Endophytic fungi from Vitex payos: identification and bioactivity


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Acta Mycologica

ORIGINAL RESEARCH PAPER

Endophytic fungi from Vitex payos: 
identification and bioactivity

Edson Panganayi Sibanda1,2, Musa Mabandla2, Tawanda 
Chisango2, Agness Farai Nhidza2, Takafira Mduluza2,3*

1 Scientific and Industrial Research and Development Centre, Food and Biomedical Technology 
Institute, 1574 Alpes Road/Scam Way, Harare, Zimbabwe
2 School of Laboratory Medicine and Medical Sciences, College of Health Sciences University of 
KwaZulu-Natal, Westville Campus, Private Bag X54001, Durban 4000, South Africa
3 Department of Biochemistry, University of Zimbabwe, PO Box MP167 Mount Pleasant, Harare, 
Zimbabwe

* Corresponding author. Email: tmduluza@yahoo.com

Abstract
Endophytic fungi isolated from medicinal plants have an important role to play in 
the search for new bioactive natural compounds. However, despite their potential 
as repositories of bioactive compounds, the endophytes of African medicinal 
plants are largely underexplored. The aim of this study was to isolate and identify 
the endophytic fungi associated with Vitex payos and evaluate their antimicrobial 
and antioxidant potential. The surface sterilization technique was used to isolate 
the endophytic fungi that were identified by rDNA sequencing of the ITS region. 
Crude methanol and ethyl acetate extracts were screened for antimicrobial activ-
ity using the agar diffusion method and evaluated for antioxidant activity using a 
commercial total antioxidant capacity assay kit. The total phenolic content of the 
extracts was determined using the Folin–Ciocalteu method and functional groups 
present in the extracts were predicted using Fourier-transform infrared spectros-
copy. Seven endophytic fungi isolates identified as Glomerella acutata, Epicoccum 
nigrum, Diaporthe species, Penicillium chloroleucon, Diaporthe endophytica, Mucor 
circinelloides, and Epicoccum nigrum were isolated from the tissues of Vitex payos. 
None of the extracts exhibited antimicrobial activity and the crude ethyl acetate 
extract obtained from E. nigrum demonstrated both the highest total phenolic 
content (2.97 ±0.13 mg GAE g−1 dry weight) and total antioxidant capacity (231.23 
±2.03 μM CRE). Fourier-transform infrared spectral analysis of the crude extracts 
from E. nigrum confirmed the presence of molecules carrying bonded hydroxyl 
functional group characteristic of phenolic compounds. These preliminary results 
indicate that most of the isolated fungal endophytes from V. payos belong to the 
phylum Ascomycota and that the isolated E. nigrum strain has potential as a source 
of natural antioxidants.

Keywords
diversity; antimicrobial; antioxidant; bioprospecting; Africa; endophyte

Introduction

There is heightened interest in bioprospecting for natural compounds with potential 
use as therapeutics owing to several factors that include the rapid development of 
antimicrobial resistant pathogenic microbes and emergence of new life-threatening 
diseases [1,2]. Endophytes are microorganisms that live within plants for at least a part 
of their life cycle without causing any visible manifestation of disease [3]. Endophytic 
fungi have been shown to produce a broad variety of bioactive secondary metabolites 
and bioprospecting of endophytes is considered a new frontier in the search for natural 
products with potential agricultural, pharmaceutical, and industrial applications [4,5]. 

DOI: 10.5586/am.1111

Publication history
Received: 2017-10-24
Accepted: 2018-08-23
Published: 2018-12-06

Handling editor
Maria Rudawska, Institute of 
Dendrology, Polish Academy of 
Sciences, Poland

Authors’ contributions
TM and MM were responsible 
for the research design; EPS, TC, 
and AFN were responsible for 
data collection and analysis; TM 
and EPS wrote the manuscript 
and MM revised the manuscript

Funding
We are grateful to the University 
of KwaZulu-Natal (College of 
Health Sciences postgraduate 
research grant) for the financial 
support of this research.

