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Received: 16 Dec 2022. Received in revised form: 01 May 2023. Accepted: 07 Jun 2023. Published online: 19 Jun 2023. 
From Volume 13, Issue 1, 2021, Notulae Scientia Biologicae journal uses article numbers in place of the traditional method of 
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Saadaoui E et al. (2023) 
Notulae Scientia BiologicaeNotulae Scientia BiologicaeNotulae Scientia BiologicaeNotulae Scientia Biologicae    

Volume 15, Issue 2, Article number 11411 
DOI:10.15835/nsb15211411 

    Research ArticleResearch ArticleResearch ArticleResearch Article.... 

NSBNSBNSBNSB    
Notulae Scientia Notulae Scientia Notulae Scientia Notulae Scientia 

BiologicaeBiologicaeBiologicaeBiologicae 

 
 

Seed diversity and germination behavior in Seed diversity and germination behavior in Seed diversity and germination behavior in Seed diversity and germination behavior in Nerium Nerium Nerium Nerium oleander oleander oleander oleander L.L.L.L.    
 

Ezzeddine SAADAOUI1*, José J.M. GÓMEZ2, Kaouther Ben YAHIA3, 
Emilio CERVANTES2 

 
1University of Carthage, INRGREF, LGVRF, Regional Station of Gabès, Tunisia; saad_ezz@yahoo.fr (*corresponding author) 

2IRNASA-CSIC. Cordel de Merinas 40, 37002, Salamanca, Spain; jjaviermg@gmail.com; ecervant@usal.es 
3University of Carthage, INRGREF, LEF, Tunisia; adam.kaouther@yahoo.fr 

 
AbstractAbstractAbstractAbstract        
    
Nerium oleander var. ‘Villa Romaine’, commonly called oleander, is an ornamental shrub that exists in 

Tunisia in the wild and cultivated form. This plant is frequently propagated and produced in nurseries and 
used in urban plantings and on roadsides. The effects of nature of the plants (spontaneous or cultivated), 
climatic conditions (localities), and altitude (from 6 to 447 m) on seed shape, size, and germination of Tunisian 
populations, were investigated. Seeds were harvested from 23 locations belonging to six bioclimatic stages and 
distributed from North to South of Tunisia. The seed parameters studied were area, roundness, J index, and 
germination rate. A significant variation was obtained between populations, categories (cultivated and 
spontaneous), bioclimatic zones and altitudes. Seeds of cultivated plants were the smaller and showed the 
higher germination rates, compared with spontaneous populations, which had large seeds and a low 
germination rate. Climatic conditions and geographical location had an effect on seed morphology; seeds in 
lower humid were small for both cultivated and spontaneous types, they also showed a low J index value and a 
high germination rate. On the other hand, in upper Saharan, seeds were large and roundness and germination 
rate were the lowest. Also, seeds from plants in higher altitudes were the smaller and presented the lower values 
of the J index compared with those collected from low-altitude sites. 

    
Keywords:Keywords:Keywords:Keywords: diversity; germination; Nerium oleander L.; seed; shape 
 
 
IntroductionIntroductionIntroductionIntroduction    
 
Nerium oleander L., an evergreen shrub or small tree, is a unique species of the genus Nerium from the 

Apocynaceae family. Even though being toxic in all its parts, this species is widely cultivated, resulting in one of 
the most poisonous among cultivated plants. It belongs to the tropical element of the Mediterranean scrub 
flora, that is, a set of taxa of tropical origin that probably evolved before the onset of the Mediterranean climate 
but now coexist with more recent, purely Mediterranean elements (Quezel, 1985). In Tunisia, N. oleander 
grows both spontaneously and cultivated. Its fruit (5-15 cm in length and 6-10 mm in diameter) consists of 
two follicles. The young unripe small fruit is green but it turns red when fully grown but still unripe. Upon 
maturation, the fruit dries, turns brown, and its follicles twist to liberate the many small, plumed, wind-
dispersed seeds (Lev-Yadunet al., 2009). The seed of N. oleander has an oblong shape and excluding 

