and Agriculture (NIFA), Peshawar, Khyber Pakhtunkhwa, Pakistan. The seeds were kept in plastic bags and utilized in an experiment with a hydrothermal time model. Seeds of the sunflower (Helianthus annuus L. var. S1-278) were sterilized in mixture of 95 percent distill water and 5 percent mercuric chloride (HgCl). The seeds were filtered via filter paper after keeping 5 min in a solution. After drying, distilled water was used to clean the seeds. The experiment was performed in Plant Physiology laboratory at the University of Peshawar's department of Botany from February to June 2022 at varied water potentials and temperatures in a room and incubator setting. For the laboratory experiment, Sunflower (Helianthus annuus L. var. S1-278) crop was selected for trial. the seeds were sown in Petri dishes (15 cm size), in different groups labelled as controlled and treated. . To prevent water from evaporating, petri dishes were placed randomly in the incubators while being covered in transparent plastic bags. Seed were considered germinated when they showed evident radicle emergence of more than 2 mm.17. Five varying water potentials (0, 0.3, 0.4, 0.5, and 0.6 MPa) solutions were prepared by adding PEG 6000 from which 10 ml solution was added to each Petri dishes and the seeds were planted at temperatures ranging from 15, 20, 25, and 30 °C.
Using distilled water, an osmotic potential of 0 MPa was produced. According to Michel and Kaufman (1973), the negative osmotic potential levels were generated with PEG (polyethylene glycol 6000; Merck, Germany). On the third day of the experiment, a reading test was given. Each replication contained 10 seeds of each type, for a total of 300 seeds per experiment.
Hydrothermal time model
After the completion of lab experiment, the radical length and plumule length of all repetitions were measured in centimeters (cm) and calculation were done for different parameters.
Thermal-time model
According to this model, the germination rate (GR) is a linear function of temperature above Tb for a specific seed fraction, percentage, or germination period. The minimum temperature where such germination can take place is known as the Tb or base temperature. The optimal temperature (To) is the temperature at which germination happens the quickest. The mathematical models that explain how temperature affects germination patterns11.
The model at sub-optimal Temperatures was.
The model at supra-optimal Temperatures was.
Rate of germination is inverse to time of emergence of seed, So Eqs. (1) and (2) give Eq. (3);
Hydro-time model
Hydro time model presented by10 and11. A seed must reach a point where it can no longer germinate when dried from its fully hydrated form. The base or threshold parameter b will only stop percentage g of the seed number from germinating.
θH is the hydrotime, GR is the germination rate, \(\uppsi\) is the osmotic potential, ψb is the base osmotic potential and tg is the germination time.
Hydro-thermal model
Combining θH equations with TT equations yields a θHTT constant for suboptimal temperature11,18: To represent germination time courses, this hydrothermal model has performed effectively. (Bradford, 2002).
θHTT is the Hydrothermal time model constant, T is the temperature, Tb is the base temperature \(\uppsi\) is the osmotic potential, ψb is the base osmotic potential and tg- germination time.
Germination parameters
Mean germination time (MGT)
The population of seeds' MGT represents how quickly they germinated. The mean germination time decreases as the population grows more germinated19.
f is the number of germinated seeds and x is number of days taken to germination.
Germination energy (Ge)
We calculated germination energy using a standard method of20
Mean germination rate (MGR)
The average rate of germination is equal to the mean germination time reciprocal21.
Germination rate index (GRI)
Greater and maximum GR are indicated by higher GRI values; GRI represents the age-percentage of seed germination regularity during the germination stage22.
Germination Index (GI)
A systematic calculation method was used to determine the germination index23.
Seed vigor index-I (SVI-I)
SVI regarding the seedling’s length by19.
Seed vigor index-II (SVI-II)
Seed vigor index regarding the seedling dry weight by19.
Antioxidants enzymes
Guaiacol peroxidase (GPX) activity
We have determined the activity of GPX according to the protocol of Castillo et al.24. Fresh plant tissues were mixed in an ice bath at 4 °C with 10 ml of phosphate buffer (pH 7.5) containing 0.5 mM EDTA. 0.1 ml of the centrifuged supernatant was mix with 16 mM guaiacol, 50 mM phosphate buffer (pH 6.1) and 2 mM H2O2. At 470.0 nm, enzyme activity was measured.
