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Article

High Genetic Diversity of Shorea acuminata Dyer in the Rehabilitated Area of a Degraded Lowland Dipterocarp Tropical Rainforest

1
Centre of Foundation Studies, Universiti Teknologi MARA, Cawangan Selangor, Kampus Dengkil, Dengkil 43800, Malaysia
2
Department of Biological Sciences and Biotechnology, Faculty of Science and Technology, Universiti Kebangsaan Malaysia, Bangi 43600, Malaysia
3
Institute of Climate Change (IPI), Universiti Kebangsaan Malaysia, Bangi 43600, Malaysia
4
Institute for Environment and Development (LESTARI), Universiti Kebangsaan Malaysia, Bangi 43600, Malaysia
*
Author to whom correspondence should be addressed.
Forests 2021, 12(10), 1344; https://doi.org/10.3390/f12101344
Submission received: 9 August 2021 / Revised: 20 September 2021 / Accepted: 26 September 2021 / Published: 1 October 2021
(This article belongs to the Special Issue Political Ecology of Forests Ecosystem Services)

Abstract

:
The United Nation’s Decade on Ecosystem Restoration 2021–2030 aims to halt ecosystem degradation to achieve Sustainable Development Goals (SDGs) by 2030. In Malaysia, the concept of sustainable forest management (SFM) has been practiced since 1901. In this study, we evaluated the genetic diversity of the native dipterocarp timber tree Shorea acuminata in a rehabilitated area at Kenaboi Forest Reserve (Kenaboi FR). The rehabilitated area was formerly a degraded forest managed with the taungya restoration system for 50 years. All trees with diameter at breast height (DBH) of 5 cm and over were measured, tagged and identified in a one-hectare study plot. A total of 132 inner bark samples were collected for DNA extraction. Four SSR markers (Sle280, Sle392, Sle475 and Sle566) and two EST-SSR markers (SleE07 and SleE16) were used to analyse 95 good-quality DNA samples. Genetic diversity parameters including maternal contribution were determined for 75 samples. The genetic diversity of big trees (He = 0.656 ± 0.19) and small trees (He = 0.652 ± 0.17) were high and both were in genetic equilibrium, with Fis values of the big trees being 0.035 and small trees being 0.164. Clustering analysis based on Jaccard’s similarity values (at 95% confidence level) confirmed that big trees in the Kenaboi FR rehabilitated area had originated from genetically diverse seed trees of the Sungai Menyala Forest Reserve which were used as the planting stock for the taungya restoration system. Maternal contribution showed that the allele contribution of the small trees came from the planted S. acuminata trees within the study area. The high genetic diversity of small trees in this study provides strong evidence that the existing big trees would be suitable for a genetically diverse seed collection to rehabilitate other degraded forests. Sustainable forest management must emphasise genetic diversity in order to ensure the resilience of rehabilitated forest ecosystems.

