Use of the Australian genus Eucalyptus in short rotation plantations in Africa and Madagascar has developed over the last century to such an extent that it is becoming the most frequently planted genus in Africa. In order to find ecologically well-adapted eucalypts, foresters have tested different species of various origins and the number of tested Eucalyptus species now exceeds 150 in Africa. Due to the ability of eucalypts to naturally form ectomycorrhizae, even in the absence of any controlled introduction of compatible ectomycorrhizal fungal partners, their introduction in new ecosystems has direct consequences for ectomycorrhizal fungus communities. A bibliographical compilation, together with original field observations on putative ectomycorrhizal fungi associated with eucalypts in Africa and in Madagascar, has been drawn up in two lists: one for Africa and one for Madagascar where surprisingly high fungal diversity was observed. The level of diversity, the putative origin of the fungi, and their potential impact on native ectomycorrhizal fungi are discussed. The development of eucalypts plantations will inexorably lead to the increase of exotic fungal species being potentially invasive in the considered region.
1. Introduction
Since colonial times, the African woodlands have been subjected to irreversible management policies that have resulted in the planting of large areas with exotic trees, for instance Pinus and Eucalyptus. In Mediterranean and tropical countries eucalypts are planted because they are generally fast-growing trees that make for a profitable business. Nowadays, eucalypt plantations cover approximately 1,8 Mha in Africa and are the most important planted genus on that continent [1]. In order to extend plantations and increase profits, it appeared necessary to find and select new eucalypt genotype adapted to different ecological situations. To that end, foresters started to test different Eucalyptus species of different origins, notably in Africa and Madagascar (e.g., [2, 3]). As a result, the number of introduced eucalypt species in African plantation trials now exceeds 150. Some of them are used in commercial plantations as pure species or as hybrids [4]. The mass introduction of these exotic species in Africa definitely has consequences for local plant biodiversity and also for soil microbial communities such as ectomycorrhizal (ecm) fungi. Indeed, the ability of eucalypt species to form ectomycorrhizae, which are ecologically important symbioses that mainly associate homobasidiomycetous fungi, was observed for the first time in South Africa by Van der Bijl [5]. Since then, the ecm status of eucalypt species has been clarified [6] notably in Australia where a large diversity of fungal partner has been described [7–12]. Until now, ecm fungi found in Africa and Madagascar have resulted putatively from chance introductions, from compatibility with native ecm fungi, or from compatibility with ecm fungi from other exotic plantations. Indeed, the use of soil as an inoculant or any other source of inoculation that might bring ecm fungi from the tree’s native area has not been reported when establishing eucalypt plantations. Some controlled field inoculation trials using pure strains were set up, but only on very limited areas (e.g., [14]) and, in this case, the invasion of neighboring plantations by the introduced strains was not reported. Controlled field inoculation trials provide ways of entry for new ecm fungi that cannot be neglected, as is the case for China [15, 16]. However, the fungal species or even the strain reference might be known, enabling tracking in the plantation or in surrounding plantations. In Africa, we are in a situation where we have no proof of any propagation of a fungal species after the controlled inoculation of a eucalypt plantation. However, we are in a particular case where human activity, eucalypt plantations, has direct and mostly uncontrolled consequences for another compulsorily related biological community: ecm fungi.
Published papers, unpublished information, and authors personal data formed the basis of our work to synthesize the knowledge available on putative ecm fungi of eucalypt plantations in Africa and Madagascar. An annotated list of putative ecm fungi of eucalypts is given for more than 20 African countries and Madagascar.
2. Materials and Methods
A bibliographical search covering 30 years was carried out enabling us to uncover all the published papers and also a large share of the “grey literature” directly linked to our topic: ecm fungi associated with eucalypts in Africa and Madagascar. Written reports and all the oral reports of ecm partnerships have always to be considered with great caution and skepticism. Indeed, proving the ability of a tree species to form ectomycorrhizae with one particular fungal species is always a difficult task; the existence of other local or introduced ecm tree species in the vicinity of eucalypt plantations as well as the mistaken identification of the fungal partner can lead to misinterpretation. Definitely doubtful data are not considered in the rest of the paper and unreliable data are presented with a special mention of what needs to be considered with caution.
