Electromagnetic Modeling of the Propagation Characteristics of Satellite Communications Through Composite Precipitation Layers


Science and Technology, 6 (2001) 15-19 
© 2001 Sultan Qaboos University 
 

Variation in Seedling Characteristics of Five 
Populations of Acacia tortilis From the United 
Arab Emirates in Response to Increasing Sodium 
Chloride Concentrations 

Fatma. M. Al-Ansari* and Rashied. S. Modawi** 

*Biology Department, U.A.E. University, P.O. Box 15551, Al Ain, U.A.E.;  
**Biology Department, Al Albayt University, P.O. Box 130346, Al-Mafraq, Jordan.  

 التباين في خواص البادرات في نمط استجابة خمس عشائر من نبات أكاسيا تورتيليس من اإلمارات العربية المتحدة
      لتراكيز مختلفة من كلوريد الصوديوم

 مضوي. األنصاري والرشيد  س. فاطمة م

مارات العربية المتحدة وبعد إجراء     تـم جمع بذور أشجار أكاسيا تورتيليس من خمسة مواقع في مدينة العين بدولة اإل              : خالصـة   
 150 و 90 و 20كلوريد الصوديوم وهي صفر و   المعاملة األولية بحامض الكبريتيك المركز نبتت تحت أربعة تراكيز من محلول

 و لطول   ولقد كان لتركيز الملح تأثيرا معنويا على كل من نسبة إنبات البذور وسرعة اإلنبات والمحتوى المائي للبادرات                . مليمول  
المجموع الجذري وللمجموع الخضري للبادرات ، كما أظهرت الدراسة أن التباين في نمط استجابة مجموعات البذور التي جمعت                  
مـن مواقع مختلفة للمعاملة بالمحاليل الملحية يشير إلى وجود اختالفات وراثية في تكيف النباتات على البيئات المحلية والذي يمكن   

الها إلى عشائر متميزة نتيجة تأثرها بدرجات متفاوتة في انخفاض منسوب المياه الجوفية والتوسع العمراني في                أن يـؤدي إلى انعز    
 .   المنطقة

   
ABSTRACT: Seeds of Acacia tortilis collected from 5 sites around the city of Al Ain in the United 
Arab Emirates were germinated in 4 concentrations of sodium chloride (0, 20, 90 and 150 mM of 
NaCl). Percent of germination, rate of germination, seedling moisture content, root and shoot lengths 
and seedling lengths were all significantly affected by salt stress. Seeds collected from the different 
sites were significantly different in their response to salinity conditions. Variations in the response of 
seedlings from different sites to the different salt treatments suggest an underlying genetic variability 
within the A. tortilis   populations, possibly resulting from variations in the prevailing local conditions. 
Urbanization in the area and the changing water table may have divided A. tortilis into distinct 
subpopulations that are significantly different in seedling characteristics and their response to saline 
conditions.  
 
KEYWORDS: Acacia tortilis, Seed Germination, Variability, Salt Stress.  

1.  Introduction 

A cacia tortilis (Forssk.) Hayne is a medium flat-topped tropical tree legume that belongs to the  family leguminosae, subfamily Mimosoidae. It is known to predominate in areas of prolonged 
dry season such as those prevailing in the eastern plains of the United Arab Emirates (Western, 
1989). In this semi-arid region, vegetation cover has shown considerable fluctuations. This is 
attributed to the scarcity of natural resources in the region, the frequent short term fluctuations in 
the climate and the increasing human interference. The city of Al-Ain of the United Arab Emirates 
(UAE) (latitude 2415 , Longitude 5545 and altitude 301.6 m above sea level) was established 160 km 
east of the Gulf Coast near Al Buraimi Oasis. The area is characterized by a relatively high water 
table, semi-stable sand dunes with frequent outcrops of limestone. Scattered stands of Acacia sp. 
And prosopis sp. are common with high incidence of annuals after a rainy winter (Western, 1989). 

