Type of Manuscript: Original research 

Title: Biodiversity of Astraeus asiaticus, a wild indigenous edible mushroom, in the forests of 

Bankura district, West Bengal and its antioxidant property 

Koushik Pandey1, Swapan Kumar Ghosh1 
1 Molecular Mycopathology Lab., Biocontrol and Cancer Research Unit, PG Department of Botany, 

Ramakrishna Mission Vivekananda Centenary College (Autonomous), Rahara, Kolkata 700118, WB, 

India 

Abstract Three forests, Beliatore, Gangajal-ghati (G-ghati), and Joyur, were surveyed for mushroom 

collection and biodiversity. Mushrooms in the rhizospheric zone of some trees, such as Shorea 

robusta, Petrocarpus marsupium, Terminalia bellrica, and Madhuca indica, were identified at the 

molecular level as Asterius asiaticus. Thereafter, the ecological diversity of this mushroom was 

determined in the forests. The diversity indices of Shorea robusta in the Beliatore, Joypur, and 

Gangajal-ghati forests were 2.303, 2.178, and 2.36, respectively. Notably, the diversity index of 

Madhuca indica in the Beliatore and Joypur forests was nearly the same as that in the Gangajal-ghati 

forest, with a value of 2.29. The total phenolics contents of the hot water, acetone, and hexane extracts 

of this mushroom were 6.8 ± 0.15, 3.95 ± 0.15, and 2.16 ± 0.26 mg GAE/g, respectively, and the total 

flavonoid contents were 2.03 ± 0.12, 1.65 ± 0.2, and 1.01 ± 0.08 mg QE/g, respectively. The ascorbic 

acid contents in the hot water, acetone, and hexane extracts were low. The antioxidant activity of the 

extracts was determined using the DPPH (1,1-Diphenyl-2-picrylhydrazyl) assay. The IC50 values of 

the hot water, acetone, and hexane extracts were 42.54±1.25c µg/ml, 54.06±1.50b µg/ml, and 

82.97±1.58a µg/ml respectively while that of the synthetic antioxidant, BHA (butylated 

hydroxyanisole), was 32.41±1.26d µg/ml. Overall, the hot water extract of this mushroom had the 

highest antioxidant content and displayed the best radical scavenging power.  

Keywords Mushroom; Biodiversity; PCR; Antioxidant; Astraeus asiaticus 

Running title: Astraeus asiaticus mushroom- its biodiversity and antioxidant property 

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1. Introduction 

 

Mushrooms, owing to their medicinal and food values, have been historically viewed as an amicable 

part of human society and have at times superseded plant and animal-procured products. Mushrooms 

are recognized as functional foods with nutritional value, structural quality, and acceptability 

(Greeshma et al., 2018; Mwangi et al., 2022; Pinto et al., 2020). Moreover, mushrooms undergo 

remarkable adjustments on imminent days for adaptation as smooth-running therapeutic foods. The 

consumption of mushrooms in Asian countries, such as India and Japan, is increasing at a significant 

rate. Based on data from Research and Markets (2021) (https://www.research and markets. com/), the 

value of the mushroom cultivation market was 16.7 billion $ (USD) in 2020, and is projected to reach 

20.4 billion $ (USD) by 2025 (Landínez-Torres et al., 2021). Palatable mushrooms are low-calorie, 

low-fat food adjuncts with moderate amounts of proteins, carbohydrates, vitamins, minerals, amino 

acids, and dietary fiber (Johnsy et al., 2011). Mushrooms also exhibit antibacterial, antifungal, 

antiviral, antiparasitic, antioxidant, anti-inflammatory, antiproliferative, anticancer, anti-HIV, 

hypocholesterolemic, antidiabetic, and anticoagulant activities (Ghosh et al., 2020a; Ghosh et al., 

2020b; Manimaran et al., 2021). Recently, Singh and Varshney (2020) estimated the food value of 

Astraeus hygrometricus, which was found to contain protein (16.02%), total carbohydrates (55.76%), 

fat (3.5%), monounsaturated oleic acid (4.59%), ash (3.8%), energy (159.5 kcal), pro-vitamin D2 

(ergosterol) (1.09 mg/g), and dietary fiber (39.78%). Among the total free amino acids (8.20 mg/g), 

7 essential amino acids (3.9 mg/g), including tyrosine (0.98) and leucine (0.92), were found. These 

researchers also found a high amount of selenium in A. hygrometricus. In this work, we opted to focus 

on the mushroom, Astraeus sp., owing to its food values of Astraeus sp. and its prominent use as a 

restorative drug owing to its antidiabetic, anticancer, hepatoprotective, anti-inflammatory, and 

cardioprotective activities (Phadannok et al., 2020). The primary aim of this study was to reveal the 

biodiversity of Astraeus asiaticus via morphological, biochemical, and molecular research in different 

woodlands or forests of the Bankura district, a red lateritic zone in West Bengal. Mycorrhizae provide 

nutrients between the roots of the host plant and fungi in the soil (Malajczuk et al., 1982). Biodiversity 

is a very important "natural capital." Different varieties, species, genera, and their complex 

interactions enable a functional ecosystem and productive economies (World Bank, 2022). Although 

wild mushrooms and fungi are an integral part of a given ecosystem, a study of their diversity and 

type has not been performed, particularly in tropical countries, such as India. As a result, a knowledge 

gap exists. Wild edible mushrooms act as natural resources for rural people and provide nutrition 

(Meena et al., 2020). Accordingly, an investigation of the biodiversity of wild edible mushroom and 

the consumption of this remarkable natural resource is of great economic importance. Astraeus species 

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are economically important as they are collected by people for consumption and sale in commercial 

markets (Manna & Roy, 2014). Bankura is recognized for its great abundance as residents can earn 

income by selling this wild edible mushroom. Thus, this mushroom is of great socioeconomic 

importance in the rural areas of West Bengal in India. A. asiaticus is a promising edible mushroom; 

however, its therapeutic value has not been explored. Therefore, in this study, the molecular 

characteristics, biodiversity, mycochemistry, antioxidant content, and antioxidant activity of this 

mushroom were determined to enable future research on its medicinal importance. 