In addition, field surveys were organized in eucalypt plantations, notably in different African countries and in Madagascar; fungal fruiting bodies were systematically collected from the plantations. Litter and a few centimeters of topsoil were removed to search for hypogeous fungi on at least 4 m2 in each plantation. Fungal specimens were deposited at the Museum National d’Histoire Naturelle de Paris (PC), France. In order to prove the ecm partnership, careful mycelium and root tracking were carried out in the field enabling us to assess physical links between fruiting bodies, ecm root tips, and the bearing trees.
Ectomycorrhizae histological studies were also carried out on materials collected in the field to reveal the fungal sheath and the Hartig net (Table 2).
3. Results
In Africa, 35 ecm fungal species are mentioned as being associated with 15 identified eucalypt species and a range of unidentified species (at least five), along with hybrids (Table 1). Pisolithus was present and often highly dominant or even alone in almost all the plantations, as is the case in the West African dry tropics with Pisolithus albus in E. camaldulensis plantations (Figure 1(a)). The importance of the genus Pisolithus and to a lesser degree, the genus Scleroderma, was noteworthy (Figures 1(b) and 1(c)). The presence of the ubiquitous ecm fungus Thelephora sp. in the wet tropics was also noteworthy (Figure 1(d)). During the surveys ([13] in Table 1), ectomycorrhizae with a typical fungal sheath and a Hartig net (Figures 1(e) and 1(f)) were found in the vicinity of fruiting bodies.
List of ectomycorrhizal fungi found associated with eucalypts in Africa with an indication of the country where the observation was made and the reference.
*
Pisolithus arhizus is a temperate European species described from acidic soils and associated with trees like Quercus, betulus, or pinus. Its presence in Africa associated with introduced Australian species is unlikely. Our assumption is that the specific epithet “arhizus” is erroneous.
**The systematic of Scleroderma are complex and the erroneous use of specific epithets in the identification of this species has to be kept in mind.
***In the absence of any indication on the subspecies, the possibilities of synonymy with other species are multiple.
#Rhizopogon is a genus mostly associated with pines and some temperate deciduous trees. A poor mycorrhizal colonization of eucalypt roots by these Rhizopogon can be considered; indeed Rhizopogon spp. differed markedly in their ability to form ectomycorrhizas according to their taxonomical section and host plant [41].
§The presence of these temperate taxa in tropical countries has to be carefully considered; confusion with local tropical taxa might be possible.
Color, diameter, fungal mantle thickness, and Hartig net depth of ectomycorrhizae in situ collected in Senegal on 3 species of Eucalyptus.
Fungal species
Color
Diameter (μm)
Mantle thickness (μm)
Hartig net depth (μm)
E. apodophylla X Pisolithus albus
bY
190±20
20±4
23±7
E. camaldulensis X Pisolithus albus
bY
240±22
26±6
24±2
E. robusta X Pisolithus albus
bY
210±18
22±4
20±6
E. camaldulensis X Scleroderma capensis
W
215±23
20±4
18±8
E. robusta X Scleroderma capensis
W
190±16
16±3
24±4
E. camaldulensis X Scleroderma verrucosum
W
150±22
14±6
23±5
Example of ectomycorrhizal fungi and ectomycorrhizae of eucalypts in Africa. (a) Pisolithus albus; (b) Pisolithus marmoratus; (c) Scleroderma flavidum; (d) Thelephora sp.; (e) golden yellow ectomycorrhizae of Pisolithus albus with E. camaldulensis; (f) cross-section of an ectomycorrhizae of Pisolithus albus with E. camaldulensis. The bar represents 50 μm.
In Madagascar, we collected 38 putative ecm fungal species from nine E. robusta plantations on the outskirts of Antananarivo (Table 3, Figures 2(a), 2(b), 2(c), 2(d), 2(e)). At these nine survey sites, Pisolithus was found only once and was far from dominant. In addition to this surprising diversity associated with E. robusta, two different Pisolithus species were found at two other sites in the southeast of Madagascar (Figure 2(f)).
List of ectomycorrhizal fungi found associated with Eucalyptus robusta and Eucalyptus sp. in Madagascar.