Ascorbate peroxidase (APX) activity
The ascorbate peroxidase activity in fresh plant material was assessed using the standard protocol of Nakano and Asada25. In a 10 ml phosphate buffer solution (pH 7.5), 500 mg fresh plant material was homogenized. Ascorbic acid 0.5 mM, potassium phosphate buffer (pH 7.0) and EDTA 0.1 mM were added to 0.1 ml of supernatant. By adding 0.1 ml of H2O2 to the solution, the reaction was initiated. The decrease in OD was measured by spectrophotometer at 290.0 nm.
Catalase (CAT) activity
Fresh plant material was tested for catalase (CAT) activity using the standard protocol of Aebi26. A 0.5 g plant tissues were homogenized with 10 ml phosphate buffer (pH 7.5) contain 0.5 mM EDTA. Homogenates were filtered, centrifuged for 25 min at 15,000 rpm, and supernatants were collected for catalase activity. 0.1 ml of supernatant was treated with 2 ml of phosphate buffer (1 M) and 0.5 ml of H2O2 (75 mM). The optical density was measured at 240.0 nm.
Superoxide dismutase (SOD) activity
Fresh plant material was analyzed according to the standard protocol of Beauchamp and Fridovich27. This sample was prepare by chopping 500 mg of plant material into 5 ml of phosphate buffer. A combination of EDTA (3 mM), nitrotetrazolium blue chloride (NBT; 2.25 mM), 5 ml methionine (390 mM), and 1.5 M Na2CO3 was added to the supernatants. After 20 min of incubation under ordinary light, 1 ml of riboflavin was added to the reaction mixture. An optical density (OD) measurement was performed with a spectrophotometer at 560.0 nm for the reaction mixture.
Peroxidase (POD) activity
Peroxidase (POD) activity in fresh plant tissues was measured according to the protocol of Vetter et al.28. Using mortar and pestle and an ice bath, 500 mg of plant material was mixed with 2 ml MES. After centrifuging the mixture at 10,000 rpm for 20 min, the supernatant was collected. One drop of H2O2 (30%), 1.5 ml of MES buffer (pH 5.5), and 0.1 ml of phenylenediamine were added to 0.1 ml of the supernatant mixture. In this experiment, the OD was measured at 485.0 nm.
Statistical analysis
For statistical analysis IBM SPSS Statistics 26 and Sigma Plot Version 11.0 software was used. Linear regression was used to examine effects of hydro time, TT and their interactions on germination characteristics and seed germination rate. The values of the parameters (\(\uppsi\) (50), \(\uppsi\)b; R2, Sig, F, SE, and T-test) were calculated using linear probate regression analysis in SPSS. The Tukey HSD test was used to show the significant difference between groups Using Excel software, several graphs of the fraction of germination vs the accelerated ageing duration and the germination parameters against \(\uppsi\) and T were plotted.
Ethical approval and consent to participate
Sunflower (Helianthus annuus L. var. S1-278) seeds were collected from the Nuclear Institute for Food and Agriculture (NIFA), Peshawar, Khyber Pakhtunkhwa, Pakistan. The trial was performed in accordance with relevant guidelines and regulations.
Results
Temperature, osmotic potential, and their interactions were found to have a substantial impact on germination rate and other characteristics. According to Fig. 1a–d, The maximum percentage of germination was found in seeds grown in distilled water (0 MPa for each temperature 15 °C, 20 °C, 25 °C and 30 °C and the lowest at (− 1.2 MPa) at 15 °C, 20 °C, 25 °C and 30 °C. According to Fig. 2a, for Helianthus annuus L. var. S1-278, the highest germination index was found at 20 °C in distilled water (0 MPa), and the lowest at 30 °C with an osmotic potential of (− 1.2 MPa). The highest value of germination rate index was found at 20 °C in distilled water (0 MPa), and the lowest at 15 °C with an osmotic stress of (− 1.2 MPa) (Fig. 2b). According to Fig. 2c the maximum value of mean germination time was found at 20 °C in distilled water (0 MPa), and the lowest at 15 °C with an osmotic potential of (− 1.2 MPa) (Fig. 2c) and the highest results of mean germination rate were recorded lowest at 30 °C with an osmotic stress of (− 1.2 MPa) while the lowest recorded for 20 °C with distal water (0 MPa) (Fig. 2d).
