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J. Hortl. Sci.
Vol. 17(1) : 245-248, 2022

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Short Communication

Effect of tree age on fruit characteristics, seed emergence and
seedling growth in Rambutan (Nephelium lappaceum L.)

Rashied Tetteh1*, Lawrence Misa Aboagye1, Eric Ansah Osafo1, Robert Darko1,
Augustine Dassah2 and Jennifer Obirih-Opareh1

1CSIR-Plant Genetic Resources Research Institute, P.O. Box 7,  Bunso, Eastern Region, Ghana.
2University for Development Studies, Box TL 1350, Tamale, Ghana.

*Corresponding author E-mail : rashbalm@yahoo.com, rashiedt62@gmail.com

ABSTRACT
Rambutan (Nephelium lappaceum L.) is an important exotic fruit from Asia, which is gaining
popularity due to its nutritional benefits. The objective of the study was to evaluate the effect
of tree age on fruit characteristics, seed emergence and seedling growth of rambutan. The
study was conducted at the CSIR-Plant Genetic Resources Research Institute, Bunso, Ghana.
Fruits of rambutan were harvested from 8, 10, 25 and 40 years old trees at different locations
of the field genebank. For each tree age, three trees were used as replicates. Fruits harvested
from trees of different ages were assessed for total fruit weight, pulp weight, pericarp weight,
seed weight, percentage seed emergence, seedling plant height and number of leaves at monthly
intervals. Fruits harvested from 8, 10, 25 and 40 years old trees did not show significant
difference in fruit characteristics and seed emergence. Significant (p<0.05) differences were
observed in plant height and number of leaves at 5 and 6 months after emergence, respectively.

Keywords: Fruit characteristics, Rambutan, Seed emergence, Seedling growth, Tree age

Rambutan (Nephelium lappaceum L.) is a tropical
fruit that belongs to the Sapindaceae family (Wall,
2006). It is closely related to several other edible
tropical fruits, including the lychee, longan, pulasan,
and mamoncillo (Morton, 1987). It originated in
Malaysia and has been widely cultivated in South-East
Asia  including T ha iland,  Malaysia,  Indonesia ,
Singapore the Philippines and Sri Lanka (Tindall et
al., 1994). The rambutan tree is of medium evergreen
height.  Thailand is the largest producer of rambutan
growing 450,000 tonnes in the world, followed by
Indonesia at 100,000 tonnes, and Malaysia, 60,000
tonnes (Le Bellec, 2014).

Tree age plays an important role in fruit quality, but
studies to determine its effect are rare in fruit crops.
Ozeker (2000) reported that 20-year-old trees of
‘Marsh’ seedless grape fruit produced bigger fruit with
thinner  rinds compa red with 34-year-old trees.
Bramlage (1993) observed that Pome fruit harvested
fr om young tr ees wer e highly susceptible to
postharvest disorders. Lower quality apples were
obtained from trees of old age (Smith, 2003).  Khalid

et al. (2012) in their studies reported that fruits
harvested from old trees (35-year-old) had slightly
inferior quality as compared to fruit produced from18-
year-old tr ees. However, no studies have been
published on the effect of tree age on fruit quality of
rambutan. Thus, there is a need for comprehensive
research to determine the possible variation in fruit
quality in relation to tree age. The present study aimed
to assess the effect of tree age on rambutan fruits
characteristics, seed emergence and seedling growth.

In this study, fruits of rambutan were obtained from
young and mature trees at CSIR-Plant Genetic
Resources Research Institute field genebank (N 06o
17.839, W 000o 27.595, Alt 198.3 m above sea level),
Bunso, Eastern region, Ghana during the harvesting
season in July, 2018. The climate of the area is semi-
equatorial type and the vegetation is moist-deciduous
rainforest, with mean minimum annual temperature of
21.4oC and a mean maximum annual temperature of
31.3oC (Aboagye, 2005).  The area experiences bi-
modal rainfall pattern from April to July and from
September to the middle of November.  It has a mean



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Tetteh et al

J. Hortl. Sci.
Vol. 17(1) : 245-248, 2022

annual precipitation of 1455 mm; with the dry season
starting from the middle of November to March.

