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Article

Diversification of African Tree Legumes in Miombo–Mopane Woodlands

by
Ivete Maquia
1,2,†,
Silvia Catarino
1,3,†,
Ana R. Pena
4,
Denise R.A. Brito
2,
Natasha. S. Ribeiro
5,
Maria M. Romeiras
1,4 and
Ana I. Ribeiro-Barros
1,6,*
1
Linking Landscape, Environment, Agriculture and Food (LEAF), Instituto Superior de Agronomia (ISA), Universidade de Lisboa, Tapada da Ajuda, 1349-017 Lisbon, Portugal
2
Biotechnology Center, Eduardo Mondlane University, Av. de Moçambique Km 1.5, Maputo 1109, Mozambique
3
Forest Research Center (CEF), Instituto Superior de Agronomia (ISA), Universidade de Lisboa, Tapada da Ajuda, 1349-017 Lisboa, Portugal
4
Centre for Ecology, Evolution and Environmental Changes (cE3c), Faculdade de Ciências, Universidade de Lisboa, 1749-016 Lisbon, Portugal
5
Faculty of Agronomy and Forest Engineering, Eduardo Mondlane University, Campus1, P.O. Box 257, Maputo 1102, Mozambique
6
Unidade de Geobiociências, Geoengenharias e Geotecnologias (GeoBioTec), Faculdade de Ciências e Tecnologia, Universidade NOVA de Lisboa, 2829-516 Monte de Caparica, Portugal
*
Author to whom correspondence should be addressed.
These authors contributed equally to this work.
Plants 2019, 8(6), 182; https://doi.org/10.3390/plants8060182
Submission received: 27 May 2019 / Revised: 17 June 2019 / Accepted: 18 June 2019 / Published: 20 June 2019
(This article belongs to the Section Plant Molecular Biology)
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Versions Notes

Abstract

:
The southern African Miombo and Mopane ecoregions constitute a unique repository of plant diversity whose diversification and evolutionary history is still understudied. In this work, we assessed the diversity, distribution, and conservation status of Miombo and Mopane tree legumes within the Zambezian phytoregion. Data were retrieved from several plant and gene databases and phylogenetic analyses were performed based on genetic barcodes. Seventy-eight species (74 from Miombo and 23 from Mopane, 19 common to both ecoregions) have been scored. Species diversity was high within both ecoregions, but information about the actual conservation status is scarce and available only for ca. 15% of the species. Results of phylogenetic analyses were consistent with current legume classification but did not allow us to draw any conclusion regarding the evolutionary history of Miombo and Mopane tree legumes. Future studies are proposed to dissect the diversity and structure of key species in order to consolidate the network of conservation areas.

1. Introduction

Tropical dry forests and woodlands constitute a large portion of the world’s vegetation, covering one-sixth of the earth’s surface and more than half of the African continent [1,2]. Among them, the Miombo–Mopane woodlands are the most predominant type of vegetation in Southern Africa, and together with Amazonia, Congo, New Guinea and the North American deserts, are considered wilderness areas of global conservation significance [3]. The woodlands play a crucial role in formal and informal economies, supporting the livelihoods of millions of rural and urban people, by providing important resources such as timber, food, medicines, biofertilizers, housing and energy [4,5,6,7,8]. The Miombo and Mopane woodlands also play an important role in the ecosystem dynamics, particularly with respect to biodiversity, water, carbon and energy balance [9,10,11,12,13].
The plant diversity of these ecosystems comprises a wealthy repository of biodiversity, with a high proportion of native species, which makes it biologically unique [14,15]. According to Olson et al. [16], five sub-regions have been delineated through the Miombo woodlands (i.e., Angolan Miombo woodlands, Central Zambezian Miombo woodlands, Zambezian Baikiaea woodlands, Eastern Miombo woodlands and Southern Miombo woodlands) that cover about 3,000,000 km2 across the Zambezian region of Angola, Democratic Republic of Congo, Malawi, Mozambique, Tanzania, Zambia and Zimbabwe [17,18]. The Mopane woodlands represent the second most significant type of vegetation in the Zambezian phytoregion, covering approximately 600,000 km2. This region includes two sub-areas (i.e., Zambezian and Mopane woodlands, and Angolan Mopane woodlands), and is distributed over northern Namibia, southern Angola, Zimbabwe, Botswana, Zambia, Malawi, southern Mozambique and northern South Africa [17,19].
The Miombo and Mopane woodlands are dominated by species belonging to the Leguminosae [2], which is considered the second most economically important plant family [20,21,22,23]. This family includes over 19,500 species spanning about 770 genera and six subfamilies, namely Caesalpinioideae, Cercidoideae, Detarioideae, Dialioideae, Duparquetioideae and Papilionoideae, many of which establish root-nodule symbiosis with N2 fixing rhizobia bacteria [23]. The Miombo woodlands are dominated by trees of the genera Brachystegia, Julbernardia and Isoberlinia, while the Mopane woodlands are dominated by Colosphosperum mopane (Benth.) Leonard [9,17,24]. Most of these trees are under severe ecological pressure, due to logging and charcoal production [25,26], as well as fires related to animal, human and climate factors [6,10,11,13], which have contributed to the massive degradation of these woodlands and raised the need for their conservation [4,24,27,28].
African forests are among the most understudied regions in the world with respect to phylogenetic diversity [29]. Characterization of a region’s phylogenetic diversity, which is based on the evolutionary relationships between species from a given geographical area, can be a powerful tool to analyze the phylogenetic structure of natural communities and can assist the study of processes governing the assembly of species in ecological communities [30,31]. The identification of areas with more or less phylogenetic diversity based on species richness is another important element for conservation studies [32]. Although the African woodlands remain of enormous evolutionary interest, assessing species diversification within Miombo and Mopane plant communities across West and East African woodlands is still understudied. Since the dominant plant lineages in Miombo and Mopane are tree legumes, this provides an excellent case study to understand the diversity and the evolutionary history of these two predominant types of vegetation in Southern Africa. In this context, the objectives of this study were: (i) to characterize the diversity and distribution of Miombo and Mopane tree legumes within the Zambezian phytoregion (Figure 1); (ii) to provide a unique view of their phylogenetic diversity and how these lineages have evolved across West and East African woodlands; and (iii) to provide new data to assist the implementation of conservation strategies and the sustainable management of the Mopane and Miombo woodlands.