Competing interests
No competing interests have 
been declared.

Copyright notice
© The Author(s) 2018. This is an 
Open Access article distributed 
under the terms of the 
Creative Commons Attribution 
License, which permits 
redistribution, commercial and 
noncommercial, provided that 
the article is properly cited.

Citation
Sibanda EP, Mabandla M, 
Chisango T, Nhidza AF, Mduluza 
T. Endophytic fungi from 
Vitex payos: identification 
and bioactivity. Acta Mycol. 
2018;53(2):1111. https://doi.
org/10.5586/am.1111

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Sibanda et al. / Endophytic fungi from Vitex payos

Medicinal plants are rich sources of bioactive natural compounds and studies have shown 
that some medicinal properties of these plants may be related to the endophytic fungi 
that they host [2]. The endophytic fungi may participate in some of the plant metabolic 
pathways or may gain some genetic information to produce specific biologically active 
compounds, such as those produced by the host plant [6]. Therefore, endophytic fungi 
isolated from medicinal plants have an important role to play in the search for new 
bioactive natural compounds. Despite this potential of medicinal plants and the rich 
plant biodiversity in Africa, only a tiny fraction of African medicinal plant species have 
been studied with regard to their endophytic fungi diversity. Vitex payos is an African 
ethnomedicinal plant used to treat several ailments in Zimbabwean traditional medicine 
[7]. As part of our contribution to the ongoing efforts to understand the diversity of 
endophytic fungi, we isolated and identified endophytic fungi found in the leaf and 
stem tissues of V. payos. Furthermore, we determined the antibacterial activity and 
antioxidant potential for some of the identified endophytic fungi strains. In addition, 
Fourier-transform infrared (FT-IR) spectroscopy was used predict the presence of 
various functional groups in the endophytic fungi crude extracts.

Material and methods

Collection and identification of plant materials

Fresh leaf and stem tissue of endophytic fungi were isolated from five leaf tissue samples 
and two stem tissue samples obtained from a single V. payos plant grown under natural 
(wild) conditions at the National Herbarium and Botanical Gardens (Harare, Zimba-
bwe). The tissue samples were pretreated by cleaning them under running water to 
remove dirt and soil particles, and then air dried to remove any surface moisture before 
they were packaged into labeled sterile sample collecting bags. The samples were then 
transported to the laboratory and stored at 4°C until endophyte isolation procedures 
could be instituted [8].

Isolation and establishment of in vitro culture of endophytes

Endophytic fungi were isolated from the leaf and stem tissues collected from the 
medicinal plant using a modified surface sterilization procedure as described by Kjer 
et al. 2010 [9]. The plant tissue samples were removed from storage and thawed by 
washing them using running tap water. The thawed plant tissue samples were then 
washed using 0.1% (v/v) Tween-80 for 15 minutes followed by another wash for 1.5 
hours using running water. The cleaned plant tissues were then transferred to a laminar 
airflow cabinet where the surface sterilization and endophyte isolation was conducted 
under aseptic conditions. The plant tissue samples were cut into 5-cm segments and 
surface-sterilized with 70% ethanol (30 seconds for leaf samples and 2 minutes for 
stem samples), soaked in 2% NaOCl solution for 15 minutes, rinsed four times with 
sterile double distilled water, and finally blot-dried using sterile paper towels. The 
effectiveness of the sterilization procedure was tested by plating 0.1 mL of the final 
sterile water rinse onto Petri dishes containing potato dextrose agar (PDA) and rolling 
the sterilized sample onto Petri dishes containing PDA. The surface-sterilized tissues 
were cut into smaller segments (1–2 cm) using sterile razor blades and placed onto 
Petri dishes containing PDA supplemented with 200 U mL−1 Penicillin-Streptomycin 
(Lonza, Basel, Switzerland; cat. No. 17-602E) and incubated at 28 ±2°C until fungal 
growth was initiated. The fungal mycelia growing out of the sample segments were 
subcultured and maintained on Petri dishes containing PDA.

