The genus Lactarius s. str. (Basidiomycota, Russulales) in Togo (West Africa): phylogeny and a new species described

Dao Lamèga Maba; Atsu K Guelly; Nourou S Yorou; André De Kesel; Annemieke Verbeken; Reinhard Agerer

doi:10.5598/imafungus.2014.05.01.05

. 2014 May 8;5(1):39–49. doi: 10.5598/imafungus.2014.05.01.05

The genus Lactarius s. str. (Basidiomycota, Russulales) in Togo (West Africa): phylogeny and a new species described

Dao Lamèga Maba ^1,^2,^✉, Atsu K Guelly ¹, Nourou S Yorou ^2,³, André De Kesel ⁴, Annemieke Verbeken ⁵, Reinhard Agerer ²

PMCID: PMC4107895 PMID: 25083405

Abstract

Lactarius s. str. represents a monophyletic group of about 40 species in tropical Africa, although the delimitation of the genus from Lactifluus is still in progress. Recent molecular phylogenetic and taxonomic revisions have led to numerous changes in names of tropical species formerly referred to Lactarius. To better circumscribe the genus Lactarius in Togo, we combined morphological data with sequence analyses and phylogeny inference of rDNA ITS sequences. Morphological and molecular data were generated from specimens sampled in various native woodlands and riverside forests; Lactarioid- and Russula sequences from public GenBank NCBI, and UNITE are included for phylogenetic analysis. The Maximum likelihood phylogeny tree inferred from aligned sequences supports the phylogenetic position of the studied samples from Togo within the subgenera Piperites, and Plinthogali.

Lactarius s. str. includes about 13 species described from West Africa, of which eight were not previously known from Togo, including one new species: Lactarius subbaliophaeus identifiable by the presence of winged basidiospores, a pallisadic pileipellis with a uprapellis composed of cylindrical cells, inconspicuous pleurocystidia, and fusiform or tortuous, often tapering apex marginal cells. It can also be recognised by a transparent white latex that turns pinkish and then blackish, and a bluish reaction of the flesh context with FeSO₄. These features mentioned do not match any of the morpho-anatomically most similar species, notably L. baliophaeus and L. griseogalus.

Keywords: distribution, ecology, ectomycorrhizas, Lactifluus, molecular phylogeny, Tropical Africa

INTRODUCTION

The diversity of biological organisms in a site can be assessed and quantified only when the underlying species richness has been comprehensively investigated. In the meantime, it has been shown that extensive species inventories of vulnerable ecosystems are urgently needed to monitor these changes in the future (Raxworthy et al. 2008). A combination of morphological and anatomical studies with molecular tools in the assessment of fungal diversity, the delimitation of taxa, and identification of new species, provides fresh possibilities (Nilsson et al. 2006, Begerow et al. 2010). Furthermore, different studies have demonstrated that cryptic species are common throughout the fungi (Wubet et al. 2004, Savolainen et al. 2005), and consequently this requires the use of modern methods (molecular tools) such as those based on the extraction of ribosomal DNA (DNA barcoding) and phylogenetic studies to establish the distinction between taxa, mainly at species level, by highlighting the interspecific as well as the intraspecific variability (Nilsson et al. 2006, Lumbsch & Huhndorf 2007, Begerow et al. 2010). Although anatomical characters are still the only unequivocal systematic and taxonomic characters of value in routine fieldwork and identifications, the use of molecular tools in species inventories and so species biodiversity assessment is inevitable. Reliance on morpho-anatomological characters in the identification process can be problematic due to the plasticity of these characters in some cases (Begerow et al. 2010). Thus, DNA barcoding is currently and commonly used in various domains of biology including mycology, although new fungus species are still described with no molecular information.

Molecular investigations in Russulales have led to the splitting of Lactarius s. lat. into three separate genera, and the newly circumscribed genus Lactarius s. str. is now a distinct monophyletic group, separated from the closely related Multifurca and Lactifluus (Buyck et al. 2008, 2010, Stubbe et al. 2010, Verbeken et al. 2011). Lactarius s. str. represents the largest clade, but has a predominantly temperate distribution; it includes about 80 % of the milkcap species (Verbeken et al. 2011) and encompasses the subgenera Piperites, Russularia, and Plinthogali. Lactifluus, in contrast, has a mainly southern distribution and in Africa makes up about 20 % of the milkcaps, making Lactarius s.str. now a rather limited group in tropical Africa with about 40 species (van Rooij et al. 2003, Verbeken & Walleyn 2010) of which about 13 species are known from the Guineo Sudanian region.

Together with the genera Lactifluus, Russula, Amanita, Tomentella, Cantharellus, Xerocomus, Boletellus, Boletus, Pulveroboletus, Veloporphyrellus, and Tylopilus, the genus Lactarius represents the common dominant ectomycorrhizal (ECM) fungal taxa in tropical African vegetation types (Verbeken & Buyck 2001, De Kesel & Guelly 2007, Rivière et al. 2007, Diédhiou et al. 2010, Bâ et al. 2012, Maba et al. 2013).

In West Africa, Lactarius and Lactifluus species occur predominantly in ceasalpinioid- and phyllantioid-dominated woodlands, savannas, and riverside forests (De Kesel et al. 2002, Ducousso et al. 2002, Maba 2010, Verbeken & Walleyn 2010, Bâ et al. 2012). Nevertheless, numerous ECM root tips formed by species of Lactifluus and Lactarius have been reported from tropical African dense rain forests (Rivière et al. 2007, Diédhiou et al. 2010, Bâ et al. 2012).