2. Results

2.1. Tree Legumes Diversity and Conservation Status

Our study categorized 78 Leguminosae trees, of which 74 were representative of the Miombo woodlands and 23 of the Mopane woodlands (19 species common to both habitats) (Table 1). Overall, the largest number of species was found in Zambia, with 71 out of the 78 species (91%), while the Democratic Republic of Congo (DRC) had the lowest number (51 species or 65%) (Table 1). Five of the six recognized subfamilies were found in the Miombo woodlands: Caesalpinioideae, the most frequent (27 species), followed by Papilionoideae (22 species), Detarioideae (21 species), and Cercidoideae and Dialioideae with only three and one species, respectively. Among the 34 genera, Brachystegia and Acacia were the most diverse with 12 and 11 species, respectively. The number of species per country ranged from 50 in the DRC to 67 in Zambia. The Mopane woodlands harbored four subfamilies of legume trees, 14 species belonging to the Caesalpinioideae subfamily, followed by Papilionoideae with six species. Only two species from Detarioideae and one from Cercidoideae were retrieved. The number of genera was lower in Mopane than in Miombo (15 versus 34). The highest number of species was recorded in Zimbabwe (23) and the lowest in the DRC (11).
Information on the conservation status of the Miombo and Mopane trees is still scarce as most of the species (66 species or 85%) have not yet been assessed globally, according to the categories and criteria of the International Union for Conservation of Nature (IUCN) Red List (Table 1). Therefore, only 12 species could be evaluated, of which seven were classified with least concern (Acacia nilotica (L.) Willd. ex Delile; Baphia massaiensis Taub.; Brachystegia puberula Burtt Davy & Hutch.; Dichrostachys cinerea (L.) Wight & Arn.; Pterocarpus brenanii Barbosa & Torre; Pterocarpus lucens Guill. & Perr.; Tamarindus indica L.), three as near threatened (Dalbergia melanoxylon Guill. & Perr.; Pterocarpus angolensis DC.; Baikiaea plurijuga Harms), and two as vulnerable species (Isoberlinia scheffleri (Harms) Greenway; Brachystegia bakeriana Burtt Davy & Hutch) (Figure 2).

2.2. Molecular Phylogenetic Analysis

As DNA sequences were not available for all the selected taxa, the analyzed set was reduced to a total of 67 species from the original set of 78 (Table 2). A total of eight datasets were created: two for each single locus (internal transcribed spacer (ITS), matK and rbcL), and two combined (ITS + matK + rbcL). The ITS matrix had the lower number of taxa and haplotype diversity (n = 38, Hd = 0.9986), while rbcL had the highest of the three (n = 53, Hd = 1.0000), followed by matK (n = 69, Hd = 0.9987). The combined set of ITS+matK+rbcL had a total of 70 sequences, with a single shared haplotype (Hd = 0.9996). A summary of the processed molecular data of this study is available in Table S1 of the Supplementary Materials.
For each data matrix, two independent phylogenies were constructed, one using maximum likelihood (ML), and another using Bayesian inference (BI). In both methods, tree rooting was performed using Polygalaceae species as outgroups, namely Monnina xalapensis, Rhinotropis acanthoclada and Xanthophyllum hainanense. Overall, the BI phylogenies achieved higher support values, but were in turn less resolved, with more polytomies than ML trees. Topologies were highly similar within the same paired datasets, and to a lesser extent between locus, showing similar clustering patterns between species.
The phylogenetic trees obtained using the matK matrix provided the best resolution and support from the singular gene analysis, showing a clear split between subfamilies and clustering between closely resembling species (Figure S1). ITS and rbcL phylogenies were generally less supported in both ML and BI analysis (Figures S2 and S3), and some taxa were also poorly positioned (i.e., found outside of the subfamily clade). The concatenated set of the three selected genes (ITS + matK + rbcL) achieved the best overall result both using BI (Figure 3) and ML (Figure 4), with a lower number of unresolved nodes, as well as higher values of support, following the clustering pattern obtained by The Legume Phylogeny Working Group [23].
The distribution of species among ecoregions (Miombo and Mopane) was as predictable and in general evenly distributed across the seven countries. The smaller subfamily, Cercidoideae, was well represented in Miombo (3 out of 3 species), holding a single taxon (Bauhinia thonningii), which was found in Mopane as well. The Detarioideae subfamily included 15 species, one common to both Miombo and Mopane (Baikiaea plurijuga), one exclusively from Mopane (Colophospermum mopane) and 13 exclusively from Miombo (Brachystegia spp., Isoberlinea spp., Julbernardia spp., Tamarindus indica and Guibourtia coleosperma). One of these species, I. scheffleri, was restricted to Tanzania and Mozambique, while B. plurijuga and G. coleosperma were not present in Tanzania, Malawi, Mozambique and the DRC. The 21 species belonging to the Papilionoideae were all present in Miombo, five of them (Dalbergia melanoxylon, Ormocarpum trichocarpum, Pterocarpus rotundifolius, Pterocarpus lucens, and Xeroderris stuhlmannii) being also present in Mopane. Three species, O. trichocarpum, Millettia stuhlmannii and M. usaramensis were present only in the eastern countries. The largest subfamily Caesalpinioideae, included 25 species, mostly Acacia spp. and Albizia spp. homogeneously distributed by country and ecoregion (Figure 3 and Figure 4).

