The ascomata and mycorrhizae of
Tuber indicum
s.l.
were collected under the forest of broad-leaf species
Populus yunnanensis
and
Quercus pannosa
in the field respectively. The symbiotic relationships of both trees with
T. indicum
were examined and affirmed based on morphology and ITS-rDNA sequences. These two mycorrhizal combinations were successfully produced on artificially controlled substrates and cultural condition. This is the first report of a mycorrhizal association and synthesis between Chinese black truffles and poplars. A hyphal net covering the mantle’s surface of the mycorrhizae was detected in both mycorrhizal combinations. The mycorrhizal colonization of
P. yunnanensis
and
Q. pannosa
suggests that
T. indicum
s.l.
has a broader host range and that additional corresponding wood species would be used as candidates for the cultivation of
T. indicum
. The nuclear-ITS sequences of the mycorrhizae included in the phylogeny of the
T. indicum
complex revealed that the two clades within the complex do not markedly differ with respect to their preferences for host species or geographical origin. Our results help to explain the wide distribution of both clades of the
T. indicum
complex. It would be more important for truffle conservation and Chinese black truffle plantation development with these two dominated & alpestrine
Populus yunnanensis
and
Quercus pannosa
at subalpine limestone areas in China.
The Asian black truffle, Tuber indicum s.l., comprises a species complex that includes T. indicum Cooke & Massee, T. himalayense B. C. Zhang & Minter and T. sinense K. Tao & B. Liu and is commercially important both in China and Europe as a result of its introduction to Europe in the 1990s. This commercial importance has motivated a series of studies on the taxonomy and phylogeny of this complex. Because these fungi are ectomy- corrhizal, investigations into the symbiotic relationships of the T. indicum complex with trees are of practical and scientific importance. Several tree species are thought to be natural hosts: Quercus incana Roxb. for T. himalayense in Himalayan India [1] and Pinus armandii Franch. and Pi. yunnanensis Franch. for T. sinense in southwestern China [2] [3] . In a previous study that tested the ability of T. indicum s.l. taxa to form mycorrhizae on artificially controlled substrates, eight Chinese trees in the genera Quercus, Cyclobalanopsis, Carpinus, Pinus and Castanea were successfully inoculated with T. indicum s.l. [4] -[7] . Successful mycorrhizal synthesis was also observed for T. indicum s.l. and the North America trees P. taeda L. and Carya illinoinensis (Wangenh.) K. Koch [8] and the European trees Q. pubescens Willd., Q. cerris L., Q. ilex L., Corylus avellana L. and Pi. pinea L. [10] -[13] .
Almost two decades of inappropriate collection and excessive commercialization have seriously threatened the natural sources of T. indicum s.l. in southwestern China [14] . To protect T. indicum s.l. while also meeting the market demand, Chinese mycologists are attempting to establish truffle plantations by producing truffle-col- onized seedlings. Plantations of Cy. glauca colonized with T. formosanum, a species closely related to T. indicum s.l. [15] , were reported to yield truffles eight years after transplantation [16] . The successful cultivation of T. formosanum implies that T. indicum s.l. plantations are feasible. The truffle plantation of Pinus armandii Franch. & Castanea mollissima Blume infected with T. indicum respectively was set up in the spring of 2008, and begin to produce truffle fruit bodies fourth years after transplantation
(http://www.cas.cn/ky/kyjz/201212/t20121220_3725060.shtml). To achieve the goal of establishing such planta- tions, the first step is to determine which trees can be used as its hosts, an analysis that necessitates a reliable field record of the symbiotic relationships between T. indicum s.l. and tree species. However, in China, most of the reports on the host trees of T. indicum s.l. have been based on natural habitats, not on mycorrhizae collection and observation. The morphological details of mycorrhizae are also necessary to determine the quality of T. indicum s.l.-inoculated seedlings. Up to now, only the mycorrhizae of T. indicum s.l. on Castanea mollissima BL. and P. armandii have been described in China [5] . The widespread distribution of T. indicum s.l. in southwest- tern China indicates that there are likely undiscovered mycorrhizal relationships. One objective of this work was to identify new natural hosts of T. indicum s.l. and to provide detailed descriptions of their mycorrhizae, and then to synthesis truffle mycorrhizae based on the results for the truffle conservation and plantation.
