Clinical Isolate of Candida tropicalis from a Patient in North Carolina: Identification, Whole-Genome Sequence Analysis, and Anticandidal Activity of Ganoderma lucidum

Abstract

In North Carolina, candida infections are on the rise and pose a significant threat to human health in clinical settings. In addition, the rise of resistance to antifungal drugs has only heightened this concern. Importantly, misidentification of Candida spp. may result in underdiagnosis, patients getting the wrong treatment and incomplete infection prevention measures. The correct and rapid etiological identification of Candida infections is of paramount importance because it provides adequate therapy, reduces mortality, and controls outbreaks. Hence, this study aimed to identify Candida sp. up to species level of a clinical isolate from an infected patient treated in North Carolina using biochemical and molecular techniques. Due to the emergence of resistance, we explored whole genomic analysis to highlight polymorphisms that can impact candida resistance. Exploration for the effectiveness of bioactive compounds in natural products to treat Candida spp. resistant to present-day drugs could provide promising new treatment options for managing infected patients. Thus, this study also investigated anticandida activity of three solvent extracts of Ganoderma lucidum against the clinical isolate of Candida sp. The findings of this study provided evidence that Candida tropicalis MYA-3404 was the only strain present in the clinical isolate. The whole genome sequencing of C. tropicalis identified mutations in genes that most likely underscore drug resistance. All extracts from G. lucidum significantly (P < 0.05) inhibited the growth of C. tropicalis. Together, this work highlights the enormous potential of biochemical and molecular techniques in identifying clinical isolates of candida to species level and the use of bioactive compounds from extracts of G. lucidum as promising anticandidal agents. Further testing is needed to confirm the phenotypic expression of resistance.

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Ewunkem, A. , Merrills, L. , Williams, Z. , Maness, L. , Meixner, J. , Justice, B. , Iloghalu, U. , Williams, V. , Kiki, L. and Singh, D. (2025) Clinical Isolate of Candida tropicalis from a Patient in North Carolina: Identification, Whole-Genome Sequence Analysis, and Anticandidal Activity of Ganoderma lucidum. Open Journal of Medical Microbiology, 15, 11-35. doi: 10.4236/ojmm.2025.151002.

1. Introduction

Candida infection is a serious opportunistic infection, which affects the oral cavity, vaginal, skin, stomach, and other parts of the body [1]. Untreated candida infection may affect vital organs like the heart, brain and kidneys, causing life-threatening complications [2]. The rate of candida infection is increasing rapidly and close to 1.5 million people have invasive candidiasis each year, with 995,000 deaths (63.6%) [3]. Severe candidiasis can be life threatening to patients with a weak immune system due to the body’s reduced ability to fight infections. This lucidly explains why 90% of patients with HIV/AIDS develop candidiasis [4]. Candidiasis because of HIV remains a persistent problem in the US.

About 25,000 cases of candidiasis occur in the US annually with a 25% mortality rate during hospitalization [5]. The Centers for Disease Control and Prevention (CDC) recently issued a warning about the increase in cases across the US. This is a cause of concern because patients in the health care setting are more susceptible. Candida infections have been making headlines in North Carolina since February 2023. According to the North Carolina Department of Health and Human Services, new cases of a multi-drug-resistant Candida were reported in North Carolina in February 2023. All reported cases occurred in patients with serious comorbid health conditions and/or a history of prolonged hospitalization. Candida infections can spread easily in healthcare settings causing invasive infections associated with mortality rates of up to 60% [6].

Isolation and identification of Candida spp. are very important because they can initiate prompt appropriate treatment fundamental to proper management of infected patients [7]. Identification of Candida at the species level is necessary to help in selecting the appropriate medication for the treatment. Traditionally, germ tube test and chromogenic culture media, have been used to identify Candida spp since they are rapid, easy-to-perform methods and allow for quick preliminary identifications of potential Candida species in clinical samples. However, these methods only reliably identifying Candida albicans and not other Candida species, such as C. tropicalis. Further confirmatory tests, like biochemical or molecular methods, are needed for accurate identification of C. tropicalis. Misidentifying Candida species can lead to a patient getting incorrect medication or treatment potentially causing serious complications for the patient due to ineffective or suboptimal antifungal therapy.

Recommended antifungal treatment for candida infections are synthetic antifungal drugs such as nystatin, clotrimazole, amphotericin B, and miconazole [8]. However, there is a steady increment in resistance to these antifungal medications. Resistance is caused by the formation of biofilms in Candida, transition from planktonic to sessile and expression of resistance genes [9]. Antifungal resistance may account for the high rates of therapeutic failures and mortality frequently documented with those infections worldwide, which necessitates the search for natural products capable of combating candida infections.

