American Journal of Plant Sciences
Vol.05 No.20(2014), Article ID:50179,10 pages
10.4236/ajps.2014.520321

Seed Germination and Effects of three Watering Regimes on the Growth of Dialium guineense (Wild) Seedlings

O. Olajide1, A. A. Oyedeji2,3*, G. S. Tom1, J. Kayode4

1Department of Forestry and Wildlife, Faculty of Agriculture, University of Uyo, Uyo, Nigeria

2Plant Science Unit, Department of Biological Sciences, Niger Delta University, Wilberforce Island, Bayelsa State, Nigeria

3Department of Environmental and Analytical Sciences, Faculty of Science and Engineering, University of Wolverhampton, Wolverhampron, UK

4Department of Plant Science, Faculty of Science, Ekiti State University, Ado-Ekiti, Nigeria

Email: solaolajide1967@gmail.com, *ayodele.oyedeji@yahoo.com

Copyright © 2014 by authors and Scientific Research Publishing Inc.

This work is licensed under the Creative Commons Attribution International License (CC BY).

http://creativecommons.org/licenses/by/4.0/

Received 19 July 2014; revised 21 August 2014; accepted 11 September 2014

ABSTRACT

The effectiveness of three pre-germination treatments in breaking dormancy of the seeds of Dialum guineense and effects of three watering regimes on the growth performance of the seedlings were investigated. The pre-germination treatments were: soaking in hot water for 10 seconds and cooling down in cold water (T1), soaking in cold water for 24 hours (T2), soaking in running water for 48 hours (T3) and control (T4), while watering regimes include: watering once daily in the morning (W1), watering once every two days in the morning (W2) and watering once every three days in the morning (W3). The results showed that germination occurred first at 5 days after sowing (5 DAS) among the seeds soaked in cold water for 24 hours before sowing (T2), while the untreated seeds (control) took the longest period of 12 days before germination occurred. T1 had the highest germination value of 49.6% while T3 had the least of 31.2%. The effects of watering regimes were found to be significantly different on stem-collar diameter, leaf area and total dry weight (P < 0.05). The least significant difference (LSD) test showed that W2 and W3 supported the best growth performance. It is concluded from the results that T2 should be adopted for breaking the dormancy of Dialium guineense seeds and watering interval of three days would not dispose the seedlings to water-stress.

Keywords:

Dialium guineense, Seeds, Dormancy, Pre-germination, Seedlings growth, Watering regimes

1. Introduction

The benefits of forest in the provision of arrays of products and services of great importance to man’s survival and balanced development have been recognized. Natural forests, particularly in the tropical region, are complex ecosystem. They have great diversity of tree species with different uses. One of the fundamental and indispensable needs of man provided by forests is food. This is the benefits that have been ignored in the past and are currently being eroded as forests in many parts of the world are cleared and the remaining trees on farmlands come under increasing pressure [1] .

Tropical rainforests are stocked with many tree species that produce copious edible, highly nutritious and medicinal fruits, seeds, leaves, twigs nuts and bark which are of socio-economic importance [2] . However, the rapidity of erosion of genetic resources occasioned by seemingly unmitigated deforestation is alarming. Attempts are being made to conserve these tree species, but these have been difficult to achieve because of paucity of information on their ecology and silviculture. Thus, the potentials of the trees have virtually not been improved, and many of them are on the verge of extinction. The essential ecological and silvicultural information needed on the trees includes flowering and fruiting patterns, seed germination and growth requirement to facilitate domestication and improvement of their potentials.

The current research is therefore, designed to investigate the germination of the seeds and seedlings growth of Dialium guineense in response to different watering regimes. Dialium guineense, commonly called Black Velvet Tamarind, is a small size tree of rainforest that produces seeds, which have edible and nutritious outer-coat. It belongs to the family Caesalpinaceae. The seeds are available in the dry season and widely sold in markets in Southeastern Nigeria. It is popularly referred to as “Vitamin C seed”. It is hoped that the information gathered would help conservation and domestication of the tree species.

2. Materials and Methods

2.1. Seed Collection

Matured and uninjured ripe fruits of Dialium guineense were collected from the southeastern belt of Nigerian rainforest. The fruits were depulped and their seeds extracted mechanically.

2.2. Seed Germination

A total of one thousand (1000) seeds were used for the germination experiment. Two hundred and fifty (250) seeds each were given the following pre-germination treatments:

1) Soaking in hot water for 10 seconds and cooling down in cold water for one hour (T1).

2) Soaking in cold water for 24 hours (T2).

3) Soaking in running water for 48 hours (T3).

4) Untreated seeds or control (T4).

All the seeds were sown on the same day on separate germination boxes filled with topsoil from forest floor by broadcasting method. Each germination box measured 90 cm × 70 cm × 7.5 cm. Watering was done daily in the morning in an over-head shade nursery. Germination counts were taken daily and spanned for five weeks from the first day germination was observed.

2.3. Growth assessment

One hundred and eighty (180) sturdy seedlings at four leaf stage were transplanted from germination boxes into polypots filled with topsoil collected from forest floor. The physicochemical parameters of the topsoil are as follows: base saturation (77.23%), sand (87.20%), silt (5.60%), clay (7.20%), pH (6.47), exchangeable cation (0.14), organic matter (3.11%), total nitrogen (0.16%), available phosphorus (29.33 mg/kg1) and exchangeable bases (7.73 cmol/kg). Sixty (60) seedlings each in three replicates of twenty (20) seedlings per replicate were subject to the following watering regimes:

1) Watered once daily in the morning (W1).

