Article Type: Research Article Article Citation: Ettagbor Hans Enukwa. (2020). EFFECTS OF
WATERING FREQUENCY AND SOIL TYPES ON SEED GERMINATION AND SEEDLING PERFORMANCE
OF LESPEDEZA CYRTOBOTRYA AND DIANTHUS BARBATUS. International Journal of Engineering
Science Technologies, 4(5), 80-88. https://doi.org/10.29121/IJOEST.v4.i5.2020.115 Received Date: 4 September 2020 Accepted Date: 12 October 2020 Keywords: Leaf Mold Soil Merchantable Soil Seedling Establishment Survival Rate Water Regimes Water Stress This
study was carried out to determine the effect of various watering regimes in
different soils on seed germination and seedling establishment for two species
(Dianthus Barbatus and Lespedeza cyrtobotrya) The ratio of water used for watering
was 16ml water/100g soil. Three watering frequencies (i.e. once daily; once
every 2 days; once every 3 days) were applied for two soil types (Leaf mold
soil and merchantable soil) for a period of 150 days. The differences in seed
germination, seedling survival and seedling growth were monitored in all
experimental units. A more regular watering frequency increases soil moisture,
and vice versa. The results showed that watering frequency had significant
effects on seed germination (p=0.008), number of plant leaves (p=0.05), with
visible but statistically insignificant effects on mean plant height (p=0.19)
and seedling survival (p=0.3) for two plant species. The total height of plant
species also varied greatly within treatments. Positive correlations were
recorded between germination rate with leaf number (r=0.79, p=0.0001); plant
height with survival rate (r=0.65, p=0.001); plant height with leaf number
(r=0.77, p=0.0001); survival rate with leaf number (r=0.66, p=0.0001) etc. Seed
germination and aboveground heights of D. barbatus and L. cyrtobotrya decreased
at the more regular watering frequency of once daily in both soils. On leaf
mold soil, the total height and mean height of L. cyrtobotrya decreased with
increased water stress at once every 3 days watering frequency. Also, the total
height of D. barbatus decreased with increased water stress at once every 3
days watering frequency on this soil, even though its mean height did not
decrease. In contrast on merchantable soil, the total height and mean height of
L. cyrtobotrya increased with increased water stress at once every 3 days
watering frequency, indicating that this plant is more resistant to stress on
this soil. Whereas, the total height and mean height of D. barbatus decreased
with increased water stress on this soil. On leaf mold soil, once every 2 days
watering was the most suitable watering frequency for both species in terms of
achieving best seed germination and seedling establishment. In contrast on
merchantable soil, once every 3 days watering frequency was most suitable for
L. cyrtobotrya, whereas both once every 2 days and once every 3 days watering
frequencies were suitable for D. barbatus on this soil. The results suggest
that using the required watering frequency and soil type is imperative to
ensure sustainability in plant production and seedling establishment.