1. Introduction

Forests around the world benefit humanity via a wide variety of functioning ecosystems that provide and regulate services such as mitigating climate change and water cycle and erosion control. Forest also provides cultural ecosystem services that people gain from their interaction with forest environmental spaces via activities such as tourism and recreation [1,2,3]. For Malaysia, the forest is not only an ecosystem service provider but it is also significant as an economic contributor. For example, the Malaysian timber industry is the third-ranked industry after palm oil and rubber in the primary commodities sector. According to the Malaysian Timber Industry Board (MTIB), the Malaysian timber and timber-related products will achieve RM23 billion for timber export in 2021 [4].
Meanwhile, deforestation and forest degradation keep accelerating and sweeping the world’s forest cover. For instance, the world population was estimated to reach 9.7 billion in 2050 and 11.2 billion in 2100 [5]. Five years prior to 2020, it was shown that the total area of tropical forests disappeared at a rate of 9.28 million hectares per year and only 25–30% of all existing tropical forests are old-growth forests [6,7]. In addition to conversion into agricultural land uses, deforestation is also a result of commodity-driven deforestation (27%), followed by logging activities (26%) and wildfire (23%) [8].
By recognising this situation, sustainable forest management is the best concept in balancing the environmental, social and economic objectives that are related to forests while meeting the needs of the present and future generations. Forest restoration and increase in forest areas are needed to meet the SDGs such as economic growth, poverty reduction and global environmental improvement.
Rehabilitation is one of the best silviculture practices in sustainable forest management. The important key to successful rehabilitation is the regeneration of the planting stocks in the degraded forest areas with high genetic diversity. Genetic diversity is an essential basis for the adaptation and resilience of tree species to environmental stress and change [9]. The effort on rehabilitating degraded areas is worthless if the planted trees have a low genetic diversity. According to Kettle [10], the establishment of plantations is increasing, but the genetic quality of the planting stocks has received little research attention. As a result, the rehabilitation areas will lose biodiversity, and the trees are not well adapted to such areas. No study has yet evaluated the genetic variation in restored tree populations [11]. The information about the genetic diversity of trees in the rehabilitated areas can be used as an indicator of long-term restoration success. Unfortunately, such studies are scarce [12,13,14].
About 250 acres of Kenaboi Forest Reserve (FR), Negeri Sembilan, Malaysia, is a rehabilitated area that has been treated with the taungya restoration system since 1969 [15,16]. The taungya restoration system is an agroforestry practice in Malaysia established since the 1950s to reduce the cost of rehabilitation of a degraded forest by using farmers who conducted forest plantations together with cash crops (banana, tapioca, papaya, pineapple, chili, pumpkin, maize, groundnut, sweet potato, watermelon, yam and ginger). Farmers gained benefits from the cash crops, while the forestry department obtained free labour services for forest plantations [17].
Compartment 107 is one of the degraded areas in Kenaboi FR that was treated by the taungya restoration system. The planting stocks were mainly indigenous species from the wildings of Shorea spesies taken from Sungai Menyala FR, Port Dickson, Negeri Sembilan. The planting stocks were Shorea leprosula Miq. (Meranti tembaga), S. parvifolia Dyer Ssp. parvifolia (Meranti sarang punai) and S. acuminata Dyer (Meranti rambai daun). Today, taungya is no longer practised in Malaysia after the new economic policies preferred a variety of industries that were more attractive than cash crop plantations in generating higher income with better assurance [17,18]. A previous study showed that compartment 107 was successfully rehabilitated with great potential for timber production of Shorea species [16]. Fatma et al. [19] found that the wildings of Shorea trees from Sungai Menyala FR were suitable planting stocks because the compartment was not only successfully rehabilitated but had established a forest structure similar to the primary forest. Fifty years of taungya restoration system showed that the highest tree density in compartment 107, Kenaboi FR was S. acuminata with 33.42% out of all trees in the compartment. However, the sustainability of the tree density relies on genetic diversity of the trees.
As mentioned earlier, genetic diversity is vital to ensure the success of the rehabilitation in the restored forest areas. In addition, the information on the genetic diversity can be used to evaluate the effectiveness of the taungya restoration system in compartment 107, Kenaboi FR. Low genetic diversity can threaten the long-term viability of the restored forests. If regeneration and spatial distributions of trees are indicators of a successful forest rehabilitation in a short term time frame, then genetic diversity is a prediction and proof of the successful adaptation of planting stocks in the rehabilitated area in the long term time frame.
In this study, the genetic diversity of the S. acuminata in compartment 107, Kenaboi FR, was evaluated using six microsatellite markers developed for S. leprosula. We assumed that the small trees are mostly the regenerated trees from seeds of the reproductively active big S. acuminata trees in the study plot. Genetic relatedness between the big and small trees of S. acuminata was determined and discussed. Maternal contribution was used to determine the allele contributions of small S. acuminata trees in compartment 107, Kenaboi FR. We hope that the results of the study will be useful to improve the policy on silviculture practices for sustainable forest management.

2. Materials and Methods

2.1. Study Plot and Sample Collection

This study was conducted in compartment 107, Kenaboi FR (300–600 m a.s.l), in the district of Jelebu, Negeri Sembilan, Malaysia (Figure 1). The district lies between latitude 2° 57′ N and longitude 102° 04′ E. Five subplots with dimensions of 20 m × 100 m each in compartment 107, Kenaboi FR, were established. The inner bark tissues were sampled from S. acuminata trees because the height of the trees made accessibility to the leaves more difficult than the inner barks. The inner barks were wrapped in wet tissues and sealed in labelled plastic bags before being brought to the laboratory. The diameter at breast height (DBH) for each S. acuminata trees in one-hectare study plot of compartment 107, Kenaboi FR, was also recorded. In this study, the trees with a diameter of 30 cm DBH and above (≥30 cm) were considered as big S. acuminata trees, and the trees with diameters below 30 cm DBH (<30 cm) were small S. acuminata trees.