Identification of the endophytic fungi

Genomic DNA was extracted from the cultures using the ZR Fungal/Bacterial DNA 
Kit (Zymo Research, Irvine, CA, USA; cat. No. D6005). The internal transcribed 



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Sibanda et al. / Endophytic fungi from Vitex payos

spacer (ITS) target region was amplified using EconoTaq PLUS GREEN 2X Master 
Mix (Lucigen, Madison, WI, USA) using the universal primers ITS1 and ITS4. The 
PCR reactions were carried out under the following conditions: initial denaturation at 
95°C for 15 minutes, 35 cycles at 95°C (denaturation) for 1 minute, 56°C (annealing) 
for 30 seconds, 72°C (extension) for 1 minute, and a final extension for 10 minutes at 
72°C. The PCR products were run on a gel and extracted (Zymo Research, Irvine, CA, 
USA; Zymoclean Gel DNA Recovery Kit; cat. No. D4001). The extracted fragments 
were sequenced in the forward and reverse directions using a BigDye Terminator v3.1 
Cycle Sequencing Kit (Applied Biosystems, ThermoFisher Scientific, Waltham, MA, 
USA) and purified (Zymo Research, ZR-96 DNA Sequencing Clean-up Kit; cat. No. 
D4050). The purified fragments were run on the ABI 3500xl Genetic Analyzer (Ap-
plied Biosystems, ThermoFisher Scientific). CLC Bio Main Workbench v7.6 was used 
to analyze the .ab1 files generated by the ABI 3500xl Genetic Analyzer and endophytic 
fungi isolates were identified on the basis of similarity of amplified sequence with those 
found in the U. S. National Center for Biotechnology Information (NCBI) database 
using the Basic Local Alignment Search Tool (nBLAST).

Secondary metabolite extraction

The small-scale fermentations and solvent extractions were carried as previously 
described [9] with modifications. Briefly, the fungi were cultivated in 500 mL of 
potato dextrose broth and were incubated at 28 ±2°C for 30 days in a shaker at 180 
rev min−1. The fungal mycelia were then separated from the culture broth by filtration 
and extracted with analytical grade methanol (MeOH) solvent (100 mL). The filtrate 
was then extracted three times at the liquid-liquid partition with an equal volume of 
analytical grade ethyl acetate (EtOAc) solvent (1:1 v/v). The resulting crude extracts 
were collected and concentrated to dryness in a vacuum rotary evaporator at 40–45°C, 
then dissolved in 1 mL of MeOH solvent, followed by drying under vacuum to obtain 
the EtOAc and MeOH extracts. The crude extracts were dissolved in dimethyl sulfoxide 
(DMSO) at a concentration of 1 mg mL−1 and kept at 4°C [10].

Determination of the antimicrobial activity of the crude extracts

The microorganisms were obtained from the American Type Culture Collection 
(ATCC, Rockville, MD, USA). The extracts were tested against the gram-positive 
bacteria Staphylococcus aureus (ATCC 11632), gram-negative bacteria Escherichia coli 
(ATCC1056) and Klebsiella pneumoniae (ATCC 13883) using the agar disk diffusion 
method using the Clinical and Laboratory Standards Institute protocol [11]. Briefly, the 
test microorganisms were grown in nutrient broth medium until 1 × 108 colony-forming 
units were attained and then were used to inoculate sterile 90-mm Petri dishes filled 
with nutrient agar medium using the spread-plate technique. Dried and sterile filter 
paper disks (6.0 mm diameter) were impregnated with 40 µL of the extracts (contain-
ing 500 µg fungal extracts), air dried under aseptic conditions in a laminar airflow 
cabinet, and placed on plates inoculated with the test microorganism. The plates were 
incubated at 37°C for 24 hours. Three sets of controls were used. The organism control 
consisted of a seeded Petri dish with no sample. In the second control, samples were 
introduced to the unseeded Petri dishes to check for sterility. Disks impregnated with 
40 µL DMSO were run simultaneously as a third control. Standard antibiotics were also 
run simultaneously as reference agents to understand the comparative antimicrobial 
efficacy. Three replicates per extract were used for the antimicrobial activity assays. 
The antimicrobial potency of the extracts was measured by their ability to prevent the 
growth of the microorganisms surrounding the disks.