Fungal species
Observation sites
Herbarium N°(*)
Associated with E. robusta
Amanita bojeri Buyck#
Anjozorobe
MG47
Amanita aff. citrina
Manjakandriana
MG23
Amanita aff. luteolus
Anjozorobe
MG44
Amanita aff. phalloides
Anjozorobe
MG35
Amanita aff. rubescens
Antananarivo
MG21
Amanita sp.1
Ampitambe
MG14
Amanita sp.2
Anjozorobe
MG20
Amanita sp.3
Anjozorobe
MG49
Amanitopsis sp.1
Manjakandriana
MG32
Boletus aff. cyanopus
Manjakandriana
MG26
Boletus sp.1#
Anjozorobe
MG19
Boletus sp.2#
Antananarivo
MG28
Boletus sp.3#
Anjozorobe
MG38
Boletus sp.4#
Anjozorobe
MG45
Cantharellus congolensis Beeli
Antananarivo
MG16
Cantharellus eucalyptorum Buyck & Eyssartier#
Anjozorobe
MG15
Cortinarius sp.1#
Antananarivo
MG31
Pisolithus albus
Anjozorobe
MG24
Rubinoboletus sp.1
Mandrake
MG13
Rubinoboletus sp.2#
Antananarivo
MG18
Rubinoboletus sp.3#
Mantasoa
MG27
Russula sp.1
Antananarivo
MG33
Russula sp.2
Anjozorobe
MG34
Russula sp.3
Antananarivo
MG36
Russula sp.4
Anjozorobe
MG39
Russula sp.5
Antananarivo
MG40
Russula sp.6
Antananarivo
MG41
Russula sp.7
Anjozorobe
MG42
Russula sp.8
Anjozorobe
MG46
Scleroderma cepa
#
Ambohimanga
MG25
Scleroderma sp.1#
Mahaela
MG12
Scleroderma sp.2#
Anjozorobe
MG50
Scleroderma verrucosum
#
Antananarivo
MG17
Xerocomus sp.1#
Falamangua
MG11
Xerocomus sp.2#
Manjakandriana
MG22
Xerocomus sp.3
Manjakandriana
MG30
Xerocomus sp.4#
Antananarivo
MG43
Associated with Eucalyptus spp.
Pisolithus albus
#
Fanjahira
MG86
Pisolithus sp.#
Petriki
MG85
*Herbarium samples have been deposited at the Museum National d'Histoire Naturelle de Paris (PC), France.
#Indicates when the observation was carried out by tracking the mycelium from fungus fruiting bodies up to fine ectomycorrhizal roots and the trunk.
Example of putative ectomycorrhizal fungi of Eucalyptus robusta in Madagascar. (a) Amanita sp.3; (b) Cantharellus eucalyptorum; (c) Cantharellus congolensis; (d) Rubinoboletus sp.; (e) Russula sp.3; (f) Pisolithus sp.
4. Discussion
Ectomycorrhizal deficiency never seems to have been a problem in the early establishment of eucalypts. Ryvarden et al. [17] noted that selected trees form satisfactory partnerships with some introduced ecm fungi, notably Pisolithus arhizus which is now extremely abundant under eucalypts in Africa, and also with some elements of the indigenous ecm mycoflora. It is interesting to note that renantherous species of Eucalyptus known for their high dependence on ecm symbiosis [6] have been excluded by foresters due to their poor growth performance even in a Mediterranean climate (North Africa and South Africa), where the range of putatively adapted species is wide. During the process of eucalypt introduction and selection, foresters have neglected ecm symbiosis. This fact has probably led to the selection of tree species dependent little on ectomycorrhizae for early survival and growth. South America is also a place where eucalypts were abundantly planted and are found to be ectomycorrhizal with a range of ecm fungi ([13, 18–20, 42, 43] and Table 4). Some similarities with the African ecm fungi have to be mentioned, notably, the importance of genera Scleroderma and Pisolithus. On another hand, importance and diversity of genera Descomyces, Hydnangium, Hymenogaster, Hysterangium, and Setchelliogaster seems scarcer in Africa rather than in South America.
List of some ecm fungi and associated eucalypt hosts spontaneously found in South America: Brazil (BR), Uruguay (UR), and Argentina (AR).
Fungal species
Host tree
Country
Chondrogaster angustisporus
Eucalyptus spp.
BR, UR
Chondrogaster sp.
E. dunnii
BR
Descomyces fusisporus sp. nov.
E. cinerea
AR
D. varians sp. nov.
E. camaldulensis
AR
Descomyces sp.
E. dunnii
BR
Hydnangium archeri (Berk.) Rodway
E. camaldulensis
AR
H. carneum Wallr.
E. cinerea, E. camaldulensis
AR
Hydnangium sp.
E. grandis
BR
Hymenogaster rehsteineri Bucholtz
Eucalyptus spp.
AR
Hysterangium affine
Eucalyptus spp.
BR
Hysterangium gardneri E. Fisch.