2) Watered once every two days in the morning (W2).

3) Watered once every three days in the morning (W3).

The seedlings were arranged in a completely randomized design in a glass overhead shade nursery. The seedlings were assessed for growth performance three months after transplanting. The growth parameters assessed include shoot height, stem collar-diameter, leaf number, leaf area and total dry weight (biomass). Seedling height and stem collar diameter were measured with metre rule and Vanier Caliper respectively. Leaf number was assessed by physical counting and total leaf area of each seedling was determined by using the grid method. The total dry weight was assessed by carefully uprooting each seedling and then separated into shoot and root components. The root and shoot components of each seedling were oven-dried to constant weight at 80˚C to determine the biomass.

2.4. Data Analysis

Percentage germination was calculated for each pre-germination treated and non-treated seeds. The mean of each growth parameter was calculated for each of the three categories of seedlings. The growth parameters data were subjected to analysis of variance (ANOVA). The means of the significantly different growth parameters were separated using least significant difference (LSD) test [3] .

3. Results

The first germination was recorded at 5 DAS from the seeds soaked in cold water for 24 hours (T2). The seeds soaked in hot water for 10 seconds (T1) had its first germination 6 DAS while the seeds soaked in cold water for 48hours (T3) and non-treated seeds (T4) recorded their first germination 7 and 12 DAS respectively. T1 had the highest germination value of 49.6%, while T3 had the least of 31.2% (Table 1).

The seedlings watered once every three days (W3) had the highest mean shoot height of 10.41 cm while those watered once every two days (W2) had 9.22 cm and the once watered everyday (W1) had 9.03 cm. The analysis of variance (ANOVA) showed that there was no significant difference (P > 0.05) between the effects of the watering regimes on the height growth of the seedlings. Seedlings subjected to W3 had the highest mean stem-col- lar diameter of 0.28 cm while those of W2 had the least mean stem-collar diameter of 0.26 cm. W1 seedlings had 0.27 cm as mean stem-collar diameter. The ANOVA of the stem-collar diameters shows that there was a significant difference (P < 0.05) between the effects of the watering regimes on the seedlings stem-collar diameters (Table 2). The stem-collar diameter data are presented in Appendix 1.

The least significant difference (LSD) Value of the stem-collar diameter was 0.0271 and it which revealed no difference between the means stem-collar diameters of W1, W2 and W3 seedlings. The highest mean leaf number of 11 was recorded by the seedlings watered once every three days (W3), while the seedlings watered once every two days (W2) had the least number of 9. The seedling watered once daily (W1) had the mean leaf number of 10. The ANOVA of leaf number was not significant (P > 0.05). The W3 seedlings had the highest mean leaf area of 152.44 cm2, while W2 had 86.96 cm2 and W1 had 81.91 cm2. The ANOVA of leaf area showed that there was a significant difference between the effects of the watering regimes on the seedlings’ leaf areas (Table 3). The leaf area data are contained in Appendix 2.

The LSD value of leaf area was 28.13 which showed that there was no difference between the mean leaf number of W1 and W2 seedlings but there was difference between W1 and W3, and W2 and W3. The W3 seedlings had the highest mean total dry weight of 0.7192 g, while W2 seedlings had 0.4220 g and W1 seedlings had the least of 0.3454 g. The ANOVA of the total dry weight indicated that there was significant difference (P < 0.05) in the effects of the watering regimes on dry matter accumulation (Table 4). The total dry weights of individual seedlings are in Appendix 3.

The LSD value of total dry weight was 0.3586, which indicated that difference only occurred between the means total dry weights of W1 and W3 seedlings.

4. Discussion

Most of the tropical forest trees’ seeds have been found to exhibit dormancy which enable them to remain on the forest floor and in the topsoil for a long period of time until favourable conditions are available via natural or human perturbation of the forest to stimulate their germination [4] [5] . Therefore, it often takes a long time before germination commences if the seeds of the trees are sown without any pre-germination treatment to break their dormancy. Dormancy can be a result of a hard seed coat, which is impervious to water and aeration required to stimulate germination or presence of chemical inhibitor in the seed cotyledon [6] [7] . In this study, germination occurred first at 5 DAS from among the seeds soaked in cold water for 24 hours as against other

Table 1. Effectiveness of pre-germination treatments on the seeds of Dialium guineense.

Table 2. Analysis of variance of stem-collar diameters of Dialiun guineense seedling subjected to three watering regimes.

*Significant; WR = watering regimes.

Table 3. Analysis of variance of leaf area of Dialium guineense seedlings subjected to three watering regimes.

*Significant; WR = watering regimes.

Table 4. ANOVA of total dry weight of Dialium guineense seedlings subjected to three watering regimes.

*Significant; WR = watering regimes.

References

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Appendix

Appendix 1. The stem-collar diameter (cm) of Dialium guineense seedlings subjected to three watering regimes.

Appendix 2. The leaf area (cm2) of D. guineense seedlings subjected to three watering regimes.

Appendix 3. The total dry weight (g) of D. guineense seedlings subjected to three watering regimes.

NOTES

*Corresponding author.