Mushrooms have been shown to be some of the best sources of natural antimicrobials. Consumption of mushrooms has increased because of consumer preference of microbiologically safe food [10]. Mushrooms have also piqued the interest of scientists and the clinical community for two major reasons. Mushrooms can modulate the immune system and are efficacious against numerous diseases due to the presence of a plethora of bioactive compounds known to inhibit mycelial growth of pathogens [11]-[14]. Ganoderma lucidum, commonly known as the reishi, varnished conk, or ling chih, is currently one of the most widely used mushrooms [15] [16]. G. lucidum is used as nutraceuticals, functional foods and as alternatives to antioxidants and antimicrobial agents [14] [17]-[19]. An analysis of G. lucidum extract revealed a range of biologically active compounds (such as polysaccharides, triterpenes, flavonoids, alkaloids, steroids ganoderic acid and less beta [1]-[3] glucan) with medicinal properties which have been the focus of many studies [14] [19]. These compounds are shown to display anti-inflammatory and anticancer properties, antifibrotic effects, cytotoxic and inhibitory activities [20] [21]. Early studies in our laboratory showed that alcohol, aqueous and dual solvent extracts of G. lucidum inhibited to different extents Gram-positive and Gram-negative bacteria; the ethanolic extract exhibited the most potent antimicrobial activity [19]. In other previous studies, the aqueous extract of G. lucidum showed the highest antimicrobial activity of Candida albicans [22] [23]. There are no previous studies indicating that G. lucidum has an ability to kill or inhibit the growth of candida that are directly collected from infected patients (clinical isolates) in a laboratory setting. In contrast other mushroom species, for example Trametes spp. and Microporus spp. have demonstrated antimicrobial activity against clinical isolate of Candida albicans [24]. To the best of our knowledge, no studies have reported on the antimicrobial activity of alcohol, aqueous and dual solvent extracts of G. lucidum extracts against clinical isolation of Candida tropicalis from a hospital patient. In this study, the antimicrobial activity of alcoholic, aqueous and dual solvent extracts from wild G. lucidum was investigated against clinical isolate of Candida sp. from a hospital patient in North Carolina, United States of America. The study highlighted the phenotypical and molecular traits for identifying Candida spp. isolates. In addition, whole genome sequencing was used to identify mutations in resistance genes in the clinical isolate of Candida tropicalis. Identifying mutations in resistance genes allows scientists and health personnels to understand the mechanisms of drug resistance, predict the emergence of resistant strains, guide treatment decisions by selecting the most effective antifungal agents against specific resistance profiles, and develop new therapeutic strategies to combat the growing problem of antimicrobial resistance.

2. Materials and Methods

2.1. Collection, Identification of Ganoderma lucidum

The wild mushrooms of G. lucidum were collected from their natural habitats in Winston Salem, North Carolina, USA in August 2023. The demonstration samples were preserved in the Antimicrobial and Genomics Lab in the Department of Biological Sciences, Winston Salem State University where standard keys were used to identify the mushrooms.

2.2. Preparation of G. lucidum Mushroom Extracts

Fresh G. lucidum mushrooms were harvested, chopped, and dried in an oven at 40˚C - 45˚C. The dried fruit body was blended to obtain mushroom powder. Mushroom extraction was carried out using 80% ethanol (Fisher Scientific, USA) and distilled water solvents following the protocol of Ewunkem et al. [19]. Briefly, the mushroom powder was weighed (100 g) and extracted by stirring with 500 ml of 80% ethanol or distilled water at 50˚C for 48 hours. Dual extraction was prepared by initial extraction in ethanol (Fisher Scientific, USA) at 50˚C for 48 hours and finally in equal volume of distilled water at 50˚C temperature for 48 hours. The obtained extracts were separated through centrifugation (4200× g, 30 min) and stored at 4˚C in 1L amber bottles prior to analysis.

2.3. High Performance Liquid Chromatography (HPLC) Analysis

HPLC analysis determined the bioactive compounds of aqueous and ethanol extracts of G. lucidum as described previously [14] [19]. HPLC was carried out on an Agilent 1100 series system equipped with a quaternary rapid separation pump (LPG-3400RS) and photodiode array detector (DAD-3000RS). Chromatography was performed in isocratic mode and the mobile phase consisted of HPLC water (A) and acetonitrile (B) using a gradient program at a flow rate of 1 mL/min. Aqueous extract and alcohol extracts of G. lucidum contents were determined based on the standard curves. Separation was performed using C18 column (4.6 mm × 250 mm i.d., 5 μm) at 35˚C with a flow rate of 1 ml/min. The multi-wavelength detector was monitored at 280 nm.

2.4. Tested Microbial Strains and Culture Conditions

The Candida sp. used in this study was isolated from a patient with suspected candida infection treated at Wake Forest Medical Center, Winston Salem State University and stored at −80˚C in tryptic soy broth with 20% glycerol for further investigation. The clinical isolate was a gift from the Department of Medical Laboratory Science (MLS), Winston Salem State University. To safeguard patients’ confidentiality, the department policy strictly prohibits the collection of any patient identifiers, including names, medical record numbers, dates of birth, contact information, or any other details that could potentially lead to patient identification to ensure that Health Insurance Portability and Accountability Act (HIPAA) is not violated. HIPAA is a federal law that protects the security and confidentiality of a patient’s health information. The candida strain was cultured on Potato Dextrose Agar (PDA), that consisted of the following ingredients in (g/L): Potato extract (200), dextrose (20) and agar (15) at a temperature of 35˚C and preserved in Potato Dextrose Broth (PDB) supplemented with 50% glycerol at a temperature of −80˚C for subsequent analysis.

2.5. Isolation and Identification of the Candida sp. Clinical Isolates

The Candida strain was directly inoculated onto blood agar (Fisher Scientific, USA) using 10 μL the culture YEPD broth and incubated at 35˚C for 24 hours. Additional identification was performed utilizing the germ test where a suspension was made in a tube containing 0.5 mL of human plasma with a colony of Candida sp. sample and incubated at 35˚C for 3 h after which a drop of suspension was placed on labeled microscope slides for examination of blastoconidia. To examine cell morphology, samples were prepared as described previously, Ewunkem et al. [19]. Briefly, morphotypes of the strain were fixated with 2.5% glutaraldehyde in 0.1 M phosphate buffer (pH 7.2) for overnight at 4˚C followed by series of ethanol gradients: 0%, 50%, 70%, 80%, 90%, and twice with 100%. Then, the samples were dehydrated with acetone twice for 30 seconds until dried by the critical point method in liquid CO2. Subsequently, the specimens were coated with gold in a vacuum evaporator and examined with a scanning electron microscope (JEOL’s new Field Emission Scanning Electron Microscope, the JSM-IT800). The identification of Candida sp. was further confirmed by Multilocus sequence typing (MLST), a highly accurate and portable system for distinguishing between isolates of a microbial species as previously described [25].