3. Discussion

As expected, the Miombo woodlands presented a higher diversity of species (74 overall taxa, 55 Miombo-exclusive) than Mopane (23 taxa, 4 Mopane-exclusive) [17,33]. This is likely related to the larger area and therefore to a rather diverse edaphic (e.g., drainage, soil depth and texture) and climate (warm to hot climate, 710 to 1365 mm mean annual precipitation and 18 to 23 °C mean annual temperature) conditions in the Miombo ecoregion [9,34]. Additionally, Mopane is usually characterized by clayed soils [33] with a discontinuous tree cover and a continuous C4 grass layer [35,36]. Thus, environmental determinants might have underlined a slight deviation on the evolutionary history of Miombo and Mopane tree legumes [37]. Also expected was the exclusive presence of the typically dominant genera of Miombo (Brachystegia, Isoberlinia and Julbernardia) and Mopane (Colophospermum mopane) in either ecosystem [17,19,24].
When comparing the results with the combined areas of Miombo and Mopane woodlands there was not a logical correlation between area size and species number in some countries. This was particularly evident in Angola, which holds the largest woodland area of Miombo and Mopane but houses only 62 out of the 78 species. Other large countries such as Zambia and Mozambique however, did not follow this trend, as the identified species were well represented. These results could be explained by three hypotheses: i) the origin point of dispersal for the Leguminosae family was Zambia and/or Zimbabwe with a more recent expansion to Angola, compared to the other neighboring countries; ii) the knowledge on species diversity in Angola is incipient; or iii) a combination of the two. Among the seven countries included in this study, the highest species diversity was found in Zambia (i.e., 71 out of the 78 scored species, and 16 out of 17 typical Miombo species), likely related to the fact that Zambia is the center of endemism for Brachystegia [9]. Except for Zambia, the number of taxa was nearly the same for countries with dry Miombo (Malawi, Mozambique and Zimbabwe) and wet Miombo (Angola, DRC, Tanzania and Malawi). However, it is important to consider that the scored diversity in this study does not reflect species abundance and frequency, which could explain this similarity despite the fact that wet Miombo is often a floristically richer region [9,38].
The rarity of a certain species or ecosystem is frequently the first and most important feature when deciding its need of protection, as is the higher risk of extinction and loss of possible unique lineages [39,40,41]. This feature is particularly significant when information on the threat status of a species is insufficient [42] as is the case of Miombo and Mopane tree legumes, whose conservation status is available for a minority of species (Table 1) [43]. Such a trend was also found for other tree lineages endemic from Africa such as the nitrogen-fixing actinorhizal trees and shrubs [44]. This issue is of upmost importance within the context of the Bonn Challenge under which many countries have pledged to restore millions of degraded and deforested woodlands and forests [45]. Thus, more efforts are needed to investigate the vegetation dynamics, anthropogenic and environmental drivers as well as the different conservation management strategies across Miombo and Mopane countries. Examples of such efforts include the recent work of, (i) Chiteculo and Surovy [46] and Chiteculo et al. [47], that characterized the vegetation composition and structure and deforestation patterns of the Miombo woodlands in the Huambo province, Angola, respectively; (ii) Ribeiro et al. [6] that conducted a 12-year analysis of the spatio-temporal patterns of fire to refine the fire management strategy in one of the most pristine areas of Miombo, the Niassa National Reserve, Mozambique; (iii) Mugasha et al. [48] that provided a pioneer study on modeling tree growth in the Miombo woodlands from Tanzania based on long-term monitoring data; and (iii) Chidumayo [49] that performed a long-term study (1982–2018) across the Miombo woodlands in Zambia to investigate the woodland drivers and contribute to the design of management plans.
The use of phylogenetic diversity as an effective complementary mean of conservation has often been the object of debate. Since the proposal of this metric by Vane-Wright [50], several studies have been able to test and evaluate this hypothesis with various results and opinions [51,52]. Regarding molecular data, the results obtained in this study corroborate previous molecular findings showing that the use of taxonomic barcodes or DNA barcoding have great applicability on the identification, phylogeny reconstruction and evolutionary analysis for forest dwelling flora [53,54,55], in our case tree legumes from the Miombo and Mopane ecoregions. The results are in line with a recent study by The Legume Phylogeny Working Group [23], clustering together four out of the six new subfamilies: Caesalpinioideae, Cercidoideae, Detarioideae and Papilionoideae (Figure 3 and Figure 4).
Functional diversity is another useful parameter to assess phylogenetic diversity and the evolutionary potential (i.e., the ability of a species to adapt to environmental changes) [56,57,58,59]. With few exceptions, the distribution of the 67 lineages and subfamilies across the seven countries was quite uniform and therefore, not informative regarding their evolutionary history across the Mopane and Miombo axis. This was particularly the case of the typically dominant genera of Miombo (i.e., Brachystegia, Isoberlinia and Julbernardia) and Mopane (C. mopane). Thus, further studies are needed in order to assess the genetic diversity and population structure of key species from Miombo and Mopane. Such complementary studies will be essential to provide better and more well-founded areas of protection for the Miombo and Mopane woodlands. In some countries where protected areas are still scarce, such as Angola, this might support the establishment of a network of protected areas spanning different sub-regions.
In conclusion, the Miombo and Mopane woodlands hold a differential phylogenetic diversity: the Miombo covers a larger area and holds a higher number of legume species; while the Mopane spans a smaller land mass that houses several unique and rare lineages. Both ecoregions hold a high value of biodiversity, even with a somewhat dissimilar composition, and as such future studies should take in account their exclusive characteristics alongside their shared ones when proposing new conserved species and areas.