For such a small territory (56 600 km²), Togo exhibits not only a high ecosystem diversity, but also one of the highest number of plant species per square km² in comparison to other West African countries (Akpagana 1989). The country harbours many natural caesalpinioid- and ECM-rich forests in the south-western highland region, but also in the central and northern parts (Afidégnon et al. 2002). The Fazao Malfakassa National Park in the central western part of the country at the border with Ghana, and the Aledjo Forest Reserve located in the central part, are two of such ECM-rich forests. Since 2007, numerous mycological collecting trips have been undertaken intensively within both forests. The sampled material comprises many ectomycorrhizal fungal taxa including Lactarius s. str. specimens for which morphological and anatomical descriptions have been prepaeed and compared with known species.

Before this study, five Lactarius s. str. species had been recorded for Togo, L. afroscrobiculatus, L. atro-olivinus, L. miniatescens, L. saponaceus, and L. tenellus (De Kesel & Guelly 2007, Maba 2010, Verbeken & Walleyn 2010). The main goal of this paper is to assess the ITS (ITS1 and ITS2) nucleotide-based phylogenetic affinity of Lactarius s. str. species now known from Togo, combining sequence analyses with maximum likelihood phylogenetic trees and morpho-anatomical diagnoses. This led us to describe L. subbaliophaeus as new species, and also indicates that the Togo Lactarius species match genetically both tropical and temperate species.

MATERIAL AND METHODS

Specimen sampling and loan of material

This study is based mainly on collections sampled from Togo, and sampling and conservation was as described in Maba et al. (2013). For demarcation between the new species presented here and previously described similar species, we examined specimens of the following species Lactarius tenellus (ADK3975, from BR, paratype), L. kabansus (AV99-179, from GENT, paratype) and L. griseogalus (R. Nicholson 179, from K(M), paratype). The anatomy of those three species was studied and and molecular data were obtained from two (L. tenellus, L. kabansus) were made. Colour terminology follows Kornerup & Wanscher (1978).

Microscopy

For microscopic studies we followed the protocol of Verbeken & Walleyn (2010) as applied in Maba et al. (2013), and for SEM micrographs Maba et al. (2013). Preliminary identifications were made using the Lactarius s. lat. monograph based on material collected in similar ecosystems in the neighbouring country Benin (van Rooij et al. 2003). Additionally, we used the monograph of Verbeken & Walleyn (2010) on tropical African Lactarius s.lat.species.

DNA extraction, sequencing, and PCR amplification

Ribosomal DNA (rDNA) was retrieved from our dried samples and specimens ADK3975 and AV99-179 (see above) following the protocol used by Maba et al. (2013). The ITS of the rDNA, comprising ITS1, ITS2 and 5.8S, was amplified using the fungi specific primer ITS1F in combination with the Basidiomycota specific primer ITS4B (Gardes & Bruns 1993). We obtained 19 ITS sequences, Lactarius s. str. (10 sequences), Lactifluus (7), Russula (1), and Termitomyces (1; Fig. 1, Table 1). All the sequences have been deposited in the European Nucleotide Archive (ENA).

Fig. 1. — Best Maximum Likelihood phylogenetic tree showing the placement of *Lactarius* samples from Togo including the newly described species and other species from tropical Africa. Bootstrap values higher than 80 % are shown above the branches. GenBank (UNITE, NCBI and ENA) sequences accession numbers are shown preceding species names and followed by country of origin of selected species. (*) indicates the new species.

Table 1.

List of the newly generated ITS rDNA sequences.

Species	Collection numbers	Country	ENA accession numbers
Lactarius afroscrobiculatus	ADK4599	Togo	HG917377
Lactarius kabansus	MD132	Togo	HG917376
Lactarius kabansus	AV99-179	Zimbabwe	HG917390
Lactarius saponaceus	MD390	Togo	HG917378
Lactarius subbaliophaeus	MD100	Togo	HG917372
Lactarius tenellus	MD149	Togo	HG917373
Lactarius tenellus	ADK397	Kenya	HG917389
Lactarius sp.	MD391	Togo	HG917380
Lactarius miniatescens	MD151	Togo	HG917374
Lactarius aff. miniatescens	MD177	Burkina Fasso	HG917375
Lactifluus edulis	C2168	Togo	HG917384
Lactifluus densiofolius	C2362	Togo	HG917385
Lactifluus longipes	ADK4315	Togo	HG917383
Lactifluus longipes	C2445	Togo	HG917391
Lactifluus foetens	C1822	Togo	HG917382
Lactilfuus foetens	MD150	Togo	HG917381
Lactifluus rubiginosus	MD389	Togo	HG917386
Termitomyces sp.	MD388	Togo	HG917388
Russula congoana	MD129	Togo	HG917387

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Sequence analyses and molecular phylogenetic inference

From the best matches generated by BlastN (Altschul et al. 1997) searches of each of our sequences, the sequences of named species and unidentified ones but close to our sequences were considered and downloaded. In order to obtain relevant sequences to use in a multiple alignment, a BlastN search was performed against the International Nucleotides Sequences Database (INSD; Benson et al. 2008), ENA (http://www.ebi.ac.uk/ena/home), and the UNITE database (Kõljalg et al. 2005, Abarenkov et al. 2010) focusing on tropical Africa sequences for determining the taxonomic affinity of the samples studied and those of closely related species. The consensus sequences were edited and assembled using BioEdit v. 7.2.5 (last update 24 Sept. 2013; Hall 2005). Our ITS sequence dataset comprised 39 in-group taxa (species and genus level) sequences and five out-group sequences. We consider as in-group, the genera Lactarius (24 samples), Lactifluus (12 samples), and Russula (3), which are all Russulaceae, and as out-group, Termitomyces (2 taxa), Agaricus (2), and Hymenagaricus (1; Fig. 1).