2.6. Molecular Characterization of Clinical Isolates of Candida sp.

Candida isolation and purification of genomic DNA were performed at SeqCoast Genomics, Portsmouth, New Hampshire, USA. SeqCoast Genomics is an expert-guided genomics center offering microbial and small genome sequencing and bioinformatic analysis services. Isolation and purification were done using the DNeasy 96 PowerSoil Pro QIAcube HT Kit (Qiagen 47021, Hilden, Germany) as per manufacturer instructions. Strain identification based on sequencing was performed on the Illumina NextSeq2000 platform using a 300-cycle flow cell kit to produce 2x150bp paired reads. A quality check for raw reads was performed with FASTQC and reads were trimmed and paired using Trimmomatic (version 0.39.0) and Breseq (version: 0.37.0) [26].

2.7. Determination of Antimicrobial Activities of G. lucidum

Antimicrobial effects of ethanol extract, aqueous and dual extracts of G. lucidum mushroom against Candida sp. were investigated using broth microdilution method in 96-well plates. 200 ul of nutrient broth containing appropriate concentration of the extract of G. lucidum was added to each well, except for the controls. Next, a 10 μL suspension of microbial cells (8 × 106 cells/mL) was added to each well; the sterility control well contained 100 mL of the nutrient broth, and the growth control well had 190 μL of medium and 10 μL of the candida suspension. The test was carried out in triplicate. The 96-well plates that contained Candida sp. were incubated at 35˚C. The growth was assessed by measuring turbidity at 600 nm for hours 0, 3 and 24 h using a Glomax multi plate reader (Promega, USA). Examination of the morphological changes of Candida sp. was performed using a scanning electron microscope (SEM) following the methods described by Ewunkem et al. [14] and Ewunkem et al. [19].

3. Results

3.1. HPLC of Aqueous and Ethanol Extracts of G. lucidum

HPLC analysis of aqueous and ethanol extracts of G. lucidum extracts showed the presence of various bioactive compounds [19]. The three predominant bioactive compounds included beta [1]-[3] glucans, ganoderic acid and triterpenoids, with beta [1]-[3] glucan being most abundant followed by ganoderic acid.

3.2. Identification of Candida sp.

Identification of Candida sp. was carried out using phenotypic and molecular methods. When grown in human plasma at 37˚C for 3 hours, they did not form germ tubes, detected as hyphae with no constrictions where the structures join the blastoconidia (Figure 1(a)). The blastoconidia were typically about around 2-5 micrometers in diameter, appeared as budding oval yeast-like cells under microscopy suggesting Candida tropicalis. When grown on bacteriological media (sheep blood agar and Nutrient broth agar), a presumptive identification of Candida tropicalis was made when they appeared as small, round, creamy colonies on blood agar (Figure 1(b)). SEM analysis of the clinical isolates of Candida sp. revealed round to oval shaped smooth-walled bodies less than 5 µM (Figure 2). The molecular results confirmed that C. tropicalis was the only strain found in the clinical sample (Table 1).

3.3. Whole-Genome Sequencing

To investigate the genetic characteristics of C. tropicalis, the genome of C. tropicalis was sequenced and analyzed to detect any polymorphisms associated with multidrug resistance. Polymorphisms were observed with all frequencies of mutations and locations reported in Table 2. Specifically, these polymorphisms occurred in: staphyloferrin A export MFS transporter/D‑ornithine‑‑citrate ligase SfaD (sfaA/sfaD); adenine phosphoribosyltransferase (KQ76_RS08360); teichoic

Figure 1. The morphological features of Candida tropicalis recovered from clinical specimens at the Wake Forest Medical Center, Winston Salem, North Carolina USA (a) Candida tropicalis showing blastoconidia in single or branched chains, with abundant pseudohyphae in human plasma under a light microscope (400×); (b) Cream-colored smooth colonies, after 24 h of incubation at 35˚C grown on the blood agar.

Figure 2. Scanning electron micrographs of Candida tropicalis clinical strain’s morphologies at ×2.00 k (A) and at ×5.00 k (B). C. tropicalis shows budding phenotype after 24 h incubation at 35˚C in YEPD medium.

Table 1. Identification of Candida strains by strain typing.