In recent years, phylogenetic studies have found that there are two phylogenetic clades within T. indicum s.l. [2] [9] [15] [17] -[23] . To explain this phylogenetic diversification, previous studies investigated the geographi- cal and biological characteristics of the two clades. Using ITS-RFLP analysis, Paolocci et al. [20] suggested that geographical origin could contribute to the inter-clade variability. This hypothesis was supported by the study of Wang et al. [22] . However, after analyzing the origins, Zhang et al. [23] failed to find any correlation between phylogenetic relationships and either host or geographical origin. Chen et al. [15] obtained similar results, ex- cept that they found that T. formosanum, a small subclade within one of the two major clades in T. indicum s.l., should be treated as a separate species based on its exclusive association with Cy. glauca, its geographic distri- bution and its different morphology. Because all of the research was based on ascomata collected from markets or herbaria, the question about host preference or/and geographical contribution was unresolved. The objective of this work was to determine if there are differences in host preference or/and geographical range between dif- ferent phylogenetic clades in the species complex of T. indicum by comparing the sequences of T. indicum s.l. mycorrhizae and ascomata collected in situ and look for new host trees.
2. Materials and Methods2.1. Sample Collections
After collecting ascomata of T. indicum s.l. (the locations are listed in Table 1), the soil beneath the ascomata was removed until the mycorrhizae was visible. Approximately 30 mycorrhizal tips with soil were collected and stored in an ice box. All samples were transported to the laboratory within one week. The soil samples contain-
Information of samples for ITS sequences used in molecular analysis
Species name
Genbank No.