4. Materials and Methods

4.1. Study Area and Spatial Analyses

The study area included the Mopane and Miombo ecoregions from the Zambezian phytoregion (i.e., Angola, Democratic Republic of Congo (DRC), Zambia, Zimbabwe, Tanzania, Malawi, and Mozambique) (Figure 1). Only the southern provinces of DRC (i.e., Tanganyika, Haut-Lomami, Lualaba, and Haut-Katanga (former province of Katanga, extinguished in 2009)), were included in this study, as only these four provinces are part of the Zambezian phytoregion [60]. The map of the terrestrial World Wildlife Fund (WWF) ecoregions [61] and the five Miombo and two Mopane sub-regions were analyzed and overlapped with the digital maps of the Zambezian region.

4.2. Database of Legume Trees

A list of the native tree legume species (Leguminosae family) from the Mopane and Miombo woodlands was created through an extensive research in scientific publications [6,12,17,33,62] and references therein and online databases, such as the African Plant Database [63], Plants of the World Online [64], Flora of Mozambique [65], Flora of Zambia [66], Flora of Malawi [67] and Flora of Zimbabwe [68]. Scientific names were updated according to The Plant List [69], while subfamilies were compiled using the organization defined by the The Legume Phylogeny Working Group (LPWG) [23]. The main distribution in the Zambezian phytoregion, species’ habit, conservation status and molecular data were also searched and compiled. Distribution data was attained in several bibliographic sources [70,71,72,73,74] and online databases, namely the Global Biodiversity Information Facility (GBIF) platform [75], and the African Plant Database [63]. The conservation status of each species was consulted in the International Union for Conservation of Nature—Red List [40].

4.3. Sequence Data and Phylogenetic Analysis

To perform the molecular analysis, three markers were selected: two chloroplast genes often used in plant barcoding, rbcL and matK [76,77]; and the internal transcribed spacer (ITS) region, which has been shown to be a useful complementary barcode [78].
The software Geneious Prime 2019.0.3 [79] was used to retrieve the selected DNA sequences from the National Center for Biotechnology Information (NCBI) GenBank database, and each locus dataset was subsequently aligned using the multiple sequence alignment tool MAFFT [80], available online [81]. The haplotype diversity of the data was verified using DNASP6 v.6.12.01 [82], and then processed with trimAl v.1.3 [83], through the Phylemon2 framework [84], to remove poorly aligned regions and improve the quality of the alignments. A concatenated set using the three loci was created using Concatenator [85] to assess the collective phylogeny of the selected taxa. PartitionFinder2 v.2.1.1 [86,87,88] was used to find the adequate partitioning and models of evolution for the four groups (three single and one combined), using the corrected Akaike Information Criterion (AICc) as the model, and partitioning by gene and codon position.
Phylogeny reconstructions were made using two different methodologies for the individual and combined locus datasets, namely maximum likelihood (ML) and Bayesian inference (BI). In both cases, species from the Polygalaceae family, a sister group of Leguminoseae, were selected as outgroups (Monnina xalapensis, Rhinotropis acanthoclada and Xanthophyllum hainanense, the latter functioning as the most exterior outgroup) [89]. ML analyses were performed using RAxML v.8.2.10 [90], through RaxmlGUI v.1.5b [91], using a ML + rapid bootstrap search and an autoMRE bootstrap. BI analyses were made using MrBayes v.3.2.6 [92], with 1.5 × 107 generations and a sample every 100 steps, with default chains and temperature. Convergence on all parameters was verified using Tracer v.1.6 [93] across all runs. The BI analyses were performed using the Cipres Gateway services [94]. Finally, we summarized, annotated and later exported the resulting phylogenetic trees using FigTree v.1.4.3 [95].

Supplementary Materials

The following are available online at https://www.mdpi.com/2223-7747/8/6/182/s1, Figure S1: The phylogenetic trees obtained using the matK matrix with ML (A) and BI (B). Figure S2: The phylogenetic trees obtained using the rcbL matrix with ML(A) and BI (B). Figure S3: The phylogenetic trees obtained using the ITS matrix with ML (A) and BI (B). Table S1: Summary of the analyzed molecular data.

Author Contributions

Conceptualization, M.M.R. and A.I.R.-B.; methodology, I.M., S.C., A.R.P.; software, D.B., A.R.P.; validation, I.M., S.C., N.R., M.M.R., A.I.R.-B.; formal analysis, I.M., S.C.; investigation, I.M., S.C.; resources, D.B., A.R.P.; data curation, M.M.R., A.I.R.-B., N.S.R.; writing—original draft preparation, I.M., S.C.; writing—review and editing, I.M., S.C., M.M.R., N.S.R., A.I.R.-B.; visualization, S.C., A.R.P.; supervision, N.S.R., M.M.R., A.I.R.-B.; project administration and funding acquisition, M.M.R., N.S.R., A.I.R.-B.

Funding

This research was funded by Fundo para a Investigação Aplicada e Multissectorial (Mozambique and Italy) and Portuguese national funds from Camões, Instituto da Cooperação e da Língua and Fundação para a Ciência e a Tecnologia (research units UID/GEO/04035/2013-GeoBioTec and UID/AGR/04129/2013-LEAF; and the grants SFRH/BD/113951/2015 to IM and SFRH/BD/120054/2016 to SC).