# Assembly name: ASM633v3

# Organism name: Candida tropicalis MYA-3404 (budding yeasts)

# Infraspecific name: strain=MYA-3404

# Taxid: 294747

# BioSample: SAMN02953608

# BioProject: PRJNA13675

# Submitter: Broad Institute

# Date: 2009-06-18

# Assembly type: haploid

# Release type: major

# Assembly level: Scaffold

# Genome representation: full

# WGS project: AAFN02

# Genome coverage: 8.85x

# Sequencing technology: ABI

# RefSeq category: Representative Genome

# GenBank assembly accession: GCA_000006335.3

# RefSeq assembly accession: GCF_000006335.3

# RefSeq assembly and GenBank assemblies identical: yes

#

## Assembly-Units:

## GenBank Unit Accession

RefSeq Unit Accession

Assembly-Unit name

## GCA_000006345.3

GCF_000006345.3

Primary Assembly

## GCA_000348035.1

GCF_000348035.1

non-nuclear

#

# Ordered by chromosome/plasmid; the chromosomes/plasmids are followed by

# unlocalized scaffolds.

# Unplaced scaffolds are listed at the end.

# RefSeq is equal or derived from GenBank object.

#

# Sequence-Name

Sequence-Role

Assigned- Molecule

Assigned- Molecule- Location/Type

GenBank-Accn

Relationship

RefSeq-Accn

Assembly-Unit

Sequence-Length

UCSC-style-name

supercont3.1

unplaced-scaffold

na

na

GG692395.1

=

NW_003020038.1

Primary Assembly

2474448

na

supercont3.2

unplaced-scaffold

na

na

GG692396.1

=

NW_003020049.1

Primary Assembly

2308670

na

supercont3.3

unplaced-scaffold

na

na

GG692397.1

=

NW_003020055.1

Primary Assembly

2216334

na

supercont3.4

unplaced-scaffold

na

na

GG692398.1

=

NW_003020056.1

Primary Assembly

1654078

na

supercont3.5

unplaced-scaffold

na

na

GG692399.1

=

NW_003020057.1

Primary Assembly

1368217

na

supercont3.6

unplaced-scaffold

na

na

GG692400.1

=

NW_003020058.1

Primary Assembly

1255791

na

supercont3.7

unplaced-scaffold

na

na

GG692401.1

=

NW_003020059.1

Primary Assembly

920995

na

supercont3.8

unplaced-scaffold

na

na

GG692402.1

=

NW_003020060.1

Primary Assembly

802573

na

supercont3.9

unplaced-scaffold

na

na

GG692403.1

=

NW_003020061.1

Primary Assembly

498422

na

supercont3.10

unplaced-scaffold

na

na

GG692404.1

=

NW_003020039.1

Primary Assembly

430102

na

supercont3.11

unplaced-scaffold

na

na

GG692405.1

=

NW_003020040.1

Primary Assembly

419327

na

supercont3.12

unplaced-scaffold

na

na

GG692406.1

=

NW_003020041.1

Primary Assembly

125861

na

supercont3.13

unplaced-scaffold

na

na

GG692407.1

=

NW_003020042.1

Primary Assembly

22644

na

supercont3.14

unplaced-scaffold

na

na

GG692408.1

=

NW_003020043.1

Primary Assembly

12816

na

supercont3.15

unplaced-scaffold

na

na

GG692409.1

=

NW_003020044.1

Primary Assembly

11214

na

supercont3.16

unplaced-scaffold

na

na

GG692410.1

=

NW_003020045.1

Primary Assembly

11104

na

supercont3.17

unplaced-scaffold

na

na

GG692411.1

=

NW_003020046.1

Primary Assembly

8471

na

supercont3.18

unplaced-scaffold

na

na

GG692412.1

=

NW_003020047.1

Primary Assembly

8448

na

supercont3.19

unplaced-scaffold

na

na

GG692413.1

=

NW_003020048.1

Primary Assembly

7285

na

supercont3.20

unplaced-scaffold

na

na

GG692414.1

=

NW_003020050.1

Primary Assembly

6389

na

supercont3.21

unplaced-scaffold

na

na

GG692415.1

=

NW_003020051.1

Primary Assembly

6342

na

supercont3.22

unplaced-scaffold

na

na

GG692416.1

=

NW_003020052.1

Primary Assembly

5408

na

supercont3.23

unplaced-scaffold

na

na

GG692417.1

=

NW_003020053.1

Primary Assembly

4896

na

supercont3.24

unlocalized- scaffold

MT

Chromosome

GG692418.1

=

NW_003020054.1

non-nuclear

50304

na

Table 2. Genomics analysis of clinical isolate of Candida tropicalis.

Position

Freq (%)

Annotation

Gene

Gene product

2,228,365

69.2

intergenic (‑35/‑67)

sfaA/sfaD

staphyloferrin A export MFS transporter/D‑ornithine‑‑citrate ligase SfaD

1,700,478

65.6

G59S (GGC→AGC)

KQ76_RS08360

adenine phosphoribosyltransferase

1,017,325

65.3

Q304* (CAA→TAA)

fmtA

teichoic acid D‑Ala esterase FmtA

342,330

62.0

I180I (ATT→ATC)

KQ76_RS01520

DUF3169 family protein

2,574,726

32.2

G69A (GGC→GCC)

KQ76_RS13020

alpha/beta hydrolase

2,389,192

32.0

R188P (CGA→CCA)

hssR

DNA‑binding heme response regulator HssR

1,213,003

31.3

E184D (GAG→GAC)

ylqF

ribosome biogenesis GTPase YlqF

860,322

31.3

E344K (GAA→AAA)

dltB

PG:teichoic acid D‑alanyltransferase DltB

2,228,366

30.8

intergenic (‑36/‑66)

sfaA/sfaD

staphyloferrin A export MFS transporter/D‑ornithine‑‑citrate ligase SfaD

2,252,747

29.9

intergenic (‑54/+157)

KQ76_RS11280/ KQ76_RS11285

M23 family metallopeptidase/HAD‑IIB family hydrolase

391,361

29.1

S36I (AGT→ATT)

KQ76_RS01815

general stress protein

810,694

29.0

M1K (ATG→AAG)

smpB

SsrA‑binding protein SmpB

1,536,460

27.5

Y112* (TAT→TAA)