2.2. DNA Extraction and Microsatellite Analysis

A total of 132 inner barks of S. acuminata were extracted by using the modified cetyltrimethylammonium bromide (CTAB) method [20]. About 3–5 g of inner bark tissues was ground by using a grinder (Millser IFM 66D, Iwatani, Japan). The samples were genotyped using seven microsatellite loci consisting of four SSR loci (Sle280, Sle392, Sle475 and Sle566 [21]) and three EST-SSR loci (SleE02, SleE07 and SleE16 [22]), all of which were developed for S. leprosula (Table 1).
Microsatellite amplification was performed in a 10 μL reaction volume containing 10 ng DNA, 50 mM KCl, 20 mM Tris–HCl (pH 8.0), 1.5 mM MgCl2 and 0.2 μM of each primer; 0.2 mM of each dNTP; and 0.5 U of Taq DNA polymerase (Bioline, Heidelberg, Germany). The PCR was carried out in a PCR MasterCycler® (Eppendorf, Germany). For SSR loci, an initial denaturing step at 94 °C for 3 min was carried out, followed by 35 cycles each at 94 °C for 1 min, 52–55 °C for 30 s and 72 °C for 45 s. A final extension step at 72 °C for 30 min was performed after the 35 cycles. For EST-SSR loci, an initial denaturing step at 94 °C for 3 min was conducted, followed by 40 cycles each at 94 °C for 1 min, 45 °C for 30 s and 72 °C for 30 s. A final extension step at 72 °C for 7 min was performed after the 40 cycles.
Genotyping was performed using the ABI PRISM® 3100 Genetic Analyzer (Applied Biosystem/Hitachi, Foster City, CA, USA), and the ABI PRISM® GeneScan software was used to score allele sizes. The total volume of PCR reaction was 25 µL with the same PCR protocol and programme, but the annealing temperature was adjusted accordingly to each primer. Only forward primers of SSR and EST-SSR were selected for fluorescent labelling either with ROX, FAM, TAMRA or HEX. The PCR amplifications were conducted by using microplate 96 well Half Skirt PCR (Axygen, Glendale, AZ, USA) and then sealed by using Microseal ‘A’ (BIO-RAD, Hercules, CA, USA). Thus, the analysis was only limited to 95 PCR reactions of S. acuminata derived from 45 small and 50 big S. acuminata trees which were selected for the analysis. The fragment analysis was carried out by preparing the amplifications into two panels in order to avoid overlapping alleles of same size from different loci (Table 2).

2.3. Data Analysis

The level of genetic diversity in compartment 107, Kenaboi FR, was estimated for polymorphic information content (PIC), observed heterozygosity, expected heterozygosity, Hardy-Weinberg equilibrium and frequency of null allele with the assistance of CERVUS 3.0 [23]. The genetic relatedness of S. acuminata trees in compartment 107, Kenaboi FR, was determined by using PAST3 Version 3.22 [24]. The genotype data from seven microsatellite loci were used to estimate similarity index in matrix form (n × n). Jaccard’s similarity coefficient was employed to build a dendrogram based on unweighted pair group method with arithmetic means (UPGMA).
Shaharuddin et al. [16] has predicted that the average diameter is 21.21 cm, and the mean annual increment is 1.06 cm per year for S. acuminata in Kenaboi FR over the 20 years period of the taungya restoration system. Now, the planted S. acuminata is almost 50 years old, and this study has found that the biggest S. acuminata tree in compartment 107, Kenaboi FR, is 60.3 cm DBH [19], supporting Shaharuddin et al. [16].
Maternal contribution between big and small S. acuminata trees in compartment 107, Kenaboi FR, was estimated by comparing genotype data from four SSR loci and three EST-SSR loci. Alleles at each locus for small S. acuminata trees were compared with that of the big S. acuminata trees. The big trees which did not share any alleles at each locus were excluded as candidate parents.
The seed trees will contribute the allele for small trees. According to Appanah and Rasol [25], the small dipterocarps trees are able to produce a fruit at 22 cm DBH. However, the study identified that only one out 22 dipterocarps trees produced fruit at the DBH size from 20 to < 30 cm DBH, which is lower compared to the dipterocarps trees that are 30–125 cm DBH and 11 out of 37 dipterocarps trees are fruiting trees. Therefore, in this study, the paternity study was conducted for big S. acuminata trees at three percentages of the biggest diameter size (DBH) trees, i.e., 10% of the biggest S. acuminata trees, 20% of the biggest S. acuminata trees and 30% of the biggest S. acuminata trees. Here, we assumed the biggest trees were the planted trees from the taungya restoration system. On the other hand, small trees of S. acuminata are the trees below 30 cm DBH, and they are mostly regenerated trees that were produced by the big S. acuminata trees in compartment 107, Kenaboi FR.