https://www.notulaebiologicae.ro/index.php/nsb/index


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ornamentation, the 100 seed weight is 0.3 g. The length, width and thickness of the seed are 4.7, 1.5 and 0.7 
mm respectively (Demonty et al., 2014; Figure 1). Molecular analyses of this species by RAPD and AFLP show 
its high genetic variability (Zibbu and Batra, 2015). Nerium oleander var. ‘Villa Romaine’ investigated in this 
work is characterized by its simple flowers, light pink and slightly fragrant. Its presence in the arid regions of 
Tunisia reflects its drought tolerance. The plant is propagated by seeds or cuttings. A germination rate above 
82% and a rooting percentage of 100% were obtained for sowing and cuttings respectively (Simion and Anton, 
2009).  

 

 
Figure 1.Figure 1.Figure 1.Figure 1. Nerium oleander. Plants growing in Bou Hedma (site number 19). Flower, leaves, fruit, seeds. 
The hairs were removed from the seed for the morphological study 
 
Seed morphology may give information useful in the phenotypic characterization and phylogenetic 

relationships between varieties and cultivars. An accurate description of seed shape may be done by comparison 
with geometric figures that resemble seed images. This method has been developed in the model plant 
(Arabidopsis thaliana L., Cervantes et al. (2010) as well as in the model legumes, Lotus japonicus L. and 
Medicago truncatula Gaertn (Cervantes et al., 2012). Also, several studies have analyzed the diversity of Silene 
species and populations with seed shape based on the comparison with geometric models, by comparing the 
seeds to the ellipse and cardioids shapes (Martín-Gómezet al., 2020, 2022a, 2022b; Juan et al., 2022; Rodríguez-
Lorenzo et al., 2022) studied the diversity. In Capparis spinosa L., the comparison of seed images with the 
cardioid curve was helpful to describe differences between two subspecies (Saadaoui et al., 2013). In the 
Euphorbiaceae Jatropha curcas L. and Ricinus communis L., seed shape was quantified by comparison with an 
ellipse; the form/production relationship has been verified (Saadaoui et al., 2015, 2017; Martín-Gómez et al., 
2016). 

We have established a protocol to analyze seed shape in N. oleander. The model applied for the 
quantitative geometric analysis has been an ellipse. Quantification with a model allows the comparison of seed 
shape in populations grown in different climatic regions as well as between seeds proceeding from plants grown 
spontaneously or cultivated in 23 locations in Tunisia. The main objectives of this work are to analyze the seed 
variability between populations, sites, and states (spontaneously or cultivated) and the effect of these 
characteristics on seed germination. We present in the study the variations in size, shape, and germination rate 
of seeds in plants of Nerium oleander. 



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Materials and MethodsMaterials and MethodsMaterials and MethodsMaterials and Methods    
 
Plant material 

Mature seeds were obtained in the spring of 2019 from developed plants growing in 23 locations in 
Tunisia (Table 1). Seeds were collected from five plants per location. Ten fruits were harvested from each 
individual, the seeds of each population were pooled and 30 seeds per location were used in the analysis. 

A total of 708 seeds from 23 populations of Nerium oleander var. ‘Villa Romaine’ grown in six different 
climatic regions throughout Tunisia was analyzed (Table 1). From the total, 570 seeds proceed from cultivated 
plants, growing on roadsides and 138 belong to spontaneous populations. Cultivated plants were obtained by 
cuttings, from spontaneous plants, and after several generations. In nature, N. oleander is mainly propagated by 
seeds. 