KQ76_RS07375

phage major capsid protein

1,027,271

27.0

A87P (GCA→CCA)

purS

hosphoribosylformylglycinamidine synthase subunit PurS

2,776,116

26.7

H117Q (CAT→CAA)

mnmG

tRNA uridine‑5‑carboxymethylaminomethyl(34) synthesis enzyme MnmG

2,574,727

26.6

G69R (GGC→CGC) ‡

KQ76_RS13020

alpha/beta hydrolase

2,564,194

26.6

A17P (GCA→CCA)

KQ76_RS12955

D‑lactate dehydrogenase

2,190,680

25.7

T500S (ACG→TCG)

KQ76_RS10985

BglG family transcription antiterminator

2,389,185

25.4

D186H (GAT→CAT)

hssR

DNA‑binding heme response regulator HssR

2,408,432

25.4

E212Q (GAA→CAA)

KQ76_RS12180

magnesium transporter CorA family protein

acid D‑Ala esterase FmtA (fmtA); DUF3169 family protein (KQ76_RS01520); alpha/beta hydrolase (KQ76_RS13020); DNA‑binding heme response regulator HssR (hssR); ribosome biogenesis GTPase YlqF (ylqF); PG: teichoic acid D‑alanyltransferase DltB (dltB); staphyloferrin A export MFS transporter/D‑ornithine‑citrate ligase SfaD (sfaA/sfaD); M23 family metallopeptidase/HAD‑IIB family hydrolase (KQ76_RS11280/KQ76_RS11285); general stress protein (KQ76_RS01815); SsrA‑ binding protein SmpB (smpB); phage major capsid protein (KQ76_ RS07375); hosphoribosylformylglycinamidine synthase subunit PurS (purS); tRNA uridine‑ 5‑carboxymethylaminomethyl(34) synthesis enzyme MnmG (mnmG); alpha/beta hydrolase (KQ76_RS13020); D‑lactatedehydrogenase (KQ76_RS12955); BglG family transcription antiterminator (KQ76_RS10985); DNA‑binding heme response regulator HssR (hssR); magnesium transporter CorA family protein (KQ76_RS12180) and magnesium transporter CorA family protein (KQ76_RS12180).

3.4. Anticandidal Activity of Aqueous Ethanol and Dual Extracts of G. lucidum Against C. tropicalis

The effectiveness of aqueous, ethanol and dual extracts of G. lucidum against C. tropicalis was observed within the first 3 hours of incubation. The anticandidal activity of each extract of G. lucidum increased with concentration (0% < 10% < 20% - 30%) (Figure 3). Each tested concentration exhibited significant (P < 0.05) effect over the control. Overall, the most effective concentration on the C. tropicalis was observed with the aqueous extract.

3.5. Scanning Electron Microscopy (SEM) Observation

Given the antimicrobial efficacy of G. lucidum against C. tropicalis, the morphological features of C. tropicalis before and after exposure to the aqueous, ethanol and dual extracts G. lucidum were evaluated by SEM. The SEM images of treated C. tropicalis cells or untreated with G. lucidum are shown in Figure 4. In the untreated C. tropicalis cells, a smooth and intact surface was clearly visible (Figure 4(a)). On the other hand, considerable morphological changes including cell membrane damage, collapse in their cell wall, deformation and shrinkage were seen in C. tropicalis treated with G. lucidum (Figures 4(b)-(d)).

4. Discussion

The rise of antibiotic-resistant candida infections is an emerging issue in North Carolina that presents a serious threat among hospital patients. Candida spp.

Figure 3. Antimicrobial activity of ethanolic, aqueous, and dual solvent extractions of G. lucidum against C. tropicalis after 3 h and 24 h of incubation. The growth of C. tropicalis was measured by a spectrophotometer at 600 nm wavelength. EE = ethanol extract; WE = water extract or aqueous extract; DE = dual extract. Asterix (*) indicates significant difference compared with control (P < 0.05).

colonize patients (especially those with multiple predisposing factors) for months to years and are often multidrug-resistant let alone difficult to identify with standard laboratory methods [6] [27]. Misidentification may sometimes lead to inappropriate management and cause multiple outbreaks in healthcare settings. In the present study, a clinical isolates of Candida sp. were obtained from a hospitalized patient diagnosed with candidiasis in Winston Salem, North Carolina, USA. Generally, isolation and identification of Candida spp. in a diagnostic laboratory includes culture, germ-tube generation in plasma, and molecular techniques [28]. We used three different methods (two phenotypic and one molecular) for the

Figure 4. Scanning electron microscopy micrographs of C. tropicalis and control groups after incubation with various G. lucidum extracts at 24 h. (a) C. tropicalis control cell with normal surface; (b) ethanol extract treated C. tropicalis with surface irregularities; (c) water extract treated C. tropicalis with surface irregularities; (d) dual solvent extraction treated C. tropicalis with surface irregularities.

identification of a Candida sp. isolated from the clinical sample. A presumptive identification of Candida tropicalis was made by observing round and cream-colored colonies on blood agar after 24 h of incubation.

Blood agar is a rich, complex medium used in medical diagnostics labs to grow and identify various bacterial pathogens as well as rapidly growing fungi including Candida. Blood agar media are generally prepared using tryptic soy agar with either 5% of sheep, rabbit, or horse blood. Blood agar plates can also identify microbes that produce hemolysins, enzymes that damage erythrocytes. Candida strains are known to exhibit hemolytic activity thus restoring the transferrin-inhibited growth of Candida. Typically, the colonies of Candida sp. on blood agar vary in appearance depending on the strain [29]. For example, C. tropicalis has creamy colonies that differ from other Candida spp. C. albicans are creamy grey with projections, or “feet”, that extend from the colony margins into the agar while C. glabrata produces relatively pink or dark purple, small colonies with pigments that may diffuse into the surrounding agar.

