Background
Cutaneous leishmaniasis (CL), is a vector-borne zoonotic infectious disease caused by protozoan parasites of the genus
Leishmania (Kinetoplastida, Trypanosomatidae) [
1,
2]. It is transferred to humans through the bite of infected female phlebotomine sand flies of the genera
Phlebotomus and
Lutzomyia [
3]. CL can cause by 21
Leishmania spp. and result in a wide spectrum of clinical manifestations in humans, with the infecting species being a great determinant of clinical outcome [
4]. Contingent upon the species of
Leishmania involved, humans and a large spectrum of mammals operate as reservoirs [
5]. The disease is endemic in the tropical and subtropical regions of 98 countries across four continents. More than two thirds of new cases of CL transpire in six countries: Afghanistan, Algeria, Brazil, Colombia, Iran and Syria. An estimated of 0.7–1.3 million new cases occur worldwide annually [
4,
6]. In Iran CL is caused by
Leishmania tropica, (the agent for anthroponotic CL),
Leishmania major (the agent of zoonotic CL), and rarely by
Leishmania infantum [
7‐
9]. In addition, it is common for different species to coexist in the same endemic areas, as seen in Fars province [
7‐
9]. Single or multiple CL lesions typically occur on exposed parts of the body, such as face, and upper and lower extremities. Lesions usually self-heal in a few months, but may persist for many years (e.g. when super-infected or when located on joints), causing considerable morbidity and large scars [
10].
There have been several reports from studies in Iran of atypical manifestations of the disease due to either uncommon sites of lesions or their unusual morphology. Lesions on atypical sites result in a more complex differential diagnosis [
7,
8]. Uncommon clinical presentations include lupoid, verrucous, sporotrichoid, erysipeloid, eczematous, psoriasiform, zosteriform, keloidal, whitlow, paronychia, carcinoma-like, and midfacial destructive lesions [
7,
8,
10‐
12]. Occasionally CL may manifest as isolated lymphadenopathy, or proceed into disseminated CL [
13,
14].
The genetic heterogeneity may cause various phenotypes that manifest themselves in the variability of clinical features observed. Therefore, bestowed genetic variations in
Leishmania populations, disease control and treatment could be challenging [
15]. Multi-locus enzyme electrophoresis (MLEE) has traditionally been the gold standard for strain and species characterization [
16,
17]. However, this customary classification has been challenged using nuclear and mitochondrial molecular markers, as they inclined to be more specific and stable [
18]. Generally, DNA analysis demands reiterated copying of the genome, and the levels of inter- and intra-species diversity has to be taken into account. In order to appraise genetic characterization, a number of nuclear and extra nuclear DNA markers have been employed, including kDNA [
19], GP63 [
20], ITS1 [
21], ITS2 [
22], the N-acetylglucosamine-1-phosphate transferase gene [
23], Cytochrome Oxidase II [
24], Cytochrome b (Cyt b) [
25], Miniexon [
26], 7SL RNA [
27], HSP70 [
28], and Cysteine Proteinase B [
29].
The mitochondrial genome has been disclosed to be a splendid origin of accessible genetic variation. Analysis of mitochondrial DNA has been used to understand the evolutionary biology at the inter- and intra-species levels [
30,
31]. Mitochondrial DNA’s rapid rate of evolution, clonal patrimony, and absence of recombination makes it an ideal target for phylogenetic studies and a source of genetic markers of species and geographically confined populations [
30,
31]. Mitochondrial kinetoplastid DNA (kDNA), arranged as mini and maxicircles, encodes proteins involved in energy production and ribosomal RNAs. Minicircles are about 800-bp in size, closely 600-bp variable and 200-bp conserved region, and repeated 10,000 times. Maxicircles are around 20–35 kb in size, and have 20–50 repetitions in the genome [
30,
31]. The mitochondrial genome can encode gene products such as Cyt b in the cellular respiration cycle [
32]. Cyt b is the principal redox catalytic subunit of Quinol, which is engaged in the electron transport process of the mitochondrial respiratory chain, and is regarded one of the most functional genes for phylogenetic studies [
32‐
34].
In the present study, the sequence analysis of the amplified Cyt b gene was applied to investigate the presence of genetic polymorphisms among Leishmania isolates and correlate the findings with the clinical features of CL lesions in Fars province, Iran, over a 2-year period. Moreover, molecular phylogenetic relationships were assessed using Cyt b gene sequences obtained by this study and download from the GenBank database.
