New species of Cystolepiota from China

ABSTRACT In this paper, a new species, Cystolepiota pseudofumosifolia, is introduced. C. pseudofumosifolia is characterized by granulose or powdery pileus with an anatomic structure that is loosely globose, as well as ellipsoid cells in chains in the pileus covering the cheilocystidia. This new species is compared to the related and similar Cystolepiota species in morphology and molecular phylogeny based on Internal transcribed spacer sequences. Both types of data support our specimens as a new species in the genus Cystolepiota.


Introduction
Cystolepiota Singer (Agaricaceae/Agaricales) is one genus of lepiotaceous fungi. Cystolepiota species are generally saprotrophic, pileus less than 50 mm in diameter, and basdiocarp heavily covered by granules on the pileus and stipe. The edge of the pileus is often appendiculate; an annulus is present but often becomes an annular zone at the stipe; the spore print is white (Vellinga 2004a;Bau and Liu 2010;Gierczyk et al. 2011). Species of Cystolepiota are very similar to Melanophyllum haematospermum (Bull.: Fr.) Kreisel which is also covered with greyishbrown powder or granules on the pileus and stipe; Lepiota sect. Echinatae has even been considered as a part of Cystolepiota by Knudsen (1978) for its inflated subglobose to ellipsoid hyphal cells of pileipellis. However, some morphological characters, such as the coloured spore print, separate M. haematospermum and L. sect. Echinatae from Cystolepiota (Vellinga 2001).
Presently, more than 10 Cystolepiota species have been identified and they have been well characterized in Europe and Western North America (Hausknecht and Pidlich-Aigner 2004;Vellinga 2004bVellinga , 2006Vellinga , 2007Gierczyk et al. 2011). The most complete phylogenetic study of Cystolepiota was conducted by Vellinga (2007). In this study, six Cystolepiota species were examined, and the monophyly of the genus was supported. This molecular approach also clarified some taxonomic problems, resulting in transferring Lepiota fumosifolia Murrill into Cystolepiota (Vellinga 2007). Some species have been recorded in Asia, such as Cystolepiota hetieri (Boud.) Singer, Cystolepiota seminuda (Lasch) Bon from Iran (Asef & Muradov 2012;Albuquerque et al. 2010), Cystolepiota pseudogranulosa (Berk. & Broome) Pegler from Sri Lanka (Pegler 1972), and Cystolepiota furfuracea T.K.A. Kumar & Manim from India (Arun Kumar and Manimohan 2009). In China, only a small number of species have been recorded from this genus, which distributed from the temperate to subtropical regions (Bau and Liu 2010;Chou 2010;Yang et al. 2011).
We conducted mushroom surveys from several national natural reserves in Yunnan Province, southwestern China in 2011 and 2012. Several new species were discovered and this paper presents one new Cystolepiota species. Vellinga split the genus of Cystolepiota into three groups based on microscopic features, that is, sect. Cystolepiota, sect. Pulverolepiota (M. Bon) Vellinga, and sect. Pseudoamyloideae Singer & Clem (Vellinga 2001). In this paper, a new species belonging to Cystolepiota sect. Cystolepiota is described, illustrated, and compared with related taxa.