Source
Host
Locality
T. indicum s.l.
JQ638967
Natural mycorrhizae
Po. yunnanensis
Kunming, Yunnan
T. indicum s.l.
JQ638968
Natural mycorrhizae
Po. yunnanensis
Kunming, Yunnan
T. indicum s.l.
JQ638963
Natural mycorrhizae
Pi. armandii
Kunming, Yunnan
T. indicum s.l.
JQ638964
Natural mycorrhizae
Pi. armandii
Huize, Yunnan
T. indicum s.l.
JQ638965
Natural mycorrhizae
Pi. armandii
Huize, Yunnan
T. indicum s.l.
JQ638966
Natural mycorrhizae
Pi. armandii
Huize, Yunnan
T. indicum s.l.
JQ638971
Natural mycorrhizae
Pi. armandii
Dali, Yunnan
T. indicum s.l.
JQ638973
Natural mycorrhizae
Pi. armandii
Panzhihua, Sichuan
T. indicum s.l.
JQ638974
Natural mycorrhizae
Pi. armandii
Panzhihua, Sichuan
T. indicum s.l.
JQ638962
Natural mycorrhizae
Pi. yunnanensis
Kunming, Yunnan
T. indicum s.l.
JQ638969
Natural mycorrhizae
Pi. yunnanensis
Kunming, Yunnan
T. indicum s.l.
JQ638970
Natural mycorrhizae
Pi. yunnanensis
Kunming, Yunnan
T. indicum s.l.
JQ638972
Natural mycorrhizae
Ca. mollissima
Chuxiong, Yunnan
T. indicum s.l.
JQ638975
Natural mycorrhizae
Q. pannosa
Gongshan, Yunnan
T. indicum s.l.
JQ638976
Natural mycorrhizae
Q. pannosa
Gongshan, Yunnan
T. indicum s.l.
JQ638977
Synthesized mycorrhizae
Pi. armandii
T. indicum s.l.
JQ638978
Synthesized mycorrhizae
Pi. armandii
T. indicum s.l.
JQ638979
Synthesized mycorrhizae
Pi. armandii
T. indicum s.l.
JQ638980
Synthesized mycorrhizae
Pi. armandii
T. indicum s.l.
JQ638981
Synthesized mycorrhizae
Pi. armandii
T. indicum s.l.
JQ638953
Synthesized mycorrhizae
Ca. mollissima
T. indicum s.l.
JQ638954
Synthesized mycorrhizae
Ca. mollissima
T. indicum s.l.
JQ638956
Synthesized mycorrhizae
Ca. mollissima
T. indicum s.l.
JQ638957
Synthesized mycorrhizae
Ca. mollissima
T. indicum s.l.
JQ638955
Synthesized mycorrhizae
Ca. mollissima
T. indicum s.l.
JQ638959
Synthesized mycorrhizae
Ca. mollissima
T. indicum s.l.
JQ638984
Ascomata
Kunming, Yunnan
T. indicum s.l.
JQ638985
Ascomata
Kunming, Yunnan
T. indicum s.l.
JQ638986
Ascomata
Kunming, Yunnan
T. indicum s.l.
JQ638987
Ascomata
Kunming, Yunnan
T. indicum s.l.
JQ638988
Ascomata
Kunming, Yunnan
T. indicum s.l.
JQ638989
Ascomata
Kunming, Yunnan
T. indicum s.l.
JQ638990
Ascomata
Huize, Yunnan
T. indicum s.l.
JQ638991
Ascomata
Huize, Yunnan
T. indicum s.l.
JQ638992
Ascomata
Huize, Yunnan
T. indicum s.l.
JQ638993
Ascomata
Huize, Yunnan
T. indicum s.l.
JQ638994
Ascomata
Chuxiong, Yunnan
T. indicum s.l.
JQ638995
Ascomata
Dali, Yunnan
T. indicum s.l.
JQ638996
Ascomata
Dali, Yunnan
T. indicum s.l.
JQ638997
Ascomata
Gongshan, Yunnan
T. indicum s.l.
JQ638998
Ascomata
Gongshan, Yunnan
T. indicum s.l.
JQ638999
Ascomata
Gongshan, Yunnan
T. indicum s.l.
JQ639000
Ascomata
Gongshan, Yunnan
T. indicum s.l.
JQ639001
Ascomata
Gongshan, Yunnan
T. indicum s.l.
JQ639002
Ascomata
Gongshan, Yunnan
T. indicum s.l.
JQ639003
Ascomata
Gongshan, Yunnan
T. indicum s.l.
JQ639004
Ascomata
Panzhihua, Sichuan
T. indicum s.l.
JQ639005
Ascomata
Panzhihua, Sichuan
T. indicum s.l.
JQ639007
Ascomata
Panzhihua, Sichuan
T. pseudexcavatum
JQ639006
Ascomata
Panzhihua, Sichuan
T. pseudexcavatum
JQ638958
Ascomata
Panzhihua, Sichuan
T. pseudexcavatum
JQ638982
Ascomata
Kunming, Yunnan
T. pseudexcavatum
JQ638983
Ascomata
Kunming, Yunnan
T. melanosporum
JQ638960
Ascomata
Italy
T. melanosporum
JQ638961
Ascomata
Italy
T. melanosporum
JQ639008
Ascomata
Italy
T. melanosporum
JQ639009
Ascomata
Italy
ing the mycorrhizae were placed in large dishes and soaked in water until the soil debris could be removed from mycorrhizae with needles. After being cleaned, the freshly isolated mycorrhizae were ready for morphological observation and DNA extraction. The host trees of the mycorrhizal samples used in this study is listed in Table 1.
2.2. Morphological Study
The macroscopic and microscopic characters of mycorrhizae were described and illustrated based on the de- scriptions of natural mycorrhizae by Agerer [24] . The mycorrhizae were photographed under a Nikon SMZ1500 stereoscope. Cross- and longitudinal sections of the mycorrhizae were prepared with a Leica CM1100 freezing microtome. The mantle layers and the anatomical structures of the hyphae were sectioned by hands. All ana- tomical sections were observed under a Nikon Eclipse E400 microscope and photographed with a Nikon E4500 camera.
