Genetic Variation in Tropical Tree Species and Plantations: A Review ()
1. Introduction
Forest trees are an essential genetic subject as they are mostly undomesticated and long-lived, enabling them to “naturally” demonstrate genetic variation over a period of time (Ingvarsson & Dahlerg, 2019). However, over time, there have been subtle human impacts on forest ecosystems, more severely in the tropics through the increasing trends of deforestation and forest degradation, directly affecting their diverse genetic resources and associated functions (Finkeldey & Hattemer, 2007). A few examples of these effects include loss of rare but significant alleles, reproductive alteration and isolation among different tree populations (White et al., 2007). Therefore, more attention has been drawn to massive tropical forest landscape restoration, particularly through plantation forestry and agroforestry systems (ITTO, 2020). However, the increasing intensity and dynamics of climatic and environmental changes still limit the success of these plantation interventions, such as increasing their susceptibility to pests and diseases and affecting their productivity.
Nevertheless, some tree populations and species tend to exhibit more resilience and adaptation to those debilitating impacts while maintaining productivity, relative to others. This capacity is largely influenced and determined by the higher levels of diversity in their genetic composition, i.e., genetic variation (Koskela et al., 2007). Genetic variation in trees is expressed in different traits, which are essential to developing plantation forests in the tropics that are substantially resilient to varying environmental stresses and are also more productive in economic, social, and ecological dimensions. These important traits include, but are not limited to, growth rate, stem form, vigour, resilience to drought and pests (Finkeldey & Hattemer, 2007).
Despite the significance of genetic variation in forest sustainability and management, there has been limited information about its patterns and importance regarding tropical species and plantations (Finkeldey & Hattemer, 2007). Although different tree species or populations may naturally have different levels of genetic variability, specific silvicultural interventions can help maintain or improve the genetic diversity in plantation stands. These interventions may range from carefully selecting appropriate (or mixtures of) reproductive materials and provenances to engaging more technical tree breeding strategies in the plantation establishment efforts (Finkeldey & Hattemer, 2007; Ivetić & Devetaković, 2017). Therefore, it is essential to provide more information on the contexts, patterns, and importance of genetic variation in tropical tree species and, ultimately, plantations, to make suitable recommendations for improving it towards the establishment and management of more productive and resilient plantations to meet the critical forest restoration needs and demands for timber products and other services. This review aimed to highlight the levels of genetic variation in common tropical tree species, identify why genetic diversity is essential in the species and their populations, and reveal ways whereby most tropical plantations miss adequate genetic variation and how it can be improved in the plantation forests.
2. What Is Genetic Variation?
Genetic variation defines the genetic differences in individuals within a population or among populations. It is the “mechanism” whereby individuals of the same population or species exhibit different genotypes (alleles) at each gene locus (Ewens, 2013), while genetic variability describes the population’s potential to produce individuals with different genotypes (Hattemer, 1995). The amounts, nature and patterns of genetic diversity vary across different plant species, of which trees have been generally found to have significantly more variations than other plant forms (Hamrick, 1979). Genetic variation explains the evolutionary change or adaptive potential and dictates the phenotypic variation of any tree population or species, expressed across their morphological or physiological traits. It provides raw materials for the variety of growth forms, yields and wood qualities for production, leafing and fruiting patterns, and adaptability to environmental changes and stresses, expressed differently by different tree species (Hamrick, 1979; Finkeldey & Hattemer, 2007).
Genetic diversity can significantly vary between tree populations, species or taxa as a result of differences in both internal attributes like genome structure & size and reproductive system, or external attributes like distribution, density and age, as well as location or environmental factors like human impacts (Hamrick et al., 1992; Akinnagbe et al., 2019).
2.1. Forms and Measures of Genetic Variation
Genetic variation can be intraspecific, which refers to the range of genetic information available among all individuals or populations of one species, or interspecific, across different species. Of the two, the intraspecific genetic variation is more regarded, which is further described as either within or among populations (Finkeldey & Hattemer, 2007).
Genetic variation within populations often dominates the variability of most species, amounting to about 89% in tree species, and it is characterised by:
· Genetic multiplicity, which considers the occurrence or number of the genetic types, alleles or genotypes. It is estimated by the proportion of polymorphic loci (PPL), i.e., the number of polymorphic gene loci (PL) divided by the number of all loci investigated, or by the number of alleles at each locus in the population which is termed “allelic richness”.