1. INTRODUCTIONThe choice of plant species and climate condition are imperative considerations for the success of ecological restoration (Andres & Jorda, 2000). Seed germination and seedling growth are critical stages in the life cycle of a plant, and are often subject to high mortality rates (Geraldine and Lisa, 1999). Seed germination and emergence determine the efficient use of the nutrients and water resources available to plants (Gan, 1996; Wojtyla et al. 2016). Water uptake triggers key biochemical and cellular processes associated with seed germination such as the reactivation of metabolism, resumption of cellular respiration, biogenesis of mitochondria, DNA repair, translation and/or degradation of stored mRNAs, transcription and translation of new mRNAs, and the onset of reserve mobilization (Bentsik and Koornneef, 2008; Nonogaki et al., 2010). Seed germination and seedling growth requirements for plants are vital information needed to facilitate domestication and improvement of their potentials. Seed germination potentials are usually dependent on a combination of environmental conditions (Karssen and Hilhorst, 1992; Carmona and Murdoch, 1995). Many studies have been carried out and reported on the pretreatment methods of seeds such as soaking seeds in water (Werker, 1980; Yu et al. 2014; Huan et al., 2016), chemical pretreatments such as immersion of seeds in acids (Todd and Duryea, 1993; Edward et al., 2013), soaking seeds in salt solutions (Yu et al. 2014), and treatment with plant growth hormonce, but there is limited information on the adequate watering frequency in different soils to enhance seed germination and seedling growth. Water is a basic requirement for germination, as it is essential for enzyme activation, breakdown, translocation, and use of reserve storage material (Morad, 2013). The current research
is therefore, designed to investigate the germination of seeds and seedlings
growth of Dianthus barbatus and
Lesperdeza cyrtobotrya in response to different watering regimes and
soils. Lespedeza cyrtobotrya is a
deciduous tree of the leguminous family and is distributed in forests at medium
and low altitudes. It is a drought-enduring plant, and is highly valued as
foliage, green manure crops, or honey resources and also for the prevention of
soil erosion (Zhu et al. 2002). Dianthus barbatus is a species of Dianthus native to southern
Europe and parts of Asia which has become a popular ornamental garden plant. The
seeds of Lespedeza cyrtobotrya and Dianthus barbatus are readily available
and widely sold by commercial suppliers. It is
hoped that the information gathered would help conservation and domestication
of the plant species that could subsequently be used for revegetation of
damaged lands. 2. MATERIALS AND METHODS2.1. SOIL TYPES, SOIL CHARACTERISTICS AND TARGET SPECIESTwo different soils
were used for this experiment including: 1. Leaf mold soil consisting of a
mixture of fermented coco peat and decomposed leaves; 2. Merchantable soil with
weathered granite, consisting of a mixture of fermented coco peat, vermiculite,
perlite and nutrient solution. The soils were purchased from commercial
suppliers. Physicochemical
analysis of the soils showed that Leaf mold soil had the lowest pH of 5.57. For
Electrical conductivity, Leaf mold soil had the highest of 13.86 dS/m, while merchantable
soil had 8.12 dS/m. Leaf mold soil had the highest soil organic matter content
of 20.175%. For total nitrogen content, Leaf mold soil had 12.71%, and Merchantable
soil had 7.72%. Available phosphorus content for Leaf mold soil (204.93 mg/Kg),
and Merchantable soil (103.91 mg/Kg). Among the cations, Ca, Mg, K, Na contents
were higher in Leaf mold soil. A woody plant (Lespedeza cyrtobotrya), and a herbaceous
plant (Dianthus barbatus) were used
for the experiment. 2.2. EXPERIMENTAL MATERIALS AND EXPERIMENTAL DESIGNPots were used as
experimental units with the pots placed on a slab in the laboratory. Leaf mold
soil was filled in 60 pots and Merchantable soil filled in 60 pots. Mature
seeds of L. cyrtobotrya and D. barbatus were purchased from
commercial seed suppliers and used for the experiment. The sample size used for
each watering frequency per soil type was 10 pots for each plant species. 10
seeds for each of the plant species were sowed in each pot with each having 10
replicates per watering frequency. Thus, a total of 1200 seeds (i.e. 600 seeds