 
Table 1. Table 1. Table 1. Table 1. Geographic localization of studied populations    

Population 
code 

Population Latitude (N) Longitude (E) 
Altitude 

(m) 
Type Bioclimate* 

1 Rimel 37°03’ 41.31’’ 9° 30’ 34.51’’ 149 Cultivated 
 
 

Lower Humid 
 

2 Teskraya 37° 15’ 14.55’’ 9° 54’ 36.17’’ 6  
Spontaneous 

 
3 Bellif 37° 04’ 05.53’’ 9° 01’ 33.80’’ 77 
4 Ain Snoussi 1 36° 49’ 45.95’’ 8° 55’ 50.29’’ 386 
4’ Ain Snoussi 2 36° 49’ 12.72’’ 8° 55’ 27.49’’ 447 

 
 
 
 

Cultivated 
 

5 Sidi Bou Said 36° 51’ 10.47’’ 10° 19’ 08.57’’ 10  
Upper Semiarid 

 
6 Grombalia 36° 35’ 26.66’’ 10° 28’ 24.49’’ 70 
7 Sidi Khelifa 36° 14’ 49.02’’ 10° 25’ 29.13’’ 30 
8 Sousse 35° 46’ 52.35’’ 10° 36’ 52.35’’ 41  

Lower Semiarid 
 

9 Msaken 35° 41’ 49.74’’ 10° 33’ 54.10’’ 46 
10 Monastir 35° 45’ 49.16’’ 10° 48’ 22.80’’ 33 
11 Kairouan 35° 40’ 30.0246’’ 10° 06’ 44.48’’ 54 

 
Upper Arid 

 

12 Hbira 35° 10’ 55.48’’ 10° 17’ 05.80’’ 140 
13 Sfax 34° 49’ 07.24’’ 10° 42’ 17.21’’ 54 
14 Bou Hedma 34° 29’ 20.41’’ 9° 26’ 41.90’’ 346 Spontaneous 

15 
Bir Ali Ben 

Khelifa 
34° 44’ 17.55’’ 10° 05’ 23.76’’ 171 

 
 

Cultivated 
 

 
 
 

Lower Arid 
 

16 Gafsa 34°26’ 06.27’’ 8° 46’ 50.95’’ 317 
17 Skhira 34°17'36.57" 10°03'56.27" 32 
18 Nahel 33° 52’ 28.07’’ 10° 03’ 51.07’’ 27 
19 Hamma 33° 52’ 50.56’’ 9° 46’ 24.98’’ 60 
20 Ghandri 33° 43’ 36.18’’ 10° 09’ 07.88’’ 43 Spontaneous 
21 Zerkine 33° 41’ 00.70’’ 10° 15’ 29.94’’ 25  

Cultivated 
 

22 Medenine 33° 21’ 40.85’’ 10° 28’ 14.03’’ 112 
23 Kebili 33° 41’ 53.23’’ 8° 57’ 56.06’’ 33 Upper Saharan 

* Bioclimates according to the classification of Emberger (1955) 

 
Image capture 

Photographs of longitudinal views of seeds were taken with a digital camera Nikon DS-Fi1 adapted to a 
Nikon ‘SMZ-1500’ stereo-microscope. Composed images containing the model (ellipse; see later) and each 
seed were elaborated with the software image Corel PHOTO-PAINT X7. Quantification of areas was done 
with Image J (Java Image Processing Program).  In this process, a microscopy photograph of graph paper was 
used to convert pixels into mm.  

 
 



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Quantitative morphology 

Two magnitudes were used for the quantitative morphological analysis: Roundness and J index. 
Roundness, obtained with Image J, is defined by Ferreira and Wayne (2010) as: 

� �
4 x area

π
Major axis��
 

 
J index reflects the percent similarity of the seed image with a geometric figure used as a model. Based on 

seed measurements and image comparisons, the model used for shape quantification is an ellipse with a relation 
between the major and minor axis of 3.7. The model was obtained by superimposing the profiles of all the seeds 
and selecting color mask (black) of higher intensity with Corel PHOTO-PAINT X7 (Figure 2).  

The ratio between major and minor axis of 3.7 is also obtained as the mean value in all the seeds. 
Quantification of the adjustment as done in each seed by superimposing the seed image with the model 
(ellipse), and the ratio of the areas in two regions: The common region in the ellipse and the seed image (C), 
and the total area occupied by the ellipse and the seed image (Figure 2). The index of adjustment (J) is defined 
by: 

100
(D) area (C) area

(C) area
  J ×

+

=

 
Where C represents the common region and D the regions not shared (total area is the sum of shared 

and non-shared). Note that J ranges between 0 and 100, and decreases when the size of the non-shared region 
grows. It equals 100 when cardioid and seed image areas coincide, i.e., area (D) is zero. 