 

2. Material and Methods 

 

2.1. Survey of habitat and sample collection 

 

A survey on mushrooms was conducted in the Beliatore, Joypur, and Gangajal-ghati forest areas in 

Bankura. Joypur and Beliatore in the Bankura district are located in the southwest part of West Bengal 

and is associated with native extremities owing to the Damodar and Dwarakeswar rivers, which 

indicate the depletion of both forest range areas. The Damodar and Dwarakeswar rivers are almost 

parallel toward the southeast, as the general slope of the district runs from northwest to southeast. A 

periodic survey was conducted in the preferred area for the collection of A. asiaticus during the rainy 

season from mid-July to August 2019. 

 

The habitat of mushrooms from the collection zone was noted, and photographs were captured. Soil 

samples from a rooting depth of 30 cm were collected from 15 zones (60 quadrats) of three forests. 

The samples were transported to the laboratory, and processed for soil chemical parameter analysis 

following the standard method (Iwabuchi et al, 1994, Das, 2021). 

 

2.2. Identification of the mushroom species 

 

Mushroom (basidioma) morphology was examined macroscopically and its size, shape, texture, color, 

and habit were determined, according to the pioneering work of Phosri et al. (2007). Biochemical tests 

were performed by dispensing a drop of chemicals (3% aqueous solution, 10% solution of potassium 

hydroxide (KOH), 10% solution of FeSO4, and vanillin) independently and directly on the tissue of 

freshly collected mushrooms, and observing the color changes immediately and after 4–5 min 

(Khaund & Joshi, 2014; Petrini et al., 2009). 

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The mushroom basidioma anatomy was observed under a compound microscope (Model No. 

Olympus CX31) after sectioning and staining with lactophenol cotton blue. Images were captured 

using a camera attached to a microscope. 

For scanning electron microscopy (SEM), the samples were transferred to a Petri dish and immersed 

in 10 mL of water to rehydrate the tissues around the spores. Thereafter, the spore samples were 

incubated in the following ethanol series with 2% glutaraldehyde for 15 min each: 30, 50, 70, 80, 90, 

95, and 100%. The samples were centrifuged, and the supernatant was collected. The sample was then 

placed in a Critical Point Dryer (CPD) and mounted. Finally, spores were prepared for SEM 

observation. The samples were coated with gold using a sputter coater. A focused image of the sample 

was used as the starting point under a scanning electron microscope. The magnification of the image 

was increased to a level close to the maximum, and the image was re-focused. A high-resolution SEM 

image was captured using an attached camera. All data or characters from macroscopic, microscopic, 

and biochemical reactions were compared with standard keys of mushrooms (Jordon, 1999; Pacioni, 

1981; Phsori, 2007; Purkayastha & Chandra, 1985), and phenotypic mushroom identification was 

conducted. 
 

For molecular identification of mushroom species, DNA was isolated from fresh basidioma using the 

modified hexadecyltrimethylammonium bromide (CTAB) method (Doyle & Doyle, 1987). In brief, 

100 mg sample was frozen in liquid nitrogen and ground using 500 µL lysis buffer [CTAB 3% (pH 

7.5), 100 mM Tris HCl, 20 mM EDTA (pH 7.5) 1.4 M NaCl2, 0.2% polyvinyl pyrolodine] and micro 

pestle in Eppendorf tubes. The sample was then incubated at 64-65 ºC for 1 h in a water bath and 

vortexed at 10-min intervals. β-mercaptoethanol (20 µg/mL) was added to the tube, which was then 

incubated at 37 °C for 45 min. The sample was combined and centrifuged at 8000 rpm for 10 min at 

4 °C using a cooling centrifuge. A total of 500 µL of chloroform: isoamyl Alcohol (24:1) was added 

to the solution, which was vortexed under chilled conditions. The solution was centrifuged at 12000 

rpm for 10 min at 4 ºC in a cooling centrifuge. The supernatant was collected in fresh Eppendorf 

tubes. A total of 500 µL of ice-chilled isopropyl alcohol (double volume) and 3 M Sodium acetate 

(1/10th volume) were added to the solution. Cold centrifugation was then performed at 12,000 rpm for 

5 min at 4 °C. The supernatant was discarded, and the pellet was collected (containing DNA), 

dehydrated with 70% ethanol, and left to dry under laminar airflow. Thereafter, the pellet was 

resuspended in 50-100 µL of TE buffer, and stored at 4 ºC overnight. Isolated DNA was purified using 

a HiMedia Purification Kit. The purified DNA was electrophoresed via electrophoresis using 0.8% 

agarose gel at 100 volts for 2-3 h. DNA bands were observed using a UV transilluminator. 

 

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The ITS1–5.8S- ITS2 marker zone for the rRNA of isolated gDNA was amplified using a PCR 

(polymerase chain reaction) protocol modified from Gardes & Bruns (1993), with primers ITS-1F (5′-

CTTGGTCATTTAGAGGAAGTAA-3′) and ITS4 (5′ TCCTCCGCT TATTGATATGC3′). In brief, 

PCR was conducted in a 50-μL reaction volume, which contained 1 ng/μL DNA template, 

approximately 1 μL; sterile distilled water, 38 μL; 10× Taq polymerase buffer with MgCl, 25 μL; 10 

mM dNTP mixes, 3 μL; template DNA, 1 μL; ITS1 forward primer, 1 μL; and Taq DNA polymerase, 

1 μL. The following PCR cycling program was employed: initial denaturation at 96 °C for 2 min 

followed by 35 cycles of denaturation at 96 °C for 1 min, annealing at 55 °C for 1 min, and extension 

at 72 °C for 2 min. The final extension at 72 °C for 10 min was terminated at the end of the 

amplification. The PCR product was sent to the SCI GENOME Laboratory, Kerala, for sequencing. 