Acknowledgments

The authors are thankful to Luis Catarino (Faculty of Science, University of Lisbon) for providing the photographs for Figure 2.

Conflicts of Interest

The authors declare no conflicts of interest.

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Figure 1. Geographical distribution of the Miombo–Mopane woodlands in the Zambezian phytoregion.
Figure 1. Geographical distribution of the Miombo–Mopane woodlands in the Zambezian phytoregion.
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Figure 2. Leguminosae species from Miombo and Mopane woodlands and their conservation status according to the IUCN Red List. (A) Baikiaea plurijuga occurs in Miombo and Mopane woodlands and is classified as near threatened; (B) Brachystegia bakeriana occurs in Miombo and is classified as vulnerable; (C) Dichrostachys cinerea occurs in both ecoregions and is classified as least concern; (D) Pterocarpus angolensis occurs in Miombo woodlands and is classified as near threatened.
Figure 2. Leguminosae species from Miombo and Mopane woodlands and their conservation status according to the IUCN Red List. (A) Baikiaea plurijuga occurs in Miombo and Mopane woodlands and is classified as near threatened; (B) Brachystegia bakeriana occurs in Miombo and is classified as vulnerable; (C) Dichrostachys cinerea occurs in both ecoregions and is classified as least concern; (D) Pterocarpus angolensis occurs in Miombo woodlands and is classified as near threatened.
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Figure 3. Phylogenetic tree of the Leguminosae tree species from Miombo and Mopane ecosystems. The phylogeny was constructed with three selected genes (ITS + matK + rbcL) using the Bayesian inference (BI) method. Acronyms for the countries/regions: Mio—Miombo; Mop—Mopane; AO—Angola; DRC—Democratic Republic of the Congo; ZM—Zambia; ZW—Zimbabwe; TZ—United Republic of Tanzania; MW—Malawi; MZ—Mozambique.
Figure 3. Phylogenetic tree of the Leguminosae tree species from Miombo and Mopane ecosystems. The phylogeny was constructed with three selected genes (ITS + matK + rbcL) using the Bayesian inference (BI) method. Acronyms for the countries/regions: Mio—Miombo; Mop—Mopane; AO—Angola; DRC—Democratic Republic of the Congo; ZM—Zambia; ZW—Zimbabwe; TZ—United Republic of Tanzania; MW—Malawi; MZ—Mozambique.
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Figure 4. Phylogenetic tree of the Leguminosae tree species from Miombo and Mopane ecosystems. The phylogeny was constructed with three selected genes (ITS + matK + rbcL) and the maximum likelihood (ML) method. Acronyms for the countries/regions: Mio—Miombo; Mop—Mopane; AO—Angola; DRC—Democratic Republic of the Congo; ZM—Zambia; ZW—Zimbabwe; TZ—United Republic of Tanzania; MW—Malawi; MZ—Mozambique.
Figure 4. Phylogenetic tree of the Leguminosae tree species from Miombo and Mopane ecosystems. The phylogeny was constructed with three selected genes (ITS + matK + rbcL) and the maximum likelihood (ML) method. Acronyms for the countries/regions: Mio—Miombo; Mop—Mopane; AO—Angola; DRC—Democratic Republic of the Congo; ZM—Zambia; ZW—Zimbabwe; TZ—United Republic of Tanzania; MW—Malawi; MZ—Mozambique.
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Table
Table 1. Leguminosae tree species from Miombo and Mopane ecosystems: main habitat, distribution in the Zambezian area, conservation status (International Union for Conservation of Nature - IUCN) and habit.
Table 1. Leguminosae tree species from Miombo and Mopane ecosystems: main habitat, distribution in the Zambezian area, conservation status (International Union for Conservation of Nature - IUCN) and habit.
TaxonSubfamilyHabitatDistribution 1Conservation Status 2Habit
AODRCZMZWTZMWMZ
Acacia arenaria SchinzCaesalpinioideaeMiombo and MopaneX XX NEShrub or small tree 2–9 m
Acacia erubescens Welw. ex Oliv.CaesalpinioideaeMiombo and MopaneXXXXXXXNEShrub or tree 2–10 m
Acacia galpinii Burtt DavyCaesalpinioideaeMiomboX XXXXXNELarge tree 8–36 m
Acacia gerrardii Benth.CaesalpinioideaeMiombo and Mopane XXXXXXNEShrub or tree 5–15 m
Acacia hebeclada DC.CaesalpinioideaeMopaneX XX NEShrub or small tree to 3 m
Acacia kirkii Oliv.CaesalpinioideaeMopaneXXXXXXXNETree 2.5–18 m