Methods
Ethics statement
The research protocol was endorsed (approval no. 94–7548) by the Institutional Ethics Clearance Committee (IECC) of Shiraz University of Medical Sciences and performed in accordance with international policies established by the Declaration of Helsinki.
Written informed consent (Code: IR.SUMS.REC.1394.S282) to participate in the study and use clinical images in publications was obtained from all adult patients and/or parents/legal guardians for children under the age of 16 years.
Patients
One hundred patients who showed different types of CL lesions participated in this study. The patients were referred to the Dermatology Clinic of Saadi Hospital and Fajr Health Center from January 2015 to the end of December 2016. Selected patient lesions (the most recent, in case of multiple lesions) were first photographed and standard clinical descriptions for these lesions were obtained from the attending dermatologist. All patients originated from different rural and urban regions of Fars province. We excluded patients with clinical evidence of intercurrent bacterial or fungal superinfection of the ulcer, and those undergoing active treatment for CL. For each patient a structured questionnaire was completed with all demographic information about the patient (including code, age, sex, address, and travel history), the lesion (including the number of lesions, localizations, onset of the disease, and clinical characteristics), and therapeutic data. The questionnaire used in our study, was designed and developed for this study.
Dermal scraping
For the margin dermal scraping, a deep disinfecting of the indurated active margin of the lesion with 70% ethanol was performed. Samples were taken by using a no. 15 disposable sterile surgical blade (Unicut, Chicago, IL, USA) to make an incision in the border of the lesion. Exudates and dermal tissues from the wall of the slit were scraped and smeared on two glass slides [
7,
8]. The touch impression smears were air dried, methanol-fixed, stained with Giemsa (Merck, Darmstadt, Germany), and finally examined for amastigotes by microscopy.
In vitro culture
Moreover, the dermal syringe-sucked fluid was collected under sterile conditions from each patient as follows: 0.1 mL of sterile saline solution was injected using an insulin syringe (1-mL, 25-gauge needle) into the nodule and the needle was rotated gently several times. A small amount of saline solution was injected into the tissue, and then aspirated. The fluid was transferred to two tubes of modified NNN culture medium. Modified NNN medium was biphasic, comprise of horse blood agar base and an overlay Locke’s solution [
7,
8]. The specimens were inoculated into the medium and incubated at 25 °C. Every 2 to 3 days, the liquid phases of cultures examined under invert microscope, in order to observe motile promastigotes. Positive cultures were mass cultivated in RPMI-1640 medium (Gibco, Frankfurt, Germany) supplemented with 15% heat-inactivated Fetal Calf Serum (Gibco, Frankfurt, Germany), 2 mM L-glutamine, 100 U/mL Penicillin, and 100 μg/mL Streptomycin (Gibco, Frankfurt, Germany) [
7,
8]. Nearly 2 × 10
6 promastigotes were harvested by centrifugation (10,000 g for 10 min) and washed thrice in cold sterile PBS (pH 7.2). Parasites pellets were stored at − 20 °C until used.
Total genomic DNA was extracted from each clinical sample using the QIAamp
® DNA Mini Kit (QIAGEN, Hilden, Germany), according to manufacturer’s instructions. Following the centrifugation and washing steps, the DNA was eluted from the silica spin columns with 50-
μL elution buffer to increase its concentration. The quantity and quality of the extracted DNA was determined by measuring optical absorbance at 260 nm using a Nano spectrophotometer (NanoDrop
® 2000, Thermo Fisher Scientific, Wilmington, DE, USA). Each samples for PCR assays were prepared with aerosol-guard pipette tips to avoid contamination. All reactions were performed in appropriated places, following the good practice of laboratories to avoid sample contamination [
7,
8]. The extracted DNA was stored at − 20 °C until used.
kDNA semi-nested PCR
All samples (cultures and impression smears) were identified to Leishmania species level using kDNA primers before they were subjected to Cyt b amplification.
The conserved area of the minicircle kDNA from the
Leishmania species of all the samples was amplified by semi-nested PCR using primers LINR4 (forward) (5′-GGG GTT GGT GTA AAA TAG GG-3′), LIN17 (reverse) (5′-TTT GAA CGG GAT TTC TG-3′), and LIN19 (reverse) (5’-CAG AAC GCC CCT ACC CG-3′) for species identification [
7,
8,
35].