Physiologically matured fully ripe fruits (Red cultivar)
were harvested at maturity at random from trees of
different ages at four locations at the same time. These
comprised of 8 years old trees, 10 years old trees, 25
years old trees and 40 years old trees. For each tree
age, three trees were used as replicates. Thirty fruits
were sampled at random from each tree.

During seedlings establishment, insect pests such as
leaf miners and ants were controlled using K-optimal
insecticide (Landa-cyhalothrin 15 g l-1 +Acetamiprid
20 g l-1: EC) at a recommended rate of 40 ml to 15 l
of water at two weeks interval. Weeds were controlled
using a hoe as and when necessary.

Whole fruit weight and its components (i.e. pericap,
pulp, aril and seed) were determined using an
electronic balance. Thirty fruits were sampled from
each tree of different age for all replicates. For fruit
dry mass,10 fruits were harvested and separated
manually into pericarp, pulp and seed for dry mass
determination. Samples were dried at 80OC for 48
hours in an oven and weighed using an electronic
balance.

For germination test, fresh seeds extracted from 30
fruits of each rambutan tree were sown in polybags
of dimension 15.5cm x 20.5cm filled with topsoil. The
completely randomised design was used with three
replicates. Seeds sown were watered daily and kept
under shade trees.  Percentage seed emergence was
computed at 21 days after sowing, as a ratio of the
total number of seeds germinated to the total number
of seeds sown multiplied by 100.

Growth of rambutan seedlings was assessed by the
number of leaves and plant height at monthly intervals
for a period of six months. Plant height was measured
with a metre rule in centimetres.

Statistical analyses wa s conducted using SPSS
Statistics 21 (IBM, Chicago, IL, USA). One-way
ANOVA was used to test the effects of treatments.
When a significant difference was detected, Tukey’s
HSD test was performed to identify significant
differences among trees of different ages.

The results showed no significant differences (p>0.05)
in total fruit weight, pericarp, seed and aril fresh
weight of rambutan fruits harvested from trees of
different ages. Rambutan fruits harvested from 8 to
40 years old trees were in the range of 26.26 to 29.99g
in total fresh weight, 12.32 to 14.97g in pericarp
weight, 11.40 to 12.86g in aril weight and 2.24 to
2.73g in seed weight while percentage seed emergence
was in the range of 94.44 to 96.67%.

On rambutan fruit dry weight basis, no significant
differences were observed in pericarp, seed and aril
from fruits harvested from trees of different ages
(Table 2). Averagely, rambutan fruit characteristics on
dry weight basis were in the range of 2.29g to 3.08g
for pericarp, 1.43g to 1.63g for seed and 0.36g to
0.50g for aril.

Fig. 1 shows the number of leaves per plant of
rambutan seedlings recorded at monthly intervals after
seed emergence. No significant difference was
observed in number of leaves at 1, 2, 3, 4 and 5 MAE.
At 6 MAE, the number of leaves differed significantly
among seedlings established from trees of different
ages. Rambutan fruits harvested from 10 years old
trees had the highest number of leaves at 6 MAE, but

Age Fresh weight (g) % Seed

(years) Total fresh weight Pericarp Aril Seed emergence

8 26.26 (2.08) 12.32 (1.31) 11.40 (0.86) 2.53 (0.17) 94.44 (1.92)

10 28.99 (7.40) 14.97 (4.47) 11.61 (2.60) 2.41 (0.46) 95.56 (5.09)

25 28.36 (2.40) 13.46 (1.89) 12.17 (0.60) 2.73 (0.13) 95.56 (1.92)

40 27.28 (2.53) 12.49 (1.71) 12.86 (1.40) 2.24 (0.06) 96.67 (3.33)

ANOVA n.s. n.s. n.s. n.s. n.s.

Each value is the mean of three replicates and the standard deviation is shown in parentheses. One-way ANOVA: n.s= not significant.