Acacia mellifera (Vahl) Benth.CaesalpinioideaeMiombo and MopaneX XXX XNETree 4–9
Acacia nigrescens Oliv.CaesalpinioideaeMiombo and MopaneX XXXXXNETree 4–30 m
Acacia nilotica (L.) Willd. ex DelileCaesalpinioideaeMiombo and MopaneX XXXXXLCTree 3–15 m
Acacia polyacanthaCaesalpinioideaeMiomboXXXXXXXNELarge tree 3.5–20 m
Acacia robusta Burch.CaesalpinioideaeMiombo XXX XNETree 5-30 m
Acacia sieberiana DC.CaesalpinioideaeMiomboXXXXXXXNETree 3–25 m
Acacia welwitschii Oliv.CaesalpinioideaeMiomboX X XNELarge tree 3–20 m
Afzelia quanzensis Welw.DetarioideaeMiomboXXXXXXXNEShrub or tree 1.5–35 m
Albizia adianthifolia (Schum.) W.WightCaesalpinioideaeMiomboXXXXXXXNETree 2.5–40 m
Albizia anthelmintica Brongn.CaesalpinioideaeMiomboX XXXXXNEShrub or tree 2–12 m
Albizia antunesiana HarmsCaesalpinioideaeMiomboXXXXXXXNETree 6–18 m
Albizia glaberrima (Schum. & Thonn.) Benth.CaesalpinioideaeMiomboXXXXXXXNEShrub or tree 9–25 m
Albizia harveyi E.Fourn.CaesalpinioideaeMiomboXXXXXXXNETree 1.5–20 m
Albizia versicolor Oliv.CaesalpinioideaeMiomboXXXXXXXNETree 3–20 m
Amblygonocarpus andongensis (Oliv.) Exell & TorreCaesalpinioideaeMiomboXXXXXXXNETree 6–25 m
Baikiaea plurijuga HarmsDetarioideaeMiombo and MopaneX XX LR/NTTree 6–25 m
Baphia bequaertii De Wild.PapilionoideaeMiomboXXX NEShrub or tree 3–10 m
Baphia massaiensis Taub.PapilionoideaeMiomboXXXXXXXLCShrub or tree to 8–10 m
Bauhinia petersiana BolleCercidoideaeMiomboXXXXXXXNEShrub or tree 3–10 m
Bauhinia thonningii Schum.CercidoideaeMiombo and MopaneX XXXXXNEShrub or tree to 2–20 m
Bauhinia tomentosa L.CercidoideaeMiomboXXXXXXXNEShrub or tree 1–8 m
Bobgunnia madagascariensis (Desv.) J.H.Kirkbr. & WiersemaPapilionoideaeMiomboXXXXXXXNEShrub or tree 2–15 m
Brachystegia allenii Hutch. & Burtt DavyDetarioideaeMiombo XXXXXXNETree 3–20 m
Brachystegia bakeriana Burtt Davy & Hutch.DetarioideaeMiomboX XX VU B1+2cShrub or tree to 10 m
Brachystegia boehmii TaubDetarioideaeMiomboXXXXXXXNETree 2.5–25 m
Brachystegia floribunda Benth.DetarioideaeMiomboXXX XXXNETree 4–15 m
Brachystegia gossweileri Burtt Davy & Hutch.DetarioideaeMiomboXXX NETree 6–24 m
Brachystegia longifolia Benth.DetarioideaeMiomboXXX XXXNETree 2–30 m
Brachystegia puberula Burtt Davy & Hutch.DetarioideaeMiomboX X X LCTree 6–12 m
Brachystegia spiciformis BenthDetarioideaeMiomboXXXXXXXNETree 5–40 m
Brachystegia tamarindoides Benth.DetarioideaeMiomboX X XXXNETree 4–30 m
Brachystegia taxifolia HarmsDetarioideaeMiombo XX XX NEShrub or tree 2–16 m
Brachystegia utilis Hutch. & Burtt DavyDetarioideaeMiomboXXXXXXXNETree 6–20 m
Brachystegia wangermeeana De Wild.DetarioideaeMiomboXXX XX NETree 1.5–20 m
Burkea africana Hook.CaesalpinioideaeMiomboXXXXXXXNETree 4–20 m
Cassia abbreviata Oliv.CaesalpinioideaeMiombo and Mopane XXXXXXNEShrub or tree 3–15 m
Colophospermum mopane (Benth.) LeonardDetarioideaeMopaneX XX XXNETree 4–18 m tall
Cordyla africana Lour.PapilionoideaeMiombo XXXXXNETree 9–40 m
Craibia zimmermannii (Harms) DunnPapilionoideaeMiombo X XNETree 4–5 m
Dalbergia arbutifolia BakerPapilionoideaeMiombo XXXXXXNEShrub or tree 3–18 m
Dalbergia boehmii Taub.PapilionoideaeMiomboXXXXXXXNEShrub or tree 4.5–21 m
Dalbergia melanoxylon Guill. & Perr.PapilionoideaeMiombo and MopaneXXXXXXXLR/NTSpiny shrub or tree 1–30 m
Dalbergia nitidula BakerPapilionoideaeMiomboXXXXXXXNEShrub or tree 2–12 m
Dialium englerianum Henriq.DialioideaeMiomboXXXX NETree 6–23 m
Dichrostachys cinerea (L.) Wight & Arn.CaesalpinioideaeMiombo and MopaneXXXXXXXLCShrub or tree 1–12 m
Elephantorrhiza goetzei (Harms) HarmsCaesalpinioideaeMiomboXXXXXXXNEShrub or tree 1–7 m
Entada abyssinica Steud. ex A. Rich.CaesalpinioideaeMiombo and MopaneXXXXXXXNETree 2.7–15 m
Erythrophleum africanum (Benth.) HarmsCaesalpinioideaeMiombo and MopaneXXXXXXXNETree 4–18 m
Faidherbia albida (Delile) A.Chev.CaesalpinioideaeMiombo and MopaneXXXXXXXNETree 6–30 m
Guibourtia coleosperma (Benth.) J. LéonardDetarioideaeMiomboXXXX NETree 12–30 m
Isoberlinia angolensis (Benth.) Hoyle & BrenanDetarioideaeMiomboXXX XX NEShrub or tree 1–20 m
Isoberlinia scheffleri (Harms) GreenwayDetarioideaeMiombo X XVU B1+2bTree 30–46 m
Isoberlinia tomentosa (Harms) Craib & StapfDetarioideaeMiomboXXX XX NETree 3–18 m
Julbernardia globiflora (Benth.) TroupinDetarioideaeMiomboXXXXXXXNETree 5–15 m
