|Year : 2019 | Volume
| Issue : 11 | Page : 507-511
Molecular characterization of Echinococcus granulosus in paraffin-embedded human tissues from Southwest Iran
Elham Yousefi1, Abdollah Rafiei1, Iran Rashidi2, Shahram Khademvatan3, Masoud Foroutan4
1 Department of Medical Parasitology, Ahvaz Jundishapur University of Medical Sciences, Ahvaz, Iran
2 Department of Pathology, Ahvaz Jundishapur University of Medical Sciences, Ahvaz, Iran
3 Cellular and Molecular Research Center and Department of Medical Parasitology, Urmia University of Medical Sciences, Urmia, Iran; Cellular and Molecular Research Center, Ahvaz Jundishapur University of Medical Sciences, Iran
4 Department of Parasitology, Faculty of Medical Sciences, Tarbiat Modares University, Tehran, Iran
|Date of Submission||18-Nov-2018|
|Date of Decision||29-May-2019|
|Date of Acceptance||02-Jun-2019|
|Date of Web Publication||26-Nov-2019|
Cellular and Molecular Research Center and Department of Medical Parasitology, Urmia University of Medical Sciences, Urmia; Cellular and Molecular Research Center, Ahvaz Jundishapur University of Medical Sciences
Source of Support: This study was supported by the Research Project of the Cellular and
Molecular Research Center of Ahvaz Jundishapur University of Medical Science (grant No.
CMRC-1000), Conflict of Interest: None
Objective: To investigate Echinococcus (E.) granulosus genotypes as the causative agents of hydatidosis in humans in the southwest of Iran (Khuzestan province).
Methods: In this study, isolates of 80 archived human paraffin embedded hydatid cysts were collected from pathology laboratories in Ahvaz city, Khuzestan province. DNA was extracted and examined by nested-PCR of ribosomal DNA (rDNA) internal transcribed spacer 1 (ITS1), and PCR-RFLP. In addition, the sequences of fragments of genes coding for Cox space1 and NADH dehydrogenase 1 (ND1) were also examined.
Results: Of the 80 paraffin samples, 44 (55.0%) were from the liver, 27 (33.8%) from the lung, and the rest from other organs. The amplified hydatid genomic DNA showed that the cysts were E. granulosus strains. The results of PCR-RFLP and sequencing analysis revealed the presence of G1 genotype (sheep strain) in all human isolates. Furthermore, no camel strain (G6) was detected among all samples in the regions studied.
Conclusions: The molecular findings indicate that the predominant genotype involved in E. granulosus transmission in southwest of Iran is the common sheep strain (G1), which occurs in human populations. These results may have important implications for hydatid disease control in the studied areas.
Keywords: Echinococcus granulosus, Human, Genotype, Iran
|How to cite this article:|
Yousefi E, Rafiei A, Rashidi I, Khademvatan S, Foroutan M. Molecular characterization of Echinococcus granulosus in paraffin-embedded human tissues from Southwest Iran. Asian Pac J Trop Med 2019;12:507-11
|How to cite this URL:|
Yousefi E, Rafiei A, Rashidi I, Khademvatan S, Foroutan M. Molecular characterization of Echinococcus granulosus in paraffin-embedded human tissues from Southwest Iran. Asian Pac J Trop Med [serial online] 2019 [cited 2021 Jan 24];12:507-11. Available from: https://www.apjtm.org/text.asp?2019/12/11/507/271290
| 1. Introduction|| |
Hydatidosis is a disease caused by the larval stage of Echinococcus (E.) granulosus, and is considered as a zoonotic disease. This disease spreads globally, and many cases of human infections are reported annually. In addition to physical harms, huge sums are spent on treatment of patients. In Iran, contamination with this worm is also of huge importance. Dogs are considered the final hosts and sheep are intermediate hosts of this parasite,,. Larval stage of this parasite is seen in animals such as livestock and humans. Iran is considered an endemic region for this parasite, and 1% of surgeries annually concern hydatid cysts in Iran. This parasite has various strains, and so far 10 strains (G1-G10) have been identified for this parasite. In regions where the disease is endemic, there is usually a relatively vast diversity among E. granulosus strains in genetic and biological terms,,. Several studies have demonstrated that in endemic areas, E. granulosus sensu lato exists as a complex of different strains, and this diversity affects epidemiology and pathogenicity of hydatid cyst.