J Index was calculated for a total of 708 seeds (30 seeds per population; except in the Bellif population 
3 of only 18 seeds).  

 

 
Figure 2.Figure 2.Figure 2.Figure 2.    Left: Image of a seed (top) and model ellipse (bottom). Right: The common region in the ellipse 
and the seed image (top), and the total area occupied by the ellipse and the seed image (bottom). J index is 
the ratio between both magnitudes 
 
 

 

Germination tests 

Thirty seeds from each location were deposited in water agar 1% in Petri dishes. A total of 708 seeds 
were analyzed after 7 days of germination at 18 °C. Twenty-five seeds per Petri dish were tested, with four 
repetitions 

 
 

 



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Statistical analysis 

Analysis of variance (ANOVA) was applied to the comparison of magnitudes between populations and 
groups of populations (climates) as well as seed types (collected from spontaneous and cultivated plants) 
between the diverse populations. The magnitudes analyzed were seed area, roundness, J index, and germination 
rate. Post-hoc analysis was carried out using the Tukey test for samples of similar sizes such as, for example, 
comparisons between seed types in a population, the Scheffé test for groups of populations (altitude, climatic 
regions, or comparison between spontaneous and cultivated populations; in general, samples are of different 
sizes). 

Seed germination is a dynamic process. The analysis of seed germination in time was done with a GLM 
(General Linear Model, Christensen, 6; McCullagh and Nelder, 1989). This method allows to work with 
qualitative variables (plant types or varieties; here the comparison between spontaneous and cultivated 
populations) and combines regression analysis throughout successive moments with ANOVA involving values 
in all time points. GLM was done with two fixed factors: plant source, with two plant types (spontaneous and 
cultivated), with 138 levels for spontaneous plant type, 570 levels for cultivated, and one random factor, seed. 

Statistical treatment and graphics were done with SPSS® v. 23. For the analysis, the significance level 
p=0.05 was established; in addition, six digits of precision were used throughout the calculations.  

 
 
Results Results Results Results     
 
Effect of population 

For all the morphological parameters analyzed (area, roundness and J Index), the variation is significant 
between populations (P <0.05). Ain Snoussi 2, cultivated plants, showed the lowest area (4.44 mm2) and 
Teskraya, spontaneous site, had the highest (7.73 mm2). For roundness, the highest value was at Ain Snoussi 2 
(0.358) and the lowest was at Kebili (0.257), belonging to lower humid and upper Saharan climates, 
respectively. At the end, the highest J index (87.4) is at Bou Hedma and Gafsa (two nearby sites) and the lowest 
is at 76 at Ain Snoussi 2 (Table 2). 

 
Table 2. Table 2. Table 2. Table 2. Comparison between populations for morphological parameters    

Population N Area (mm2) Roundness J Index 
Rimel 30 7.22g.h 0.273a.b.c 86.1b.c 
Teskraya 30 7.73h 0.297a.b.c 85.2b.c 
Bellif 18 4.74a.b 0.294a.b.c 85.4b.c 
Ain Snoussi 1 30 6.15c.d.e.f 0.267a.b 84.1b.c 
Ain Snoussi 2 30 4.44a 0.358d 76.0a 
Sidi Bou Said 30 7.00f.g.h 0.280a.b.c 84.3b.c 
Grombalia 30 6.35c.d.e.f.g 0.293a.b.c 85.8b.c 
Sidi Khelifa 30 5.69b.c.d.e 0.293a.b.c 84.7b.c 
Sousse 30 6.48d.e.f.g 0.283a.b.c 86.0b.c 
Msaken 30 6.95f.g.h 0.267a.b 86.3b.c 
Monastir 30 5.59b.c.d 0.283a.b.c 85.6b.c 
Kairouan 30 5.37a.b.c 0.300a.b.c 83.1b.c 
Hbira 30 5.35a.b.c 0.293a.b.c 85.1b.c 
Sfax 30 6.31c.d.e.f.g 0.290a.b.c 83.4b.c 
Bou Hedma 30 6.55d.e.f.g 0.283a.b.c 87.4c 
Bir Ali Ben Khelifa 30 6.75f.g.h 0.312c 83.5b.c 
Gafsa 30 4.76a.b 0.273a.b.c 87.4c 
Skhira 30 6.03c.d.e.f 0.307b.c 82.6b 
Nahel 30 6.40d.e.f.g 0.280a.b.c 87.3c 
Hamma 30 6.63e.f.g 0.287a.b.c 84.6b.c 
Ghandri 30 6.52d.e.f.g 0.293a.b.c 85.8b.c 