Determination of total phenolic content of the crude extracts

The total phenolic content of the extracts was determined by the Folin–Ciocalteu 
method. Briefly, 0.2 mL of each crude extract (dissolved in DMSO at a concentration 



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Sibanda et al. / Endophytic fungi from Vitex payos

of 1 mg mL−1) was added to 2.8 mL of distilled water and mixed thoroughly with 0.5 
mL of Folin–Ciocalteu reagent for 3 minutes, followed by the addition of 2 mL of 20% 
(w/v) sodium carbonate. The mixture was left to stand for a further 60 minutes in the 
dark and absorbance was measured at 650 nm using a model I-290 spectrophotometer 
(Lasany, Panchkula, India). The total phenolic content was calculated from the calibration 
curve, and the results were expressed as mg of gallic acid equivalent per g dry weight. 
Three replicates per extract were used for the determination of total phenolic content 
and the mean values (±SD) were calculated.

Determination of the antioxidant activity of the crude extracts

The total antioxidant capacity (TAC) of the endophytic fungal extracts at 1 mg mL−1 
concentration was determined using the OxiSelect Total Antioxidant Capacity Assay 
Kit (Cell Biolabs, Inc., San Diego, CA, USA) using the manufacturer’s instructions. 
The method is based on the single electron transfer (SET) mechanism and involves 
the reduction of Cu2+ to Cu+ by the endogenous antioxidants and by other reducing 
equivalents in the sample. The Cu+ interacts with a coupling chromogenic reagent 
that produces a color with a maximum absorbance at 490 nm. The absorbance value is 
proportional to the total antioxidant (respectively reducing) capacity of extracts. The 
samples were analyzed spectrophotometrically at 490 nm using the SPECTROstar Nano 
microplate reader (BMG LABTECH, Ortenberg, Germany). TAC was determined 
using a calibration curve based on uric acid standards. The results were expressed as 
μM copper reducing equivalents (CRE). Three replicates per extract were used for the 
determination of the antioxidant activity of the crude extracts and the mean values 
(±SD) were calculated.

FT-IR analysis

Infrared spectra were collected on a Nicolet 6700 FT-IR spectrometer (Thermo Fisher 
Scientific) equipped with a diamond crystal attenuated total reflectance sampling 
accessory (Thermo Fisher Scientific). A few grams of the samples were placed on the 
attenuated total reflectance unit and scanned from 500 to 4,000 cm−1 with a resolution 
of 4 cm−1. Each recorded spectrum was the result of 36 coadded scans. FT-IR was 
performed to predict the presence of various functional groups in the isolates.

Data analysis

The colonization rate of endophytes was determined as the total number of segments 
yielding ≥ 1 isolates divided by the total number of segments from which endophytes were 
isolated (expressed as a percentage). The results for the antimicrobial and antioxidant 
activity and total phenolic content determination assays are expressed as the mean ±SD 
of triplicates (n = 3). Difference analysis (one-way ANOVA) of the antioxidant activity 
results was conducted using Microsoft Excel 2013 (Microsoft, USA). A p value <0.05 
was considered to indicate statistically significant differences between groups.

Results

Isolation of endophytic fungi

A total of seven endophytic strains were isolated from V. payos and the endophytic 
colonization rate was 100%. The isolated strains were identified (Tab. 1) and all found 
to belong to the phylum Ascomycota, except for Mucor circinelloides, which is a member 
of the phylum Zygomycota.