The presumptive C. tropicalis that demonstrated characteristic morphology was examined by germ-tube test, microscopy, and molecular technique to confirm its positive identity in the patient’s sample. The germ tube test is a screening test or a diagnostic tool that helps differentiate Candida spp. [30]. Blastoconidia of C. albicans are typically 2 - 8 μm in diameter and larger than blastoconidia (1 - 4 μm) of C. glabrata. Blastoconidia of C. dubliniensis are smooth-edged and viscid, made up entirely of blastoconidia. It should be noted that the blastoconidia are noticeably smaller than the blastoconidia of C. albicans and may appear round or oval confirming our results (Figure 1(a)) [31]. In general Candida spp. that form blastoconidia are commensal in nature but become opportunistic pathogens causing opportunistic infections when the blastoconidia convert into the hyphal form through morphogenesis [32]. In addition, the transition of blastoconidia to hyphae is linked to resistance against certain antifungal drug due to cell wall changes, biofilm architecture, efflux pump and metabolic plasticity [33] [34]. Whole genome sequencing, therefore, will undoubtedly be a useful tool to pinpoint specific genetic sequences within the genome of C. tropicalis genome that code for resistance.

The whole genome sequencing analysis of the clinical isolate of Candida sp. was used to identify genetic mutations associated with resistance to antifungal drug. The clinical isolate contains four resistance genes, staphyloferrin A export MFS transporter/D‑ornithine‑‑citrate ligase (sfaA/sfaD); adenine phosphoribosyltransferase (KQ76_RS08360), Ribosome biogenesis GTPase YlqF (ylqF) and BglG family transcription antiterminator (KQ76_RS10985) [35]-[40]. Staphyloferrin A export MFS transporter/D‑ornithine‑‑citrate ligase (sfaA/sfaD) plays an important role in multidrug resistance by transporting substances either down their concentration gradient or uphill using the energy stored in the electrochemical [36] [41]. Ribosome biogenesis GTPase YlqF (ylqF) facilitates structural changes and protein interaction ensuring protein synthesis which is essential for Candida’s growth and survival [39]. Targeting ribosome biogenesis GTPases could be a potential strategy for developing new drugs against Candida infections [37]. BglG family transcription antiterminator (KQ76_RS10985) controls gene expression, adaptation, and the ability to overcome antifungal therapy [35] [40]. Polymorphisms in staphyloferrin A export MFS transporter/D‑ornithine‑‑citrate ligase (sfaA/sfaD); adenine phosphoribosyltransferase (KQ76_RS08360), Ribosome biogenesis GTPase (ylqF) and BglG family transcription antiterminator (KQ76_RS10985) contribute to antifungal resistance by allowing Candida to evade the drug’s effects, often through mutations in genes associated with drug uptake, efflux pumps, or the target molecule itself, leading to decreased susceptibility to antifungal medications. Studying genetic polymorphisms in Candida allows for better understanding of resistance mechanisms and helps in monitoring the emergence of resistant strains. Furthermore, insight into the genetic basis of resistance can guide the development of new antifungal drugs that target different pathways or overcome known resistance mechanisms. The fact that polymorphisms were found in the clinical isolate strengthens the argument that pathogenic candida represents one of the most frequent causes of fungal infections, associated with high morbidity and mortality in the healthcare system [41]. Antibiotic-resistant candida can be difficult to treat hence the use of natural products can be extremely successful in the discovery of new medicine. In this context, extracts of Ganoderma lucidum, which remain unexplored in this area, might be a valuable resource in the search of new bioactive extracts/compounds which have already demonstrated antibacterial activity [14] [19].

A whole genomic analysis also showed mutations in eight genes dedicated to transport and metabolism, synthesis, invasion, oxidative stress, and energy production. These genes included adenine phosphoribosyltransferase (KQ76_RS08360), DUF3169 family protein (KQ76_RS01520); alpha/beta hydrolase (KQ76_RS13020); DNA‑binding heme response regulator HssR (hssR); Hosphoribosylformylglycinamidine synthase subunit PurS (purS); tRNA uridine‑5‑carboxymethylaminomethyl (34) synthesis enzyme MnmG (mnmG); D‑lactate dehydrogenase (KQ76_RS12955); magnesium transporter CorA family protein (KQ76_RS12180). Adenine phosphoribosyltransferase (KQ76_RS08360) catalyzes a salvage reaction resulting in the formation of AMP, that is energetically less costly than de novo synthesis [42]. DUF3169 family protein (KQ76_RS01520) is required for penetration of the host cells [43]. Alpha/beta hydrolase (KQ76_RS13020) plays a pivotal role in lipid metabolism [44]. DNA‑binding heme response regulator HssR (hssR) is a transcriptional activator that plays an important role in the activation of genes required for respiration and oxidative stress and genes necessary for uptake and utilization of iron [45] [46]. Hosphoribosylformylglycinamidine synthase subunit PurS (purS) is vital to produce purine nucleotides building blocks for DNA and RNA [47]. tRNA uridine‑5‑carboxymethylaminomethyl (34) synthesis enzyme MnmG (mnmG) is responsible for proper tRNA function in translation [48]. D‑lactate dehydrogenase (KQ76_RS12955) functions as an enzyme that converts D-lactate into pyruvate, essentially allowing the fungus to utilize D-lactate as a carbon source for energy production, particularly in environments where other sugars might be limited; this process is important for its survival and adaptation to different host conditions [49]. Magnesium transporter CorA family protein (KQ76_RS12180) controls the transport of divalent ions such as magnesium ions across the membrane [50]. Typically, Candida and other yeast must adapt to various host microenvironments during colonization of the host. Furthermore, genetic mutations of candida genes underline the rapid evolution of this aggregative phenotype [51]. Mutations in these genes could have enhanced some important pathogenicity factors of candida which allow colonization, adhesion, invasion, and damage to the host tissues. Additionally, polymorphisms of genes associated with transport and metabolism, synthesis, invasion, oxidative stress, and energy production in the clinical isolate of Candida sp. might have enabled the pathogen to grow, survive, and adapt to changing environmental conditions. Therefore, healthcare facilities should monitor candida infections in patients for such polymorphisms. In our study a clinical isolate of Candida sp. was identified as C. tropicalis. C. tropicalis is known to colonize the ears, wounds, respiratory tracts, urinary tracts, and skin of immunocompetent individuals, and can also cause serious bloodstream and/or invasive infections largely in immunocompromised patient [52] [53].