The obtained sequence was compared with other related sequences using a BLAST search in GenBank 

(NCBI) (Ghosh et al., 2022; Podder & Ghosh, 2019) and submitted to GenBank, NCBI (Baltimore, 

USA). 

 

 

2.3. Biodiversity analysis and mushroom extraction in different solvents  

Biodiversity analysis 

 

Fifteen study zones were selected from three forests in the Bankura district. Thus, 60 quadrats were 

used in this study. For mushroom biodiversity, quadrats (50 m × 50 m) were randomly selected and 

the mushroom diversity was determined. Mushroom diversity was analyzed using the Shannon 

Weaver Biodiversity Index (H) (Shannon and Weaver 1962): Ĥ= -∑(ni /N) loge (ni /N), where ni is the 

individual number of species i and N is the sum of ni.  

 

Mushroom extraction in different solvents 

 Mushroom extraction was carried out using the most polar solvent (hot water), semipolar solvent 

(acetone), and nonpolar solvent (hexane). The collected basidiomata were washed, dried, and crushed 

into powder using a grinder machine. Thereafter, 10 g of powder was poured separately into hot water, 

acetone, and hexane in a 1:10 ratio. For the hot water extract (HWE), a mixture of mushroom powder 

and water was boiled at 100 °C for 2 h in a water bath (Chen et al., 2016). However, for the acetone 

and hexane extracts, the mixture of mushroom powder and solvent was shaken on a shaker at 150 rpm 

for 1 h and then it was placed in an incubator which was set to 38 °C for 72 h. Each extract was filtered 

through Whatman No. 4 filter paper and Whatman No.1 filter paper. The filtrates were centrifuged at 

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3000 rpm for 15 min, concentrated through evaporation using a rotary evaporator at 50 °C, and 

lyophilized into powder using a lyophilizer (Figure 1). The extracts were stored at −20 °C for further 

use.  

 

2.4. Qualitative tests of different solvent extracts of mushroom fruit body for mycochemicals  

 

Flavonoid  

 Briefly, 0.2 g of extract was dissolved in 4 mL of distilled water in a test tube. Thereafter, diluted 

sodium hydroxide (1 M) was added to the mixture, resulting in a yellow solution that 

 turned colorless following the addition of a few drops of dilute acid (10% hydrochloric acid), 

confirming the presence of flavonoids (Hossain et al., 2013). 

 

Terpenoids  

 Approximately 0.2 g of extract was dissolved in a mixture of 2 mL of chloroform and 3 mL of 

concentrated sulfuric acid. A reddish-brown color eventually appeared run, indicating the presence 

of terpenoids (Mujeeb et al., 2014). 

 

Cardiac glycosides  

 Briefly, 0.2 g of the extract was combined with 2 mL of glacial acetic acid and one drop of FeCl3. 

This mixture was then added to 1 mL concentrated H2SO4. When the upper layer and the interface 

between the two layers turned bluish-green and reddish-brown, respectively, this indicated the 

presence of cardiac glycosides (Auwal et al., 2014). 

 

Steroids  

 The crude extract (0.2 g) was treated with a few drops of acetic acid anhydride in a test tube. 

Concentrated H2SO4 was carefully added dropwise using the inner wall of the test tube. The presence 

of a brown ring on the surrounding surface indicated the presence of steroids (Gul et al., 2017) 

 

 

Saponins  

 The extract (0.2 g) was mixed with 5 mL distilled water in a test tube. The solution was shaken 

vigorously for approximately 5 min, and then incubated for 30 min. The formation of a honey comb 

froth indicated the presence of saponin (Auwal et al., 2014). 

 

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Alkaloid  

 Briefly, 0.2 g crude extract was weighed in a separate test tube and warmed in 2% sulfuric acid for 

2 min. In a separate test tube, the solution was mixed with a few drops of Dragendroff reagent. The 

presence of an orange red precipitate indicated the presence of alkaloid (Auwal et al., 2014). 

 

Carbohydrate  

 The extract (0.2 g) was dissolved in water (2 mL). Thereafter, 2-3 drops of Molisch's reagent [3.75 

g of α-naphthol in 25 mL ethanol (99%)] were added to the solution for the formation of a layer 

without shaking the test tube. Thereafter, a drop of concentrated sulfuric acid (99%) was added to 

the mixture. The presence of a purple color, which indicates the presence of carbohydrates, was 

determined at the interface (Auwal et al., 2014). 

 

 

Phlobatannins  

Briefly, 0.2 g extract was dissolved in 2 mL of water and then added to 3 mL of dilute HCl (10%). 

A red precipitate indicated the presence of phlobatannins (Auwal et al., 2014). 

 

Phenol  

 Briefly, 0.2 g of extract was dissolved in 2 mL of distilled water. The 

 solution was then treated with two drops of 5% FeCl3. The production of a deep blue color indicated 

the presence of phenol (Talukdar et al., 2017).  

 

Tannin  

 The extract (0.2 g) was dissolved in 4 ml of distilled water, heated in a water bath (50 °C), and 

filtered. Two drops of 1% FeCl3 were added to the filtrate. The formation of a dark green solution 

indicated the presence of tannins (Fransina et al., 2019; Usman et al., 2009). 