The result showed that germination is negatively affected by high osmotic stress (− 1.2 MPa). According to the results recorded in Fig. 3a, it was observed that germination energy has highest value for distilled water (0 MPa) while the lowest value recorded for − 1.2 MPa osmotic stress at 25 °C. Therefore, osmotic stress reduced the value of germination energy as compared to controlled group. Highest value of overall germination percentage of experiment was recorded for controlled group (0 MPa) at 20 °C while lowest value recorded at 30 °C in − 1.2 MPa osmotic potential (Fig. 3b). According to Fig. 3c, the highest value of seed vigor index-I recognized for distilled water (0 MPa) in 30 °C. While the lowest value recognized at 20 °C for − 0.9 MPa osmotic stress. The seed vigor index-II gave maximum value in controlled group at 20 °C and the minimum value was recorded for − 1.2 MPa 25 °C (Fig. 3d). The highest values of radicle length and plumule length were recorded at 0 MPa in 30 °C, while the lowest values were recorded at − 1.2 MPa at 20 °C. The highest time to 50 percent germination was reported in 0 MPa at 25 °C and the maximum value of coefficient of velocity of germination recorded under 0 MPa at 20 °C (Fig. 4a–d).
According to the results of antioxidant enzymatic activities (Fig. 5) temperature and osmotic potential fluctuation highly affected the enzymes' activities and concentration. The highest activity of CAT, APX and GPX was measured at 15 °C in − 1.2 MPa and the lowest value of CAT and GPX were recorded at 30 °C in controlled group (0 MPa). While the APX minimum value was noted at 20 °C under 0 MPa osmotic stress. In addition, highest value of POD was recorded at 30 °C under − 1.2 and the lowest value was observed at 25 °C in controlled condition. Moreover, highest value of SOD was noted at 25 °C under − 1.2 MPa while the lowest value was measured at 30 °C under controlled condition. All the enzymatic activities were greatly affected by both the varying temperature and osmotic potential. The lowest response of all enzymes was recorded at 0 MPa and the highest at − 1.2 MPa (Fig. 5).
The correlation between seventeen measured parameters across five treatments were shown in Fig. 6. According to correlation matrix the SVI-I, GRI, GE, CVG, GP, GI, SVI-II, RL, PL and CVG were positively correlated to each other. MGR was negatively correlated with GP, SVI-II and T50%. GE has shown negative correlation with PL, RL and SVI-I. All enzymes have negative correlation with germination parameter while positively correlated with each other. According to Fig. 7 two different clustered were formed between treatments. First cluster consisted of − 0.9 and − 1.2 MPa treatments while the second cluster consisted of controlled group, − 0.3 and − 0.6 MPa osmotic potentials respectively. GI, SVI-II, SVI-I and CVG showed high association with controlled group, − 0.3 and − 0.6 MPa osmotic potentials. PCA was carried out for the germination of datasets. According to the results, all treatments were variously distributed in the datasets. The distribution of treatment showed that the osmotic potential significantly affected the germination attributes. The PCA further results described that the first two component accounted for 74.3% of the total variation. In addition, the first two component showed highest percentage of variance (Fig. 8).
Under sub and supra optimal conditions, the thermal time model effectively predicted germination kinetics for the osmotic potential ranges (0 to − 1.2 MPa) and varying temperatures. Additionally, the TT model had a growing R2 value and was holding onto the germinating rate data under filtered water. Furthermore, the ceiling, optimum, and base temperatures were determined using GR (g) responses. The results recorded in Table 1 shows that the highest value to TTsub was noted at 30 °C in − 0.9 MPa osmotic stress and the minimum value was calculated at 15 °C under − 1.2 MPa. The results of TTsupra was recorded highest at 15 °C for controlled group (0 MPa). While the results of θH were highest at 30 °C in controlled group (0 MPa) and minimum value was recorded at 20 °C under − 1.2 MPa. The value of θHTT was maximum at 30 °C under controlled conditions (0 MPa) and minimum at 15 °C under − 1.2 MPa osmotic potential. For GR the maximum value was noted under 30 °C for − 1.2 MPa osmotic stress and the minimum value recorded in 30 °C for control (0 MPa). Meanwhile the highest value recorded in 15 °C for − 0.3 MPa osmotic stress and lowest at 25 °C under − 1.2 MPa osmotic stress.