3. Results

A total of 123 genomic DNA were extracted from 132 inner barks of S. acuminata in compartment 107, Kenaboi FR. Nine of the inner barks were not of good quality due to poor handling in the field. About 48 genomic DNA were from small S. acuminata trees, whereas 75 genomic DNA were from big S. acuminata trees.
Out of the seven primers used, six primers were found to be polymorphic in the ABI PRISM® GeneScan software. The primers were four SSR loci and two EST-SSR loci. Only one primer showed monomorphic locus, which is SleE02. PCR was successfully amplified for 41 small S. acuminata trees and for 34 big S. acuminata trees with the mean of alleles being 6.7 and at 6.5 alleles. respectively (Table 3). SleE16 is the most efficient primer to detect polymorphism with the highest PIC, which is 0.813 for big S. acuminata and 0.786 for small S. acuminata trees. The lowest PIC is locus Sle280 with 0.309 for big S. acuminata and 0.293 for small S. acuminata trees.
The expected heterozygous (He) was higher than the observed heterozygous (Ho) for both big and small S. acuminata trees. The expected heterozygous for big S. acuminata is 0.656 and small S. acuminata trees is 0.652, whereas the observed heterozygous value for big S. acuminata is 0.623 and small S. acuminata trees is 0.549. This comparison was not significantly different from the Hardy–Weinberg equilibrium at p < 0.01 after sequential Bonferroni correction via CERVUS. The inbreeding coefficient (Fis) for the 34 big S. acuminata trees is 0.035 lower than Fis of the 41 small S. acuminata trees, which was 0.164. All of the six microsatellite loci did not significantly deviate from the Hardy–Weinberg equilibrium for both big and small S. acuminata trees. Null allele was detected in all loci except for Sle392 for big S. acuminata with a frequency range of −0.08 to 0.23. The highest null allele frequency was displayed by locus SleE07, and the lowest null allele frequency was shown by Sle475. For small S. acuminata trees, the highest null allele frequency was displayed by locus Sle475 at 0.13, and the lowest was shown by Sle392 at −0.01. According to Marshall et al. [26], the negative value for null allele frequency can be assumed as no existence of null allele. The null allele frequency that is below 0.2 can be used in the analysis of genetic diversity and paternity [27,28]. In this study SleE16 yielded null allele frequency of 0.23, but the locus SleE16 was not prone as null allele in the previous study [22]. On the contrary a high frequency of null allele indicates that the primer used has failed to detect loci in the PCR assay and, thus, cannot be used in genetic diversity and paternity study.
A dendrogram based on UPGMA revealed that 75 individuals of S. acuminata in compartment 107, Kenaboi FR, are divided into two main clusters, which are I and II (Figure 2). In cluster I, about 46% of S. acuminata consisted of big trees and 54% of S. acuminata consisted of small trees, whereas cluster II comprise only a big tree, A11 and two small trees, which are R4 and R98. The Jaccard’s similarity coefficient ranged from 0 to 0.889. The highest similarity of 89% was observed, and it was between R52 and R149. No similarity was observed between A11, A37, A40, A67 and A73, respectively, implying that these trees are taken from different seed trees with no shared pollen donors in Sungai Menyala FR. The small tree R4 also does not have similarity with R26, R28, R92 and R148 and also with two big trees, which are A63 and A80. The highest Jaccard’s similarity coefficient for regenerated trees is 0.385 for R4 and R98. Therefore, the S. acuminata trees in compartment 107, Kenaboi FR are genetically diverse as illustrated in the dendrogram. Figure 3 shows the distribution for all S. acuminata trees in compartment 107, Kenaboi FR. The ten big S. acuminata trees with DBH 50 cm and above are dispersed in the compartment, and the trees could be potential seed trees in this rehabilitated area.
The total exclusion probability (the exclusion probability in the case of both parents being unknown [26]) over four SSR loci and two EST-SSR loci for S. acuminata is 0.849. From the maternal contribution, when the percentage of the biggest big tree of S. acuminata increased, the percentage of allele contribution of small S. acuminata from the planted trees in the study plot decreased (Table 4). The mean for percentage of allele contribution from big S. acuminata trees outside of the study plot is 7.8%. The allele contribution of small S. acuminata from big S. acuminata outside of the study plot was 14%, if the big S. acuminata is 10% of the biggest trees. The DBH for 10% of the biggest tree was between 52 and 60 cm, which is a small amount of a big tree, and only eight big S. acuminata trees were in the study plot. If the big S. acuminata was 20% of the biggest trees, i.e., trees between 46 and 60 cm DBH (15 trees), the allele contribution of small S. acuminata trees was 9.5% from big S. acuminata outside of the study plot. If the big S. acuminata was 30% of the biggest tree, i.e., trees between 42 and 60 cm DBH (24 trees), the allele contribution of small S. acuminata trees comes from the planted trees in the study plot.