 

2.5. Divergent biochemical assay for antioxidant content and antioxidant potentiality 

Antioxidant content  

 

Total phenolics content assay  

The total phenolic content (TPC) of various solvent extracts was measured using the Folin–Ciocalteu 

reagent method (Mc Donald et al., 2001). Briefly, 0.1 mL Folin-reagent Ciocalteu's (0.5 N) reagent 

and 0.5 mL extract were mixed and incubated for 15 min at room temperature. Saturated sodium 

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carbonate solution (2.5 mL) was then added to the mixture, which was then incubated at room 

temperature for 30 min. The absorbance was measured at 760 nm. The results are expressed as mg of 

quercetin equivalent (QEs) per g of mushroom dry weight and are presented as mean ± SD (standard 

deviation) of triplicate experiments. 

Total flavonoid content (TFC) assay 

 The TFC of the extract was evaluated using a standard guideline suggested by Meda et al. (2005). 

Briefly, equal amounts of 2% AlCl3 (prepared in absolute methanol) and the extracts (1 mg/mL) were 

incubated in a glass tube at room temperature for 10 min. Thereafter, the absorbance was measured 

at 415 nm. The results are expressed as mg of quercetin equivalent (QEs) per g of mushroom dry 

weight and are presented as mean ± SD of triplicate experiments. 

 

Total ascorbic acid content assay 

 The total ascorbic acid content (TAAC) was determined using the Folin-Ciocalteu reagent method 

proposed by Jagota and Dani (1982). Briefly, 0.5 mL extract solution (1 g extract in 1 mL ethyl 

acetate) was quickly mixed with 0.8 mL of 10% trichloroacetic acid and refrigerated for 5 min before 

centrifugation at 3000 rpm for 5 min. Thereafter, 0.2 mL was retrieved from the mixture and mixed 

with 1.8 mL distilled water to a final volume of 2 mL. Finally, 0.2 mL of diluted Folin-Ciocalteu (1:9) 

was added to the diluted extract mixture. After a 10 min incubation at room temperature (27 °C), the 

absorbance at 760 nm was measured. Finally, the results are expressed as milligrams of ascorbic acid 

equivalents (AAEs) per gram of mushroom extract, with the mean standard deviation (SD) of three 

replicates. 

 

 

Antioxidant activity assay 

 

DPPH Assay  

1,1-Diphenyl-2-picrylhydrazyl (DPPH) radical scavenging activity (RSA) was determined using a 

modified method described by Bondet et al. (1997). Ten different concentrations (10-100 μg/mL) 

were prepared from the mushroom extract, and 900 μL DPPH (0.1 M) was added to each. The DPPH 

solution was prepared by adding 2 mg DPPH powder to 50 mL ethanol (0.1 M). After 2 h of incubation 

in the dark, the sample was subjected to a spectrophotometric study at a wavelength of 517 nm, and 

the absorbance was recorded. The percentage of DPPH reduction was calculated using the following 

formula: % DPPH reduction or % of inhibition = Ac−As
Ac

𝑥𝑥 100 

Where Ac is the absorbance of the solvent (control) and As is the absorbance of the sample. 

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Finally, the IC50 (50% of inhibition) value was calculated. 

 

 

 

3 Results 

 

3.1 Habitat study and soil analysis  

 

The collected mushrooms were rhizospheric and ectomycorrhizal under the roots of Shorea robusta, 

Modhuca indica, Petrocarpus marsupium, and Terminalia bellrica. When immature, the mushrooms 

were subterranean but when they were fully matured, they exposed by breaking the soil surface. The 

soil pH of the Beliatore, Gangal-ghati (G-ghati) forest was 6.3, and that of the Joypur forests was 6.5, 

6.3, and 6.2, respectively. The soil analysis revealed that the organic carbon content of the collected 

soils ranged from 0.82 to 0.93%. The carbon content of Beliatore soil samples was 0.93%, while that 

of the G-ghati soil sample was 0.87%, and that of the Joypur soil sample was 0.82%. The electrical 

conductivity (EC) of the three forest soil samples ranged from 81.58 to 86.72 µS. The value was 86.72 

µS in the Beliatore forest, 84.29 µS in the G-ghati Forest, and 81.58 µS in the Joypur Forest. The 

available nitrogen content of the Beliatore forest sample was 220 kg/ha, while that of G-ghati, and 

Joypur forest sample was 140 kg/ha and 180 kg/ha, respectively. The available phosphorus content in 

the forest soils of the Bankura district ranged from 72.67 to 74.34 kg/ha, with values of 74.34 kg/ha, 

73.54 kg/ha, and 72.67 kg/ha in the Beliatore, G-ghati, and Joypur forests, respectively. In the study 

area, available potassium ranged from 215.7 to 218.4 kg/ha, indicating a high potassium content in 

the three-forest soil sample of Bankura district. The available potassium contents in the three forests 

(Beliatore, G-ghati and Joypur) were 215.7, 214.2, and 218.4 kg/ha respectively and the N:P: K ratios 

in these forests were 3:1:3, 2:1:3, and 2:1:3, respectively (Table 1). 