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Zerkine 30 6.34c.d.e.f.g 0.283a.b.c 84.3b.c 
Medenine 30 6.29c.d.e.f.g 0.263a.b 83.9b.c 
Kebili 30 6.66e.f.g 0.257a 85.3b.c 

N: Number of Seeds 
Significant differences (at 0.05 significant level) are indicated by different letters (a,b,c,d,e,f,g and h) 

 
Effect of the category (spontaneous /cultivated) 

A summary of results concerning the comparison between spontaneous and cultivated plants is 
presented in Table 3; a significant difference (P <0.05) was observed between these two categories regarding 
for the area, J Index, and germination rate. Seeds of the cultivated plants are smaller, and have a lower J index 
and higher germination rate.  

On the other hand, the roundness and germination rate are without significant differences between 
spontaneous and cultivated sites. 

Only location number 4 (Ain Snoussi, in the lower humid climate) contains spontaneous and cultivated 
plants, and also in this population seeds from cultivated plants are smaller, with higher roundness and lower J 
index values than the seeds obtained from spontaneous plants (Figure 3).  

 
TabTabTabTable 3. le 3. le 3. le 3. Comparison between spontaneous (S) and cultivated (C) plants for area, roundness, J index and 
germination % 

 Type N Mean Standard deviation Standard error Significance 

Area (mm2) 
S 38 6.48 1.44428 0.12295 

0.005 
C 70 6.14 1.23909 0.05190 

Roundness 
S 38 0.286 0.04233 0.00360 

0.638 
C 70 0.288 0.05182 0.00217 

J Index 
S 38 85.6 4.4436 0.3783 

0.012 
C 70 84.5 5.3372 0.2236 

Germination (%)  
S 38 49 50 4.3 

0.001 
C 70 65 48 2.0 

N: Number of Seeds 

 



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Figure 3.Figure 3.Figure 3.Figure 3. Representative seeds of the two populations grown in Ain Snoussi (cultivated (A) and 
spontaneous (B)) and Kebili’s population(C) (Scale is 5 mm). 
 
Effect of bioclimates 

Bioclimates have a significant effect (P <0.05) on the parameters of seed diversity. For the cultivated 
populations, a low area was recorded in lower humid and upper arid. However, the highest value was observed 
in the upper Saharan (Table 4 and Figure 3). For roundness, the highest value was recorded in lower humid, 
and the lower value was in upper Saharan. J index also varied. In fact, the lowest averages were in the lower 
humid, and high averages were observed in lower semi-arid, lower arid and upper Saharan. For germination, 
the lowest germination rate is in the upper Saharan (Table 4). 

For the spontaneous populations, area, roundness, and germination rate were not significantly different. 
Only the J index was significantly different. Indeed, it was low in the lower humid and high in the upper and 
lower arid (Table 5). 