According to Table 2 the T and ѱ have highly affected germination of sunflower seeds. The thermal time model shown the germination kinetics for increasing temperature at sub and supra-optimal condition. . The minimum value of base water potential at 50 percent germination was (− 1.01) at 20 °C. The high temperatures (25 °C and 30 °C) have significant value for osmotic potentials (between − 0.6 to − 0.9 MPa). The F value have fluctuations and have no fixed pattern. The base, optimum and ceiling temperatures for sunflower in this experiment were 6.8, 20 and 30 °C respectively (Table 3).
Discussion
Seed lot response to T and ѱ during germination can be quantitatively characterized by the HTT model. Temperature and water potential influences on seed germination can be described and quantified using the HTT model11. However, numerous investigations reported the tg at sub-optimal TT using the thermal time model. Moreover, these models started to lose effectiveness at supra-optimal TT. Furthermore, the decrease in germination rate when Ts surpassed the ideal temperature was not predicted by thermal time models11. In order to overcome these constraints and address associated issues,11 and10 created the HT and hydrothermal time models. Bradford further claimed that HTT models were reliable tools for comprehending the interactions between Ts and Ys (environmental parameters) in a seed lot as they relate to seed germination29
Analyzing germination characteristics under different environmental condition is necessary to pinpoint the best location for a species to flourish and germinate. To measure how these stresses affect seed germination in this way, mathematical model like the HT, TT and HTT model are helpful30. Environmental temperature is one of the major environmental factor that influences seed germination in a variety of plant species31,32,33. Another abiotic stress that prevents young seedlings and seeds from sprouting is water stress34. Hydrothermal time (HTT), thermal (TT), and Hydrotime (HT) models were created by several research as efficient ways to characterize and forecast seed population germination reactions under various environmental variables. These models are frequently employed as tools in both agronomy and elementary research since they are simple to use and provide a clear biological understanding of the parameters35.
According to the findings in Figs. 1, 2 and 3, a substantial decline in growth was observed when water potential was reduced in the germination energy, mean germination time, and germination % at the optimal temperature of 30 °C. The result is similar according to30 who hypothesized that variations in water potential would affect FGP more so than changes in temperature. The Sunflower showed least growth at 35 °C which is similar according to the result of36 who showed that the growth of agronomic parameters was significantly decrease at 35 °C and almost no growth at 40 °C. The result is also similar to35 who displayed the lowest hydrotime value (− 0.6 MPa h) at 35 °C. Our results were also in agreement with the findings of37 who reported that the germination of Cucumber and Melon seed were significantly inhibited at temperatures of 42 °C (8–10%) and 45 °C (9–10%), respectively. Additionally, Watermelon, Winter Squash, Summer Squash, and Pumpkin seeds did not germinate at 42 °C. The T and ѱ had significantly affected the growth of Sunflower. Osmotic potential, temperature, and their interactions had a significant impact on all cultivars' germination rates and germination percentages (P ≤ 0.01)38. T and ѱ have a substantial impact on agronomic parameters, water deficit causes a reduction in the pace and percentage of germination; if not a full inhibition39.
It was found that drought stress significantly reduced antioxidant enzymes levels, including superoxide dismutase (SOD), peroxidase (POD) and catalase (CAT). Plants subjected to water deficit stress showed a decrease in APX and GPX levels. According to40 and41, who studied a remarkable increase in antioxidant enzymes levels under abiotic stress, their results were consistent with the findings of our study. Furthermore, it has also been found that the level of antioxidant enzymes in plants was significantly correlated with the level of stressors in the environment, thus scavenging excess oxidative stress and reducing the oxidative damage caused by reactive oxygen species.