Finally, mutations in four genes not associated with fungi were found in this clinical isolation of Candida tropicalis. One mutated gene was teichoic acid D‑Ala esterase FmtA (fmtA), which is not typically found in fungi because teichoic acids are a unique structural component of Gram-positive bacteria cell walls. D‑Ala esterase reduces the positive charge on the cell surface, impacting resistance to cationic antimicrobial peptides and contributing to overall bacterial survival [54]. PG:teichoic acid D‑alanyltransferase DltB (dltB) is linked to bacterial virulence contributing to resistance against host immune responses [55]. M23 family metallopeptidase/HAD‑IIB family hydrolase (KQ76_RS11280/KQ76_RS11285) plays a crucial role in breaking down the bacterial cell wall peptidoglycan by cleaving specific bonds within its structure [56]. SsrA‑binding protein SmpB (smpB) has a high affinity to protect bacteria from degradation and prevent secondary structure formation [57]. Phage major capsid protein (KQ76_RS07375) protects and encapsulates the viral genome, forming the structural shell of the virus particle, allowing for delivery of the genetic material to a host cell [58].

The presence of mutations in genes associated with bacteria in Candida, known as “bacteria genes in Candida”, is due to complex interactions between bacteria and Candida species where certain bacterial factors can influence the behavior and virulence of Candida. This interaction is very common in mixed microbial communities like the gut microbiome where bacteria and Candida coexist and can influence each other’s activity which may facilitate virulence and pathogenicity in both pathogens. For example, the interactions can either enhance or suppress candida virulence depending on the specific bacterial species and environmental conditions [59]. For instance, the interaction between C. albicans and Viridans streptococci is important for candida colonization affect polymicrobial biofilm virulence mechanisms, adhesion, invasion, and antimicrobial resistance [60] [61]. These findings suggest that patients with Candida infections may have higher rates of bacterial infections. Understanding trans-kingdom interactions may help identify novel strategies to treat infectious diseases. The presence of bacterial genes in the patience samples may not only represent the presence of bacterial infections, it may also represent sample bacterial contamination in the hospital setting, as hospitals have a high prevalence of bacteria on surfaces and in the air, which can easily contaminate clinical isolates of Candida cultures if proper aseptic techniques are not followed during sample collection and handling; this can potentially compromise the accuracy of the Candida identification and susceptibility testing. This may require careful interpretation of the report, ranging from sample contamination to urinary tract infections, including disseminated candidiasis. Scanning Electron Microscopy (SEM) can provide strong visual clues.

In this study, scanning electron microscopy (SEM) was used to study the morphology of the clinical isolate of Candida sp. SEM has been used to analyze the morphologies of clinical isolates of Candida strains [62] [63]. SEM images of clinical isolates from our patients appeared round to oval-shaped yeast cells with filamentous structures (hyphae). These data are in accordance with the results generated by Ma et al. [64] who described the morphology of C. albicans and C. tropicalis using SEM. In the control cultures, C. tropicalis and C. albicans were round or oval with smooth surface and 2 - 5 μm in diameter. Strain typing is a highly accurate tool for detecting Candida strains in clinical isolates such as C. albicans, C. glabrata, and C. tropicalis and C. krusei [65]-[68]. In this study stain typing confirmed the presence of C. tropicalis MYA-3404 in the clinical isolate from the patient.

C. tropicalis MYA-3404 is a diploid opportunistic pathogenic yeast, whose genome size is 14.5 Mb and contains 6258 genes encoding proteins and a guanine-cytosine content of 33.1% [69]. C. tropicalis causes both superficial and systemic infections in humans and has been increasingly isolated as the cause of invasive candida infections, ranking as the third most isolated species in patients with Candida infection [70] [71]. C. tropicalis has various virulence factors such as the morphological transition from yeast cell to hyphae, the production of extracellular hydrolytic enzymes (such as phospholipase, proteinase and hemolysin), biofilm formation and phenotypic switching [72] [73].