2.3. DNA Extraction, PCR Amplification and Sequencing
DNA was extracted from ascomata or 6 - 10 mycorrhizal tips using the CTAB method (Doyle, 1987 [25] ) with the minor modification of adding 200 µL of 5 M potassium acetate after the treatment with 4 × CTAB. The ITS5 primers [26] and ITS4LNG [27] were used to amplify the ITS region from the ascomata or mycorrhizal samples to confirm the identities of the fungi in the mycorrhizae using blast (http://blast.ncbi.nlm.nih.gov/Blast.cgi). The final amplification reactions (25 µL) contained 10 mM Tris-HCl (pH 9.0), 50 mM KCl, 1 mM MgCl2, 100 µM of each dNTP, 0.2 µM of each primer, 1.5 U of Taq Polymerase (Takara Taq, Takara Biotechnology, Dalian Co. Ltd., China), 0.2 µL of BSA (1%) and 50 ng of DNA template. The cycling parameters were an initial denatura- tion at 95˚C for 5 min; 35 cycles of denaturation at 94˚C for 1 min, annealing at 52˚C for 45 s and extension at 72˚C for 45 s; and a final extension at 72˚C for 10 min. The amplification products were electrophoresed on a 1.2% agarose gel. Sequencing was performed with an ABI Prism BigDye terminator cycle sequencing kit v3.1 and an ABI PRISM 3730 automatic sequencer.
2.4. Data Analysis
ITS sequences were edited with SeqMan (DNASTAR Package). Alignments were performed with Clustal X Version 1.81 [28] and adjusted manually with BioEdit Version 5.0.9 [29] . Maximum parsimony analysis was conducted with Paup* 4.0b 10 [30] using a heuristic search and tree bisection reconnection (TBR) branch swap- ping with 1000 search replicates; a random sequence was added to each replicate. Gaps were treated as missing data. Character states were treated as equally weighted and unordered. Four ITS sequences of T. pseudoexca- vatum G. Moreno et al. were used as the outgroup. To indicate the phylogenetic diversity within the T. indi- cum complex, 4 ITS sequences of the sibling species T. melanosporum Vittad. were included in the phylogenic analysis.
2.5. Mycorrhizal Synthesis
The fully mature ascocarps of T. indicum used in mycorrhizal synthesis were commercially acquired from a wild edible fungous market in Kunming, Yunnan, China, and the origins were unknown. Seeds of Q. pannosa pro- vided by the Kunming Botanical Garden were used to produce seedlings following the method in [5] . The Po. yunnanensis seedlings were propagated by the traditional cutting & layering method. The methods for the pro- duction of T. indicum s.l. mycorrhizae on host trees and the examination of mycorrhizae followed the protocols in [5] .
3. Results3.1. Morphological Characters of Mycorrhizae
Mycorrhizal system unramified to monopodial-pinnate, with 1 - 2 orders of ramification, brown to light brown in color; short-distance exploration type (Figure 1(a)). Main axes 1 - 3.5 mm long, 0.7 - 1.5 mm in di-
Mycorrhizae formed by T. indicum s.l. on Po. yunnanensis. (a) Natural mycorrhizae (bar = 200 µm); (b) Synthesized mycorrhizae (bar = 2000 µm); (c) Cross-section of mantle (bar = 10 µm); (d). Longitudinal section of mantle (bar = 10 µm); (e) Outer mantle layer (bar = 10 µm); (f) Inner mantle layer (bar = 10 µm); (g) Hyphal net on mantle (bar = 10 µm); (h)-(i) Emanating hyphae (bar = 10 µm)
ameter, straight or slightly bent. Unramified ends 0.5 - 3 mm long, 0.5 - 0.8 mm in diameter, straight, cylindrical or slightly tapering, apex round, tips usually lighter than the other parts (Figure 1(b)). Surface smooth or woolly with whitish emanating hyphae; emanating hyphae distinct, numerous, and distributed unequally.