· Genetic diversity, which additionally considers the (relative) frequency of the genetic types. It is variably measured by allelic diversity (i.e., the inverse of expected homozygosity), expected heterozygosity (i.e., one minus expected homozygosity), or observed heterozygosity (i.e., the proportion of all heterozygotes from all trees investigated in a population). Expected homozygosity is the summation of all alleles. In population genetics, genetic diversity and expected heterozygosity are the commonest attribute and measure for assessing genetic variation within populations, respectively.
Genetic variation among tree populations can be characterised and measured by genetic distance and genetic differentiation. While the first quantifies the genetic differences between two populations, genetic differentiation measures the differences between an arbitrary number of populations (Finkeldey & Hattemer, 2007).
2.2. Sources of Genetic Variation
Genetic variation is a result of four evolutionary factors: mutation, random genetic drift, selection, and gene flow or migration (White et al., 2007; Ingvarsson & Dahlerg, 2019; Nonić & Šijačić-Nikolić, 2021). Mutations are heritable changes in the genetic structure of individuals, which are not attributed to recombination or gene interaction. They cause genetic variation in populations by creating entirely new alleles. Genetic drift defines the random fluctuations of genetic structures, strongly in small populations, often due to limited population size. It mostly leads to a loss of genetic diversity within populations. Gene flow or migration refers to the movement of alleles from one population to another through fruit, seed or pollen dispersal. For instance, gene flow both by pollen and seeds was significantly the source of maintaining the genetic diversity within populations of a pioneer tree species, Croton floribundus, in some Brazilian successional forests (Silvestrini et al., 2015). It could lead to either an increased intrapopulation genetic variability or, in the long-term, a decreased interpopulation genetic divergence. Lastly, selection describes a process whereby a population’s genetic composition changes due to the greater reproductive contribution of individuals better suited to the environmental conditions. Unlike natural forest conditions, selection is done artificially in plantations based on several economically relevant factors like growth and resistance. This process thereby tends to reduce the genetic variability of man-made plantation forests (Nonić & Šijačić-Nikolić, 2021).
2.3. Assessment of Genetic Variation
Genetic variation within or among tree populations is assessed using gene markers. A gene marker, also known as gene locus or marker locus, is typically an environmentally stable trait whose variation is determined only by genetic factors. Different types of gene markers have been applied in genetic inventories of tropical forest trees. These include morphological or phenotypic, biochemical, and molecular markers (Finkeldey & Hattemer, 2007) and cytogenetic markers (Chesnokov et al., 2020). Further descriptions of the markers are provided in Table 1 below.
Table 1. Common genetic markers and their features.
SNP single nucleotide polymorphism; SSR simple sequence repeats; RAPD random amplified polymorphic DNA; AFLP amplified fragment length polymorphism; FISH/GISH fluorescence/genomic in situ hybridization (adapted from (Chesnokov et al., 2020)).
3. Genetic Variation in Tropical Forest Tree Species
Several marker-based studies have investigated genetic variation in different tree species across the tropics. Finkeldey & Hattemer (2007) provided the last broad review of these studies. Therefore, this paper updates the review with more recent examples of genetic variation patterns in tropical tree species, as presented in Table 2.
Overall, tropical tree species differently possess varying levels of genetic variation within populations (HE): low, intermediate and high. In contrast, some top economic species have a low genetic variation (e.g., Eucalyptus tereticornis, Mansonia altissima), others like Pinus caribaea and Swietenia macrophylla exhibit high diversity. However, the levels and extents of genetic diversity vary with species, populations, provenances and the genetic markers used. The same tropical tree species could possess wide-ranging genetic diversity levels across different populations and with different markers. Acacia mangium earlier recorded as low as 0.01 within-population expected heterozygosity across tropical forest populations in Australia despite its indigeneity to the range (Butcher et al., 1998). Yuskianti & Isoda (2012) conversely found the species to have a high genetic diversity (0.623) in its other natural range/population in Indonesia. Similar findings have also been reported in species like Prunus africana even in same tropical Kenya, 0.137 (Dawson & Powell, 1999) against 0.830 (Farwig et al., 2008) and Pinus merkusii in Thailand (0.058) and Indonesian (0.559) populations (Changtragoon & Finkeldey, 1995; Nurtjahjaningsih et al., 2007).