PCR was performed in a Bio-Rad MyCycler Thermocycler (Hyland Scientific, Stanwood, WA, USA). The PCR conditions were composed of pre-denaturation at 94 °C for 5 min, then 40 cycles of denaturation at 94 °C for 30 s, annealing at 52 °C (LINR4 and LIN17) or 58 °C (LINR4 and LIN19) for 45 s, and extension at 72 °C for 1 min, followed by final extension at 72 °C for 10 min. Amplicons were analyzed on 1.5% agarose gels (AddGene, Watertown, MA, USA) by electrophoresis at 90 V in 1 × TAE buffer (40 mM Tris-acetate and 1 mM EDTA, pH 8.3) and visualized by UV light (Uvitec, Cambridge, UK) after being stained with GelRed® (Biotium, Hayward, CA, USA). Cross-contamination was monitored by negative controls for sample extraction and PCR solutions.
Cyt b nested-PCR
Maxicircle Cyt b gene was amplified using nested-PCR. Nest 1 primers corresponded to COIIIF (5′ - GTT TAT ATT GAC ATT TTG TAG ATT - 3′) and MURF4R (5′ - CGA CGA ATC TCT CTC TCC CTT - 3′). Nest 2 primers matched to LCBF1 (5′ - GGT GTA GGT TTT AGT TTA GG - 3′) and LCBR2 (5′ - CTA CAA TAA ACA AAT CAT AAT ATA CAA TT - 3′) [
34].
The partial region of the Cyt b gene was amplified with Pfu DNA Polymerase (Agilent Technologies, Santa Clara, CA, USA) under the following conditions: initial denaturation at 94 °C for 5 min, followed by 40 cycles, each consisting of 30 s at 94 °C, 45 s at 58 °C (COIIIF and MURF4R) or 50 °C (LCBF1 and LCBR2), 1 min at 72 °C, and a final extension at 72 °C for 10 min. Electrophoresis and visualizing were performed under the same conditions as described above.
Roche Molecular Diagnostics Laboratories (Roche, Penzberg, Germany) synthesized all primers.
Reference strains of L. major (MHOM/IR/54/LV39) and L. tropica (MHOM/IR/89/ARD-L2) were used as positive controls.
Sequencing
The amplified DNA fragments of both kDNA and Cyt b genes were visualized on 1.5% agarose gels, parallel with standard DNA marker (Fermentas, Vilnius, Lithuania) to permit sizing. The PCR products were extracted from gel sections using the QIAquick® Gel Extraction Kit (QIAGEN, Hilden, Germany).
Sequencing of 200 ng of the amplified kDNA gene products were accomplished by using the LINR4 and LIN19 primers. Direct sequencing was performed to bridge gaps in nucleotide sequences.
Sequencing of the amplified Cyt b gene products were executed by using Nest 2 primers (LCBF1, LCBR2) and two specific internal primers LCBF4 (5′ – TGT TAT TGA ATA TGA GGT AGT G - 3′) and LCBR4 (5′ – GAA CTC ATA AAA TAA TGT AAA CAA AA - 3′). DNA sequencing was carried out on an ABI PRISM® 3730xl Genetic Analyzer (Applied Biosystems, Foster City, CA, USA) by the Sanger dideoxy chain termination method using the Big Dye™ Terminator Cycle Sequencing Ready Reaction Kit (Applied Biosystems, Foster City, CA, USA). Sequence accuracy was confirmed by sequencing both directions through the sequencing service of Roche Molecular Diagnostics (Roche, Mannheim, Germany). Special attention was paid to the double peaks and the accurate direction of the sequences was guaranteed. The variations between and within Leishmania species, and the number of different nucleotides in each sequence was determined.
Phylogenetic analysis
The raw nucleotide sequences and chromatograms of both forward and reverse directions were viewed and analyzed using the Chromas (2.6.6) program. The nucleotide sequences were aligned and analyzed using the MUSCLE multiple sequence alignment program [
36]. Consensus sequences were compared with homologous sequences in the GenBank database using the BLAST algorithm [
37]. The sequences were assembled and edited with the BioEdit (7.2.6) to identify single nucleotide polymorphisms (SNPs) [
38]. Multiple alignments were performed with data related to
Leishmania species from Iran and other countries deposited in GenBank. The parasite species were confirmed based on the homology with kDNA and Cyt b genes sequences from
Leishmania reference strains. A molecular phylogenetic tree was constructed by the Neighbor-Joining (NJ) method and genetic distances were calculated with Maximum Composite Likelihood model using MEGA-X [
39]. The reliability of the NJ tree was assessed by the bootstrap method with 1000 replications.
Leishmania equatorensis was treated as out-group in Cyt b phylogenetic analysis.
Statistical analysis
The Fisher’s Exact Test was used for analyzing the relation between clinical features and Leishmania species involved. All statistical analyses were performed using SPSS (SPSS 24.0, Chicago, IL, USA). A P-value < 0.05 was considered statistically significant.