per plant species) were used in the experiment. 2.3. WATERING OF EXPERIMENTAL POTSWatering of the pots was done immediately after sowing using
spray irrigation to keep the experiment ongoing. Watering
was done between 07:00 am and 09:00 am when it was cool in order to reduce
evaporative losses. Tap water, drawn fresh as and when required, was used to
irrigate the pots. The required amount of water was filled in the spray can and
spraying done accordingly. The ratio of
water used for watering was 16ml water/100g soil. Three watering regimes
each lasting 120 days were applied: (1) Once daily (2) Once every two days (3) Once
every three days. The watering regimes were simulations of seasons were
rainfall could be frequent, moderate or far apart. 2.4. DATA COLLECTION AND ANALYSISThe experiment was conducted between the months of February and June. Data were collected on germination rate, survival rate, seedling height, relative growth rate and leaf number. Leaf number was assessed by physical counting. Seedling height was measured with metre rule. The relative growth rates (RGR) were calculated as follows: RGR % = (Mf/Mi _ 0.05) x 100 ∆T Where Mf is the final measurement of the mean stem length, Mi is the initial measurement of the mean stem length, and ∆T is the number of months passed between the measurements (Zammith & Scarano, 2006; Zhong et al., 2009). Analysis involved a comparison of the measured and calculated parameters of the species by watering regime using two ways ANOVA procedures, with Turkey’s Test used (p<0.05) to test statistical significance of differences between means. All analyses were conducted using SPSS software (23). 3. RESULTS3.1. THE EFFECT OF WATERING FREQUENCY ON SEED GERMINATIONThe two ways ANOVA showed that watering frequency significantly affected (p=0.008) seed germination of all two species. On Merchantable soil, seed germination of D. barbatus and L. Cyrtobotrya increased with reduced watering frequency from once daily, to once every 2 days, and to once every 3 days watering (Fig. 1). At a watering frequency of once every 3 days on this soil, D. barbatus achieved a germination rate of 90%, and 24.5% for L. cyrtobotrya. On Leaf mold soil, seed germination of D. barbatus increased with reduced watering frequency (from once daily to once every 2 days), and then decreased as watering frequency reduced further (from once every 2 days to once every 3 days). At a watering frequency of once every 2 days on this soil, D. barbatus achieved a germination rate of 67%. Also, on Leaf mold soil, seed germination of L. cyrtobotrya increased with reduced watering frequency (from once daily to once every 2 days), and then showed no significant change as watering frequency reduced further (from once every 2 days to once every 3 days), with germination rates of 17% and 18% respectively. Merchantable soil with watering frequency of once every 3 days had the highest germination rate for both species.
Figure 1: Effects of watering frequency on the seed germination of two species (mean ± SE). Once daily (W1) (control), Once every 2 days (W2), and Once every 3 days (W3) represent the watering frequencies used for leaf mold soil (LMS) and merchantable soil (MS). The letters above the error bar indicates the level of difference among watering frequencies for each soil type at p = 0.05 within each species. 3.2. THE EFFECT OF WATERING FREQUENCY ON SEEDLING SURVIVALWatering frequency affected seedling survival of all two species, even though the effect was not significant (p=0.301). On Merchantable soil, seedling survival of D. barbatus and L. Cyrtobotrya decreased with reduced watering frequency from once daily, to once every 2 days, and then increased as watering frequency further reduced to once every 3 days (Fig. 2). At a watering frequency of once every 3 days on this soil, D. barbatus achieved a survival rate of 61%, and 73% for L. cyrtobotrya, whereas at a watering frequency of once daily, D. barbatus achieved a survival rate of 73%, and 100% for L. cyrtobotrya. On Leaf mold soil, seedling survival of D. barbatus decreased with reduced watering frequency (from once daily, to once every 2 days, to once every 3 days). At a watering frequency of once daily on this soil, D. barbatus achieved a survival rate of 61%, and 51% at a watering frequency of once every 2 days. Also, on Leaf mold soil, seedling survival of L. cyrtobotrya decreased with reduced watering frequency (from once every 2 days to once every 3 days), with survival rates of 41.2% and 28% respectively.