Candida infections kill more than one million people each year and are challenging to eliminate despite the existence of antifungal treatments. Infections with C. tropicalis are treated with several classes of antifungal drugs such as azoles, echinocandins, and amphotericin B [74]. These drugs work by inhibiting enzymes that produce the fungal cell membrane, causing the membrane to become unstable and leak, leading to cell death [75]. Furthermore, some anticandidal drugs can target the synthesis of chitin, a major component of the fungal cell wall [76]. However, resistant strains of C. tropicalis are commonly detected in patients, demanding an urgent need for new treatments. Mushroom extracts are a potential alternative because they contain bioactive compounds and secondary metabolites such as beta [1]-[3] glucans, ganoderic acid and triterpenoids that can kill or inhibit the growth of pathogens [19] [77] [78]. The bioactive compounds can act individually or in synergism to inhibit growth [79]. The present study involved G. lucidum extracts using water, ethanol and dual extracts (combined water and ethanol) and investigated activity against C. tropicalis. The water extract showed strongest anticandidal activity compared to the water and dual extracts. This may be due to the higher proportion of water-soluble bioactive compounds in G. lucidum mushroom [80]. A previous study indicated that G. lucidum and Pleurotus ostreatus ethanolic extracts showed a greater antimicrobial activity than water extracts [81].

Antimicrobial activity of extracts can affect the morphology of cells often frequently causing visible changes [82]. Scanning electron microscopy (SEM) is used to visualize the morphological changes in cells exposed to antimicrobial extracts [19] [83]. In this study, SEM was used to confirm the antimicrobial activity of extracts against C. tropicalis. Regardless of the extraction method SEM images of C. tropicalis treated with these extracts showed altered morphology and loss of cell integrity. This can be explained by the interaction of the bioactive compounds [19] and metabolites of G. lucidum extracts with C. tropicalis organelles and cellular process. Studies have shown that bioactive compounds and secondary metabolites can disrupt membrane permeability or redox balance and inhibit cell wall synthesis [84]. These results are in agreement with Pereira et al., [85] who showed that aqueous and methanolic extracts of Macrocybe titans extracts caused morphological changes and slight damage to C. albicans.

However, this study has potential limitations, for example, the study is based on testing an isolate obtained from a single patient instead of different clinical samples. A single isolate may not represent the entire candida population within a patient, potentially leading to misinterpretation of resistance patterns. Also, the site of sample collection can influence the type of Candida isolated, potentially not reflecting the full range of pathogens involved in an infection. Furthermore, a key a limitation of using clinical isolates is that they only represent a snapshot of the species of Candida present in a designated patient at a predetermined time, potentially not capturing the full spectrum of resistant strains. Resistant strains are influenced by antibiotic usage, leading to skewed susceptibility patterns if not carefully interpreted. The process of isolating and testing clinical isolates can be time-consuming and perhaps not always accurately reflect the in vivo dynamics of infection. In vivo antimicrobial susceptibility testing was performed in controlled laboratory conditions, which may not fully reflect the complex environment of the human body. Interpreting the antimicrobial results without considering the clinical context, such as patient factors and infection site, can lead to inappropriate treatment choice. No invitro tests were performed for antifungal sensitivity. We are currently performing some invitro antifungal sensitivity test to compare the invitro susceptibility data with the molecular findings.

5. Conclusion

In North Carolina, candida infections are an emerging public health concern due to their potential for multi-drug resistance. Moreover, candida infections can rapidly spread in health care settings, leading to outbreaks with high mortality rates among vulnerable patients. There are multiple species of candida that can cause infections in hospitals and correct identification can directly lead to better outcomes, ensuring that the patient receives the appropriate medical care, preventing potential errors like administering wrong medications. Specific identification of candida is crucial for optimal treatment. This study aimed to identify Candida up to species level of a clinical isolate from a patient treated in a local medical center in Winston Salem, North Carolina. Additionally, whole genomic sequencing was performed to identify resistance genes. Moreover, the study assessed the antimicrobial activities of three solvent extracts of G. lucidum mushroom extract against the clinical isolate of Candida sp. The findings of this study provide evidence that Candida tropicalis MYA-3404 was the most prevalent Candida species in the clinical sample. The whole genome sequencing analysis of the C. tropicalis isolate revealed the occurrence of point mutations in genes involved in drug resistance. However, all the extracts of G. lucidum showed potent antimicrobial activities against C. tropicalis by altering morphology causing loss of cell integrity where antimicrobial efficacy is directly influenced by the bioactive compounds present in G. lucidum. Given that drug resistant candida infections are a growing health care problem, G. lucidum provides a new approach to treatment. Our study findings suggest several opportunities for additional study. Molecular studies and related techniques should be exploited to investigate the role of active components of G. lucidum extracts in controlling and preventing the proliferation of various cancer cells and diseases caused by viral pathogens. Further investigation is needed to perform antifungal sensitivity test and to evaluate the effects of extracts of G. lucidum on human cells.

Author Contributions

Conceptualization, A.E., V.W., U.I., L.M., L.K., L.M., J.M. and D.S.; Methodology, A.E., U.I., L.M., L.K., L.M. and B.J.; Formal analysis, A.E., L.K., U.I., and Z.W.; Investigation, A.E., L.M., U.I., L.K., and D.S.; Writing—original draft, A.E., L.M., L.M. and D.S.; Writing—review & editing, L.M., L.M., Z.W., B.J., L.K and U.I. All authors have read and agreed to the published version of the manuscript.

Funding

The project was funded by Genomic Research and Data Science Center for Computation and Cloud Computing (GRADS-4C)-211512.

Acknowledgments

The authors sincerely thank the Department of Biological Sciences, Winston Salem State University for all the logistics.

Conflicts of Interest

The authors declare no conflicts of interest regarding the publication of this paper.

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