Cross-section of mantle 15 - 25 µm thick, pseudoparenchymatous composed of 4 - 6 layers with elliptical to hyphal cells 3 - 13 × 2 - 8 µm, walls thin or slightly thick, light brown, slightly discernible with different layers (Figure 1(c)). Longitudinal section of mantle 18 - 25 µm thick, pseudoparenchymatous composed of 5 - 7 layers of elliptical to hyphal cells 4 - 20 × 2 - 8 µm, walls thin or slightly thick, light brown, subglobose to elliptic, slightly discernible with different layers (Figure 1(d)). The tip in transverse sections same as in other parts but with smaller cells. Hartig net reaches the 1 - 2 layers of cortex cells, composed of 1 - 2 layers of hyphal cells, colorless, subglobose, 1 - 3 µm in diameter.
Mantle in plan views is covered by a hyphal network, especially in regions of growth (Figure 1(g)). The sur- face net 1 - 2 layers, formed by anastomosed and irregularly connected hyphae, 3 - 5 µm in diameter, 5 - 12 µm between septa, cell walls thin to slightly thick, smooth, colorless to yellowish brown. Outer mantle layers pseu- doparenchymatous epidermoid with irregularly polygonal and sinuous cells interlocked in a puzzle-like pattern, cells 8 - 25 × 4 - 10 µm, 6 - 8 cells in a square of 20 × 20 µm, thick walled, with yellowish brown walls, 1 - 2 µm thick, not gelatinous (Figure 1(e)). Inner mantle layers pseudoparenchymatous or a transitional type between plectenchymatous and pseudoparenchymatous, cells 7 - 18 × 3 - 10 µm, 6 - 9 cells in a square of 20 × 20 µm, thin walled or slightly thick walled (Figure 1(f)). Mantle structures of the very tips same as in other parts of the mycorrhizae but with smaller cells.
Emanating hyphae growing from hyphal net, loosely woolly, yellowish brown to blackish brown, cylindrical, tips rounded or tapering, thin walled, smooth, straight or bent, 25 - 280 µm long, 2 - 4 µm in diameter at the top, 3 - 5 µm in diameter at the base, septate, 20 - 80 µm long between two septa, ramifications frequent and almost perpendicular branching near base, clamps lacking (Figure 1(h) and Figure 1(i)).
Tuber indicum s.l. × Quercus pannosa (Figure 2).
Mycorrhizae formed by T. indicum s.l. on Q. pannosa. (a) Type of ramification (bar = 500 µm); (b) Mycorrhizal tips with emanating hyphae (bar = 150 µm); (c) Cross-section of the mantle (bar = 10 µm); (d) Longitudinal section of the mantle (bar = 10 µm); (e) Mantle in plan views (bar = 10 µm); (f) Hyphal net on the mantle (bar = 10 µm); (g) Emanating hyphae in plan views (bar = 10 µm); (h) & (i) Emanating hyphae in transverse views (bar = 10 µm)
Mycorrhizal system unramified, monopodial-pinnate to monopodial-pyramidal, with 1 - 3 orders of ramification, light brown when young, brown to darkish brown; short-distance exploration type (Figure 2(a)). Main axes 0.8 - 3.5 mm long, 0.3 - 0.5 mm in diameter, straight or slightly bent. Unramified ends 0.3 - 2 mm long, 0.2 - 0.5 mm in diameter, straight or rarely slightly bent, cylindrical or slightly tapering, apex round (Figure 2(b)). Surface smooth or woolly with whitish emanating hyphae; emanating hyphae distinct, numerous, distributed unequally.
Cross-section of mantle 12 - 25 µm thick, pseudoparenchymatous composed of 4 - 7 layers of elliptical to hyphal cells, cells 3 - 15 × 2 - 6 µm, walls thin or slightly thick, indiscernible with different layers (Figure 2(c)). Longitudinal section of mantle 18 - 25 µm thick, pseudoparenchymatous composed of 5 - 7 layers of subglobose hyphal cells; cells 3 - 25 × 2 - 6 µm, walls thin or slightly thick, indiscernible with different layers (Figure 2(d)). The tip in transverse sections same as in other parts but with smaller cells. Hartig net reaches the 1 - 2 layers of cortex cells, composed of 1 - 2 layers of hyphal cells, colorless, subglobose, 1 - 3 µm in diameter.