Table 1. Rambutan fruit characteristics and percentage seed emergence



247

Effect of tree age on fruit characteristics, seed emergence and seedling growth

was not significantly different from trees which were
8 and 25 years old. Rambutan seedlings from 40-year-
old trees obtained the lowest number of leaves. Leaves
are the principal photosynthetic organs of plants
(Wright et al, 2004). The production of leaves
represents an increase in the photosynthetic surface
area for plants. Koch et al. (2004) and Tozer et al. (
2015) reported that the size of leaves (e.g., leaf surface
area, leaf dry mass and leaf length) profoundly affects
a variety of biological processes, for instance, plant
gr owth, surviva l,  r eproduction, and ecosystem
function. In the present study, the increase in number
of leaves indicates a higher photosynthetic activity in
seedlings from fruits harvested from 10 years old trees.
Besides, the increase in number of leaves in seedlings
from 10 years old rambutan trees could also impact
on plant-water relations and nutrient uptake positively.

Table 2. Rambutan pericarp, seed and aril dry weight.

Age (years)
Dry weight (g)

Pericap Seed Aril

8 2.44 (0.26) 1.62 (0.18) 0.44 (0.26)

10 3.08 (0.83) 1.63 (0.21) 0.36 (0.17)

25 2.16 (0.10) 1.61 (0.02) 0.37 (0.03)

40 2.29 (0.28) 1.43 (0.13) 0.50 (0.07)

ANOVA n.s. n.s. n.s.

Each value is the mean of three replicates and the standard deviation is shown in
parentheses. One-way ANOVA: n.s= not significant.

Rambutan seedlings plant height at monthly intervals
after seed emergence obtained from fruits harvested
from different tree ages is shown in Fig. 2. No
significant difference was observed in plant height at
1, 2, 3, 4 and 6 months after emergence. However, at
5 MAE,  a  significant differ ence (p<0.05) was
observed. Rambutan fruits harvested from 10 years
old trees had the highest plant height at 5MAE, but
was not statistically different from tress which were
8 and 25 years old. Rambutan fruits sampled from 40
years old trees obtained the lowest plant height at
5MAE. The increase in seedling plant height from
fruits harvested from 10 years old trees may be
attributed to the increase in number of leaves observed
in the present study. Similarly, Lyngdoh et al. (2014)
indicated that seedling attributes after 12 months
showed that seedlings obtained from young and

Fig. 1. Number of leaves per plant of rambutan seedlings at months
after emergence from trees of different ages. Each value is the mean
of three replicates and the vertical bars indicates standard error. One-
way: *p<0.05, n.s.=not significant. When a significant difference
was detect ed, Tukey’s HSD te st was performed t o identify
significant differences among the 4 treatments. Different letters
above the bar indicate significant difference.

Fig. 2. Plant height of rambutan seedlings at months after
emergence form trees of different ages. Each value is the mean
of three replicates and the vertical bars indicates standard error.
One-way: *p<0.05, n.s.=not significant. When a significant
difference was detected, Tukey’s HSD test was performed to
identify significant differences among the 4 treatments. Different
letters above the bar indicate significant difference.

J. Hortl. Sci.
Vol. 17(1) : 245-248, 2022



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Tetteh et al

middle-aged plantations of Livistona jinkensiana
(between 18 to 45 years) performed better than those
beyond 50 years. Raja et al. (2004) also found that
seeds collected from middle-aged trees of Areca nut
which were 45 years old consistently had highest shoot
length, root length, number of roots, seedling dry
weight and vigour index compared to seeds collected
from trees aged 7,14,21 and 28 years. Mao et al.
(2014) reported a significant effect on relative height
growth rate by altering their biomass allocation among
Pinus thunbergia seedlings obtained from different age
classes.

Tree age had no significant effect on rambutan fruit
char a cter istics a nd seed emergence.  However,
seedlings established from fruits harvested from trees
of different ages showed significant differences in
number of leaves per plant and plant height. Fruits
harvested from 10 years old trees exhibited better
seedling growth. Seedlings obtained from rambutan
fruits from middle-aged trees can be considered for
nursery establishment.

ACKNOWLEDGEMENT
The authors acknowledge the Council for Scientific
and Industrial Research-Plant Genetic Resources
Research Institute (CSIR-PGRRI) for the plant
material and facilities. We are also grateful to Mr.
Nicholas Badger, Benjamin Kwakye Adu and all staff
at the seed store of CSIR-PGRRI for their support
during the study.

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J. Hortl. Sci.
Vol. 17(1) : 245-248, 2022

(Received: 10.06.2021; Revised: 18.05.2022; Accepted: 26.06.2022)


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