Nucleotide sequence accession numbers
The partial sequences of the Cyt b gene obtained in this study were deposited in the GenBank database under accession numbers KX176846, KY290231, KY360312-KY360314.
Discussion
Cutaneous leishmaniasis is a polymorphic disease that can divulge distinctive clinical outcomes, and is characterized by skin lesions and ulcers on exposed parts of the body, departing perpetual scars. CL is allotted in greater than half of the 31 provinces of Iran, with 29,201 incidence cases reported in Fars province from 2010 to 2015 [
40]. Fars province in southern Iran is a hyper-endemic region of CL [
41]. Early identification and genetic characterization of causative agents of CL using Cyt b gene or other genetic markers has been avail for appraisal of
Leishmania polymorphisms, since infected
Leishmania species are confederated with the clinical presentation and drug susceptibility.
In this study, we used Cyt b gene sequencing to study genetic diversity among 100
Leishmania isolates from the different parts of Fars province, Iran and to correlate the genetic polymorphism of the parasite with the clinical manifestations of the disease in humans. One of the advantages about using gene sequencing is the understanding of the inter- and intra-species genetic diversity of
Leishmania. Cyt b is situated in the maxicircle part of the kinetoplast that is about 50 copies. There is sufficient degree of nucleotide sequence change amid
Leishmania spp. genomes for characterization and heterogeneity aims [
34]. Recently sequencing of the Cyt b gene has been employed with prosperity for
Leishmania sp. identification [
33,
42‐
47] and polymorphism [
25,
34,
42,
43,
48‐
50]. Despite the low inter-species heterogeneity of the Cyt b gene, the key nucleotide positions depicted previously corroborate the potential of this gene as a molecular marker for
Leishmania species characterization, not only in geographically related isolates, but also in widely separated regions [
45].
The data from this study revealed genetic diversity of the Cyt b gene of
Leishmania spp. isolated from a wide spectrum of clinical forms of CL in Fars province, Iran. This is in accordance with prior studies. Myint et al. [
49] found three types of Cyt b polymorphism of
L. major and no connection between clinical presentation and causal
Leishmania parasites. Ramirez et al. [
51] reported a high genetic diversity displayed by
L. panamensis and
L. braziliensis using Cyt b barcoding.
The genetic diversity of
Leishmania spp. seen in academic research studies is dependent on a number of factors ranging from the parasite’s different eco-epidemiologies (e.g. are parasites isolated from humans, reservoir hosts or vectors; are they transmitted anthroponotically or zoonotically) to laboratory tools and molecular tools used (e.g. nuclear in contrast with mitochondrial DNA) [
43]. Additionally, the occurrence of clonal reproduction and hybridization causes intrinsic genetic diversity in
Leishmania [
52,
53]. Of all these factors, sexual reproduction is the basic biological process that influences the population’s genetic structure. Many authors have reported evidence of hybrid formation and fortuitous bouts of genetic exchange or hybridization in
Leishmania [
54‐
57]. Clearly, infrequent or rare sessions of sexual recombination in normally asexual parasites can have a deep effect on the range of genetic diversity. It has been informed that increased transmission potential and a new form of CL is the result of hybrid formation between
L. major and
L. infantum [
56,
57].
A high degree of genetic polymorphisms in
Leishmania parasites based on ITS1 and kDNA genes has been reported previously in Iran [
58‐
62], and in the neighboring country of Afghanistan [
63,
64]. In a preceding study by Baghaei, mutual connection between the genetic heterogeneity of
L. major and clinical presentations of ZCL in Isfahan, Iran based on PCR-RFLP of ITS gene in the ribosomal operon, has been investigated [
58]. His study revealed that
L. major is genetically highly polymorphic and a correlation may exist between genetic heterogeneity of the parasite and the clinical picture of the disease in human. The PCR-RFLP of the RNA polymerase II largest subunit (RPOIILS) gene of
L. major has divulged genetic diversity in Iran [
65]. The genetic variability of
L. major from Iranian isolates have been disclosed antecedently by Single-Strand Conformation Polymorphism PCR (SSCP-PCR) and sequence analysis of the ITS gene [
60]. The Permissively Primed Intergenic Polymorphic-PCR (PPIP-PCR) displayed further genetic heterogeneity amid the clinical isolates of
L. major causing CL in Isfahan, Iran [
66]. Supplementally, the genetic polymorphism of the rDNA gene of
L. major has been informed in Fars province, Iran [
67].