Mantle in plan views is covered by a hyphal network, especially in regions of growth (Figure 2(f)). Surface net 1 - 3 layers, formed by anastomosed and irregularly connected hyphae, 3 - 8 µm in diameter, 6 - 12 µm between septa, cell walls thin to slightly thick, smooth, colorless to yellowish brown. Mantle indiscernible with different layers, composed of pseudoparenchymatous epidermoid with irregularly polygonal cells interlocked in a puzzle-like pattern, cells 8 - 25 × 5 - 15 µm, 4 - 8 cells in a square of 20 × 20 µm, thick walled, with pale brown walls, 0.5 - 1.5 µm thick, not gelatinous (Figure 2(e)). Mantle structures of the very tips same as in other parts of mycorrhizae but with smaller cells.
Emanating hyphae growing from both the outer mantle layer cells and hyphal net, loosely woolly, whitish to yellowish brown, cylindrical, tips rounded, thin walled, smooth, straight or bent, 60 - 350 µm long, 2 - 3 µm in diameter at the top, 3 - 4 µm in diameter at the base, septate, 20 - 60 µm long between two septa, ramifications frequent and almost 60 - 90 degree branching, clamps lacking (Figures 2(g)-(i)).
3.2. Phylogenetic Analysis
Forty-nine ITS sequences of T. indicum s.l. were used in the phylogenetic analysis (Table 1), including 23 from ascomata, 15 from natural mycorrhizae and 11 from synthesized mycorrhizae. Of the 566 total characters analyzed, 371 characters were constant, 18 were parsimony uninformative, and 177 were parsimony informative. The most parsimonious tree (Figure 3) included 261 steps (CI = 0.8697, RI = 0.9693).
The ITS phylogenetic tree (Figure 3) revealed that T. indicum s.l. is well separated into Group A and Group B. Two subclades, Group A and T. melanosporum, cluster in one clade that is a sister Group to with Group B with 100% bootstrap support. Thirty-one sequences of T. indicum s.l. clustered in Group A, and 18 clustered in Group B (the geographic distribution of the two groups is shown in Figure 4). Eighteen ITS sequences in Group A and 8 ITS sequences in Group B were from mycorrhizae (sequence origins are shown in Table 1).
4. Discussion
Using blast and ITS sequences from natural mycorrhizae in the NCBI database, we confirmed the symbiotic relationships between T. indicum s.l. and Q. pannosa, Po. yunnanensis, Ca. mollissima, Pi. armandii and Pi. yunnanensis. All Q. pannosa and Po. yunnanensis seedlings formed mycorrhizal systems with T. indicum on artificially controlled substrates. Before this study, eight indigenous trees of the genera Quercus, Cyclobalanopsis, Castanea, Carpinus and Pinus were successfully inoculated with T. indicum s.l. [4] -[7] . Tuber indicum s.l. has also been reported to form mycorrhizae with two North American trees, Pi. taeda and Carya illinoinensis [8] , and five European trees, Q. pubescens, Q. cerris, Q. ilex, Co. avellana and Pi. pinea [10] -[13] under artificially controlled conditions. Currently, sixteen trees are known to be symbiotic with T. indicum s.l. The higher diversity of the hosts indicates that T. indicum s.l. has wider host compatibility and higher ecological adaptability, suggesting that this species is more suitable than T. menosporum for artificial cultivation.
For the first time, we found Chinese black truffle mycorrhizae on poplars. Prior this study, the white truffles T. magnatum Pico and T. rapaeodorum Tul. & C. Tul. were found in association with the European poplar tree Po. alba L. [31] -[33] . The confirmation of the mycorrhizal relationship between T. indicum s.l. and Po. yunnanensis is of particular practical importance because Yunnan aspen seedlings can be easily produced by asexual reproduction and grow more rapidly. The Yunnan aspen is widely distributed in the middle-lowlands (altitude 1600 - 3500 m) of southwestern China and is an important species for afforestation because it grows quickly [34] . The
One of the 32 most parsimonious trees obtained from the analysis of the ITS sequences. (Km = Kunming, Gs = Gongshan, Hz = Huize, Dl = Dali, Chx = Chuxiong, Pzh = Panzhihua)
successful production of mycorrhizae using Po. yunnanensis seedlings and T. indicum s.l. confirmed the feasi- bility of using this tree on truffle conservation and plantations.