The variation in genetic diversity has also been attributed to the markers used. This partly contributed to the differences in the genetic variations recorded in similar Malaysian populations of Shorea leprosula by Lee et al. (2000) and Ang et al. (2016) at isozyme and microsatellite gene loci, respectively. Furthermore, Fofana et al. (2013) compared the performance of SSRs and AFLPs in assessing
Table 2. Examples of tropical tree species and their levels of genetic variation within populations.
He: average expected heterozygosity within populations.
genetic variation in Tectona grandis and found the estimates of variability acquired using SSRs to be higher than the latter. The report with Acacia mangium and Prunus africana substantiates the differential estimations due to markers, where microsatellites assessed higher diversity than their counterpart markers (Table 2). However, this is inconsistent with other studies where no significant distinction is found between/among the several polymerase chain reaction (PCR) markers, such as on Jatropha curcas (Gupta et al., 2008).
3.1. Some Factors Influencing Genetic Variation in Tropical Tree Species and Populations
Different factors typically contribute to the directional pattern of genetic variation among tropical tree species and populations (Figure 1). Following the hypotheses that species distribution and population density/size influence genetic
Figure 1. Directional factors influencing genetic diversity in tropical trees.
variability, this is also observed amongst tropical trees, where those that are endemic and with low density in the forests are attributed to lower genetic diversity, partly due to higher inbreeding. Thus, the smaller the population, the higher the chance of genetic drift, i.e., bottleneck effect, owing to the correspondingly small reproductive ability (Hamrick et al., 1992; Butcher et al., 1998). Seed dispersal also tends to influence genetic variation among tropical tree species, as anemochorous (wind-pollinated) tree species are likely to sustain higher genetic variability than the zoochorous (animal-pollinated) due to a better gene flow from longer-distance pollen dispersal (Finkeldey & Hattemer, 2007; Bittencourt & Sebbenn, 2007).
Similarly, anthropogenic impacts like fragmentation and logging on forest trees as well as their regeneration or succession status potentially affect their genetic diversity in the tropics. In this case, non-pioneer species and fragmented, isolated or logged populations are more prone to genetic erosion and diversity loss than the pioneers and continuous or primary tree populations (Pither et al., 2003; Akinnagbe et al., 2019). The genetic variation in several tropical tree species has been critically reduced by human disturbance, such as Prunus africana in Kenya (Dawson & Powell, 1999), Araucaria augustifolia in Brazil (Bittencourt & Sebbenn, 2007), and Shorea leprosula in Malaysia (Ang et al., 2016). However, these directional trends of influence on tropical trees’ genetic variation are not entirely always constant (Minn et al., 2014; Akinnagbe et al., 2019). For instance, Noreen & Webb (2013) found high genetic diversity in Koompassia malaccensis populations across Singapore despite the high habitat loss. Silvestrini et al. (2015) reported similar levels of genetic diversity of Croton floribundus within some Brazilian primary and successional forests. Also, Wang et al. (2012) found no significant variance in genetic diversity between pre- and post-fragmentation cohorts of a wind-pollinated tree’s populations (Castanopsis sclerophylla); rather, an enhanced gene flow due to the removal of genetic barrier by fragmentation.
By implication, genetic diversity (pattern) varies with individual trees, populations, provenances, species, markers and several ecological and anthropogenic factors. Hence, there is a need for suitable genetic inventories and, more importantly, establishing plantations populations with adequately selected plant materials of certain species and provenances with high levels of genetic variation.