The Full Multiple alignment was performed automatically (L-INS-i) using the latest available online version of MAFFT v. 7.130b (Katoh & Toh 2008; update of 27 Sept. 2013), by applying the best accurate option for the alignment. After the online multiple alignment, the resultant sequence dataset was corrected manually by removing ambiguously aligned regions as well as mismatched and empty common columns. Our final sequence dataset was composed of 44 ITS rDNA sequences (including those newly generated and those from GenBank) for a length of 700 bp. The most Maximum Likelihood (ML) bootstrap tree was inferred in MEGA 5.2 (Tamura et al. 2011, update June 2013) by applying the General Time Reversible nucleotide substitution model (GTR + G +I). Gamma Distribution (G) was set as the rates among sites in the Rates and Patterns parameters (Shape parameters = 4). The Subtree-Pruning-Regrafting Extensive (SPR; level 5) with a very strong branch swap filter was applied as the ML heuristic method for Tree Inference Option (TIO). The phylogeny tree was obtained with the bootstrap method of analysis of 1000 replicate trees.

RESULTS

ITS rDNA sequence and phylogenetic analyses

The phylogenetic analysis of all 44 sequences is presented in Fig. 1, four well-supported clades were obtained (Groups I to IV). The first (clade I) was larger and well supported (100 %) clade and constitutes Lactarius s. str (clade I), and included 24 sequences, including 10 of those newly generated (Table 3), notably Lactarius afroscrobiculatus ADK4599 (1 sample), L. tenellus (2), L. kabansus (2), L. miniatescens (1), L. saponaceus (1), Lactarius sp. MD391(1 sample), Lactarius aff. miniatescens MD177 (1), and the specimen MD100 (1). The second (clade II) encompased sequences of Lactifluus. The third (clade III) represented the genus Russula with three species, and the last (clade IV) the out-group with five taxa.

Table 3.

Lactarius species recorded in Togo 2007–2013.

Species	Specimens	Collector/Date	Locality and ecosystem type
Lactarius sp.		Dao Maba	Aledjo woodlands dominated by Isoberlinia tomentosa and Uapaca togoensis, 09°13’6’’ N 01°11.4’38’’ E
	MD391¹	16 July 2013

Lactarius afroscrobiculatus		Andre De Kesel	Fazao, woodland dominated by Isoberlinia doka and Uapaca togoensis and/or Afzelia africana, 08°43.9’6.3” N 0°47.6’7.4” E
	BR 163477-32; 163418-79	16 July 2007
		Atsu Guelly	Aledjo, gallery forest dominated by Uapaca guinensis Isoberlinia doka and Uapaca togoensis, 09°16’34.0” N 01°13’32.4” E
	C2268²	31 May 2008

Lactarius atro-olivinus		Andre De Kesel	Aledjo, gallery forest dominated by Berlinia grandiflora, 09°16’46’’ N 01°12’’41.6’ E
	BR 163674-35	11 July 2007
	BR163490-45	23 May 2008	Ilè Forêt claire à Uapaca togoensis, 07°36’7.4” N 0°51’10.5” E
	ADK4538³; ADK4813; ADK4836	15 May 2010	Ola, gallery forest dominated by Berlinia grandiflora and Uapaca guineensis, 07°33’12.3” N 0°52’37.8” E
		17 May 2010
		Dao Maba	Aledjo, gallery forest dominated by Berlinia grandiflora and Uapaca guineensis, 09°16’45’’ N 01°11’47’’ E
	MD07	9 Sept. 2008

Lactarius kabansus		Dao Maba	Fazao, woodland dominated by Isoberlinia doka and Uapaca togoensis, 08°45’24’’ N 00°48’08’’ E
	MD132	19 June 2011

Lactarius melanogalus		Andre De Kesel	Aledjo, gallery forest dominated by Berlinia grandiflora, 09°16’46’’ N 01°12’41.6’’ E
	ADK4292	11 July 2007

Lactarius miniatescens		Andre De Kesel	Tchamba, Gallery forest dominated by Milletia thonningii, Lonchocarpus sericeus, 08°56.6’9.2 N ‘’ 01°31.9’6.6 E ‘’
	BR 163828-92	13 July 2007
		Dao Maba	Fazao, woodland dominated by Isoberlinia doka and Uapaca togoensis, 08°48’52.35’’ N 0°45’29.2’’ E
	MD09	27 May 2008
	MD151	19 Jun 2011	Fazao, woodland dominated by Isoberlinia doka and Uapaca togoensis, 08°42’21’’ N 00°46’18’’ E
	MD401	18 July 2013	Aledjo, gallery forest dominated by Berlinia grandiflora and Uapaca guineensis, 09°16’28.5’’ N 01°13’21.5’’ E

Lactarius Subbaliophaeus sp. nov.		Dao Maba	Fazao, woodland dominated by Uapaca togoensis and Afzelia africana, 08°42’21’’ N 0°46’22’’ E
	MD100	16 June 2011
		Dao Maba	Aledjo woodlands dominated by Isoberlinia tomentosa and Uapaca togoensis, 09°13’8’’ N 01°11.4’42’’ E
	MD14	26 May 2008

Lactarius saponaceus		Andre De Kesel	Aledjo, woodland dominated by Isoberlinia tomentosa, 09°13.9’8.1’’ N 01°11’44.2’’ E
	BR 158418-17	11 July 2007
		Dao Maba	Aledjo, woodland dominated by Isoberlinia tomentosa, 09°13’27’’ N 01°11’53’’ E
	MD390	18 July 2013

Lactarius tenellus		Andre De Kesel	Fazao, woodland dominated by Uapaca togoensis, 08°43’14.5’’ N 0°46’33.2’’ E
	BR 163798-62	20 July 2007
		Atsu Guelly	Fazao, woodland dominated by Isoberlinia doka and Uapaca togoensis, 08°43’19’’ N 00°46’31’’ E
	C2142	3 June 2008
		Dao Maba	Fazao, woodland dominated by Isoberlinia doka and Uapaca togoensis, 08°45’24’’ N 00°48’08’’ E; 08°42’25’’ N 00°46’24’’ E
	MD149; 126; 159	18–19 June 2011

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¹MD = collection of D. Maba;

²2C= collection of A. Guelly;

³3ADK= collection of A. De Kesel.