Tuber indicum s.l. mycorrhizae are characterized by a mantle composed of epidermoid cells interlocked in a puzzle-like pattern and woolly emanating hyphae that branch almost perpendicularly [5] [10] -[13] [35] . The mycorrhizae of T. melanosporum, a member of the same phylogenetic lineage, share all these characters with T. indicum s.l. except the hyphal net on the surface of the mantle, as shown in previous studies [36] [37] . However, a surface hyphal net on the mantle was also detected in T. indicum s.l. mycorrhizae in our study. These newly discovered characters broaden the diversity of T. indicum s.l. mycorrhizae, making it impossible to distinguish the mycorrhizae of these two species.
Geographical origins have been used to explain the inter-clade variability in T. indicum s.l. [20] [22] . The samples from Kunming, Huize, Dali and Gongshan, including T. indicum s.l. mycorrhizae and ascomata collected in situ, belonged to Group A, whereas samples from Gongshan, Panzhihua and Chuxiong belonged to Group B (shown in Figure 4). Groups A and B in our study are comparable to clades I and II, respectively, described by Wang et al. [22] . However, the origins of the two separate clades determined by Wang et al. [22] are different from the origins determined in our study. Samples from Gongshan all belonged to clade II in Wang et
Geographic distribution of the two groups within T. indicum s.l. (triangles indicate the origins of Group A; circles indicate the origins of Group B)
al.’s study [22] but belonged to both Group A and Group B in our study. In addition, samples from Huize be- longed to Group A and those from Chuxiong belonged to Group B in our study, whereas samples from Huize belonged to clade II and those from Chuxiong belonged Group I in Wang et al.’s study [22] . Because the samples were collected in situ in this study, our results indicate that two groups are not geographically distinct, supporting the results of Zhang et al. [23] and Chen et al. [15] . In our study, Pi. armandii was the natural host of five samples in Group A and of two samples in Group B, indicating that the two groups do not have distinct natural host preferences. Moreover, no host preference in the inoculation experiments was detected for Group A or Group B, as both groups included ITS sequences from mycorrhizae on Pi. armandii and Ca. mollissima. Al- though only ITS rDNA sequence was used in our study, the two clades in our phylogenic tree are consistent with the topologies inferred from ITS, LSU and β-tubulin sequences in Chen et al.’s study [14] . Our results support Chen et al.’s conclusion [15] that there are two cryptic species in the T. indicum complex. Furthermore, inter- clade differences in mycorrhizal morphology were not detected in our study, and the lack of distinct mycorrhizal morphologies could contribute to the presence of two cryptic species in the T. indicum complex.
Acknowledgements
The first author is very grateful for the help of Dr. X. H. Wang, who critically reviewed the manuscript and offered invaluable suggestions. Dr. Y. Wang is greatly appreciated for his help with assessing the mycorrhizae formed and for his kind encouragement. Many thanks are given to Lawrence Glacy for his linguistic assistance and to our colleagues who helped collect specimens and perform the field work. This study was financed by the National Science Foundation of China (No. 30470011, 31270075); the Joint Founds of the National Science Foundation of China and Yunnan Province Government (No. U1202262); the Yunnan Program of Innovation to strong provinces by Science & Technology (No. 2009AC013); the Key Laboratory for Plant Biodiversity and Biogeography of East Asia (KLPB), Kunming Institute of Botany, Chinese Academy of Sciences (No. 080- 6361121); the Key Laboratory of Food Fermentation & Brewing Technology, State Ethnic Affairs Commission of the People’s Republic of China (2012SY05); and Natural Science Foundation of Ningxia (NZ13089).
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