E. camaldulensis
AR
H. inflatum
Eucalyptus spp.
BR
Labyrinthomyces sp.
E. dunnii
BR
L. laccata var. pallidifolia sp.
E. dunnii
BR
L. proxima sp.
E. dunnii
BR
Laccaria sp.
E. grandis
BR
Pisolithus albus
Eucalyptus spp.
BR
P. marmoratus
Eucalyptus spp.
BR
P. microcarpus
Eucalyptus spp.
BR
Pisolithus sp.
E. grandis
BR
Scleroderma albidum sp.
E. dunnii
BR
S. areolatum sp.
E. dunnii
BR
S. bougheri sp.
E. dunnii
BR
S. cepa sp.
E. dunnii
BR
Scleroderma sp.
E. grandis
BR
Setchelliogaster tenuipes (Setch.) Pouzar
E. camaldulensis
AR
Setchelliogaster sp.
E. dunnii
BR
Thelephora sp.
E. grandis
BR
4.1. Fungal Diversity in Africa
According to Buyck [44], the native ecm fungi are unable to form ectomycorrhizae with exotic trees and consequently, eucalypts ecm fungi are limited to a few ecm fungal species that are now cosmopolitan. The observation made by Härkönen et al. [23] corroborated Buyck’s observation: the indigenous fungi cannot grow in symbiosis with the introduced trees. These assertions seem rather excessive; indeed records of typical European species such as Amanita muscaria, A. phalloides, Paxillus involutus, or Rhizopogon luteolus [21, 23, 32, 33] or typical African species such as Amanita zambiana, Cantharellus densifolius, or Phlebopus sudanicus [24, 25, 45], indicate possibilities for some native fungi, or for fungi introduced with other exotic species such as pines, to form ectomycorrhizae with eucalypts. The presented data clearly show that the level of fungal diversity in Africa remains very low under eucalypts: only 34 ecm fungal species were recorded since 1918 [5]! The easily disseminated (by wind and rain splashing) and largely distributed genus Pisolithus is present and dominates in most plantations; other records always seem exceptional. A regular increase in fungal diversity, due to new uncontrolled introductions, to the extension of plantations to new climatic and soil conditions, and to the ageing of some plantations creating favorable conditions for the development of late stage ecm fungi is unavoidable. With the increasing importance of eucalypt plantations in Africa, we have here an interesting area to improve our knowledge on the role played by ecm diversity in the sustainability of eucalypt plantations.
On the other hand, the presence of ecm fungi associated with eucalypts has not yet been reported under native ecm trees. Presumably there is incompatibility between eucalypt ecm fungi and those of the indigenous African ecm trees (e.g., Afzelia spp., Brachystegia spp., Berlinia spp., and Isoberlinia spp. among the Caesalpiniaceae; Monotes spp., Marquesia spp. among the Dipterocarpaceae; Uapaca spp. among the Euphorbiaceae).
4.2. The Case of Madagascar
In Madagascar 80% of the vascular plants were considered to be endemic [46]. It also has one of the highest concentrations of endemic plant families: nine families represented by a total of 19 genera ca. 90 species [47, 48]. Of these, the ectotrophic Sarcolaenaceae [49] represent 56 species. Plantations of the Central Plateau are widely dominated by one single species: E. robusta. Among the 38 putatively ecm fungal species found associated with E. robusta, some red cap Russula sp. and Cantharellus eucalyptorum are marketed locally as edible, and the latter is exported to the surrounding countries. The number of ecm fungi found associated with E. robusta in a one-year survey was larger than the number of ecm fungi found in the whole of continental Africa since more than 80 years of observations. Amanita, Boletus (s.l.), Cantharellus, and Russula are the dominating genera found under E. robusta; on the other hand, members of the Sclerodermataceae were rarely observed. The presence of Madagascan endemic plant taxa able to form ecm in eucalypt plantations or in the nearby surroundings as been carefully explored and none of the already known ecm families such as Sarcolaenaceae, Rhopalocarpaceae, Caesalpiniaceae, or Euphorbiaceae has been found. Other grass and shrubs growing under the canopy of eucalypts plantations were arbuscular mycorrhizal or for a few of them, nonmycorrhizal (unpublished). To conclude, this striking difference has yet to be elucidated.