The sequences of Lactarius we investigated formed a monophyletic group and were well supported within the larger monophyletic group. In this Lactarius clade, sequences of L. torminosus from Belgium, L. aff. wenquanensis from Thailand, and L. purpureus from Papua New Guinea, all belonging to the subgenus Piperites, are well supported in this genus with tropical Africa taxa sequences included.

Specimen MD100 nested within the Lactarius clade, suggesting it was a member of Lactarius. Morphological and molecular arguments/dissimilarities with the closest species provided below support our decision to describe specimen MD100 as a new species, namely L. subbaliophaeus.

BlastN search suggests the unidentified sequence of Lactarius sp. (UDB013804), Lactarius sp. (UDB016864), and of L. baliophaeus (GU258277), all from Zambia, as closest to that of the newly proposed species, with identity rates of 94 %, 92 %, and 90 % respectively. As the clade containing L. baliophaeus (sect. Nigrescentes), is strongly supported as close to the new species, there is no doubt that L. subbaliophaeus is a member of this section according to our phylogenetic inference results (Fig. 1), and so agreed with its morpho-anatomical affiliation (Table 2). Sequences of the loaned material of L. tenellus and L. kabansus fell into a strongly supported internal clade (99 %) of Lactarius s. str. representing a portion of L. sect. Plinthogali, and support the placement of the sampled specimenss from Togo (100 %). These latter above two species represent Lactarius subg. Plinthogali, sect. Plinthogali.

Table 2.

Summary of the distinctive features of the most similar species, Lactarius baliophaeus, and L. griseogalus, and those of L. subbaliophaeus, using data from Verbeken & Walleyn (2010).

Features	*L. baliopheus*	*L. griseogalus*	*L. subbaliophaeus*
Basidiomata	Pileus 30–70(–90) mm; greyish yellow to brownish (4A3-5 to 4B3-5), dark blond to yellowish brown (5D4-5 to 5E4-5)	Pileus to 36 mm, very dark brown, almost black	Pileus 40–65 mm; greyish brown to beige- brown (5CD3 to 6DE3)
Lamellae and lamellulae	Broadly adnate, to decurrent, crowded L+l = 4+12 to 3+6/cm	Broadly adnate, not decurrent, distant (total 28)	Broadly adnate, to slightly subdecurrent, distant L+l = 4–5/cm
Context	Firm, white to cream then orange-red, greyish red, finally black	Very thin and transparent, turning red then red- orange, finally black	Firm, first whitish becoming blackish finally black
Latex	Water-like, then successively brownish, blood-red, buff, cream	Hyaline turning grey then dark brown	Transparent white, becoming pinkish grey (7A2) then blackish
Reaction of context to FeSO₄	Unchanging	Weakly greyish green	Bluing
Taste	Mild, then acrid	Mild, slightly astringent	Bitter and acrid
Basidiospores	Globose to subglobose	Usually ellipsoid, rarely subglobose	Globose, subglobose rarely ellipsoid
	Q = 1.01–1.07–1.09–1.15	Q = 1.07–1.21–1.36–1.55	Q = 1.04–1.11–1.27
	Plage distally amyloid	Plage not, or slightly amyloid	Plage not amyloid
Cystidia	Pleurocystidia 40–55 × 9–11 μm scarce to abundant, often arising deep in the hymenium, slightly thick-walled	Pleurolamprocystidia 50–65 × 7–10 μm abundant fusiform or irregular, thick-walled	Pleurocystidia 35–56 × 6–9 μm, scarce, inconspicuous subcylindrical, subclavate, thin-walled
Marginal cells	21–40 × (2–)3–5 μm, cylindrical, tortuous or fusiform, rounded, mucronate, with tapering apex	20–35 × 4–7 μm, rarely clavate, mostly fusiform	23–72 × 3–6 μm, subcylindical, fusiform or tortuous, almostly septate, mostly with tapering apex
Pileipellis	Hymeniderm, suprapellis 10–25 × 3–5 μm, thin-walled	Palisade, suprapellis thick, 25–40 × 3–5 μm, thin-walled	Palisade, suprapellis thin 20–60 × 3–5 μm, thin-walled

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TAXONOMY

Lactarius subbaliophaeus Maba & Yorou, sp. nov.

MycoBank MB807658

(Figs 2, 3 and 4)

Fig. 2. — Light microscopy of *Lactarius subbaliophaeus* (MD100). A. Pleuroprocystidia. B. Pileipellis. C. Marginal cells. D. Hymenium. E. Pleuropseudocystidia. F. Spores. Bars = 10 μm.

Fig. 3. — SEM of *Lactarius subbaliophaeus* (MD100). **A–B**. Basidiospores in differents views. C. General view.

Fig. 4. — Basidiome of *Lactarius subbaliophaeus* (MD100). A. General view (shape and spaced lamellae). B. Pileus view. C. Lamellae and exuding latex. Bars = 10 mm.