The decrease in GP may be because of the heat breakdown of essential amino acids necessary for seed germination with decrease in the concentration of GP a decline in water potential and an equal decrease in water resources may occur42. The minimal temperature (Tb) for sunflowers in our study was 15 °C. Tb is a critical cardinal temperature threshold under which the rate of germination drops and plant's physiological activities could be more challenging to maintain, therefore it must be taken into consideration while developing a crop simulation model and selecting the appropriate growth season11. Under laboratory conditions, seeds are typically incubated at a constant temperature, but in the field, temperature variations may become a problem at the seedlings' emergence stage. Compared to seeds exposed to steady temperature, those subjected to variable temperatures collected fewer thermal hours43. Both the ideal (To) and ceiling (Tc) temperatures for the current study were measured at 30 °C. Cardinal temperatures are roughly three in number: the optimal temperature (To), where high germination happens right away; the ceiling (Tc) and base (Tb) temperatures, where germination rates are at their lowest levels44. The ƟH values were used by scientists and breeders to rank cultivars according to how susceptible they were at 30 °C, the base water potential with the lowest 50% germination value (0.18) was measured and it was further shown by Tb constancy that this modification was maintained at all possible temperatures and osmotic potential values. A seed lot's uniform fluctuations in seed germination are represented by the ѱb (g) indicator45. Studies on the carrot and onion46, potato17, tomato47 and watermelon30 have shown that at optimal temperature, base osmotic potential levels are minimum, and they linearly rise at supra-optimal temperatures.
Conclusion
In conclusion, water potential, temperature, and their interactions have a considerable impact on germination percentage, germination rate, and other metrics (SVI-I, GRI, GI, SVI-II, MGT and GE). The sunflower germination response might very well be reported by the hydrothermal time models at all osmotic potentials and temperatures. The models correctly predicted (Sunflower) Helianthus annuus L. var. S1-278 germination time in response to water potential and temperature. Seeds cultivated at 20 °C with no osmotic potential were shown to have high germination metrics such GE, GP, GRI, and T50%. Therefore, the temperatures, hydrothermal time model (HTT) cardinal and germination findings may be used to illustrate how seed germination would react to changing temperature, individually or together, in upcoming climatic changes. To forecast future germination time courses, the model's parameters should explore how various abiotic stressors affect the physiological behavior of seed populations.
Data availability
All data generated or analyzed during this study are included in this published article (Supplementary Data).
Abbreviations
- TTsupra:
-
Thermal time constant at supra-optimal temperature
- TTsub:
-
Thermal time constant at sub-optimal temperature
- θH:
-
Hydrotime constant
- θHTT:
-
Hydrothermal time constant
- T:
-
Temperatures
- GR:
-
Germination rate
- ψ:
-
Water potential
- PEG:
-
Polyethylene glycol
- GI:
-
Germination index
- SVI-I:
-
Seed vigor index I
- GRI:
-
Germination rate index
- GE:
-
Germination energy
- SVI-II:
-
Seed vigor index II
- MGT:
-
Mean germination time
- GP:
-
Germination percentage
- GRI:
-
Germination rate index
- T50%:
-
Time to 50 percent germination, To Optimal temperature, Tb Base temperature, Tc ceiling temperature
References
Andrew, R. L. & Rieseberg, L. H. Divergence is focused on few genomic regions early in speciation: Incipient speciation of sunflower ecotypes. Evolution 67, 2468–2482 (2013).
Harter, A. V. et al. Origin of extant domesticated sunflowers in eastern North America. Nature 430, 201–205 (2004).
Muller, M. H., Latreille, M. & Tollon, C. The origin and evolution of a recent agricultural weed: Population genetic diversity of weedy populations of sunflower (Helianthus annuus L.) in Spain and France. Evol. Appl. 4, 499–514 (2011).
Nandha, R., Singh, H., Garg, K. & Rani, S. Therapeutic potential of sunflower seeds: An overview. Int. J. Res. Dev. Pharm. Life Sci. 3, 967–972 (2014).
Bewley, J. D. & Black, M. Dormancy and the Control of Germination 199–271 (Springer, 1994).
Bradford, K. J. & Somasco, O. A. Water relations of lettuce seed thermoinhibition. I. Priming and endosperm effects on base water potential. Seed Sci. Res. 4, 1–10 (1994).
Mayer, A. & Poljakoff-Mayber, A. Chemical composition of seeds. Ed 2, 10–20 (1975).
Hills, P. & Van Staden, J. Thermoinhibition of seed germination. S. Afr. J. Bot. 69, 455–461 (2003).
Argyris, J., Dahal, P., Hayashi, E., Still, D. W. & Bradford, K. J. Genetic variation for lettuce seed thermoinhibition is associated with temperature-sensitive expression of abscisic acid, gibberellin, and ethylene biosynthesis, metabolism, and response genes. Plant Physiol. 148, 926–947 (2008).