15 



AL ANSARI and MODAWI 
 

Ground water constituted the major source of water for domestic and agricultural uses. Ground 
water depletion during the last three decades may have resulted in the lowering of the water table 
and increased soil salinity, especially around Al Ain. It may have also contributed to the decline in 
stands of Acacia and Prosopis in the region (Western, 1989).  

 
Figure 1. Relative location of the different seed collection sites around the city of Al Ain, UAE. 
 

Increasing soil salinity is a common problem that is affecting more lands in semi-arid areas. 
Plant adaptation due to prevailing conditions demands their ability to grow at sodium chloride 
concentrations that are lethal to unadapted plants. Plant species that are adapted to saline soils may 
become a valuable genetic resource. It has been suggested that a great deal of variability exists for 
adaptation to drought and salinity in arid and semi-arid conditions (Amzallag et al., 1995). Stability 
in the expression of such trails has been shown to correlate with coefficient of variation under 
uniform conditions.  

 
Table 1: Analysis variance summaries (mean squares) of the data for germination percentage, 
rate of germination and lengths of shoots, roots and seedlings of five populations of A. tortilis 
under saline conditions.  

  
Source of Variance Germination 

percentage 
Germination 
rate 

Seedling 
length 

Shoot length Root length  

Population (P) 414.79*** 5.88** 1454.8* 2552.75** 1359.96** 
Salinity (S) 273.77*** 2.06* 10067.7*** 470.14** 1272.24** 
P× S interaction 20.0*** 1.65* 2091.1* 1134.28** 199.49 N S 

  
*, ** and *** = significant at .05, .01 and .001 levels respectively; NS = non-significant.  
 

Stress conditions may expose unrecognized variability within and between plant populations. 
Limited reports dealt with tree legumes of the region in relation to drought adaptations. We carried 

 16



VARIATION IN SEEDLING CHARACTERISTICS OF FIVE POPULATIONS   
 

out the study on the population biology and adaptation of one of the key species (Acacia tortilis) in 
the changing environments of the region. The primary objective of the present study was to assess 
the extent of variation for salt tolerance in different populations of Acacia tortilis, particularly at 
the initial growth stages.   

2.  Materials and Methods 

Mature pods and seeds of A. tortilis were collected from five sites around the City of Al-Ain in 
the UAE: site A, south west (Zakhir); site B, west (Asharej); site C, east (Al-Buraimi); site D, north 
east (Al-Oha); and site E, north of Al-Ain (Al-Hili). See Figure 1.The urban collection sites are 
undisturbed areas that are at least 5 km apart, separated by major structures such as the University 
Campus, a highway, residential areas and the city center. Within each site seven to thirteen trees 
were sampled. Seed and pod collections were made towards the end of the spring of 1996. Seed 
moisture content was determined by weight difference before and after oven drying at 105 C for 24 
h. Seeds were pretreated with concentrated sulfuric acid for 30 min, thoroughly washed with 
distilled water, placed in 9 cm Petri-dishes on “seed test thick” 9 cm filter papers (Whatman’s No. 
1) and kept moistened with 0, 20, 90 or 150 mM of NaCl solutions. Fifty seeds were placed in each 
Petri dish with three replicates for each treatment combination. Seeds were germinated at 25° C ± 
1°  C. The germination was assessed as the percentage of seeds with radicles emerging each day for 
10 days. The mean rate of germination of each population was determined as Maguire Index  where 
MI equals the sum Ni /Ti , where Ni = the number of seeds that germinated in each time, Ti from 
the beginning of the experiment. Root and shoot lengths for each treatment were measured after 10 
days of germination. Data were analyzed statistically using two-way analysis of variance.  

 
Table 2: The effect of NaCl concentration in germination medium on seedlings root, on shoot 
length germination percentage and an germination rate of five populations of Acacia tortilis 
from UAE.  