Etymology: The epithet refers to the morphological and anatomical similarity with L. baliophaeus.

Diagnosis: Pileus locally smooth, mostly veined in the centre, striate at the margin, with greyish brown to beige brown colour. Lamellae are distant, adnate and slightly subdecurrent. Basidiospores winged, pleurocystidia inconspicuous, fusiform or tortuous, often with tapering apex marginal cells, a palisadic pileipellis with suprapellis composed of cylindrical cells, thin-walled. Marginal cells of lamellae subcylindrical, fusiform or tortuous, mostly septate and mostly with tapering apex. Lactarius subbaliophaeus is recognized by the transparent white latex turning first pinkish, then blackish; context with FeSO₄ bluish; taste bitter and acrid.

Type: Togo: Central region: Prefecture of Tchaoudjo, National Park of Fazao-Malfakassa, 08°42’11’’ N 0°46’25’’ E, on soil in gallery forest dominated by Uapaca guineensis and Afzelia africana, 16 June 2011, Dao Maba MD100 (TOGO – holotype; GENT – isotype). GenBank accession no. HG917372.

Description: Pileus 40–65 mm diam, sometimes asymmetric, plano-convex, depressed in the centre, becoming sub-infundibuliform when old; slightly umbonated, dry, matt, locally smooth, veined in the centre, striate at the margin, greyish brown to beige-brown (5CD3 to 6DE3), locally pale at the margin. Margin incurved, edge crenulated, sometimes slightly striate when old. Lamellae spaced or distant, adnate, slightly subdecurrent, unequal, irregular (L+l = 4-5/cm), becoming blackening when injured. Stipe 30–45 × 8–13 mm, rigid, irregular, dry, central, clavate to subclavate at the base, yellowish grey (4B3), becoming darkish when bruised. Context first whitish becoming blackish, thinner at the margin and thick in the centre of pileus. Latex very abundant, transparent white, becoming pinkish grey (7A2) then blackish; taste bitter and acrid, smell not observed. Chemical reaction: context bluing with FeSO₄. Basidiospores globose, subglobose rarely ellipsoid, 8–8.5–9 × 7–7.5–8(–8.5) μm (Q = 1.04–1.11–1.27; n = 75), amyloid ornamentation composed of ridges up to 0.5–1 μm, sometimes more and forming almost a complete reticulum, plage mostly inamyloid. Basidia 4-spored, 20–66 × 11.5–14 μm, clavate, with a granule-like or guttule-like content, sterigmata 4–8–10 × 1–2–3 μm. Pleurocystidia, 35–56 × 6–9 μm, scarce, inconspicuous, subcylindrical to subclavate, rarely projecting, thin-walled. Pleuropseudocytidia 4–5–6 μm diam, abundant, cylindrical, sometimes tortuous, with brown contents. Lamellar edge sterile. Marginal cells of lamellae 23–72 × 3–6 μm, subcylindical, fusiform or tortuous, mostly septate and mostly with tapering apex. Hymenophoral trama composed of a mixture of abundant laticiferous hyphae and sphaerocytes at the base. Pileipellis a palisade, suprapellis composed of dense cylindrical elements of 22–35 × 3–5 μm, thin-walled and with isodiametric cells at the base. Stipitipellis a trichoderm to ixotrichoderm with entangled hyphae at the base and cylindrical elements in the suprapellis. Clamps absent.

Additional specimen examined: Togo: Central region: Prefecture of Assoli, Forest Reserve of Aledjo, 09°13.9’8.1’’ N 01°11.4’42’’ E, inwoodlands dominated by Isoberlinia tomentosa and Uapaca togoensis, 26 May 2008, Dao Maba MD14 (TOGO).

DISCUSSION

Lactarius subbaliophaeus differs from L. baliophaeus and L. griseogalus in the greyish brown to beige-brown pileus and distant, adnate, slightly subdecurrent lamellae. Microscopically, it has inconspicuous pleurocystidia that are fusiform or tortuous, often tapering at the apex; a palisadic pileipellis with a suprapellis composed of cylindrical cells. The marginal cells of the lamellae are subcylindical, fusiform or tortuous, mostly septate, and with a tapering apex. It is easily identifiable by the transparent white latex that turns first pinkish and then blackish, a bluish reaction of the flesh context to FeSO₄; and a bitter and acrid taste (Table 2).

Considering the morphological and anatomical features summarized in Table 2, it is clear that L. subbaliophaeus differs most from L. griseogalus and is closest to L. baliophaeus, but differs from the latter.

Detailed analyses of the ITS rDNA sequences revealed that L. subbaliophaeus deviates from L. baliophaeus by 12 % (sequence length 700 bp). Sequences of both species fall within two different terminal clades, each well supported by a bootstrap of 100 % and 99 %, respectively. The sequence of L. baliophaeus clusters as sister species with the sequences of two unidentified collections from Zambia (Lactarius sp., UDB013899) and from Cameroon (Lactarius sp UDB013969), whilst the sequence of L. subbaliophaeus forms a terminal sister clade together with two samples from Zambia (UDB0130804, UDB016864). Lactarius subbaliophaeus and L. baliophaeus belong both to Lactarius sect. Nigrescentes (Fig. 1), what is corroborated by morpho-anatomical features (see Table 1).