Today, the best way to identify parasite strains is to use molecular-based techniques. Although characteristics of genus Echinococcus species in livestock and humans have also been studied using morphological methods, molecular study of parasite genotypes in humans has rarely been performed in Iran,,,. There are also many studies that have demonstrated DNA extracted from parasite protoscoleces have important effects on PCR results. The aim of this study was to characterized E. granulosus sensu lato strains from paraffin embedded hydatic cyst isolated from human tissue in south west Iran (Khuzestan province).
| 2. Materials and methods|| |
2.1. Sample collection
A total of 80 paraffin block samples were collected from the archives of the teaching hospitals of the south west Iran; Khuzestan province (Imam Khomaini and Shafa hospitals) and the city’s private laboratories [Figure 1]. All suspicious paraffin samples were excluded and only confirmed samples were included in the study. Information such as age, sex and infected organ were registered. Two thin sections (8-10 micron) were prepared from each paraffin block, and placed into 1.5 mL microtubes. In the next step, thin sections were de- paraffinized using Schneider et al. 2008 method, by pouring 1 mL of xylol on each sample, incubating at 37°C for 10 min, and centrifuging at 1 500 g for 5 min. This stage was performed twice, and samples were then placed in 70%, 80%, 90%, and 100% alcohol, for re-hydration and preparation for molecular methods respectively.
2.2. DNA isolation and nested PCR
Genomic DNA from all 80 samples were extracted applying a procedure using the QIAamp DNA Mini Kit (Qiagen, Germany) according to the manufacturer’s instructions with modification, including: increasing time of incubation to 48 h and amount of proteinase K to 40 μL in 56° C, respectively. DNA concentration was measured by spectrophotometric determination at A260.
An ITS1 fragment was amplified from each sample by Nested PCR. First step PCR amplification was performed using primer pair EGF 1 (5’ CCA AAC TTG ATC ATT TAG AGG AAG 3’) and EGR 2 (5’ TAT GGG CCA AAT TCA CTC ATT ACC 3’) as outer primers and for second PCR, internal primers were as follows: EgF: (5’GTC GTA ACA AGG TTT CCG TAGG 3’) EgR: (5’ TAG ATG CGT TCG AAG TGT CG 3’). The thermo cycler used and PCR conditions were set as previously described for amplification of first and second step PCR as follows: One cycle of 95°C for 2 min, 94°C for 30 sec, 55°C for 45 sec, and 72°C for 1 min, all steps repeating for 30 cycles. For final extension 72°C for 5 min was used,. Electrophoresis was performed by adding 7μL sample of the second PCR to 1.5% (w/w) agarose gel, stained with ethidium bromide for 45 min at 100 V. The bands were observed by ultraviolet transillumination.
All PCR products were digested for 6-8 h with the restriction endonucleases AluI, TaqI and RsaI using buffers recommended by the manufacturer (Fermentas, Vilnius, Lithuania) in a final volume of 20 μL including 5 μL of PCR product, 5 units of the restriction enzymes, 2 μL of the supplied buffer and 8 μL of molecular grade water. Restriction fragments of amplicons were electrophoresed using a 2% (W/V) agarose gel at 100V for 180 min.
2.4. Sequencing method and phylogenetic analysis
Fragments of mitochondrial genes amplified with specific primers that previously described as JB3/JB4.5 primers (5´-TTTTTTGGGCATCCTGAGGTTTAT-3´/5´ TAAAGAAAGAACATAATGAAAATG-3´) for COX1 and JB11/JB12 primers (5´-AGATTCGTAAGGGGCCTAATA-3´/5´ ACCACTAACTAATTCACTTTC-3´) for NAD1, respectively and NAD1 band was found 450 bp, and COX1 band was 400 bp respectively. PCR product of the COX1 and NAD1 genes from 17 randomly selected samples was sequenced by MWG (Germany) and the resulting data were analyzed using Chromas software (http://www.technelysium.com.au/Chromas.html). Data submitted in the GenBank database were obtained with accession numbers: Cox1 LC060667.1-LC060676.1 and NAD1 LC060691-LC060697, respectively.