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Antimicrobial activity

None of the extracts exhibited antibacterial activity against the test microorganisms: E. 
coli (ATCC1056), K. pneumoniae (ATCC 13883), and S. aureus (ATCC11632) as well 
as strains of the same bacteria obtained from clinical samples.

Antioxidant capacity and total phenolic content

The antioxidant activity of EtOAc and MeOH extracts of the two representative isolates 
obtained from stem (E. nigrum; isolate TS2) and leaf (Diaporthe species; isolate TL3) 
tissues was determined. The EtOAc and MeOH extracts of the endophytic fungi E. 
nigrum both exhibited antioxidant activity, while for the Diaporthe species of endophytic 
fungi only the MeOH extract showed some antioxidant activity (Tab. 2). Data analysis 
revealed significant differences [F(2, 6) = 8,429.77, p < 0.00001 at the 0.05 alpha level] 
in the antioxidant activities of the studied extracts, whereas there was no significant 
difference [F(1, 4) = 5.495, p = 0.07902 at the 0.05 alpha level] in the total phenolic 
content between the EtOAc extract from E. nigrum and the MeOH extract from the 
Diaporthe species.

FT-IR analysis

The EtOAc extracts from E. nigrum that exhibited both the highest antioxidant and 
total phenolic content were further analyzed using FT-IR spectroscopy, which is a 
well-established tool for the characterization and identification of functional groups 
present in extracts. The FT-IR spectral analysis of the EtOAc extract of E. nigrum 
revealed the presence of multiple functional groups, including –OH, –CHO, –COOH, 

Tab. 1 Endophytic fungi isolated from the stems and leaves of V. payos.

Isolate code* Sequence similarity with % sequence similarity Accession number

TL1 Glomerella acutata 99 AM991137

TL2 Epicoccum nigrum 99 KX869952

TL3 Diaporthe sp. 98 KU671340

TL4 Penicillium chloroleucon 99 KP016813.

TL5 Diaporthe endophytica 96 AB899789

TS1 Mucor circinelloides 100 KC461495

TS2 Epicoccum nigrum 99 KX869952

* TL – endophyte isolated from leaf tissues; TS – endophyte isolated from stem tissues.

Tab. 2 Total phenolic content and antioxidant capacity of extracts obtained from E. nigrum and Diaporthe species*.

Endophyte Isolate code
Total phenolic content (TPC) 

(mg GAE/g extracta)
Total antioxidant capacity (TAC) 

1mg/mL [CREb (μM)]

Ethyl acetate extracts

Epicoccum nigrum TS2 2.97 ±0.13 231.23 ±2.03

Methanol extracts

Epicoccum nigrum TS2 0.50 ±0.01 32.28 ±2.96

Diaporthe species TL3 2.76 ±0.07 60.97 ±2.53

* Results are represented as means ±SD (n = 3). a Gallic acid equivalent; b copper reducing equivalent.



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and –COOR [12]. Important IR absorption frequencies obtained from the extracts are 
tabulated in Tab. 3.

Discussion

The observation that most of the isolated endophytic fungi belonged to genera in 
the phylum Ascomycota is in line with observations from other studies [13–15]. It is 
important to note that all the genera of endophytic fungi isolated from V. payos in this 
study have previously been isolated from a wide range of other different plant hosts 
in diverse environments, suggesting that these genera are not host and environment 
specific.

The obtained preliminary antimicrobial activity results suggest that the studied 
endophytic fungi do not have potential as sources of new antimicrobial agents against 
the assessed bacterial species. While this is disappointing, the results support the 
findings from other studies that not all endophytic fungi strains have antibacterial 
activity [16]. However, there is a need to assess the antibacterial activity of these strains 
against other test microorganisms, screen them for antifungal activity, and vary the 
fermentation conditions before we totally discount these strains as potential sources 
of new antimicrobial agents.