 
Table 4. Table 4. Table 4. Table 4. Comparison between climatic regions for cultivated plants    

Bioclimate N Area (mm2) Roundness J Index Germination (%) 

Lower Humid 60 5.83a 0.316c 81.0a 75b 
Upper Semi-arid  90 6.35a. b 0.289b. c 84.9b 72b 
Lower Semi-arid 90 6.34a. b 0.278a. b 85.9b 67b 
Upper Arid 90 5.68a 0.294b. c 83.9a. b 72b 
Lower Arid 210 6.17a. b 0.286b 84.8b 59a. b 
Upper Saharan 30 6.66b 0.257a 85.3b 33a 

 
    
    



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Table 5. Table 5. Table 5. Table 5. Comparison between climatic regions for spontaneous plants 

Bioclimate N Area Roundness J Index Germination (%) 

Lower Humid  88 6.43a 0.285a 84.8a 58 a 
Upper Arid 30 6.54a 0.283a 87.4b 43 a 
Lower Arid  30 6.52a 0.293a 85.8a. b 33 a 

 
Effect of altitude 

Table 6 shows a significant difference for the values of the area, as well as those of the J index according 
to the altitude; indeed, the area is 6.87 mm2 at low altitude and 5.47 mm2 at high altitude, in the same way the 
average values of J index are high (85.29) at altitude below 30 m and low (83.71) for altitudes above 300 m. On 
the other hand, these differences according to the altitudes are not significant for the roundness and 
germination rate.  

 
Table 6. Table 6. Table 6. Table 6. Comparison between seeds grown in different altitudes    

Parameters Altitude N Mean 
Standard 
deviation 

Standard 
error 

Significance 

Area (mm2) 
Below 30 m 120 6.87 1.12 0.102 

0.000 
Above 300 m 120 5.47 1.33 0.122 

Roundness 
Below 30 m 120 0.28 0.050 0.004 

0.147 
Above 300 m 120 0.29 0.059 0.005 

J Index 
Below 30 m 120 85.29 4.49 0.410 

0.037 
Above 300 m 120 83.71 6.94 0.634 

Germination (%) 
Below 30 m 120 58 49.5 4.5 

0.197 
Above 300 m 120 50 50.2 4.6 

 
    
DiscussionDiscussionDiscussionDiscussion    
 
Among the two magnitudes used to quantify seed shape in Nerium oleander, roundness and J index, 

taking as the model an ellipse of a relationship between the major and minor axis of 3.7. The values of the J 
index based on this model give an accurate approach to seed shape useful and complementary to roundness 
values. Nevertheless, the values obtained for J index are still lower than those obtained with other geometric 
models applied to a range of seed species. Cardioid or cardioid-derived figures were applied to the model plant 
Arabidopsis thaliana (L.) Heynh (Cervantes et al., 2010), as well as to the model legumes Lotus japonicus and 
Medicago truncatula Gaertn (Cervantes et al., 2012) and Capparis spinosa L. (Saadaoui et al., 2013). Ellipse-
based models were applied to the Euphorbiaceae Ricinus communis L. (Martín Gómez et al.2016; Saadaoui et 
al., 2017) and Jatropha curcas L. (Saadaoui et al., 2015). In the majority of these cases J index values were around 
90 reaching values over 95. To make shape comparisons between genotypes or treatments, we find that values 
for J index of 90 or upper provide better results. In general, those high values are obtained for seeds that present 
simple shapes, similar to geometric figures, and without appendixes or specialized structures for dissemination. 
Seeds of N. oleander, in addition to the hairs that cover their surface, don’t adjust completely to the ellipse 
because they tend to have elongated, sharpened and curled shapes, resulting in complex structures, diverging 
from simple geometric models. These parameters may be related to the complexity of seed dispersion (Herrera, 
1991) 

For cultivated plants, extreme climates (lower humid and upper Saharan) are characterized by extreme 
values for all three morphological parameters analyzed (J index, Roundness, and area; Table 4); this result 
points to the effect of climate on the development and morphology of the seed. There is no difference in seed 



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area between the spontaneous populations, although aridity favors small seeds (Peco et al., 2003; Saadaoui et 
al., 2013). But seeds of the Saharan site have an elongated shape which may assist them in hiding in small holes 
or apertures in the soil to adapt to the arid desert conditions (Figure 3).  