4. Importance of Genetic Variation in Tropical Plantations
4.1. Genetic Variation Reduces Inbreeding Depression & Accumulation of Harmful Alleles and Improves Fitness and Fecundity of Plantation Trees
Inbreeding depression is the process whereby the offspring exhibit homozygosity, removal of heterozygote superiority, and an increased possibility of risky mutations resulting from mating genetically closely related parents, i.e., “inbreeding” (Reed & Frankham, 2003). Therefore, this tends to reduce the genetic base within the particular species or accumulate harmful alleles, which can directly impact the fitness, survival and fertility of the individual offspring trees/populations (Nonić & Šijačić-Nikolić, 2021). It can result in the loss of certain desired traits of plantation forest trees, such as vigour and growth form. Also, there are increased chances of tree population size reduction or even species extinction, owing to the resultant continual drop in their reproductive rate due to effects like embryo abortion, impaired fruit set, decreased overall seed yield and reduced germination of remnant seeds (Reed & Frankham, 2003; Nonić & Šijačić-Nikolić, 2021). Hence, it is essential to maintain genetic variation to avert the issue of wide fecundity among the tree species or populations whereby only a very few tree individuals in the forest are able to produce sufficiently vital genetic materials for subsequent sustainable rotations and productivity.
4.2. Genetic Variation Increases Forest Productivity
In plantation forests, there is often a positive relationship between the level of genetic variation and productivity (Nonić & Šijačić-Nikolić, 2021). An example is the varying high tree stem qualities, which potentially increase the economic versatility and productivity of the plantation products. In a provenance mixing experiment, genetic diversity from using different provenances of one tree species had a positive effect on tree growth and stand productivity (Pretzsch, 2021). That is, an increase in genetic variation within the stand through provenance mixtures/richness yielded proportionate increases in its incremental volume and stem diameter notwithstanding the stand densities.
The interspecific variation from species-mixtures could also enhance productivity, e.g., by facilitating products diversification from the plantations under several rotation periods (Forrester et al., 2006; Liu et al., 2018). Agroforestry systems are an essential component of plantation forestry in tropical forest landscape reforestation. Maintaining genetic variation in such systems is also of great significance while integrating trees into livelihood systems whereby the mixed species create the opportunities to obtain a variety of attributes of desired products, thus enhancing local livelihoods. An example is the varieties of fruits obtained from a fruit tree species, which ripen at varying times to meet market demands over an extended period (Dawson et al., 2009).
4.3. Genetic Diversity Reduces Competition in Forest Stands
Genetic diversity brings about variation in structure in a forest stand, which tends to create differences in the use and competition for resources like space or light in the crown layer or water and nutrients in the soil. Different morphological/phenotypical traits are expressed by various genetically different provenances and plant materials. These varied expressions result in biomass partitioning, as well as diversification or asynchrony in sprouting, light assimilation, leaf shedding, and water uptake, all of which could decrease overlapping niches, increase resource use complementarity and site use efficiency, and reduce competition (Chmura & Rozkowski, 2002; Pretzsch, 2021). Such reduced competition also influences both productivity of the plantation site and stand. Furthermore, the genetic variation from combining species that have complementary traits like light-demanding with shade tolerant, fast with slow-growing, and shallow with deep rooting may limit competition within the plantations (Liu et al., 2018).
4.4. Genetic Diversity Drives Ecological Diversity and Ecosystem Functions
The importance of diversity cannot be overemphasized in maintaining the structure and functions of any forest ecosystem. Meanwhile, genetic diversity constitutes the basis of biodiversity (Nonić & Šijačić-Nikolić, 2021). Buttressing further, Zytynska (2011) found within-species genetic variation in a tropical forest of Brosimum alicastrum to influence the communities of epiphytes and invertebrates (including spiders, ants, crickets) around the tree trunks and leaf litter. The genetic distance between species populations, assessed using the AFLP marker, correlated positively with the community differences of the associated epiphytic plants and invertebrates. This could thus imply that the more genetically different tree populations or species are, the more ecologically diverse or relevant they are. Among other essential ecosystem functions provided by tropical forests (plantations) are carbon sequestration and storage, contributing significantly to the global carbon cycle. However, their potential to accumulate aboveground biomass or soil carbon can be affected by genetic variation in the species considered (Chmura et al., 2021; Mora-Orozco et al., 2022). Nevertheless, it is noteworthy that such relationships between genetic variation and ecological diversity or function may not always be strong, positive, or significant. For instance, in a tropical subdeciduous forest in Mexico, Cruz-Salazar et al. (2021) found both a significant relationship and a negative association between different indices of genetic diversity and tree species diversity.