 
NaCl concentration (mM)  

 0 20 90 150 0 20 90 150 
Population Root length (MM) Germination percentage  
A Zakhir 34.4 a* 42.9 ab 41.0 ab 29.7 ab 35.0 b 35.3 b 31.7 b 20.3 b 
B Asharej 33.7 a 36.7 ab 48.9 a 40.6 a 42.3 ab 42.7 ab 41.7 ab 29.0 ab 
C Al Buraimi 41.8 a 49.3 a 46.3 ab 35.7 ab 41.0 ab 39.7 ab 36.7 ab 34.7 ab 
D Al Oha  41.4 a 39.8 ab 35.2 ab 21.5 b 48.7 a 48.7 a 44.0 a 42.7 a 
E Al hili 40.9 a 34.3 b 32.2 b 28.5 ab 34.0 b 36.7 b 33.0 ab 30.3 ab 
 Shoot length (mm) Germination rate (number/day) 
A Zakhir 59.0 a 56.7 a 47.0 a 37.8 a 23.4 b 23.4 b 23.6 b 22.3 b 
B Asharej 52.1 ab  52.4 ab 38.7 b 29.8 ab 24.3 ab 24.0 ab 23.5 b 22..0 b 
C Al Buraimi 46.8 bc 41.5 bc 38.0 bc 28.3 ab 24.7 a 24.5 a 24.6 a 26.0 a 
D Al Oha  52.8 ab 56.3 ab 40.6 ab 32.6 ab 25.1 a 24.7 a 23.9 ab 22.8 ab 
E Al hili 47.5 b 45.9 ab 37.7 bc 25.4 b 24.3 ab 24.2 ab 24.2 ab 23.8 ab 
 Change in root length:shoot length 

ratio as % of control 
Change in seedling water content as 
% of control 

A Zakhir 0.0 +31 +53 +36 0.0 -0.44 -4.01 -5.68 
B Asharej 0.0 +8 +94 +109 0.0 -1.90 -4.25 -5.82 
C Al Buraimi 0.0 +34 +37 +42 0.0 +0.68 -4.29 -5.76 
D Al Oha  0.0 -9 +12 -15 0.0 -0.78 -4.36 -6.59 
E Al hili 0.0 -13 -1 +30 0.0 -2.94 -4.53 -4.52 

  
* Along each column means followed by the same letter are not significantly different (α = 0.05) 
according to Duncan Multiple Range test.   

 17



AL ANSARI and MODAWI 
 

Table 1 shows mean square, F values and probability for the different parameters as affected 
by population, salinity. The five populations were significantly different in all parameters. The 
different populations were also significantly affected by the different salt concentrations.  

The data for on root lengths, shoot lengths, germination percentage and germination rate of the 
5 populations of A. tortilis are presented in Table 2. The five populations were significantly 
different in seed germination percentage (Table 1). The increasing concentrations of the saline 
solutions decreased the germination medium was also did different NaCl concentrations. The 
populations showed a slight but significant reduction in the rate of germination that was more 
pronounced at the higher salt concentrations.  

Although the five populations of seeds were significantly different in their initial seed 
moisture content, their respective seedlings lost 4-4.5 % and 4.5-6.6 % of their moisture content 
when geminated at 90 mM and 150 mM of NaCl solutions, respectively, as compared to 
germination in distilled water (Table 2).  

Root length of seedlings from populations D and E were markedly reduced by the higher salt 
concentrations. Seedlings of populations A, B, C had longer roots at the 20 and 90 mM salt levels 
but reduced length when germinated in distilled water and 150 mM NaCl. Shoot length of 
populations A, B, D and E were not significantly reduced by the 20 mM treatment compared to the 
control. However, in all populations the increase in salt from 20 mM to 90 mM and then to 150 
mM resulted in a significant reduction in shoot length. Both root and shoot lengths as well as the 
overall seedling length showed significant population times salt concentration interaction. In all 
populations, seedling length was significantly reduced at 150-mM NaCl. The effect of the higher 
salt concentrations was more pronounced on the shoot than on the root elongation.  The is reflected 
in the increase in root: shoot ratio for populations A, B and C. Populations D and E both showed 
increases and decreases in root: shoot length ratio compared to the control.  
 