4. Discussion

The microsatellite markers that were developed for S. leprosula were applicable to amplify 75 S. acuminata in compartment 107, Kenaboi FR. Other studies mentioned that the markers are able to resolve the genetic parameters in other Shorea species as well [21,22,29,30]. The SSR markers are derived from genomic libraries. On the contrary, EST-SSR markers are the sequence derived from expressed and functional sequences that are present in the genome [31]. Thus, this study suggests that the transferability of genomic SSRs and EST-SSRs to closely related species is high due to the conservation of flanking DNA sequences of SSR motifs between closely related species.
The mean expected heterozygosity (He) detected in big and small tree S. acuminata was 0.656 and 0.652, respectively. These values are almost similar to that reported in a previous study on the same species but in a primary forest where the same SSR markers, i.e., Sle280, Sle392, Sle475 and Sle566, were used, providing a mean expected heterozygosity of 0.676 [29].
Genetic diversity for big and small trees of S. acuminata was high although the big trees were wildings from one population in Sungai Menyala FR. This value is considered high compared to other studies, which are 0.616 [28] and 0.811 [32]. The high genetic diversity of S. acuminata in the rehabilitated area of Kenaboi FR draws a few possibilities that need to be understood. The possibilities are either that the Sungai Menyala FR is a good seed production area for enrichment planting, or because S. acuminata is a desirable species to be used as a planting stock or the effects of the type of silviculture practices may influence the genetic diversity of the rehabilitated area.
Zeng and Fisher [33] claimed that the genetic diversity for native tropical oak in Hong Kong, Quercus bambusifolia, is the highest (0.69) when the sources of seeds for the trees are from multiple populations rather than the trees which are naturally regenerated in one rehabilitated forest area. Ang et al. [34] found that the genetic diversity of S. leprosula used for enrichment planting was low compared to natural regenerated stands. More reduction happens if the seedlings were taken from single-species plot compared to mixed-species plot. The genetic diversity value is not significantly different for enrichment planting of S. parvifolia either in the permanent forest or other silviculture systems. However, the details of the planting stocks used in this enrichment planting programme are not described [35]. A reasonable explanation for the high genetic diversity of S. acuminata in the rehabilitated area of Kenaboi FR is that the planted S. acuminata were taken from different seed trees in Sungai Menyala FR. Therefore, when the planting stocks were planted in a degraded area during the taungya system, the area was successfully rehabilitated and contained high genetic diversity after 50 years. The idea that the planting stocks of S. acuminata were taken from different seed trees in Sungai Menyala FR was supported by cluster analysis (Figure 2). The average of similarity index of 0.329 indicates that all 75 S. acuminata trees are highly diverse. Trees A11, A37, A40, A67 and A73 are the trees that originated from different seed trees in Sungai Menyala FR. Tree A67 is the biggest S. acuminata tree in compartment 107, Kenaboi FR; therefore, the tree is the planted tree from the taungya restoration system. This tree also can be suggested as a potential seed tree in the rehabilitated area in addition to the other nine big S. acuminata trees, which are A15, A18, A32, A40, A42, A63, A64, A79 and A91 (Figure 3). The highest similarity observed for small trees of S. acuminata was between R52 and R149 with DBH of 28 cm and 11 cm, respectively. Tree R52 is most likely a planted S. acuminata during the taungya restoration system with stunted growth. According to Shaharuddin et al. [16], the taungya plot was not treated with proper silvicultural treatment until the study was conducted. Therefore, interspecies and intraspecies competition could occur and affect the growth of some planted trees, resulting in some stunted trees. Moreover, a previous study observed that small size dipterocarps are also able to produce fruits [25], and R149 could be a progeny of R52 with 89% similarity between each other.