Morphological examination
Collections were made in the field, photographs were taken in situ, and the odour and discoloration after bruising were recorded. The fruiting bodies were wrapped in aluminium foil and kept separately in a compartmented box in order to avoid mixing or crushing (Zhao et al. 2010). The description of macroscopic characters, chemical testing, and further photography of fresh samples were carried out as soon as possible following the methodology described by Largent (1986). Colour terms follow those of the Online Auction Color Chart™ (www. OnlineAuctionColorChart.com). The samples were then dried completely using a drier, sealed in plastic bag, and deposited in the Herbarium of Mycology, Institute of Microbiology, Chinese Academy of Sciences (HMAS), Beijing, China.
Microscopic characters were examined from the pileus, gill, stipe, and veil of dried specimens following the protocols of Largent (1986) and Nauata (2001). First, a small piece of material was softened with absolute ethanol, then sliced by hand and successively mounted in 5% NaOH, Congo red solution, and Cresyl blue for observation under the microscope. The anatomic structures of the lamellae, pileipellis, stipitipellis, and partial veil, including basidiospores, basidia, cystidia, and clamp connections, were examined (Robin 1999). The size of the basidiospores, basidia, and cystidia were observed based on at least 20 measurements with the following abbreviations: avl = average length, avw = average width, Q = quotient of length to width, and avQ = average quotient.
Sequence alignment and phylogenetic analyses Preliminary analysis of the Internal transcribed spacer (ITS) sequences were performed using Basic BLAST (www.blast.ncbi.nlm.nih.gov) in order to detect the contamination of materials. Sequences were downloaded from GenBank, and manually adjusted using Mafft 7.300 and BioEdit 7.0.9.0 when necessary (Hall 1999;Katoh and Standley 2013). Gaps were not removed from the alignment. The sequence alignments were submitted online (www.phylogeny.fr.cgi) to determine the relationship between these sequences.
Maximum parsimony (MP) analyses were performed using PAUP*4b10 (Swofford 2004). Maximum bootstrap (BS) values were obtained from 1000 replicates from the MP analysis. The tree bisection-reconstruction (TBR) algorithm was used in a heuristic search, and BS support was determined with 1000 replicates (Felsenstein 1985). A total of 5000 Maxtrees were set. Branches of zero length were collapsed, and all most parsimonious trees were saved. Clade stability was assessed in a BS analysis with 1000 replicates, each with 10 replicates of a random stepwise addition of taxa.
A Kishino-Hasegawa test (KH test) (Kishino and Hasegawa 1989) was performed to determine whether trees were significantly different. The consistency index (CI), retention index (RI), rescaled consistency (RC) index, homoplasy index (HI), and tree length (TL) were also calculated.
The best nucleotide substitution model for Bayesian analyses was chosen using MrModeltest 2.3 (Nylander 2004). Bayesian phylogenetic inference was performed using MrBayes 3.2.6 Ronquist and Huelsenbeck 2003). Four Markov chains were run for 1,000,000 generations and sampled every hundredth generation, resulting in 10,000 trees. The trees sampled before the searches reached an average deviation of split frequencies lower than 0.01 were discarded as the burn-in, and the remaining trees were used to calculate Bayesian posterior probabilities (PPs) for the individual clades. The resulting trees were visualized using FigTree 1.4.2.

Phylogenetic analysis
The ITS dataset included 11 sequences representing eight Cystolepiota species, and Lepiota clypeolaria was chosen as the out-group (Table 1). The alignment contained 695 characters, of which 434 characters were constant; 73 were parsimony uninformative; and 188 were parsimony informative. Gaps were treated as missing data. One most parsimony tree was found in the heuristic search. The tree has a CI of 0.799, RI of 0.761, RC of 0.608, HI of 0.201, and TL of 442. GTR+G was selected as the best model by hierarchical likelihood ratio tests (hLRTs) in MrModeltest 2.3 through using the Akaike information criterion. The average deviation of split frequencies at the end of the run was 0.003267.
The phylogenetic trees estimated by MP and Bayesian inference had almost identical topologies. The Bayesian tree was presented (Figure 1). The two samples from this new species grouped together with strong support (BS = 100, PP = 0.99) and appeared sister to the subclade of Cystolepiota fumosifolia (BS = 99, PP = 1; Figure 1).
Fungal names: FN570270 Etymology: refers to the similarity to the species C. fumosifolia (Murrill) Vellinga in morphology.

Discussion
Vellinga provided an in-depth and comprehensive description of Cystolepiota, including a key to Cystolepiota species (Vellinga 2001(Vellinga , 2007. Cystolepiota bucknallii (Berk. & Broome) Singer & Clémençon and Cystolepiota icterina F.H. Møller ex Knudsen have lilac-tinged pileus; the cap of Cystolepiota moelleri Knudsen is covered with small pink granulose warts, and C. seminuda (Lasch) Bon has a vinaceous stipe, characters which make them easily differentiated from C. pseudofumosifolia in the field. Cystolepiota petasiformis (Murrill) Vellinga and Cystolepiota pulverulenta (Huijsman) Vellinga are distinct species in this genus because they have elongate and inflated pileipellis cells, which is also an obvious feature to separate it from the new species. Cystolepiota oregonensis (H.V. Sm.) Vellinga is similar to the new species in the field, but the former shows reddish-brown discoloration after touching or bruising.
The phylogenetic tree of Cystolepiota indicated that our samples belong to Cystolepiota and represented a different species from C. bucknallii, Cystolepiota adulterina (F.H. Møller) Bon, C. seminuda, C. hetieri, and C. pulverulenta (Huijsman) Vellinga ( Figure 1). Furthermore, these two specimens belong to the same species and are closely related to C. fumosifolia (Murrill) Vellinga. C. pseudofumosifolia is also morphologically similar to C. fumosifolia because they share not only macroscopic characters but also microscopic characters, such as size and shape of the pileipellis and cheilocystidia (Vellinga 2006). However, our species presents smaller and narrower spores than those of C. fumosifolia (4.9-5.7 × 2.6-3.1 μm, avQ = 1.8). A key to known species of Cystolepiota in China is provided.
Key to the known species of Cystolepiota in China Funding