4.5. Genetic Diversity Enhances Resilience against Changing Environment and Reduces Risks of Pests and Pathogens in Plantations
Forest trees are exposed to global and environmental changes due to their long gestation and largely non-domestication. The dynamic impacts of increased intensity and distribution of forest pests and diseases, temperature rise, rainfall pattern changes, drought, frost, and growing seasonal changes are evident in forest tree growth, productivity, and survival. However, enhancing genetic variation among tree populations and species can significantly improve their resilience and adaptability, that is, adaptive traits (Finkeldey & Hattemer, 2007; Nonić & Šijačić-Nikolić, 2021). White et al. (2007) consider it a major condition for the evolutionary adaptability of forest trees. Several other authors have also affirmed that considering tree species with high levels of genetic variation and ensuring such are maintained when establishing plantations will facilitate their adaptability to the changing environments and help them tolerate stress factors in the sites (Aitken et al., 2008; Dawson et al., 2009).
High genetic variability is needed in any species and plant materials considered for plantation forestry to cope with the outbreaks of (new) pests and diseases. This is particularly important because of the often low interspecific diversity in most plantation forests, even in the tropics, resulting from their usual mono-species/monoculture composition (Liu et al., 2018). For instance, when Leucaena tree species was first introduced to Asia and Africa in the 80’s - 90’s, its plantations were severely attacked and damaged by psyllid (Heteropsylla cubana). This event was significantly attributed to the narrow genetic base of the species introduced; that is, the variation in the genetic material and provenance required to adapt to the new region outside its natural range was low (Rao et al., 2000). Therefore, to maximise the survival and resilience of plantations in the tropics, it is essential to select and utilise plant stock and provenances with adequate levels of genetic diversity. Adaptability, and not just adaptedness to current environmental conditions, facilitates the long-term survival of tree populations (Nonić & Šijačić-Nikolić, 2021).
4.6. Genetic Variation Forms the Basis of Tree Improvement and Breeding
The genetic variation of populations or species in plantations is assessed and harnessed in breeding projects to modify the expressions of their economically and ecologically important traits, including growth and yield, stem form, vigour, wood quality, resilience to drought and pests, etc. This process involves selecting individuals, provenances and progeny families of tree species commercially suitable for plantation establishment (i.e., provenance-progeny trials). Besides the deployment of improved seeds from seed orchards, clonal forestry is widely and increasingly considered the best approach to deliver the greatest genetic gain through the use of well-tested clones in plantations, which is significantly based on genetic variation and its assessment. Cloning typically involves genotypic duplication through vegetative means, preserving the original genetic composition and individual traits, unlike the seed propagation method (Monteuuis, 2021).
Among the several tropical tree species whose genetic variations in certain traits have been assessed, breeding programs have mostly been on Eucalyptus and Pinus species (Finkeldey & Hattemer, 2007), as well as others like Acacia (Harwood et al., 2015) and teak (Monteuuis, 2021). Taking acacia for instance, selected clones of A. auriculiformis and hybrid of A. mangium and A. auriculiformis have been successfully deployed, e.g., in Vietnam. Prospects for genetic improvement in wood qualities and form have also been established for the species, among other growth traits (Harwood et al., 2015). Similarly, teak clonal plantations have extensively developed over the last decades in many tropical countries, including Brazil, India, Côte d’Ivoire, Indonesia, etc., owing to their great possibility to produce enormous yields of best quality timber with high commercial value. This advancement largely hinges on the considerable provenance (genetic) variation exhibited in the species for the economically important traits, as well as the ease of assessment using genetic markers (Kollert & Kleine, 2017; Monteuuis, 2021).
5. Missing Genetic Variation in (Tropical) Plantation Forestry and Recommendations for Improvement
Plantations are mostly monocultures established through artificial selection of plant materials for uniformity, easy management, and increased yield, thus, potentially limiting their genetic variability (Liu et al., 2018). This, therefore, places great significance on choosing well-adapted and well-adaptable plant stock. The use of clones in monocultures has generally proven more successful in producing considerable yields over seedlings, together with other advantages like improved uniformity, the capture of favourable genetic gains and specific adaptations, independence of seed limitations, etc. (Libby & Rauter, 1984; Monteuuis, 2021). All these have contributed to the increasingly widespread adoption of clonal plantations globally. Finkeldey & Hattemer (2007) asserted that many of the world’s most productive tree plantations use clones. They facilitate high-profit maximisation on plantation investments within the shortest time possible when outstanding genotypes and appropriate sites are considered (Monteuuis, 2021).