Julbernardia paniculata (Benth.) TroupinDetarioideaeMiomboXXXXXXXNETree 2–20 m
Millettia stuhlmannii Taub.PapilionoideaeMiombo XX XNETree 6–25 m
Millettia usaramensis Taub.PapilionoideaeMiombo XXXXNEShrub or tree 2–10 m
Mundulea sericea (Willd.) A. Chev.PapilionoideaeMiomboX XXXXXNELarge shrub or tree 1–8 m
Ormocarpum trichocarpum (Taub.) Engl.PapilionoideaeMiombo and Mopane XXXXNEShrub or small tree 1–6 m
Peltophorum africanum Sond.CaesalpinioideaeMiombo and MopaneXXXX XXNETree 3–12 m
Pericopsis angolensis (Baker) MeeuwenPapilionoideaeMiomboXXXXXXXNETree 3–20 m
Philenoptera bussei (Harms) ShrirePapilionoideaeMiombo XXXXXNETree 3–15 m
Philenoptera nelsii (Schinz) SchrirePapilionoideaeMopaneX XX NEShrub or tree 4–12 m
Philenoptera violacea (Klotze) ShrirePapilionoideaeMiomboXXXXXXXNETree 4.5–27 m
Pterocarpus angolensis DC.PapilionoideaeMiomboXXXXXXXLR/NTTree 5–30 m
Pterocarpus brenanii Barbosa & TorrePapilionoideaeMiomboXXXXXXXLCTree 4–12 m
Pterocarpus lucens Guill. & Perr.PapilionoideaeMiombo and MopaneX XX XXLCTree 7.5–18 m
Pterocarpus rotundifolius (Sond.) DrucePapilionoideaeMiombo and MopaneXXXXXXXNETree 3–25 m
Senna petersiana (Bolle) LockCaesalpinioideaeMiombo XXXXXXNEShrub or small tree 2–6 m
*Tamarindus indica L.DetarioideaeMiomboXXXXXXXLCTree to 25 m
Xanthocercis zambesiaca (Baker) Dumaz-le-GrandPapilionoideaeMiombo XX XXNETree 7–30 m
Xeroderris stuhlmannii (Taub.) Mendonça & E.P. SousaPapilionoideaeMiombo and Mopane XXXXXNETree up to 20 m
Total numbers-
Number of species (Miombo)--58506762646062--
Number of species (Mopane)--19112123171817--
Number of species (Miombo and/or Mopane)--62517166656264--
* The origin of Tamarindus indica is uncertain and some sources (Africa Plant Database) suggest that it is native only in Madagascar. 1 Distribution: AO—Angola; DRC—Democratic Republic of Congo; ZM—Zambia; ZW—Zimbabwe; TZ—United Republic of Tanzania; MW—Malawi; MZ—Mozambique. 2 Conservation status according to IUCN Red List: LC—least concern; NT—near threatened; VU—vulnerable; NE—not evaluated.
Table
Table 2. Leguminosae tree species from Miombo and Mopane ecosystems used in the phylogenetic analyses. GenBank accession numbers for the corresponding internal transcribed spacer (ITS) and cpDNA (rbcL and matK) sequences.
Table 2. Leguminosae tree species from Miombo and Mopane ecosystems used in the phylogenetic analyses. GenBank accession numbers for the corresponding internal transcribed spacer (ITS) and cpDNA (rbcL and matK) sequences.
TaxonSubfamilyrbcLmatKITS
Acacia arenaria SchinzCaesalpinioideaeJX572181JX517408-
Acacia erubescens Welw. ex Oliv.CaesalpinioideaeJF265248JF270605JQ265878
Acacia galpinii Burtt DavyCaesalpinioideaeJX572194JX518092JQ265866
Acacia gerrardii Benth.CaesalpinioideaeJF265250JF270607JQ265879
Acacia hebeclada DC.CaesalpinioideaeJX572199JX517672JQ265920
Acacia kirkii Oliv.CaesalpinioideaeJX572204JX517387JQ265829
Acacia mellifera (Vahl) Benth.CaesalpinioideaeJX572211JX517310-
Acacia nigrescens Oliv.CaesalpinioideaeEU213440EU214210KY688811
Acacia nilotica (L.) Willd. ex DelileCaesalpinioideaeJF265255JF270612JX139101
Acacia polyacanthaCaesalpinioideae--JQ265902
Acacia robusta Burch.CaesalpinioideaeJX572222JX517547-
Acacia sieberiana DC.CaesalpinioideaeJF265259JX517353JQ265854
Acacia welwitschii Oliv.CaesalpinioideaeJX572234JX518159-
Afzelia quanzensis Welw.DetarioideaeJX572247JX518045KY306488
Albizia adianthifolia (Schum.) W.WightCaesalpinioideaeJQ025020JQ024935-
Albizia anthelmintica Brongn.CaesalpinioideaeJX572254JX517977-
Albizia antunesiana HarmsCaesalpinioideae---
Albizia glaberrima (Schum. & Thonn.) Benth.CaesalpinioideaeJX572256JX518104-
Albizia harveyi E.Fourn.CaesalpinioideaeJX572257JX518176-
Albizia versicolor Oliv.CaesalpinioideaeJX572260AF274210-
Amblygonocarpus andongensis (Oliv.) Exell & TorreCaesalpinioideaeJX572301AF521812-
Baikiaea plurijuga HarmsDetarioideaeJX572322JX517704KY306501
Baphia bequaertii De Wild.Papilionoideae---
Baphia massaiensis Taub.PapilionoideaeJF265298JF270652-
Bauhinia petersiana BolleCercidoideaeJX572327JX517937-
Bauhinia thonningii Schum.CercidoideaeKU568124KT461985-
Bauhinia tomentosa L.CercidoideaeJX572328JX517621KX057838
Bobgunnia madagascariensis (Desv.) J.H.Kirkbr. & WiersemaPapilionoideaeJX572335AY386940EF560800