Gummerson, R. The effect of constant temperatures and osmotic potentials on the germination of sugar beet. J. Exp. Bot. 37, 729–741 (1986).
Bradford, K. J. Applications of hydrothermal time to quantifying and modeling seed germination and dormancy. Weed Sci. 50, 248–260 (2002).
Ellis, H. M. & Horvitz, H. R. Genetic control of programmed cell death in the nematode C. elegans. Cell 44, 817–829 (1986).
Covell, S., Ellis, R., Roberts, E. & Summerfield, R. The influence of temperature on seed germination rate in grain legumes: I. A comparison of chickpea, lentil, soyabean and cowpea at constant temperatures. J. Exp. Bot. 37, 705–715 (1986).
Hardegree, S. P. Predicting germination response to temperature. I. Cardinal-temperature models and subpopulation-specific regression. Ann. Bot. 97, 1115–1125 (2006).
Roberts, E. Temperature and seed germination. In Proceedings of the Symposia of the Society for Experimental Biology, 109–132 (1988).
Ellis, R. & Barrett, S. Alternating temperatures and rate of seed germination in lentil. Ann. Bot. 74, 519–524 (1994).
Alvarado, V. & Bradford, K. A hydrothermal time model explains the cardinal temperatures for seed germination. Plant Cell Environ. 25, 1061–1069 (2002).
Grundy, A., Phelps, K., Reader, R. & Burston, S. Modelling the germination of Stellaria media using the concept of hydrothermal time. New Phytol. 148, 433–444 (2000).
Ullah, S., Afzal, I., Shumaila, S. & Shah, W. Effect of naphthyl acetic acid foliar spray on the physiological mechanism of drought stress tolerance in maize (Zea Mays L.). Plant Stress 2, 100035 (2021).
Mrđa, J., Crnobarac, J., Dušanić, N., Jocić, S. & Miklič, V. Germination energy as a parameter of seed quality in different sunflower genotypes. Genetika-Belgrade 43, 427–436 (2011).
Mubeen, M. et al. Effect of plant growth promoting bacteria and drought on spring maize (Zea mays L.). Pak. J. Bot 53, 731–739 (2021).
Ranal, M. A. & Santana, D. G. D. How and why to measure the germination process?. Braz. J. Bot. 29, 1–11 (2006).
Wang, C., Wu, B. & Jiang, K. Allelopathic effects of Canada goldenrod leaf extracts on the seed germination and seedling growth of lettuce reinforced under salt stress. Ecotoxicology 28, 103–116 (2019).
Castillo, F. J., Penel, C. & Greppin, H. Peroxidase release induced by ozone in Sedum album leaves: Involvement of Ca2+. Plant Physiol. 74, 846–851 (1984).
Nakano, Y. & Asada, K. Spinach chloroplasts scavenge hydrogen peroxide on illumination. Plant Cell Physiol. 21, 1295–1307 (1980).
Aebi, H. [13] Catalase in vitro. In Methods in Enzymology, vol. 105, 121–126 (Elsevier, 1984).
Beauchamp, C. & Fridovich, I. Superoxide dismutase: Improved assays and an assay applicable to acrylamide gels. Anal. Chem. 44, 276–287 (1971).
Vetter, J., Steinberg, M. & Nelson, A. Enzyme assay, quantitative determination of peroxidase in sweet corn. J. Agric. Food Chem. 6, 39–41 (1958).
Bradford, K. J., Still, D. W. Applications of hydrotime analysis in seed testing. Seed Technol. 2004, 75–85 (2004).
Bakhshandeh, E., Atashi, S., Hafeznia, M., Pirdashti, H. & Teixeira da Silva, J. A. Hydrothermal time analysis of watermelon (Citrullus vulgaris cv. ‘Crimson sweet’) seed germination. Acta Physiol. Plant. 37, 1–8 (2015).
Bhattacharya, A., Malik, A. & Malik, H. K. A mathematical model to describe the fungal assisted algal fl°Cculation pr°Cess. Bioresour. Technol. 244, 975–981 (2017).
Windauer, L. B., Martinez, J., Rapoport, D., Wassner, D. & Benech-Arnold, R. Germination responses to temperature and water potential in Jatropha curcas seeds: A hydrotime model explains the difference between dormancy expression and dormancy induction at different incubation temperatures. Ann. Bot. 109, 265–273 (2012).