Figure 2: Effects of watering frequency on the seedling survival of two species (mean ± SE). Once daily (W1) (control), Once every 2 days (W2), and Once every 3 days (W3) represent the watering frequencies used for leaf mold soil (LMS) and merchantable soil (MS). The letters above the error bar indicates the level of difference among watering frequencies for each soil type at p = 0.05 within each species. 3.3. SEEDLING LEAF NUMBERWatering frequency significantly affected (p=0.05) the number of plant leaves for all two species. On Merchantable soil, the number of leaves of L. Cyrtobotrya increased with reduced watering frequency from once daily, to once every 2 days, and to once every 3 days watering (Fig. 3), whereas on this same soil the number of leaves for D. barbatus increased with decreased watering frequency (from once daily to once every 2 days), and then reduced as watering frequency further decreased to once every 3 days. At a watering frequency of once every 3 days on this soil, L. cyrtobotrya achieved a mean of 17.7 leaves, and 26.5 leaves for D. barbatus at watering frequency of once every 2 days. On Leaf mold soil, the number of leaves of D. barbatus and L. cyrtobotrya increased with reduced watering frequency (from once daily to once every 2 days), and then decreased as watering frequency reduced further (from once every 2 days to once every 3 days). At a watering frequency of once every 2 days on this soil, D. barbatus achieved a mean of 24.4 leaves, and 16.1 leaves for L. cyrtobotrya.
Figure 3: Effects of watering frequency on the number of leaves for two species (mean ± SE). Once daily (W1) (control), Once every 2 days (W2), and Once every 3 days (W3) represent the watering frequencies used for leaf mold soil (LMS) and merchantable soil (MS). The letters above the error bar indicates the level of difference among watering frequencies for each soil type at p = 0.05 within each species. 3.4. THE EFFECT OF WATERING FREQUENCY ON SEEDLING HEIGHTWatering frequency affected the aboveground height of seedlings for all two species, even though the effect was not significant (p=0.19). On Merchantable soil, seedling height of L. Cyrtobotrya increased with increased watering frequency from once daily, to once every 2 days, and to once every 3 days watering (Fig. 4). Also, on this soil, the aboveground height of D. barbatus increased as the watering frequency decreased from once daily to once every 2 days, but reduced as watering frequency further decreased to once every 3 days. At a watering frequency of once every 3 days on this soil, L. cyrtobotrya achieved mean height of 14.5cm, and 14.1cm for D. barbatus at once every 2 days watering frequency. On Leaf mold soil, aboveground height of D. barbatus increased with reduced watering frequency. At a watering frequency of once every 2 days on this soil, D. barbatus achieved aboveground height of 14.5cm, and 14.9 at a watering frequency of once every 3 days. Also, on Leaf mold soil, the aboveground height of L. cyrtobotrya decreased with reduced watering frequency (from once every 2 days to once every 3 days), with mean heights of 13.8cm and 11.5cm respectively.
Figure 4: Effects of watering frequency on the seedling height (aboveground height) for two species (mean ± SE). Once daily (W1) (control), Once every 2 days (W2), and Once every 3 days (W3) represent the watering frequencies used for leaf mold soil (LMS) and merchantable soil (MS). The letters above the error bar indicates the level of difference among watering frequencies for each soil type at p = 0.05 within each species. Watering frequency also affected the total aboveground height of seedlings for all two species. On Merchantable soil, total seedling height of L. Cyrtobotrya increased with decreased watering frequency from once daily, to once every 2 days, and to once every 3 days (Fig. 5). Also, on this soil, the total aboveground height of D. barbatus increased as the watering frequency decreased from once daily to once every 2 days, but reduced as watering frequency further decreased to once every 3 days. At a watering frequency of once every 3 days on this soil, L. cyrtobotrya achieved total height of 231cm, with 651cm and 625cm for D. barbatus at once every 2 days and once every 3 days watering frequencies respectively. On Leaf mold soil, the total aboveground height of D. barbatus increased with reduced watering frequency (from once daily, to once every 2 days), and then reduced as watering frequency further reduced to once every 3 days. At a watering frequency of once every 2 days on this soil, D. barbatus achieved total aboveground height of 449cm. Also, on Leaf mold soil, the total aboveground height of L. cyrtobotrya decreased with reduced watering frequency (from once every 2 days to once every 3 days). L. cyrtobotrya achieved a total height of 97cm on this soil at the once every 2 days watering frequency.