However, this practice is attributed to some economic, technical and ethical concerns and risks, especially in large-scale monoclonal plantations (Kleinschmit et al., 1993; Monteuuis, 2021). The deployment of a large number of individuals of one or a few clones, which are completely homogenous, increases the risks of the spread of pests and diseases, climate change impacts, as well as causes vitality and productivity losses due to the missing genetic diversity (Kleinschmit et al., 1993; Burdon & Aimers-Halliday, 2006). To avert these risks of plantation failure, deploying an appropriate maximum number of clones is essential. Also, a considerable emphasis must be placed on ensuring that the clones are of relatively equal proportions to maximise genetic differentiation within the plantations (Roberds & Bishir, 1997). Different forest geneticists have proceeded to provide suitable recommendations in these regards. While Libby (1982) earlier recommended mixtures of between 7 - 25 genetically distinct and equally represented clones, Roberds & Bishir (1997) reported planting up to 30 - 40 unrelated clones in clonal plantation mixtures is a more sufficient and better strategy to provide resistance against risks of failure.
It is equally important to consider selecting an adequate deployment method to establish the plantations. Clones are deployed mainly in two forms: intimate multi-clonal mixtures or mosaics of small monoclonal blocks (or rows) (Kleinschmit et al., 1993; Roberds & Bishir, 1997; Burdon & Aimers-Halliday, 2006). While multi-clonal mixtures may be more effective in averting the risks of plantation failure or pest and disease damages than monoclonal mosaics, such strategy has been conversely attributed to possible undesirable heterogeneity in stem growth, asymmetry in competitive interactions, and incompatibility in silvicultural interventions among the clones (Burdon & Aimers-Halliday, 2006; Donnelly et al., 2017). Although it is said not to significantly affect plantation stand productivity (Donnelly et al., 2017), the monoclonal mosaics/blocks pattern is mostly adopted in large-scale industrial clonal plantations of teak and eucalypts, for instance (Zobel & Talbert, 1984; Monteuuis, 2021). The size of the monoclonal mosaics is typically dependent on some factors: “the total number of clones deployed, their genetic relatedness, their individual phenotypic characteristics, the rotation length and the total area to be planted” (Monteuuis, 2021). Therefore, it is crucial to provide adequate information about the genetic origins and features of the different clones to establish the clonal plantations, whether in mixtures or mosaics, to optimise the complementary benefits of their genetic diversity. Furthermore, shortening the economic rotation lengths of the clonal plantations is a viable approach to reducing environmental risks. In this way, the trees are harvested or harvestable before the pests and pathogens get well-adapted to the plantations (Kleinschmit et al., 1993).
Lastly, there has been a growing interest in mixed-species plantation systems, which can maintain (interspecific) genetic variation. Establishing plantations with more diverse and complex mixtures of tree species that express complementarity in structural and functional traits like growth rate, shade tolerance, rooting depth, and crown structure can help maximise their resource use, productivity and resistance to catastrophes. However, species mixtures can reduce soil fertility, tree growth and productivity in some cases and can be complex to select, combine and manage multiple species effectively. Hence, they require adequate and careful design and appropriate management (Liu et al., 2018).
6. Conclusion
Genetic variation is highly significant in tropical tree species and plantations by enhancing fecundity, vitality, productivity, and resilience. Although tropical tree species are of varying levels of genetic variation from low to high, their plantations are mostly monocultures, established mainly for yield increment but usually with low/missing genetic diversity. The risks of genetic base reduction and failure become more prominent with the growing use of clonal plantations due to the absolute genetic homogeneity of such plant materials. Therefore, deploying multiple clones with equal proportions in mixtures managed under shortened rotations and gradual transition to mixed-species systems are vital to increasing genetic variation in tropical plantations, thus improving their resilience against climatic, biological, and environmental risks.
Acknowledgements
Our sincere appreciation goes to the anonymous reviewer who provided constructive remarks and edits that significantly shaped the paper.