In addition, substantial heterogeneity has been studied and reported within the ITS gene of strains of
L. tropica [
59,
64,
68,
69]. Oryan et al. [
61] and Shirian et al. [
62] assessed the heterogeneity of
L. major causing CL based on sequencing of kDNA and showed a high genetic diversity of the parasite and correlations among the geographical origin and the clinical outcomes of the disease. Moreover, conspicuous genetic variability has been exhibited within the
Nagt gene amidst
L. tropica,
L. major, and
L. infantum strains [
70,
71], and by RAPD-PCR among
L. major and
L. infantum strains [
72‐
74]. Considerable genetic diversity was detected among
L. major strains from different endemic areas and even between some isolates of the same endemic area in Iran using the RAPD technique [
73]. The latter result might be elucidated by substantial “Gene Flow” among isolates belonging to the same area [
75].
The findings of higher molecular diversity in
L. major isolated from tropical and subtropical regions of the Fars province in this study rather than
L. tropica from the Shiraz region could be related to the greater number of animal reservoirs and diversity of sand fly fauna encountered in these regions [
3,
5,
41].
In this study, an intelligible correlation was discerned between the Cyt b gene sequence polymorphism of isolates and clinical pictures of skin lesions. This is in conformity with previous studies [
42,
49,
50]. Our results disclosed noteworthy variations in the clinical features of the CL caused by
L. major secluded from different geographical regions of Fars province, Iran. The CL typically demonstrates as papules, scaled-crusted nodules, and ulcerative plaques. However, it may sometimes pose in various atypical clinical outcomes such as sporotrichoid, erysipeloid, lupoid, keloidal, eczematous, erythematous, psoriasiform, zosteriform, chancriform, hyperkeratotic, verrucous, whitlow, paronychia, carcinoma-like and other atypical exhibitions [
7,
8,
10,
11]. Coherent with these data, in a prior study, assessment of four
L. major isolates collected from four different endemic areas in Iran displayed diverse clinical and immunological patterns in BALB/c mice [
76]. The different clinical expressions of CL depend on both intra-species genetic diversity of
Leishmania and host immune status. Compound lesions have been portrayed in connection to
L. mexicana,
L. braziliensis,
L. tropica and
L. major, the mentioned last leading to primarily dermotropic types. In similar circumstances, the disease disseminates from the initial lesion by way of the lymphatic vessels, presenting subcutaneous nodules or localized adenopathy that have a similar appearance to lymphocutaneous sporotrichosis [
10,
11].
In addition to the intra-species genetic variability of the
Leishmania, host immune reaction performs a significant function in the clinical presentation of CL. For example, patients with defect of the T cell reply frequently improve an anergic condition named diffuse CL characterized by multiple nodular lesions full of amastigotes. Moreover, host genetic inheritance and bacterial habitat are contributed to the outcome of CL [
77‐
80]. It has turned into limpid that the outcome of CL arises from an equilibrium between pro- and anti-inflammatory agents [
81]. In CL patients, pathophysiology of disease is allied with a strong Th1 immune response to
Leishmania antigens. Lesion dimension clearly connects with the immensity of
Leishmania antigen- aroused TNF yield by peripheral blood mononuclear cells, and with the amount of flow TNF and IFN-γ producing CD4
+ lymphocytes [
82,
83]. Furthermore, there is an alliance between the strength of the inflammation and the frequency of CD8
+ T cells exuding granzyme A [
84].
Extra agents that have been asserted to affect the clinical outcome of CL comprise the place of inoculation, the total amount of the inoculated promastigotes, hormonal secretion quality, the quantity, quality and variety of food intake of the host, and the temperament of the final non-blood repast of the vector. Besides, agents like a non-native person, aged people communally, utilize of oral steroid drugs, immunodeficiency illnesses, and still lesion pollution with inorganic particles are able to modify the signs and symptoms of CL [
85].
With relation to the effective causes of CL in Iran, the high usually recognized parasites were
L. major and
L. tropica, respectively. Dependent upon the results of this study,
L. major is the supreme species liable for CL in this district. Three
Leishmania spp. comprise of
L. major,
L. tropica, and sometimes
L. infantum had been recognized as the causative agents of CL and ML collaborated with disparate clinical pictures in this territory [
7‐
9]. The data procured in this study disclosed that those patients who had the similar clinical outcomes and came from the same geographical source were affected with almost linked strains of
L. major in the phylogeny. Certain patients with various clinical configurations were situated in the equal bunch.
The established data from this study revealed that a correlation might be exist between the genetic variability of the parasite, clinical manifestation, and geographical source of the disease in humans. This is in agreement with previous studies [
48‐
50].