With respect to other species found in Togo (Table 3), the sequence of L. afroscrobiculatus of Lactarius subg. Piperites is sister to the clade that includes the Togoan species, L. torminosus, L. aff. wenquanensis, and L. purpureus. This tropical species is known for its typical morphological characters (sticky cap and scrobiculate stipe) and relate it to the temperate species of Lactarius subgen. Piperites (Heilmann-Clausen et al. 1998, Verbeken & Walleyn 2010). Another unidentified sample from Togo (Lactarius sp., MD391) clusters with species of L. subgen. Piperites with an 87 % of bootstrap value. As Lactarius subgen. Piperites has additional representative species (L. barbatus and L. acrissimus) in tropical Africa, it is likely that Lactarius sp. MD391 constitutes an additional member within this group. Morpho-antomical studies of this collection are still required.

The remaining taxa studied (L. tenellus, L. kabansus, L. miniatescens, and L. saponaceus from Togo and L. angiocarpus from Zambia) are well supported as members of L. sect. Plinthogali, revealing L. sect. Plinthogali as polyphyletic (Fig. 1), as L. saponaceus, L. angiocarpus, and L. miniatescens form a clade sister to L. sect. Nigrescentes, whereas L. kabansus and L. tenellus belong to a different clade with 100 % bootstrap support (Fig. 1, Sect. Plinthogali 1 and 2).

Contrary to L. sect. Plinthogali with more taxa found in Togo from L. sect. Nigrescentes, only two well characterized species have been found. This section appears actually monophyletic, but morpholo-anatomical studies on the more closely related samples are in this section needed. Generally, additional sequences of particularly these two sections as well as from other species are necessary for a better understanding of the phylogenetic tendency/relationship between species of tropical African Lactarius s. str. species. Nevertheless, our study reconfirms the monophyly of Lactarius s. str. as elegantly demonstrated by Buyck et al. (2008, 2010).

Ecologically, species including Lactarius atro-olivinus, L. afroscrobiculatus, and L. miniatescens have no apparent preference for a special vegetation type, as they were sampled from savanna woodlands as well as gallery forests (Table 3). Moreover, whether in a gallery or savanna, L. afroscrobiculatus was collected in habitats that harbour Uapaca species and Isoberlinia doka; L. atro-olivinus occurs often in the presence of Berlinia grandiflora and Uapaca guineensis; and L.miniatescens with Uapaca species. In contrast, L. tenellus is almost always sampled from savanna woodlands that harbour U. togoensis and I. doka as native ectomycorrhizal trees, with a tendency to prefer U. togoensis. Lactarius saponaceus seems to preferably occur in presence of I. tomentosa. Lactarius kabansus is widely distributed in the Congo-Zambezian domain and constitutes the first record from the Guineo-Sudanian domain, and was sampled from savanna woodlands dominated by I. doka and U. togoensis. Lactarius subbaliophaeus was sampled twice in savanna woodlands dominated by U. togoensis, and I. tomentosa or Afzelia africana. Future investigations will reveal more details regarding their distribution and ecological preferences.

During several consecutive collection trips, Lactarius s. str. appeared to be relatively poorly represented in Togo as compared with Lactifluus (Maba et al. 2013), both genera being collected in the same habitats. Lactarius s. str. was represented by eight taxa with six known at species level, and two still unidentified. Of the seven sections including Chromospermi, Piperites, Amari, Russularia, Nigrescentes, Plinthogali, and Pseudofuliginosi reported for tropical Africa, four are represented in the vegetation types of Togo (Piperites, Nigrescentes, Plinthogali, and Pseudofuliginosi). However, considering that 75 % of the species of Lactarius harvested in West Africa are found in the ecosystems of Togo, and mainly as not all parts of the vegetation types have been investigated, it can be expected that additional new species are still to be collected and described.

Acknowledgments

We are much indebted to the International Foundation for Sciences (IFS, grant D/5178-1), the German Academic Exchange Service (DAAD, grant A/11/72562) and the German Research Foundation (DFG GZ-Yo174/2-1) for financial support.

REFERENCES

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Katoh K, Toh H. (2008) Recent developments in the MAFFT multiple sequence alignment program. Brief Bioinform 9: 286-298. doi: 10.1093/bib/bbn013. [DOI] [PubMed] [Google Scholar]
Kõljalg U, Larsson K-H, Aberenkov K, Nilson RH, Alexander IJ, Eberhardt U, Erland S, Høiland K, Kjøller R, Larsson E, Pennanen T, Sen R, Taylor AFS, Tedersoo L, Vrålstad T, Ursing BM. (2005) UNITE: A database providing web-based methods for the molecular identification of ectomycorrhizal fungi. New Phytologist 166: 1063–1078 [DOI] [PubMed] [Google Scholar]
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Maba DL. (2010) Le genre Lactarius de la Réserve de Faune d’Aledjo. [Mémoire de DEA Biologie de Développement, option Mycologie.] Lomé: Université de Lomé; [Google Scholar]
Nilsson RH, Ryberg M, Kristiansson E, Abarenkov K, Larsson K-H, Kõljalg U. (2006) Taxonomic Reliability of DNA Sequences in Public Sequence Databases: A Fungal Perspective. PLoS ONE 1(1): e59. doi:10.1371/journal.pone.0000059. [DOI] [PMC free article] [PubMed] [Google Scholar]
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Rivière T, Diédhiou AG, Diabate M, Senthilarasu G, Hatarajan K, Verbeken A, Buyck B, Dreyfus B, Bena G, Bâ AM. (2007) Genetic diversity of ectomycorrhizal Basidiomycetes from African and Indian tropical rain forests. Mycorrhiza 17: 415–428 [DOI] [PubMed] [Google Scholar]
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Stubbe D, Nuytinck J, Verbeken A. (2010) Critical assessment of the Lactarius gerardii species.complex (Russulales). Fungal Biology 114: 271–283 [DOI] [PubMed] [Google Scholar]
Tamura K, Peterson D, Peterson N, Stecher G, Nei M, Kumar S. (2011) MEGA5: Molecular Evolutionary Genetics Analysis using Maximum Likelihood, Evolutionary Distance, and Maximum Parsimony Methods. Molecular Biology and Evolution 28: 2731–2739 [DOI] [PMC free article] [PubMed] [Google Scholar]
van Rooij P, De Kesel A, Verbeken A. (2003) Studies in tropical African Lactarius species (Russulales, Basidiomycota) 11. Records from Benin. Nova Hedwigia 77: 221–251 [Google Scholar]
Verbeken A, Nuytinck J, Buyck B. (2011) New combinations in Lactifluus. 1. Lactifluus subgenera Edules, Lactariopsis, and Russulopsis. Mycotaxon 118: 447–453 [Google Scholar]
Verbeken A, Walleyn R. (2010) Monograph of Lactarius in Tropical Africa. Fungus Flora of Tropical Africa, vol. 2 Brussels: National Botanic Garden of Belgium; [Google Scholar]
Verbeken A, Buyck B. (2001) Diversity and ecology of tropical ectomycorrhizal fungi in Africa. In Tropical Mycology (Watling R, Frankland JC, Ainsworth AM, Isaac S, Robinson C, eds) 1: 11–24 Wallingford: CABI Publishing; [Google Scholar]
Wubet T, Weiß M, Kottke I, Teketay D, Oberwinkler F. (2004) Molecular diversity of arbuscular mycorrhizal fungi in Prunus africana, an endangered medicinal tree species in dry afromontane forests of Ethiopia. New Phytologist 161: 517–528 [DOI] [PubMed] [Google Scholar]