J index showed a considerable difference between studied bioclimates. For cultivated plants, the lowest 
is in the upper humid and the highest is in the lower semi-arid, followed by upper Saharan. Also, for the 
spontaneous plants, the lowest J index is in upper humid and the highest values are in upper arid, followed by 
lower arid. A correlation was observed between the spontaneous and the cultivated for the bioclimate effect on 
the J. index. Domestication reduces seed shape and J index, but the characters are variable with climatic regions. 

Germination rate differs between cultivated sites; the highest values were recorded for upper humid, 
upper semi-arid, lower semi-arid, and upper arid and lower for lower arid and upper Saharan. The latter showed 
the lowest germination rate (33%). This shows the direct effect of climatic conditions on cultivated plants and 
the quality of their seeds. Indeed, abiotic stress, particularly elevated temperature and water stress will reduce 
seed yield and quality (Hampton et al., 2016). 

Seed size and shape is influenced by altitude. Plants grown at higher altitudes produce seeds smaller and 
with lower values of the J index. Bonnier (1890) in his classical experiments cultivating diverse plant species at 
varying altitudes showed that higher altitudes result in reduced plant size, which may also result in smaller seed 
size. Similarly, in cactus (Gymnocalycium monvillei (Lem.) Britton and Rose), Bauk et al. (2015) studied the 
effect of altitude on the seed parameters and concluded the presence of a relationship between altitude and seed 
height and shape. Also, Pluess et al. (2005) confirmed the effect of altitude on the seed size for several species 
studied in the Swiss Alps. Rawat and Bakshi (2011) studied Pinus wallichiana and recorded a negative 
correlation between altitude, 1000 Seed weight, and Germination percentage. This correlation is positive with 
the germination period. But, for Abies pindrow (silver fir), Bhat et al. (2018) obtained a negative correlation 
between altitude and percentage germination. Our results showed the effect of population, climate, and altitude 
on seed diversity, also, the plant culture acts on these variables. Other factors may be influencing the seed size 
and shape of Nerium oleander seeds.  

 
ConclusionsConclusionsConclusionsConclusions        
 
This study was carried out at 23 Nerium oleander var. 'Villa Romaine' sites in different bioclimates of 

Tunisia. The analyses of variations within these localities by using morphological (Area, Roundness and J 
Index) and physiological (germination) parameters showed high variability. These variables reflected 
differences in size, shape and physiological behavior. The observed variations seemed to be directly related to 
populations, their nature (spontaneous or cultivated), and/or bioclimatic conditions and altitudes. 
 
 

Authors’ ContributionsAuthors’ ContributionsAuthors’ ContributionsAuthors’ Contributions 
  
Conceptualization of research (EC, ES, JJMG); Designing of the experiments (EC, JJMG); 

Contribution of experimental materials (ES, KY, JJMG); Execution of field/lab experiments and data 
collection (ES, KY, JJMG); Analysis of data and interpretation (EC, ES, JJMG, KY); Preparation of the 
manuscript (EC, ES, JJMG, KY). All authors read and approved the final manuscript. 
 
 

Ethical approvalEthical approvalEthical approvalEthical approval (for researches involving animals or humans) 
 
Not applicable. 
 



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AcknowledgementsAcknowledgementsAcknowledgementsAcknowledgements    
 
This research received no specific grant from any funding agency in the public, commercial, or not-for-

profit sectors. 
 
 

Conflict of InterestsConflict of InterestsConflict of InterestsConflict of Interests    
 
The authors declare that there are no conflicts of interest related to this article. 
 
 
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https://doi.org/10.1139/cjb-2015-0026  

Bhat HA, Mughal AH, Din Dar MU, Mugloo JA (2018). Cone, seed and germination characteristics in silver fir (Abies 
pindrow Spach) along the altitudinal gradient in western Himalayas. International Journal of Chemical Studies 
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Bonnier G (1890). Cultures expérimentales dans les Alpes et les Pyrénées. Revue Générale de Botanique 2:513-546. 
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