 

3.2. Identification of mushroom  

  

Phenotypical identification  

The fruiting season for this mushroom is May-August. The basidioma of this species was globose and 

smooth, with an unexpanded diameter of 10-16 x 8-14 mm and expanded diameter of 14-23 x 8-12 

mm. The gleba was initially white; however, when the spores matured, the gleba and its granulate 

outer peridium turned purplish chestnut. The exoperidium was slightly viscous and smooth, and the 

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https://en.wikipedia.org/wiki/Gleba
https://en.wikipedia.org/wiki/Spore
https://en.wikipedia.org/wiki/Gleba


color was white, covering the endoperidium (Figure 2). The endoperidium is a thin membranous layer 

of tissue, enclosing the spore mass in a 20–30 mm diameter sac, nearly round, with an irregularly 

shaped ostiole at the top, surface felty rough, whitish, and gray to brown color. Basidiospore mass 

was whitish when young, and black and powdery at maturity. The spores were reddish-brown, roughly 

spherical with minute warts, measuring 7.5–11 μm in diameter. The mycelial layer consisted of 

branched hyphae that were 4–7 μm in diameter. The hyphae of the fibrous layer were 6–9 μm in 

diameter and branched, and the collenchyma-type layer contained branched hyphae 3–4 μm in 

diameter (Figure 3). Scanning electron micrographs provided a clear three-dimensional image and 

stereoscopic view of the mushroom spore and hyphal structures. Ornamentation on the spore surface 

and hyphal structure were clearly observed (Figure 4). The basidiospores showed extensive, dense, 

and rounded spine, and were globose, ranging from 8.65–15.3 mm diameter. Other features included 

ornamentation, purplish chestnut color, very densely ornamented with rounded, narrow, tapered, 

occasionally coalescent, spines 0.9–1.50 mm long.  

In the present biochemical identification study, no color change was observed when 10% KOH, 4% 

HNO3, Phenol, Vanillin, and 10% H2SO4 were employed (Table 2). The color change profiles 

generated for each species of wild edible mushrooms in the present study served as an additional tool 

to identify similar mushrooms. 

The collected mushroom was identified as Astraeus sp. based on the macroscopic and microscopic 

characteristics, biochemical reactions, and comparison with the standard keys of mushrooms (Jordon, 

1999; Pacioni, 1981; Phosri et al., 2007; Purkayastha & Chandra, 1985). 

 

 

Molecular Identification of Fungal Species  

The mushroom sample was identified as Astraeus asiaticus using BLAST in the NCBI database based 

on query coverage (98.0%) and identity score (83. 05%) (Figure 5) of sequence homology search. The 

nucleotide sequence of the ITS zone was submitted to Genbank, NCBI (Baltimore, USA) and 

published under the Accession no MZ931288.1. The strain name is “Aa_skg.”  

 

Phylogenetic analysis  

The phylogenetic tree (Figure 6) revealed that the test organism was closely related to Astraeus 

asiaticus. Thus, the wild mushroom was concluded to be a member of Astraeus asiaticus. 

 

3.3. Biodiversity Analysis  

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https://en.wikipedia.org/wiki/Hypha
https://en.wikipedia.org/wiki/Collenchyma


 The mushroom is terrestrial, grows under various trees, and is widely distributed in the three forests 

of Bankura district, West Bengal, India. Astraeus asiaticus can establish a symbiotic relationship with 

a wide range of trees. This ectomycorrhizal species forms a symbiotic relationship with trees, such as 

Shorea robusta, Modhuca indica, Petrocarpus marsupium, and Terminalia bellrica. In our study, the 

abundance of basidioma in this species was found to be associated with the roots of Shorea robusta; 

however, in the case of Madhuca indica, a moderate number of this species was found. Very poor or 

low numbers of this species were found in association with the roots of Terminalia bellrica and 

Petrocarpus marsupium. Further, no mushroom basidioma was found in association with Eucalyptus 

globulas and Acacia auriculiformis trees (Table 3). 

The ecological diversity of Shorea robusta and Madhuca indica in the 60 quadrats of 15 zones of 

three forests was calculated using the Shannon diversity index formula. 

The diversity index of Shorea robusta was 2.303 in the Beliatore forest, 2.178 in the Joypur forest, 

and 2.36 in the Gangajal–ghati forest (Table 4). Further, the diversity index of Madhuca indica was 

2.25 in the Beliatore forest, 2.26 in the Joypur forest, and 2.29 in the Gangajal–ghati forest (Table 5). 

  

3.4. Mushroom extraction, mycochemistry, antioxidant content, and potentiality study  

 

Mushroom extraction 

The HWE had the highest extraction yield (0.47 ± 0.01%) for A. asiaticus (Table 6). The polarity 

index of water is 10.2. Accordingly, water dissolves many polar and ionic solutes, such as proteins, 

water soluble carbohydrates, and mineral salts. In contrast, the nonpolar solvent, n-hexane, only 

dissolves nonpolar compounds, such as lipids, as its polarity index is 0.1, resulting in 0.32 ± 0.01b% 

crude product (HE). Acetone is a dipolar solvent; thus, it has an intermediate relative polarity. The 

polarity index of acetone is 5.1, resulting in a crude product, acetone extract (AE) of 0.42 ± 0.02%. 

The yields of HWE and AE were similar (P=0.005); however, their yields differed from that of HE 

based on Duncan multiple test analysis (Table 6). 

 

Mycochemical screening using a qualitative test 

Based on the mycochemical screening results (Table 7), the active ingredients in the HWE were 

flavonoids, cardiac glycosides, saponins, alkaloids, carbohydrates, carbohydrates, and phenols. For 

acetone, the active ingredients were flavonoids, cardiac glycosides, saponins, alkaloids, and phenols; 

and for the hexane extract, the active ingredients were terpenoids, cardiac glycosides, saponins, 

alkaloids, and tannins. Phlobatannins and steroids were not detected in any sample. Major active 

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ingredient metabolites, such as flavonoids, alkaloids, phenols, and carbohydrates, were found in the 

polar HWE, while terpenoids were found in the nonpolar hexane extract. 

 

Antioxidant content  

 

 Total phenolics, flavonoid, and ascorbic acid content  

 

 The total phenolics contents of the hot water, acetone, and hexane extracts were 6.8 ± 0.15, 3.95 ± 

0.15, and 2.16 ± 0.26 mg GAE/g, respectively, and the TFCs were 2.03 ± 0.12, 1.65 ± 0.2, and 1.01 

± 0.08 mg QE/g, respectively. Figure 7 shows the ascorbic acid concentration in the mushroom 

extracts. The ascorbic acid content in the hot water, acetone, and hexane extracts was low (0.167 ± 

0.03, 0.14 ± 0.04, and 0.11 ± 0.005 mg AAE/g, respectively).  