GenBank database was searched for similar sequences using BLAST (National Center for Biotechnology Information; www. ncbi.nlm.nih.gov/BLAST/) and output was then analyzed to find a significant homology. DNA sequences were aligned with ClustalW and the sequences were entered in PAUP* to generate phylograms for each dataset.
| 3. Results|| |
The present study was conducted on 80 paraffin-embedded samples of human hydatid cysts, collected from Khuzestan province. Examination of 80 paraffin-embedded isolated during 2005 to 2014 showed that among the 80 samples, the highest frequency related to the age group of 21-30 years with prevalence of 21.25% (17/80), and the lowest frequency related to the over 60-year-old age group. Of the 80 isolates, 52 were collected from female (29 from liver, 17 from lung, 2 from spleen, and 4 from others) and 28 from male (15 from liver, 10 from lung, 1 from spleen, and 2 from peritoneum) respectively. Women’s and men’s mean age were (29±2) and (31±1) years, respectively. Of the 80 paraffin samples, 44 (55.00%) were from liver, 27 (33.75%) from lung, and the rest from other organs [(Spleen, 3 (3.75%); peritoneum, 3 (3.75%), kidney, 1 (1.25%), parotid1 (1.25%), pelvis1 (1.25%)]. About 55.00% of the samples were from the liver, and 33.75% from lung. Following De-paraffinization, samples’ genomes were extracted and results showed that, 74 samples of the 80 paraffin isolates examined had suitable DNAs for the next stage. Nested-PCR was performed with ITS-1 gene specific primers (internal and external primers), that amplified genomic DNA showed sharp bands (1 000 bp) that this rang associated with E. granulosus sens lato [Figure 2]
|Figure 2: Internal transcribed spacer 1 (ITS1) nested-PCR results of extracted DNA of Echinococcus granulosus sens lato isolates. Nested PCR using inner primers. M: DNA marker (100 bp); N: negative control; Lane 1: positive control; Lane 2-9: isolates of liver 1, liver 2, lung 1, lung 2, spleen, parotid glands, kidney, and the peritoneum.|
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Results of genotyping hydatid cyst paraffin isolates showed that enzyme pattern of all samples were related to E. granulosus sensu stricto strain (G1 or sheep strain). Results obtained from enzyme- digested PCR products with ALU-1 enzyme showed 180 bp and 700 double-band pattern in all samples [Figure 3]A. Results of enzyme digested PCR products with Taq-1 enzyme showed 1 000 bp single band pattern in all samples, similar to the sheep strain pattern [Figure 3]B. Results obtained from enzyme-digested PCR products with RSA enzyme showed the same 320 bp and 680 double-band pattern in all samples, similar to sheep pattern [Figure 3]C.
|Figure 3: PCR-RFLP digests with: A: Alu enzyme; B: Taq-1 enzyme and C: RsaI enzyme respectivly; M: DNA size marker (100 bp); Lane 1-8: isolates of liver 1 , liver 2, lung 1, lung 2, spleen, parotid glands, kidney and the peritoneum.|
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The multiple sequence alignment was done in Mega software and results were compared between the obtained sequences. Phylogenetic trees were generated by comparing submitted sequences with reference sequences in GeneBank: DQ062857.1 for COX1 and AJ237632 for NAD1. The sequences were highly homologous with few differences, corresponding to punctual base substitution. Phylogenetic analyses using character method like Maximum Parsimony showed that the topology was similar among the trees obtained with significant bootstrap support for the clades which confirmed E. granulosus sensu stricto strain (G1 or sheep strain) [Figure 4]A and [Figure 4]B.