[R1] Abarenkov K, Nilson R, Larsson K-H, Alexander IJ, Eberhard U, Erland S, Høiland K, Kjøller R, Larsson E, Pennanen T, Sen R, Taylor AFS, Tedersoo L, Vrålstad T, Ursing BM, Liimatainen K, Peintner U, Kõljalg U. (2010) The UNITE database for molecular identification of fungi-recent updates and future perspectives. New Phytologist 186: 281–285 [DOI] [PubMed] [Google Scholar]

[R2] Afidégnon A, Carayon J-L, Fromard F. (2002) Carte de Végétation du Togo. Paris: Laboratoire de Botanique et Ecologie Végétale; [Google Scholar]

[R3] Altschul SF, Madden TL, Schäffer AA, Zhang J, Zhang Z, Miller W, Webb DJ. (1997) Gapped BLAST and PSI BLAST: a new generation in protein database search programs. Nucleic Acids Research 25: 3389–3402 [DOI] [PMC free article] [PubMed] [Google Scholar]

[R4] Akpagana K. (1989) Recherches sur les forêts denses humides du Togo. Thèse de Doctorat Université Bordeaux III; [Google Scholar]

[R5] Bâ AM, Duponnois R, Moyersoen B, Abdala G, Diédhiou AG. (2012) Ectomycorrhizal symbiosis of tropical African trees. Mycorrhiza 22: 1–29 [DOI] [PubMed] [Google Scholar]

[R6] Begerow D, Nilsson RH, Unterseher M, Maier W. (2010) Current state and perspectives of fungal DNA barcoding and rapid identification procedures. Applied Microbiology and Biotechnology 87: 99–108 [DOI] [PubMed] [Google Scholar]

[R7] Benson DA, Karsch-Mizrachi I, Lipman DJ, Ostell J, Wheeler DL. (2008) GenBanks. Nucleic Acids Research 36: 25–30 [DOI] [PMC free article] [PubMed] [Google Scholar]

[R8] Buyck B, Hofstetter V, Verbeken A, Walleyn R. (2010) Proposal to conserve Lactarius nom. cons. (Basidiomycota) with a conserved type. Taxon 59: 295–296 [Google Scholar]

[R9] Buyck B, Hofstetter V, Eberhardt U, Verbeken A, Kauff F. (2008) Walking the thin line between Russula and lactarius: the dilemma of Russula subsect. Ochricompactae. Fungal Diversity 28: 15–40 [Google Scholar]

[R10] De Kesel A, Guelly KA. (2007) Les Champignons de la chaine de l’Atakora. Rapport de Séminaire de formation. Bruxelles: Jardin Botanique National de Belgique; [Google Scholar]

[R11] De Kesel A, Codjia JTC, Yorou SN. (2002) Guide des Champignons Comestibles du Bénin. Bruxelles: Jardin Botanique National de Belgique; [Google Scholar]

[R12] Diédhiou AG, Selossé MA, Galvana A, Diabaté M, Dreyfus B, Bâ AM, Miana S, Béna G. (2010) Multi-host ectomycorrhizal fungi are predominant in a Guinean tropical rainforest and shared between canopy rees and seedlings. Environmental Microbiology 12: 2219–2232 [DOI] [PubMed] [Google Scholar]

[R13] Ducousso M, Bâ AM, Thoen D. (2002) Les champignons ectomycorhiziens des forêts naturelles et des plantations d’Afrique de l’Ouest: une source de champignons comestibles. Bois et Forêts des Tropiques 13: 51–63 [Google Scholar]

[R14] Gardes M, Bruns TD. (1993) ITS primers with enhanced specificity for basidiomycetes application to the identification of mycorrhizes and rusts. Molecular Ecology 2: 113–118 [DOI] [PubMed] [Google Scholar]

[R15] Hall T. (2005) BioEdit Version 7.2.5 Biological sequence alignment editor for Win95/98/NT/2K/XP Carlsbad, CA: Ibis Biosciences; [Google Scholar]