 

Antioxidant potential or scavenging activity based on the DPPH method  

 DPPH was used to evaluate the RSA of the mushroom decoction. DPPH is a stable free radical that 

exhibits idiosyncratic sorption at 517 nm. The absorption of these radicals decreases as antioxidants 

provide protons. As a measure of the magnitude of radical scavenging, a decrease in absorbance was 

confirmed. The free radical-scavenging capabilities of the extracts were calculated using the DPPH 

assay. A method by which antioxidants prevent lipid oxidation is free radical scavenging. The 

distillate method for scavenging DPPH free radicals can be used to assess the antioxidant activity of 

individual chemicals or extracts in a specific situation.  

Figure 8 shows the DPPH RSA of all solvent extracts of this mushroom. The IC50 (50% of inhibition) 

values for the HWE, acetone extract, and nonpolar hexane extract were 42.54 ± 1.25 µg/mL, 54.06 

±1.50 µg/mL, and 82.97 ± 1.58 µg/mL, while that of synthetic antioxidant BH was 32.41 ± 1.26 

µg/mL.  

 

 

4. Discussion and Conclusions  

 

 Wild edible mushrooms, which serve as a good economic source for underprivileged residents of 

Bankura district, W.B., were collected to perform phenotypic and molecular identification studies and 

determine their diversity. This mushroom has been consumed as a good food in this area and adjoining 

districts. According to the literature, this genus of mushroom is distributed worldwide, especially in 

Africa, Asia, Australia, Europe, Mexico, North America, and South America (Pavithra et al., 2015). 

A literature survey revealed that Astraeus hygrometricus, A. asiaticus, A. morganii, A. sirindhorniae, 

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A. odoratus, A. pteridis, A. smithii, A. telleriae, A. koreanus, and A. thailandicus have been discovered 

globally (Verma et al., 2019). In this study, both phenotypic and molecular identification of this 

mushroom were successfully performed. The relevance of nucleic acids as molecular markers applies 

to fungal taxonomy. PCR is an established habitual tool for field mycology. For example, internal 

transcribed spacer (ITS) regions are amplified by PCR and subsequently sequenced for molecular 

phylogenetic analysis of diverse mushroom species. The DNA sequences obtained via PCR are used 

for population genetics and biodiversity research on mushroom species (Ghosh et al., 2022, Izumitsu 

et al., 2012). In this study, both phenotypical and molecular (ITS1-5.8s-ITS-2 zone of rDNA) 

identification revealed that this mushroom belonged to the species, Astraeus asiaticus, which was first 

identified in this district of West Bengal, India. Astraeus asiaticus is a new species of star-shaped 

gasteroid fungus that differs morphologically from other genera of star-shaped fungi. This genus does 

not possess distinct peristome or columella. Further, the spores of this genus are larger than those of 

Geastrum, and its capillitial hyphae are longer and more branched (Phosri et al., 2014). Phosri et al. 

(2007) identified this species at the morphological and molecular levels. Our phenotypical and 

molecular results align with the findings of Phosri et al. (2007). Recently, Topno and Srivastava 

(2021) collected puff balls from Chota Nagpur Plateau (Jharkhand). These puff balls were 

phenotypically and molecularly (ITSs markers) similar to Astraeus asiaticus. Similarly, Vishal et al. 

(2021) collected two earth star mushrooms from Sal forest of the Porahat forest division of Jharkhand 

state, India and identified these mushrooms A. asiaticus and A. odoratus based on molecular studies 

(ITSs marker). From the GENBANK database (NCBI, Baltimore, USA), we identified five accession 

Nos for Astraeus sp. from 2008 to 2020: AJ629895.1 for A. hygrometricus from West Bengal, India 

in 2008; MN257431.1 and MT611066.1 for A. asiaticus from our neighboring state, Jharkhand, India 

in 2019 and 2020; and MN262679.1 and KJ847767.1 for Astraeus odoratus in 2019 and 2016. 

SEM studies of spores and hyphae were performed according to the findings of Phosri et al. (2007). 

The study of biodiversity of this species of mushroom as ectomycorrhizan in this work in W.B. was 

first time work but in other states of India, diversity work has been done to some extent in other 

species (A. hygrometricus) (Topno and Srivastava, 2021; Semwal et al., 2014; Verma et al., 2017; 

Vishal et al., 2021). After a distribution search of Astraeus species in India, this genus was found in 

the provinces of Himachal Pradesh, Uttar Pradesh, Uttarakhand, Madhya Pradesh, Chhattisgarh, 

Punjab, Karnataka, Kerala, Jharkhand, and Odisha, and in our state (Pavithra et al., 2015; Phosri et 

al., 2004; Pyasi et al., 2013; Semwal et al., 2014; Topno & Srivastava, 2021; Vishal et al., 2021). 

Some Asian varieties of A. hygrometricus are reported to differ from those which are found in North 

America and are recognized as new species, such as A. asiaticus and A. odoratus (Mortimer et al., 

2012). In the present case, the Astraeus species was identified as A. asiaticus. 