Brachystegia allenii Hutch. & Burtt DavyDetarioideaeKU568100KX146320-
Brachystegia bakeriana Burtt Davy & Hutch.Detarioideae---
Brachystegia boehmii TaubDetarioideaeJX572347EU361886KY306513
Brachystegia floribunda Benth.DetarioideaeKU568148KX146363KY306515
Brachystegia gossweileri Burtt Davy & Hutch.Detarioideae---
Brachystegia longifolia Benth.DetarioideaeKU568078KX146300AF513687
Brachystegia puberula Burtt Davy & Hutch.Detarioideae---
Brachystegia spiciformis BenthDetarioideae-EU361888KY306518
Brachystegia tamarindoides Benth.Detarioideae---
Brachystegia taxifolia HarmsDetarioideae---
Brachystegia utilis Hutch. & Burtt DavyDetarioideae---
Brachystegia wangermeeana De Wild.Detarioideae---
Burkea africana Hook.CaesalpinioideaeJQ025025JQ024940KX057840
Cassia abbreviata Oliv.CaesalpinioideaeJX572384JF270682-
Colophospermum mopane (Benth.) LeonardDetarioideaeJF265343JF270696AY955788
Cordyla africana Lour.PapilionoideaeJF265371KP177913-
Craibia zimmermannii (Harms) DunnPapilionoideaeJX572478JX518072-
Dalbergia arbutifolia BakerPapilionoideaeJX572499JX517956AB828608
Dalbergia boehmii Taub.PapilionoideaeJX572501JX517962AB828617
Dalbergia melanoxylon Guill. & Perr.PapilionoideaeKU748232KY484235KM276150
Dalbergia nitidula BakerPapilionoideae-JX970899-
Dialium englerianum Henriq.Dialioideae---
Dichrostachys cinerea (L.) Wight & Arn.CaesalpinioideaeJQ025041KX302328AF458820
Elephantorrhiza goetzei (Harms) HarmsCaesalpinioideaeJX572549JX517358-
Entada abyssinica Steud. ex A. Rich.CaesalpinioideaeJX572556AF521829KX057869
Erythrophleum africanum (Benth.) HarmsCaesalpinioideaeJX572568JX517525-
Faidherbia albida (Delile) A.Chev.CaesalpinioideaeKX119293KX119382KX057872
Guibourtia coleosperma (Benth.) J. LéonardDetarioideaeJX572650JX518076-
Isoberlinia angolensis (Benth.) Hoyle & BrenanDetarioideaeKU568126KX146343HM041837
Isoberlinia scheffleri (Harms) GreenwayDetarioideaeAM234240EU361983HM041838
Isoberlinia tomentosa (Harms) Craib & StapfDetarioideaeKX119306KX162205KX057885
Julbernardia globiflora (Benth.) TroupinDetarioideaeJX572701JX517829-
Julbernardia paniculata (Benth.) TroupinDetarioideaeKU568145KX146360-
Millettia stuhlmannii Taub.PapilionoideaeJX572773JX517411-
Millettia usaramensis Taub.PapilionoideaeJX905971JX905956-
Mundulea sericea (Willd.) A. Chev.PapilionoideaeJQ025063JQ024975AF467482
Ormocarpum trichocarpum (Taub.) Engl.PapilionoideaeJX572810JX517885AF068158
Peltophorum africanum Sond.CaesalpinioideaeJX572846KX302342-
Pericopsis angolensis (Baker) MeeuwenPapilionoideaeKU568030KX584412KX584402
Philenoptera bussei (Harms) ShrirePapilionoideaeJX572848JX518116-
Philenoptera nelsii (Schinz) SchrirePapilionoideae---
Philenoptera violacea (Klotze) ShrirePapilionoideaeJF265547JF270890JX506439
Pterocarpus angolensis DC.PapilionoideaeKY829237KY829168KY829139
Pterocarpus brenanii Barbosa & TorrePapilionoideaeJX572903JN083540JN083475
Pterocarpus lucens Guill. & Perr.PapilionoideaeKU568062KX146285JN083486
Pterocarpus rotundifolius (Sond.) DrucePapilionoideaeJF265565JF270907JN083509
Senna petersiana (Bolle) LockCaesalpinioideaeJF265596JX517765-
Tamarindus indica L.DetarioideaeAB378732JQ587877KY306654
Xanthocercis zambesiaca (Baker) Dumaz-le-GrandPapilionoideaeJX573092JX517427-
Xeroderris stuhlmannii (Taub.) Mendonça & E.P. SousaPapilionoideaeJX573093JX517470AF467485

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Maquia, I.; Catarino, S.; Pena, A.R.; Brito, D.R.A.; Ribeiro, N.S.; Romeiras, M.M.; Ribeiro-Barros, A.I. Diversification of African Tree Legumes in Miombo–Mopane Woodlands. Plants 2019, 8, 182. https://doi.org/10.3390/plants8060182

AMA Style

Maquia I, Catarino S, Pena AR, Brito DRA, Ribeiro NS, Romeiras MM, Ribeiro-Barros AI. Diversification of African Tree Legumes in Miombo–Mopane Woodlands. Plants. 2019; 8(6):182. https://doi.org/10.3390/plants8060182

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Maquia, Ivete, Silvia Catarino, Ana R. Pena, Denise R.A. Brito, Natasha. S. Ribeiro, Maria M. Romeiras, and Ana I. Ribeiro-Barros. 2019. "Diversification of African Tree Legumes in Miombo–Mopane Woodlands" Plants 8, no. 6: 182. https://doi.org/10.3390/plants8060182

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