A maternal study discovered that there are allele contributions in small S. acuminata from the big trees that were not in the one-hectare study plot. There is a probability that during the early days of the taungya system, the number of big S. acuminata tree in the study plot was limited. Furthermore, the S. acuminata species is a predominantly outcrossing species. Thus, mating was between big S. acuminata tree in the study plot and outside of the study plot due to less big S. acuminata tree in the study plot. Decreased population size may decrease the effective population size; hence, it may limit mating opportunities [36]. The results fit the study by Sujii et al. [14] in which the private alleles in juveniles in the restoration areas were found and claimed as an evidence of gene flow between restored and neighbouring natural populations. After 50 years, the rehabilitated area of Kenaboi FR contains high tree density of the big S. acuminata tree, and outcrossing events may occur between the big trees in the study plot. Thus, all allele contributions of small S. acuminata trees come from the planted trees in the study plot. Although the allele contributions of small S. acuminata trees originate within a study plot, the genetic diversity of the S. acuminata population in the rehabilitated area remains high. This is because the source of planting stocks used to rehabilitate the forest includes seedlings from different seed trees in Sungai Menyala FR.
The genetic diversity of future generations in the rehabilitated area depends on the diversity of remnant seed trees in the study plot and gene flow from neighbouring stands. According to Shaharudin [37], the residual stocking after harvesting should be at least 32 commercial trees per hectare of different species from the DBH class between 30 and 45 cm. This study found ten highly diverse big S. acuminata trees to produce very highly diverse seedlings for future enrichment planting program. Hence, more trees of similar species should be retained after harvesting for successful regeneration of high quality tree species for future harvest.
Compartment 107 is a successfully rehabilitated area that preserved the high genetic diversity of important commercial tree species such as S. acuminata. Therefore, the compartment should be protected as a seed production area. Furthermore, the compartment is also the oldest rehabilitated forest area in Malaysia providing very valuable knowledge on sustainable forest management. This forest will be best protected by gazetting the area as one of the High Conservation Value Forest (HCVF) in Malaysia.

5. Conclusions

The taungya restoration system that was practised by the Forestry Department of Negeri Sembilan, Malaysia, since 1969 has successfully rehabilitated a forest area that was once a poorly degraded area in Kenaboi FR. The structural function of this forest is now similar to primary forest, and the genetic diversity of S. acuminata is high. As this species is recommended for enrichment planting programmes, seed collection should follow the best practice protocol of collecting from many seed trees. The big trees in compartment 107, Kenaboi FR, and the area where their seed was collected in Sungai Menyala FR should be marked and protected. Both forests are suggested as ideal seed production areas to produce good quality planting stock. It is highly recommended that compartment 107, Kenaboi FR, should be proposed as a protected area and classified as a High Conservation Value Forest (HCVF).

Author Contributions

Sampling design and collection, data analysis and writing and manuscript preparation, F.N.A.H.; conceptualization, S.M.I.; manuscript review and writing, W.J.W.A.; supervision, W.R. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Data Availability Statement

This study did not report any data.