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In our study, the plants supporting this mushroom were Shorea robusta, Madhuca indica, Petrocarpus 

marsupium, and Terminalia belerica. Such finding is supported by other researchers (Harley et al., 

1997; Verma et al., 2017). The ectomycorrhizal association of Astraeus with the roots of members of 

Pinaceae, Betulaceae, Fagaceae, Ericaceae, and Dipterocarpaceae has been reported (Wilson et al., 

2012). The diversity index obtained in our study indicated that the ecological diversity of this 

mushroom was similar in the three forests in Bankura district, W.B. By analyzing the soil quality of 

these three forests, they were found to be more or less similar in respect to NPK and pH status, aligning 

with the results of another study (Das, 2021). Mushrooms contain high amounts of antioxidant 

compounds (Chun et al., 2021; Shaffiqueet et al., 2021; Wani et al., 2010). The antioxidant activity 

of A. hygrometricus was demonstrated previously (Mandal et al., 2015, Pavithra et al., 2016). 

Compounds, such as phenolic compounds, flavonoids, and ascorbic acids, have been found in other 

Astraeus species (Astraeus odoratus and Astraeus pteridis) (Arpha et al., 2012; Isaka et al., 2016; Lai 

et al., 2012; Mallick et al., 2016; Pimjuk et al., 2015; Rahi & Malik, 2016; Stanikunaite et al., 2008). 

In this study, the different parameters of the mycochemistry study of A. asiaticus were successfully 

analyzed based on the total phenolic, flavonoid, ascorbic acid, and antioxidant contents, and the free 

RSA of this mushroom. In our experiment, all extracts of this mushroom had a high amount of 

phenolic compounds; however, the HWE had the best results. Similarly, this HWE had the highest 

antioxidant activity among the extracts. The antioxidant properties depend on phenolic compounds 

(Velioglu et al.,1998; Xu, 2013). The dietary intake of a substantial amount of phenolic compounds 

is important as they play the role of free radical terminators that reduce the incidence of many diseases, 

such as atherosclerosis, cancer, and heart diseases (Alothman et al. 2009; Xu, 2013). The antioxidant 

activity of many wild mushrooms is positively correlated with total phenolics (Lo & Cheung, 2005; 

Xu, 2013). Phenolic compounds have redox properties and antioxidant properties. As their free radical 

scavenging ability is facilitated by their hydroxyl groups, the total phenolic concentration can be used 

as a basis for rapid screening of antioxidant activity. Recently, Bouyahya et al. (2022) reviewed the 

role of phenolic compounds in improving the chemosensitivity of anticancer drugs.  This study first 

time has compared the antioxidant activity of polar, semipolar, and nonpolar extracts of Astraeus 

asiaticus. So, mycochemical analyses should be performed to identify the active phenolic and 

flavonoid components. Ascorbic acid plays an important role as a protective antioxidant. In this study, 

the ascorbic acid contents in the hot water, acetone, and hexane extracts were 0.167 ± 0.03, 0.14 ± 

0.04, and 0.11 ± 0.005 AAEs/g, respectively, aligning with previous results (Mau et al, 2002). The 

highest ascorbic acid content of 0.167 ± 0.03 AAEs/g, which was obtained using the HWE, might 

account for the better results found for their antioxidant activity. The HWE of A. asiaticus displayed 

potential scavenging activity (IC50 = 42.54 ± 1.25 µg/mL), which is comparable to that of the standard 

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antioxidant, BHA. In general, the lower the IC50 value, the higher the antioxidant property. 

Accordingly, the HWE of Astraeus asiaticus was found to exhibit antioxidant attributes. These 

findings indicate that the HWE of mushroom species has a conspicuous effect on scavenging free 

radicals. Pavitra et al. (2016) reported that the antioxidant activity of A. hygrometricus is 

concentration-dependent and does not decrease after cooking. Herein, the HWE of A. asiaticus had 

the best antioxidant activity, which aligns with previous findings (Pavitra et al., 2016). Antioxidants 

are important compounds that help increase the resistance of the body to free radicals. Mycochemistry 

revealed that this mushroom was the source of some volatile compounds, such as 1-octanol, 1-octen-

3-ol, and 1-octen-3-one, which had a "mushroom-like, earthy, and pungent odor that was evident as 

an oily and moss-like smell upon opening the caps." During the cooking of mushroom samples, 

furfural, benzaldehyde, cyclohexenone, and furanyl compounds are emitted (Mortimer et al., 2012; 

Verma et al., 2017). Recently, Isaka et al. (2017) isolated 17 known and seven new lanostane 

triterpenoids, such as astraeusins, 26-epi-artabotryol C1, and 26-epiastrasiaone, from A. asiaticus. To 

our knowledge, the current study is the first to assess the antioxidant content and activity of this edible 

mushroom species, and its biodiversity in the forests of Bankura district.  

  

 Based on our findings, the species of Astraeus in the forest of the Bankura district was A. asiaticus. 

Further, this species was mycorrhizally associated with Shorea robusta and Madhuca indica. Based 

on the ecological diversity of this mushroom, A. asiaticus was associated with the above-mentioned 

specific plants. The mycochemistry of this mushroom revealed good quality and content of 

antioxidants, including phenolic compounds, flavonoids, and ascorbic acid, and good antioxidant 

activity (scavenging of free radicals). Therefore, this mushroom is a good source of valuable nutrients, 

including antioxidants, scientifically validating our eating habits. This work may fill the knowledge 

gap, to some extent, related to this wild edible mushroom (gift of nature), and encourages further 

assessments. 

Acknowledgements 

The authors would like to thank the Department of Science and Biotechnology Technology of West 

Bengal, India for providing financial support. 

Authors’ contributions  

SKG designed the study and wrote and revised the manuscript. KP performed the experimental work, 

literature survey, and statistical analysis.  

 

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Tables: 

Table 1 Mean values for the soil physico-chemical parameters and the N, P, and K ratios of the soil 

samples collected at selected quadrants of the Forests in Bankura district. 