Figure 5: Effects of watering frequency on the total height (aboveground height) for two species. Total height represents the sum of heights for all the plants. Once daily (W1) (control), Once every 2 days (W2), and Once every 3 days (W3) represent the watering frequencies used for leaf mold soil (LMS) and merchantable soil (MS). The letters above the error bar indicates the level of difference among watering frequencies for each soil type at p = 0.05 within each species. 3.5. THE EFFECT OF WATERING FREQUENCY ON SEEDLING RELATIVE GROWTH RATE (RGR)Watering frequency also affected the Relative Growth Rate (RGR) of seedlings for all two species. On Merchantable soil, RGR of L. Cyrtobotrya and D. barbatus increased with decreased watering frequency (from once daily, to once every 2 days), and then reduced as watering frequency further decreased to once every 3 days (Fig. 6). At a watering frequency of once every 2 days on this soil, L. cyrtobotrya achieved RGR of 94.3%, and 133.2% for D. barbatus. On Leaf mold soil, the RGR of D. barbatus and L. Cyrtobotrya increased with reduced watering frequency. At a watering frequency of once every 3 days on this soil, D. barbatus achieved RGR of 172.4%, and 101.5% for L. cyrtobotrya.
Figure 6: Effects of watering frequency on the relative growth rates (%) of two species (mean ± SE). Once daily (W1) (control), Once every 2 days (W2), and Once every 3 days (W3) represent the watering frequencies used for leaf mold soil (LMS) and merchantable soil (MS). The letters above the error bar indicates the level of difference among watering frequencies for each soil type at p = 0.05 within each species. 4. DISCUSSIONThe efficient progression of germination determines the nature of seedling establishment and the proper development of mature plants (Wojtyla et al. 2016). The initial step in germination is the imbibition of water by the various tissues within the seed. This enables the embryo to break through the softened seed coat and renders the seed coat more permeable to gases, so that respiration can proceed (Meyer and Donald, 1952). The amount of water provided to the soil influence seed germination and seedling establishment (Tylor et al., 1982), but there is limited information on the favorable watering frequency for seed germination and plant growth. The germination and growth of different plant species also vary with respect to soil types and watering frequencies. Stiles (1948) reported that seed germination varies with varieties, as seed coats of different seeds have different absorption capacities of water. Generally in this study, some measured parameters showed positive correlations with each other such as: germination rate with leaf number (r=0.790**, p=0.000); plant height with survival rate (r=0.651**, p=0.001); plant height with leaf number (r=0.774**, p=0.000); survival rate with leaf number (r=0.657, p=0.000) etc. This study showed that seed germination and aboveground heights of D. barbatus and L. cyrtobotrya decreased at the more regular watering frequency of once daily, both in the Leaf mold soil and Merchantable soil. This result is similar to that obtained by Dasberg and Mendel (1971) who reported that at high soil moisture, germination of Oryzopsis holciformis decreased. More regular watering of once daily thus provided high soil moisture, which reduced seed germination. This decrease in germination could be as a result of the thickening of the water films around the seeds, which interfered with oxygen diffusion. On Leaf mold soil, the total height and mean height of L. cyrtobotrya decreased with increased water stress at once every 3 days watering frequency. These results agreed with that of Momen et al. (1979); Lutfor and Mesbah (2000); Majnoun et al. (2009) who reported decrease in plant height with more severe soil moisture deficits. Similarly, the total height of D. barbatus decreased with increased water stress at once every 3 days watering frequency on this soil, even though its mean height did not decrease. Water stress results in depression of plant height (Nielsen and Nelson, 1998; Shenkut and Brick, 2003; Mannan et al. 2016) especially in soils that easily become dry and hardened as it is the case for Leaf mold soil. Also, reduced soil moisture during the early seedling stage diminishes growth which in turn would result in a reduction of yield (Constable and Hern, 1978). It affects both elongation and expansion growth (Anjum et al., 2003; Shao et al., 2008). Thus, the decrease in plant height on this soil with time could be as a result of the fact that the top soil easily got dried and hardened over time thus reducing