Acknowledgments

The authors would like to thank the Head of Department of Biological Sciences and Biotechnology, Faculty of Science and Technology, Universiti Kebangsaan, Malaysia, for providing logistics, laboratory space, research staff and assistance during field sampling. Lastly, the authors would like to thank the Director of Negeri Sembilan State Forestry Department for granting permission to conduct research within the forest reserve areas.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Location of Kenaboi Forest Reserve, Jelebu, Negeri Sembilan, Malaysia. Source: Modified from Forest Department of Negeri Sembilan.
Figure 1. Location of Kenaboi Forest Reserve, Jelebu, Negeri Sembilan, Malaysia. Source: Modified from Forest Department of Negeri Sembilan.
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Figure 2. UPGMA cluster based on Jaccard for 34 big S. acuminata trees (A) and 41 small S. acuminata trees (R) in compartment 107, Kenaboi FR.
Figure 2. UPGMA cluster based on Jaccard for 34 big S. acuminata trees (A) and 41 small S. acuminata trees (R) in compartment 107, Kenaboi FR.
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Figure 3. Distribution of 34 big (A) and 41 small (R) Shorea acuminata trees in 1 hectare compartent 107, Kenaboi FR. The potential seed trees are displayed with red circle.
Figure 3. Distribution of 34 big (A) and 41 small (R) Shorea acuminata trees in 1 hectare compartent 107, Kenaboi FR. The potential seed trees are displayed with red circle.
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Table 1. Characteristics of four SSR loci and three EST-SSR loci developed from Shorea leprosula.
Table 1. Characteristics of four SSR loci and three EST-SSR loci developed from Shorea leprosula.
LociAccession No.Primer Sequence (5′-3′)RepeatAllele Size Range (bp)Annealing Temp. (°C)
Sle280AJ616880F: GCAACTAAAATGGACCAGA
R: GAGTAAGGTGGCAGATATAGAG(CT)7107–13752
Sle 392AJ616886F: ATGTCCTTGAAGATGTAAAGTGGGTG
R: AATAATGGAAGTGAGACGAGGCTG(GA)11161–23155
Sle 475AJ616888F: AGCGAAACCCTTGTGGAGA
R: GAGACTACGGTGGCGACGA(GA)10129–13950
Sle 566AJ616890F: TGAGTAACAAGTAATGAGGG
R: GCAGAGATTGAAACAGAAG(GA)1359–10452
SleE02DC649188F: GGAGGAGAGAAACGAAG
R: GTTTGAGGTAGTGAATAACGAGC(AGC)9142–16045
SleE07DC649404F: AGAAGAATATGGGTACGACTG
R: GTTTGAATCAACTGGCACCTCTAT(GAA)7175–19045
SleE16DC651058F: TCGTCAACCTCCGTAGTCC
R: GTTTGCGCAATAAATAGAGCAATCA(CT)12184–19245
Table 2. Two panels consisting of seven microsatellite loci in fragment analysis.
Table 2. Two panels consisting of seven microsatellite loci in fragment analysis.
PanelLociAllele SizeFluorescentPeak Colour
Panel 1Sle280107–137TAMRAYellow
Sle392161–231TAMRAYellow
Sle56659–104FAMBlue
Panel 2Sle475129–139FAMBlue
SleE02142–160TAMRAYellow
SleE07175–190ROXRed
SleE16184–192HEXGreen
Table 3. Four microsatellite SSR primers and two microsatellite EST-SSR primers developed for S. leprosula and transferability to 75 S. acuminata in compartment 107, Kenaboi FR: expected heterozygosity (He); observed heterozygosity (Ho); inbreeding coefficient (Fis); polymorphic information content (PIC); Hardy–Weinberg (HW); not significant (NS). Figures in the brackets are the estimated standard errors of the mean for genetic diversity parameters.