 

 

Name of 

the 

district 

Name of 

the 

forests 

Soil 

pH 

Electrical 

Conductivit

y 

(µS) 

Carbon 

(%) 

Organic 

Nitrogen  

Kg/ha 

Phosphorus 

Kg/ha 

Potassiu

m Kg/ha 

N:P:K 

Bankura Beliatore 6.5 86.72 0.93 220 74.34 215.7 3:1:3 

Gangajal 

–ghati(G-

ghati) 

6.3 84.29 0.87 140 73.54 214.2 2:1:3 

Joypur 6.2 81.58 0.82 180 72.67 218.4 2:1:3 

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https://doi.org/10.1111/j.1469-8137.2012.04109.x
https://www.worldbank.org/en/topic/biodiversity,


Table 2 Color change profile based on the fruiting bodies of Astraeus asiaticus. 

 

 

 

 

 

 

 

 

Table 3 Association of Astraeus asiaticus with different trees. 

 

 

 

 

 

 

Note: - indicates no association or mushroom fruit body, + indicates presence of a lower number of 
mushroom fruit bodies or association, ++ indicates a moderate number of fruit bodies, and +++ 
indicates an abundance of mushroom fruiting bodies.  

 

Table 4 Shannon Weaver biodiversity index of the association between Astraeus asiaticus and 

Shorea robusta. 

Test Colour changed observed 

10% KOH None 

4% HNO3 None 

Phenol None 

Vanilin  None 

10% H2SO4 None 

Trees Fruit body association with trees 

Shorea robusta +++ 

Petrocarpus marsupium  + 

Terminalia bellrica + 

Acacia auriculiformis - 

Modhuca indica ++ 

Eucalyptus globulas - 

Forest Zones Quadrates in 

each zone 

Total no of 

quadrates in the 

forest 

Shannon Weaver 

biodiversity index of A. 

asiaticus 

 

Beliatore 5 4 20 2.303 

Joypur 5 4 20 2.178 

 

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Table 5 Shannon Weaver biodiversity index of the association between Astraeus asiaticus and 

Modhuca indica. 

 

 

Table 6 Percentage yield of the crude products using different solvents. 

 

Gangajal –

ghati 

5 4 20 2.36 

Forest Zones Quadrate in 

each zone 

Total no of 

quadrates in 

the forest 

Shannon Weaver 

biodiversity index of 

A. asiaticus 

 

Beliatore 5 4 20 2.25 

Joypur 5 4 20 2.26 

Gangajal –

ghati 

5 4 20 2.29 

Solvent 

name 

(Extract 

name) 

Method of 

extraction 

Ratio of 

solute and 

solvent 

Initial weight of 

Mushroom 

powder(gm) 

Final crude 

weight 

(gm)(±SD) 

Percentage of 

yield (%) 

(±SD) 

Hot water 

(HWE) 

Dipping 

method 

1:10 500 2.26± 0.15 0.47± 0.01a 

Acetone 

(AE) 

Dipping 

method 

1:10 500 2.1± 0.12 0.42± 0.01a 

Hexane 

(HE) 

Dipping 

method 

1:10 500 1.52± 0.08 0.32± 0.02b 

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Note: Same letters in the same row indicate statistical similarity, while different letters indicate 

statistical difference (P=0.05) based on Duncan’s multiple test. 

Table 7 Mycochemical screening of the polar (water), dipolar (acetone), and nonpolar (hexane) 

solvent extracts of Astraeus asiaticus. 

 

 

 

 

 

 

 

 

 

 

 

 

Note: (-) Absence, (+) Presence. 

 

 

 

 

 

 

 

 

 

 

 

Mycocompound 

/class 

Hot water extract 

(HWE) 

Acetone extract 

(AE) 

Hexane extract 

(HE) 

Flavonoid + + - 

Terpenoid - - + 

Cardiac glycoside + + + 

Steroid - - - 

Saponins + + + 

Alkaloid + + + 

Tanins - - + 

Carbohydrate + - - 

Phenol + + - 

Phlobatannins - - - 

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Figures 

 

 

 

 

Figure 1 Design of the mushroom fruitbody extraction process in different solvent systems 

 

 

 

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 Figure 1 Images of Astraeus asiaticus. A. Young sporocarps collected from the field; B. Young 

sporocarp; C. Mature sporocarp. 

 

 

 
Figure 3 Images of the anatomy of Astraeus asiaticus - A. Cross-section of the gleba; B. Cross-section 

showing the arrangement of long thick-walled septate hyphal cells; C. spore mass; D. spore mass with 

basidiospore (40X). 

 

 

 

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Figure 4 Scanning electron micrograph. A. Scanning electron micrograph of the hyphae structure 

(bar= 1 µm); B. Scanning electron micrograph of mature basidiospores displaying dense, rounded 

spine in groups (bar = 200 nm).  

 

 

 

 

 

 

 

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Figure 5 BLAST result of Astraeus sp. with the highest sequence similarity of Astraeus asiaticus. 

 

 

 

 

 

 

 

 

 

 

 

 

 

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Figure 6 Neighbor-joining phylogenetic tree showing the evolutionary relationship of the ITS gene 

sequences. The tree was constructed based on evolutionary distances, which revealed that the test 

organism is closely related to Astraeus asiaticus sp. 

 

 

 

 

 

 

 

 

 

 

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Figure 7 Total phenol, flavonoid, and ascorbic acid contents of Astraeus asiaticus in the hot water, 

acetone, and hexane extracts. 

 

 

 

 

 

 

 

 

 

 

 

 

 

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Figure 8 IC50 value of the different solvent extracts of Astraeus asiaticus (± SD is depicted at the 

top of data bar). Similar letters at the top of data bars indicate statistical similarity, while different 

letters indicate statistical difference (P=0.05) based on Duncan’s multiple range test. 

 

 

 

 

 

 

 

 

 

 

 

 

 

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