The EtOAc extract of the endophytic fungus E. nigrum exhibited both the highest 
antioxidant activity and total phenolic content. Endophytic and marine-derived strains 
of E. nigrum have been shown to have antioxidant activity [17,18]. This suggests that 
this species might be generally predisposed to produce natural antioxidants. Phenolic 
compounds have redox properties and are antioxidants owing to their hydroxyl groups 
that confer to them their free radical scavenging ability [15,19]. The total phenolic 
content and antioxidant activity results collected for the extracts obtained from the stem 
isolate of E. nigrum (TS2) suggest that phenolic content influenced antioxidant activity. 
However, there is a need for further studies to confirm this observation. Endophytic 
species of the genus Diaporthe have been reported to have antioxidant activity; our results 
for the MeOH extract of our Diaporthe leaf isolate tally with those observations.

Tab. 3 Major bands observed in the FT-IR spectra of the E. nigrum EtOAc extracts.

Wave number (cm−1) Vibration band/group Probable compound classes

3,600–3,300 Hydrogen-bonded O–H stretch Phenols, alcohols
3,000–2,500 H–C–H asymmetric and symmetric stretch Saturated aliphatic

O–H stretch Carboxylic acid
S–H stretch Thiols

1,820–1,680 C=O stretch Carbonyls, lactones
1,600–1,550 C–C=C symmetric stretch Aromatics

–C=N– Thiols and thio-substituted compounds
C=O Carbonyls

N–H bend Amines
Nitrogen-oxy Aromatic nitro compounds

1,500–1,450 C–C=C asymmetric stretch Aromatics
1,420–1,300 C=O Carbonyls

Aliphatic nitro compounds Hetero-oxy compounds
Dialkyl/aryl sulfones Sulfur-oxy compounds

1,250–1,000 C–O stretch Alcohols, Phenols
C–N Aliphatic amines
N–O Aromatic amine oxide
C=S Thiocarbonyl

Φ–O–H Aromatic ethers



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Biological activity of extracts is influenced by the functional groups present in the 
extracts. Hence, functional group analysis plays an important role in understanding the 
biological activity of extracts [20]. In the present study, the FT-IR spectral analysis of the 
E. nigrum crude EtOAc extracts suggests the presence of molecules carrying the bonded 
hydroxyl (–OH) functional group. The hydroxyl group is an integral part of most of the 
phenolic compounds, such as flavonoids and tannins. Therefore, the FT-IR results serve 
to provide further supporting evidence for the presence of phenolic compounds in the 
crude EtOAc extracts. The FT-IR spectra analysis also suggests that diverse groups of 
functional groups (and hence diverse classes of compounds) are potentially present in 
the extracts. This is in line with previous findings by other researchers that endophytic 
fungi produce diverse classes of metabolites [21–23]. However, it is important to note that 
further investigations using different techniques are required to identify the compounds 
present in the E. nigrum crude EtOAc extracts. To the best of our knowledge, this is 
the first reported work on the identification, antibacterial and antioxidant activities of 
fungal endophytes isolated from V. payos. The results of this study suggest that while 
fungal endophyte isolates obtained from V. payos have potential as sources of natural 
antioxidants, further research is required to isolate and identify the bioactive molecules 
from the crude extracts and evaluate in vivo their biological activities.

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	Abstract
	Introduction
	Material and methods
	Collection and identification of plant materials
	Isolation and establishment of in vitro culture of endophytes
	Identification of the endophytic fungi
	Secondary metabolite extraction
	Determination of the antimicrobial activity of the crude extracts
	Determination of total phenolic content of the crude extracts
	Determination of the antioxidant activity of the crude extracts
	FT-IR analysis
	Data analysis

	Results
	Isolation of endophytic fungi
	Antimicrobial activity
	Antioxidant capacity and total phenolic content
	FT-IR analysis

	Discussion
	References

		2018-12-06T17:03:54+0000
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