Table 3. Four microsatellite SSR primers and two microsatellite EST-SSR primers developed for S. leprosula and transferability to 75 S. acuminata in compartment 107, Kenaboi FR: expected heterozygosity (He); observed heterozygosity (Ho); inbreeding coefficient (Fis); polymorphic information content (PIC); Hardy–Weinberg (HW); not significant (NS). Figures in the brackets are the estimated standard errors of the mean for genetic diversity parameters.
LocusNumber of AllelesAllele Size Range (bp)HeHoFisPICNull Allele FrequencyHW
Big treen = 34
Sle2804111–1280.3350.3240.0330.3090.05NS
Sle3927175–1870.7840.7650.0240.7380.00NS
Sle4758126–1870.5930.647−0.0910.557−0.08NS
Sle5661263–1140.6970.6760.0300.6520.01NS
SleE075180–1880.6830.794−0.1630.606−0.08NS
SleE169190–2030.8450.5290.3740.8130.23NS
Mean6.5 0.656 (±0.180)0.623 (±0.174)0.035 (±0.184)0.613 (±0.178)
Small treen = 41
Sle2803111–1280.3190.2680.1600.2930.06NS
Sle3926175–1870.7730.78−0.0090.728−0.01NS
Sle4757126–1870.5330.390.2680.5050.13NS
Sle5661063–1140.7650.6340.1710.7250.09NS
SleE075180–1880.7000.5610.1990.6350.11NS
SleE169190–2030.8200.6590.1960.7860.10NS
Mean6.7 0.652 (±0.191)0.549 (±0.188)0.164 (±0.09)0.612 (±0.186)
Table 4. Maternal contribution for S. accuminata according to percentage of the biggest tree in compartment 107, Kenaboi FR. The underlined allele is probably the allele from big S. acuminata in the study plot.
Table 4. Maternal contribution for S. accuminata according to percentage of the biggest tree in compartment 107, Kenaboi FR. The underlined allele is probably the allele from big S. acuminata in the study plot.
Observed AlleleTree < 30 cm DBH *
DiameterLocusTree ≥ 30 cm DBHTree < 30 cm DBHIn Study Plot (%)Outside Study Plot (%)
Biggest 10%SLEE07A, B, C, DA, B, C, D1000
(52–60 cm)SLEE16A, B, C, D, E, FA, B, C, D, E, F, G8614
n = 8SLE280A, B, CA, B, C1000
SLE392A, B, C, D, EA, B, C, D, E1000
SLE475A, B, C, DA, B, C, D, E, F, G5743
SLE566A, B, C, D, EA, B, C, D, E, F, G7129
Mean 8614
Biggest 20%SLEE07A, B, C, DA, B, C, D,1000
(46–60 cm)SLEE16A, B, C, D, E, FA, B, C, D, E, F, G8614
n = 15SLE280A, B, CA, B, C1000
SLE392A, B, C, D, EA, B, C, D, E1000
SLE475A, B, C, D, E, FA, B, C, D, E, F, G8614
SLE566A, B, C, D, EA, B, C, D, E, F, G7129
Mean 90.59.5
Biggest 30%SLEE07A, B, C, DA, B, C, D1000
(42–60 cm)SLEE16A, B, C, D, E, F, G, HA, B, C, D, E, F, G, H1000
n = 24SLE280A, B, CA, B, C1000
SLE392A, B, C, D, EA, B, C, D, E1000
SLE475A, B, C, D, E, F, GA, B, C, D, E, F, G1000
SLE566A, B, C, D, E, F, GA, B, C, D, E, F, G1000
Mean 1000
* Small S. acuminata trees that received alleles.
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Abd Hamid, F.N.; Wan Ahmad, W.J.; Mohamad Ismail, S.; Ratnam, W. High Genetic Diversity of Shorea acuminata Dyer in the Rehabilitated Area of a Degraded Lowland Dipterocarp Tropical Rainforest. Forests 2021, 12, 1344. https://doi.org/10.3390/f12101344

AMA Style

Abd Hamid FN, Wan Ahmad WJ, Mohamad Ismail S, Ratnam W. High Genetic Diversity of Shorea acuminata Dyer in the Rehabilitated Area of a Degraded Lowland Dipterocarp Tropical Rainforest. Forests. 2021; 12(10):1344. https://doi.org/10.3390/f12101344

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Abd Hamid, Fatma Nadiah, Wan Juliana Wan Ahmad, Shaharuddin Mohamad Ismail, and Wickneswari Ratnam. 2021. "High Genetic Diversity of Shorea acuminata Dyer in the Rehabilitated Area of a Degraded Lowland Dipterocarp Tropical Rainforest" Forests 12, no. 10: 1344. https://doi.org/10.3390/f12101344

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