Derakhshan, Z. et al. Antioxidant activity and total phenolic content of ethanolic extract of pomegranate peels, juice and seeds. Food Chem. Toxicol. 114, 108–111 (2018).
Allen, P. When and how many? Hydrothermal models and the prediction of seed germination. New Phytol. 2003, 1–3 (2003).
Bidgoly, R. O., Balouchi, H., Soltani, E. & Moradi, A. Effect of temperature and water potential on Carthamus tinctorius L. seed germination: Quantification of the cardinal temperatures and modeling using hydrothermal time. Ind. Crops Prod. 113, 121–127 (2018).
Saberali, S. & Shirmohamadi-Aliakbarkhani, Z. Quantifying seed germination response of melon (Cucumis melo L.) to temperature and water potential: Thermal time, hydrotime and hydrothermal time models. S. Afr. J. Bot. 130, 240–249 (2020).
Kader, M. A comparison of seed germination calculation formulae and the associated interpretation of resulting data. J. Proc. R. Soc. N. S. W. 138, 65–75 (2005).
Bakhshandeh, E., Jamali, M., Afshoon, E. & Gholamhossieni, M. Using hydrothermal time concept to describe sesame (Sesamum indicum L.) seed germination response to temperature and water potential. Acta Physiol. Plant. 39, 1–9 (2017).
Alam, M. et al. Enhancing seed germination and seedling growth of chebulic myrobalan (Terminalia chebula Retz.) by appropriate soaking and sowing time after collection of fruits. Bangl. J. Agric. 2021, 45–54 (2021).
Notununu, I., Moleleki, L., Roopnarain, A. & Adeleke, R. Effects of plant growth-promoting rhizobacteria on the molecular responses of maize under drought and heat stresses: A review. Pedosphere 32, 90–106 (2022).
Ojuederie, O. B., Olanrewaju, O. S. & Babalola, O. O. Plant growth promoting rhizobacterial mitigation of drought stress in crop plants: Implications for sustainable agriculture. Agronomy 9, 712 (2019).
Nazar, Z. et al. Glycinebetaine-induced alteration in gaseous exchange capacity and osmoprotective phenomena in safflower (Carthamus tinctorius L.) under water deficit conditions. Sustainability 12, 10649 (2020).
Mesgaran, M. B., Onofri, A., Mashhadi, H. R. & Cousens, R. D. Water availability shifts the optimal temperatures for seed germination: A modelling approach. Ecol. Model. 351, 87–95 (2017).
Baath, G. S. et al. Guar responses to temperature: Estimation of cardinal temperatures and photosynthetic parameters. Ind. Crops Prod. 145, 111940 (2020).
Abdellaoui, R., Boughalleb, F., Zayoud, D., Neffati, M. & Bakhshandeh, E. Quantification of Retama raetam seed germination response to temperature and water potential using hydrothermal time concept. Environ. Exp. Bot. 157, 211–216 (2019).
Rowse, H. & Finch-Savage, W. Hydrothermal threshold models can describe the germination response of carrot (Daucus carota) and onion (Allium cepa) seed populations across both sub-and supra-optimal temperatures. New Phytol. 158, 101–108 (2003).
Dahal, P. & Bradford, K. J. Hydrothermal time analysis of tomato seed germination at suboptimal temperature and reduced water potential. Seed Sci. Res. 4, 71–80 (1994).
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The authors extend their appreciation to the Researchers supporting project number (RSP2024R173), King Saud University, Riyadh, Saudi Arabia.
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Conceptualization, M.J., F.A.; data curation, B.A.; formal analysis, W.S., B.A., T.M.; funding acquisition T.M.; investigation, F.A.; methodology, M.J., S.U.; software, S.E., A.W., M.S.A., B.A.; supervision, S.U.; writing—original draft, M.J., F.A., W.S., S.U., B.A.; writing—review and editing, B.A., M.J., W.S., F.A., S.U., M.S.A., A.W., S.E., T.M.
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Javid, M., Ullah, S., Amin, F. et al. Computing the effects of temperature and osmotic stress on the seed germination of Helianthus annuus L. by using a mathematical model. Sci Rep 14, 9978 (2024). https://doi.org/10.1038/s41598-024-60015-8
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DOI: https://doi.org/10.1038/s41598-024-60015-8
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