4.3. Hypotheses on the Possible Origins of ECM Fungi in Eucalypts Plantations
Until now, the rational use of ecm fungi by eucalypt plantations has been poorly developed in Africa. Inoculations with selected ecm strains are still restricted to some experimental plantations [14]. The origin of the ecm fungi found associated with eucalypts in Africa and in Madagascar has yet to be elucidated. At least, three hypotheses can be put forward: (1) chance introductions from Australia of (fully) compatible ecm fungi (e.g., Pisolithus spp.), (2) compatibility with some “broad host” ecm fungi growing in native African forests, and (3) compatibility with some ecm fungi growing in other exotic plantations (e.g., pine plantations). In any event, further studies are necessary to unravel the origins of the fungi in eucalypt plantations.
Curiously, in Madagascar, the level of fungal diversity observed under E. robusta is comparable to the diversity level of native ectotrophic forests [49]. The possibility that ecm fungi associated with E. robusta in Madagascar are of Australian origin has to be explored. Comparisons of our material collected under eucalypts (Table 2) with native Australian specimens and with samples of ecm fungi from native Madagascan ectotrophic forests are necessary to unravel the origins of the fungi observed in eucalypts plantations in Madagascar.
FAOGlobal forest resources assessment, 2000, http://www.fao.org/forestry/fo/fra/index.jspDelwaulleJ. C.1979Nogent-sur-Marne, FranceCentre Technique Forestier TropicalOtegbeyeG. O.SamarawiraI.Growth and form of Eucalyptus camaldulensis Dehnh provenances in northern Nigeria1991423-42192282-s2.0-0026304311DelwaulleJ. C.GarbayeJ.LaplaceY.Ligniculture en milieu tropical : les reboisements en eucalyptus hybrides de la savane côtière congolaise198133248255Van der BijlP. A.Note on Polysaccum crassipes DC: a common fungus in eucalyptus plantations round pretoria19186209214PryorL. D.Ectotrophic mycorrhiza in renantherous species of eucalyptus195617745085875882-s2.0-3374495776610.1038/177587b0WarcupJ. H.Occurrence of ectomycorrhizal and saprophytic discomycetes after a wild fire in a eucalypt forest19909481065106910.1016/S0953-7562(09)81334-8MillerO. K.New species of Amanita from western Australia1991691226922703MillerO. K.Three new species of Amanita from western Australia1992845679686BurgessT. I.MalajczukN.GroveT. S.The ability of 16 ectomycorrhizal fungi to increase growth and phosphorus uptake of Eucalyptus globulus Labill. and E. diversicolor F. muell199315321551642-s2.0-002779641510.1007/BF00012988CastellanoM. A.BougherN. L.Consideration of the taxonomy and biodiversity of Australian ectomycorrhizal fungi1994159137462-s2.0-5124916376110.1007/BF00000093BougherN. L.BrundrettM.DellB.MalajczukN.GongM. Q.Diversity of ectomycorrhizal fungi associated with eucalypts in Australia1995Canberra, AustraliaAustralian Centre for International Agricultural Research815Proceedings of the N°62GiachiniA.OliveiraV. L.CastellanoM. A.TrappeJ. M.Ectomycorrhizal fungi in Eucalyptus and Pinus plantations in southern Brazil2000921–6116611772-s2.0-0000269928GarbayeJ.DelwaulleJ. C.DianganaD.Growth response of eucalypts in the congo to ectomycorrhizal inoculation19882421511572-s2.0-0024226357DellB.MalajczukN.L'inoculation des eucalyptus introduits en Asie avec des champignons ectomycorhiziens australiens en vue d'augmenter la productivité des plantations19974917418410.4267/2042/5667GroveT. S.MalajczukN.BurgessT.ThomsonB. D.HardyG.SchînauA. P. G.Growth responses of plantation eucalypts to inoculation with selected ectomycorrhizal fungiProceedings of the IUFRO Symposium on Intensive Forestry: The Role of Eucalypts1991Pretoria, South AfricanSouth African Institute of Forestry8693RyvardenL.PiearceG. D.MasukaA. J.1994Harare, ZimbabweBaobab BooksKasuyaM. C. M.Da Silva CoelhoI.da Silva CamposD. T.de