[R16] Heilmann-Clausen J, Verbeken A, Vesterholt J. (1998) The Genus Lactarius. [Fungi of Northern Europe vol. 2.] Copenhagen: Svampetryk; [Google Scholar]

[R17] Katoh K, Toh H. (2008) Recent developments in the MAFFT multiple sequence alignment program. Brief Bioinform 9: 286-298. doi: 10.1093/bib/bbn013. [DOI] [PubMed] [Google Scholar]

[R18] Kõljalg U, Larsson K-H, Aberenkov K, Nilson RH, Alexander IJ, Eberhardt U, Erland S, Høiland K, Kjøller R, Larsson E, Pennanen T, Sen R, Taylor AFS, Tedersoo L, Vrålstad T, Ursing BM. (2005) UNITE: A database providing web-based methods for the molecular identification of ectomycorrhizal fungi. New Phytologist 166: 1063–1078 [DOI] [PubMed] [Google Scholar]

[R19] Kornerup A, Wanscher JH. (1978) Methuen Handbook of Colour. London: Methuen; [Google Scholar]

[R20] Lumbsch HT, Huhndorf SM. (2007) Whatever happened to the pyrenomycetes and loculoascomycetes? Mycological Research 111: 1064–1074 [DOI] [PubMed] [Google Scholar]

[R21] Maba DL, Guelly AK, Yorou NS, Verbeken A, Agerer R. (2013) Two new Lactifluus species (Basidiomycota, Russulales) from Fazao Malfakassa National Park (Togo, West Africa). Mycological Progress doi: 10.1007/s11557-013-0932-4. [Google Scholar]

[R22] Maba DL. (2010) Le genre Lactarius de la Réserve de Faune d’Aledjo. [Mémoire de DEA Biologie de Développement, option Mycologie.] Lomé: Université de Lomé; [Google Scholar]

[R23] Nilsson RH, Ryberg M, Kristiansson E, Abarenkov K, Larsson K-H, Kõljalg U. (2006) Taxonomic Reliability of DNA Sequences in Public Sequence Databases: A Fungal Perspective. PLoS ONE 1(1): e59. doi:10.1371/journal.pone.0000059. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R24] Raxworthy CJ, Pearson RG, Rabibisoa N, Rakotondrazafy AM, Ramanamanjato JB, Raselimanana AP, Wu S, Nussbaum RA, Stone DA. (2008) Extinction vulnerability of tropical montane endemism from warming and upslope displacement: a preliminary appraisal for the highest massif in Madagascar. Global Change Biology 14: 1703–1720 [Google Scholar]

[R25] Rivière T, Diédhiou AG, Diabate M, Senthilarasu G, Hatarajan K, Verbeken A, Buyck B, Dreyfus B, Bena G, Bâ AM. (2007) Genetic diversity of ectomycorrhizal Basidiomycetes from African and Indian tropical rain forests. Mycorrhiza 17: 415–428 [DOI] [PubMed] [Google Scholar]

[R26] Savolainen V, Cowan RB, Vogler AP, Roderick GK, Lane R. (2005) Towards writing the encyclopaedia of life: an introduction to DNA barcoding. Philosophical Transactions of the Royal Society of London, Biological Sciences 360: 1805–1811 [DOI] [PMC free article] [PubMed] [Google Scholar]

[R27] Stubbe D, Nuytinck J, Verbeken A. (2010) Critical assessment of the Lactarius gerardii species.complex (Russulales). Fungal Biology 114: 271–283 [DOI] [PubMed] [Google Scholar]

[R28] Tamura K, Peterson D, Peterson N, Stecher G, Nei M, Kumar S. (2011) MEGA5: Molecular Evolutionary Genetics Analysis using Maximum Likelihood, Evolutionary Distance, and Maximum Parsimony Methods. Molecular Biology and Evolution 28: 2731–2739 [DOI] [PMC free article] [PubMed] [Google Scholar]

[R29] van Rooij P, De Kesel A, Verbeken A. (2003) Studies in tropical African Lactarius species (Russulales, Basidiomycota) 11. Records from Benin. Nova Hedwigia 77: 221–251 [Google Scholar]

[R30] Verbeken A, Nuytinck J, Buyck B. (2011) New combinations in Lactifluus. 1. Lactifluus subgenera Edules, Lactariopsis, and Russulopsis. Mycotaxon 118: 447–453 [Google Scholar]

[R31] Verbeken A, Walleyn R. (2010) Monograph of Lactarius in Tropical Africa. Fungus Flora of Tropical Africa, vol. 2 Brussels: National Botanic Garden of Belgium; [Google Scholar]

[R32] Verbeken A, Buyck B. (2001) Diversity and ecology of tropical ectomycorrhizal fungi in Africa. In Tropical Mycology (Watling R, Frankland JC, Ainsworth AM, Isaac S, Robinson C, eds) 1: 11–24 Wallingford: CABI Publishing; [Google Scholar]

[R33] Wubet T, Weiß M, Kottke I, Teketay D, Oberwinkler F. (2004) Molecular diversity of arbuscular mycorrhizal fungi in Prunus africana, an endangered medicinal tree species in dry afromontane forests of Ethiopia. New Phytologist 161: 517–528 [DOI] [PubMed] [Google Scholar]

PERMALINK

The genus Lactarius s. str. (Basidiomycota, Russulales) in Togo (West Africa): phylogeny and a new species described

Dao Lamèga Maba

Atsu K Guelly

Nourou S Yorou

André De Kesel

Annemieke Verbeken

Reinhard Agerer

Abstract

INTRODUCTION