 
3.  Discussion 

Analysis of the germination characteristics of five seed populations of A. tortilis, collected 
from five sites around Al Ain, suggests that the recently urbanized semi-arid plains of eastern 
U.A.E. have been under the influence of both biotic and abiotic factors. This may have started the 
noticeable changes in the local plant communities observed by Western, (1989). The low 
germination percentage observed in this study at different salt levels, despite seed pretreatment 
with sulfuric acid suggests that the hard seed coat of the species has developed as an adaptation to 
permit a few seeds to germinate in the harsh conditions of the semi-arid climate. Populations A and 
B had a very low rate of germination at the higher salt levels. Seedling length was the highest at the 
20 mM salt concentration for all populations except E where the control produced the longer 
seedlings. However, 20 and 90 mM levels of NaCl seemed to have promoted root growth of 
population B. It has been previously suggested (Saab et al  1990) that higher NaCl concentrations 
increased root growth and decreased shoot growth. This was reflected in the increased root length : 
shoot length ratio with the increasing salt concentration. This was true for all the populations 
except D which showed a slight decline in root to shoot ratio at the 150 mM concentration. The 
populations were also different in their response. Koehl (1996) suggested that reduced shoot : root 
ratio has a selective advantage in delaying the onset of critical water saturation deficit and thereby 
the plants ability to take up additional water from deeper soil levels.  

Coleoptile and root growth has also been reported to be involved in seedling response to 
dehydration (Guidera, et al, 1997). Salinity is reported to cause a reduction of water uptake in 
many species of Acacia seeds (Rehman, et al, 1996). In this study this was reflected in reduced 
seedling water content. The variation between the population may point to possible adaptation to 
changing local environments. The high heritability estimates for the rate of germination in rice, 
chickpea and lentil reported by Rao, et al (1997) and Mamo, et al, (1996) may explain the high 
genetic variability observed variation between populations in their seedling characteristics. Studies 

 18



VARIATION IN SEEDLING CHARACTERISTICS OF FIVE POPULATIONS   
 

are underway to quantify the genetic variability within this species and to correlate such 
adaptations with environmental attributes specific to the region.  

References 

AMZALLAG, G.N, SELIGMAN, H and LERNER, H.R. 1995. Induced variability during the 
process of adaptation in Sorghum bicolor. Journal of Experimental botany 46: 1017-1024.    

GUIRERA, M., SHROYER, J.P., KIRKHAM, M.B. and PAULSEN, G.M. 1997. Wheat coleoptile 
and root growth and seedling survival after dehydration and  rehydration Agronomy Journal 
89(5): 822-826.    

KOEHL, K. 1996. Population specific traits and their implications for the evaluation of drought-
adapted ecotypes in Armeria maritime. Botanica Acta 109(3): 206-215.   

MAMO, T., RICHTER, C. and HEILIGTAG, B. 1996. Salinity effects on growth and ion content 
of some chickpea (Cicer areitinum L) and lentil (Lens culinaris Medic.) varieties. Journal of 
Agronomy and Crop Science 176(4): 235-247.    

RAO, L.V., SUBBA, S.K. and VANISREE, G. 1997. Genetic variability for seedling 
characteristics among rice (Oryza sativa L.) cultivars. Seed Research 24(2): 124-128.    

REHMAN, S, HARRIS, P.J.C., BOURNE, W.F. and WILKIN, J. 1996. The effect of sodium 
chloride on germination and potassium and calcium content of Acacia seeds. Seed Sci & 
Technology. 25: 45-57.   

SAAB, I.N., SHARP, R. E., PRITCHARD, J and VOETBERG, G.S. 1990. Increased endogenous 
abscisic acid maintains primary root growth and inhibits shoot growth in maize seedlings at 
low water potentials. Plant Physiology  93: 1329-1336.   

WESTERN, A. 1989. The Flora of The United Arab Emirates-An introduction. UAE University, 
Al Ain, U.A.E.  

 
 
 
Received   2 October 2000 
Accepted   21 January 2001 
                     

 
 

 19


	Fatma. M. Al-Ansari* and Rashied. S. Modawi**
	ÝÇØãÉ ã. ÇáÃäÕÇÑí æÇáÑÔíÏ  Ó. ãÖæ�
	Materials and Methods