AraújoE. F.TamaiY.MiyamotoT.Morphological and molecular characterization of pisolithus in soil under eucalyptus Plantations in Brazil2010346189118982-s2.0-79951699605GiachiniA. J.SouzaL. A. B.OliveiraV. L.Species richness and seasonal abundance of ectomycorrhizal fungi in plantations of Eucalyptus dunnii and Pinus taeda in southern Brazil20041463753812-s2.0-1184425703510.1007/s00572-004-0297-2NouhraE. R.DominguezL. S.DanieleG. G.LongoS.TrappeJ. M.ClaridgeA. W.Ocurrence of ectomycorrhizal, hypogeous fungi in plantations of exotic tree species in central Argentina200810057527592-s2.0-5814915784310.3852/07-182AbourouhM.FechtalM.Achnal El KadmiriA.Les mycorhizes et les maladies des eucalyptus1994Caisse Nationale du Crédit Agricole132153AbourouhM.2000Rabat, MoroccoUniversity Mohamed VHärkönenM.SaarimäkiT.MwasymbiG.Edible mushrrooms of Tanzania199534191PeglerD. N.1977London, UKHMSOKew Bulletin, Additional Series VIPeglerD. N.PiearceG. D.The edible mushrooms of Zambia198035475491KreiselH.Checklist of the gasteral and secotioid Basidiomycetes of Europe, Africa and the Middle East200110213313Bañares BaudetA.1988Tenerife, SpainMonografías XXXVI, Instituto de Estudios CanariosMaillatJ.Les champignons des Eucalyptus19951445DucoussoM.Safou-MatondoR.2000Montpellier, FranceCIRAD-ForêtMalençonG.Champignons hypogés du nord de l'Afrique—I. Ascomycètes19737261288HeinemannP.Hygrophoraceae, Laccaria et boletineae II (Complément)196615279308ThoenD.Premières indications sur les mycorhizes et les champignons mycorhiziques des plantations d'exotiques du haut-shaba (République du Zaïre)19749215227MalençonG.BertaultR.1975Rabat, MoroccoTome 2, Faculté des SciencesDissingH.LangeM.Gasteromycetes of congo196232325416DissingH.LangeM.Gasteromycetales II196413233252MouayaT.1989Brazzaville, CongoMémoire de fin d'étude, Université Marien NgouabiDucoussoM.DuponnoisR.ThoenD.Pisolithus sp. host range in Senegal and infectiveness on some Australian and African AcaciaProceedings of the 3rd Conference on Forest Soils1995Balikpapan, IndonesiaDemoulinV.DringD. M.Gasteromycetes of Kivu (Zaïre), Rwanda and Burundi197545339372ThoenD.DucoussoM.Champignons et ectomycorhizes du fouta djalon19892214563DucoussoM.1991Lyon, FranceCIRAD-ISRAMolinaR.TrappeJ. M.Biology of the ectomycorrhizal genus, Rhizopogon. I.Host associations, host-specificity and pure culture syntheses199412646536752-s2.0-0028174992CortezV. G.SulzbacherM. A.BaseiaI. G.AntoniolliZ. I.Borges da SilveiraR. M.New records of hysterangium (Basidiomycota) from a eucalyptus plantation in southern Brazil201191220LupatiniM.BonnassisP. A. P.SteffenR. B.OliveiraV. L.AntoniolliZ. I.Mycorrhizal morphotyping and molecular characterization of Chondrogaster angustisporus giachini, castellano, trappe & oliveira, an ectomycorrhizal fungus from eucalyptus20081884374422-s2.0-5374908490110.1007/s00572-008-0191-4BuyckB.UBWOBA : les champignons comestibles de l'Ouest du burundi1994341123DucoussoM.BâA. M.ThoenD.Les champignons ectomycorhiziens des forêts naturelles et des plantations d'Afrique de l'ouest : une source de champignons comestibles20032755163LowryP. P.SchatzG. E.PhillipsonP. B.GoodmanS. M.PattersonB. D.The classification of natural and anthropogenic vegetation in Madagascar1997Washington, DC, USASmithsonian Inst Press93122SchatzG. E.LowryP. P.IIWolfA. E.Endemic families of madagascar—I. A synoptic revision of Melanophylla baker (Melanophyllaceae)1998202233242SchatzG. E.LowryP. P.IIWolfA. E.Endemic families of Madagascar—II. A synoptic revision of Sphaerosepalaceae199921107123DucoussoM.BénaG.BourgeoisC.BuyckB.EyssartierG.VinceletteM.RabevohitraR.RandrihasiparaL.DreyfusB.PrinY.The last common ancestor of Sarcolaenaceae and Asian dipterocarp trees was ectomycorrhizal before the India-Madagascar separation, about 88 million years ago20041312312362-s2.0-914421958110.1046/j.1365-294X.2003.02032.x