the amount of water and dissolved nutrients for uptake by the seedlings. On Merchantable soil, the total height and mean height of L. cyrtobotrya instead increased with increased water stress at once every 3 days watering frequency, indicating that this plant is more resistant to stress on this soil. Contrarily, the total height and mean height of D. barbatus decreased with increased water stress at once every 3 days watering frequency on this soil. Generally, the survival rates of both species reduced in treatments that had higher germination rates especially on Merchantable soil. This could be as a result of the fact that with increased germination, more seedlings were available in the soil, thus resulting to increased competition for soil nutrients and eventual death of some weaker seedlings. However, on leaf mold soil, increased water stress (once every 3 days watering frequency) resulted to lower survival rates of both L. cyrtobotrya and D. barbatus. Severe water stress may affect photosynthesis, disturb metabolism and finally result to plant death (Jaleel et al., 2008). This study showed that generally on Leaf mold soil, once every 2 days watering is the suitable watering frequency for many plant species in terms of achieving best seed germination and seedling establishment. Thus, on this soil, high soil moisture (once daily watering frequency) and very low soil moisture (once every 3 days watering frequency) discourages seed germination and seedling establishment. Contrarily on Merchantable soil, once every 3 days watering is the suitable watering frequency for L. cyrtobotrya in terms of achieving best seed germination and seedling establishment, whereas both 2 days and 3 days watering frequencies tend to be suitable for D. barbatus on this soil. Watering frequency is thus an important determinant in soils for seed germination and seedling establishment, as it has a direct contribution to the adequate or required amount of soil moisture. The results provide enough proof for the selection of species and soils, as well as the determination of the watering frequency, with regards to seed germination and seedling establishment. 5. CONCLUSIONWatering frequency significantly affects seed germination and seedling establishment on different soil types. Generally, once every 2 days watering frequency is appropriate for seed germination and seedling establishment for most species on Leaf mold soil. Thus, more frequent watering (once daily watering frequency) and increased water stress (once every 3 days watering frequency) on this soil discourages seed germination and seedling establishment. Therefore, soils that easily get dried and hardened can be more productive only in conditions of moderate soil moisture. Contrarily, once every 3 days watering frequency is appropriate for seed germination and seedling establishment on Merchantable soil. Both L. cyrtobotrya and D. barbatus performed well on this soil at the once every 3 days watering frequency. The once every 2 days watering frequency is also adequate for germination and restoration of D. barbatus on this soil. This indicates that plants tend to be more resistant on soils that have a good drainage and do not easily become hardened, but have the potential of retaining moisture for a considerable period. Tree plants (L. cyrtobotrya) appeared to perform poorly in conditions of high moisture both on Leaf mold soil and Merchantable, and also in conditions of water stress (once every 3 days watering frequency) on Leaf mold soil. Contrarily, herbaceous plants (D. barbatus) performed better than L. cyrtobotrya on these conditions. SOURCES OF FUNDINGThis research received no specific grant from any funding agency in the public, commercial, or not-for-profit sectors. CONFLICT OF INTERESTThe author have declared that no competing interests exist. ACKNOWLEDGMENTThis research did not receive any specific grant from funding agencies in the public, commercial, or not-for-profit sectors. REFERENCES[1] Andres, P. and Jorba, M. 2000. Mitigation strategies in some motorway embankments (Catalonia Spain). Restoration Ecology 8:268–275. [2] Anjum, F., Yaseen, M., Rasool, E., Wahid, A. and Anjum, S. 2003. Water stress in barley (Hordeum vulgare L.). I. Effect on morphological characters. Pakistan Journal of Agricultural Sciences 40: 43-44. [3] Bentsik, L., and Koornneef, M. 2008. Seed dormancy and germination. Arabidopsis Book 6, e0119. doi: 10.1199/tab.0119. [4] Carmona, R. and Murdoch, A.J. 1995. Interactions of temperature and dormancy – relieving compounds on the germination of weed seeds. 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