|Figure 4: Dendrogram obtained for Echinococcus granulosus isolates by the maximum likelihood analysis at the COX1 (A) and NAD1 (B) genes in comparison with reference (DQ620857.1 & AJ237632.1) respectively . The result strongly supports they are supposedly an anamorph/teleomorph pair. A: COX1 rooted tree and B: NAD1 rooted tree.|
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| 4. Discussion|| |
Hydatidosis is a zoonotic disease, and is commonly found in many areas of the world, especially in the Mediterranean region,. Identifying various genotypes of E. granulosus sensu lato, as hydatid cyst agent in endemic regions, can have a significant effect on disease control programs, especially in human[15-17]. The present study conducted on 80 paraffin block samples showed that the highest level of infection in humans occurred in the liver (55.00%), followed by the lung (33.75%). In addition, our results showed that the infection is more prevalent in 21-31 years old which is in concordance with the study of Rokni et al which mentioned the overall range of 20-40 years old as the age group of the highest cases.
The present study findings showed that liver is more affected compared to other organs. This are similar with studies conducted in Iran and other parts. In Iran, liver infection has been reported from 90.5% by Ahmadi et al. to 71.6% by Yazdi et al,,,.
DNA extraction methods are important for genotyping of the larval stage of E. granulosus and researchers have proposed various techniques to extract tissue DNA,,,. In the present study, extraction of DNA from paraffin blocks faced with some difficulties. After trying various extraction techniques, finally, Schneider et al. method (with slight modification) was employed to extract parasite genome. These modifications included: increased incubation time at 65°C, and use of large amounts of proteinase K. DNA extraction and PCR results showed 74 positive isolates out of 80 samples. This may have been due to cyst tissue calcification and extended length of time elapsed since the preparation of blocks, as well as inappropriate paraffin block preparation techniques, which in the long term causes DNA damage and lack of response in molecular studies.
In this study, ITS-1 and rDNA examination results using Nested- PCR specific method showed that all 74 human isolates had the same pattern, weighing approximately 1 000 bp. This pattern is similar to that found in studies of Rahimi et al. and Mc Manus et al. and is indicative of hydatid cyst infection in people. Shahnazi et al. reported E. granulosus DNA open pair 1 000 and 1 100 sizes in human hydatid cysts. In a study similar to the present one, Kia et al. determined genotypes of 30 human hydatic cyst samples using PCR method and RFLP with EGF1/EGR2 primers, and obtained 1 000 bp bands. In a study of Zhang et al. in Iran, conducted on 4 human isolates and 16 animal isolates of E. granulosus using molecular methods on COX-1, various sheep strains and camel strain from different parts of Iran were reported.
In the present study, RFLP results obtained from all separated human isolates using restriction enzymes: ALU-1, Taq-1, and Msp-1 showed similar patterns to sheep isolate pattern with G1 genotype, and no other strain, such as E. canadensis G6 or buffalo G3 strains were found in Khuzestan province. E. granulosus sensu stricto G1 strain, as the dominant strain has been reported in many studies in different parts of Iran, Middle Eastern countries, and North Africa,,,. The present study results are similar to previous studies in southwest Iran, in which out of 329 isolates separated from slaughtered animals in the province, such as: cattle, sheep, goat and 5 human isolates, but only sheep strain was found. In two similar studies conducted by Parsa et al. in Lorestan province, adjacent to Khuzestan on animals, the dominant strain in Lorestan was senso stricto, which is the same sheep strain,. In another adjacent province, Ilam, animal studies also indicated frequent G1 strain in the region. Interactions and constant movement of nomadic livestock between these three provinces, hugely helps uniformity of a dominant strain in these adjacent provinces. The present study results are also similar to Zhang et al. study conducted in 1998 from north China and Iran.
In an extensive study conducted in 2005 in Tunisia on 50 human, 166 cattle, 150 sheep, and 3 camel isolates, all sheep, human, and cattle isolates were identified as sheep strain, and camel strain was only found in camel isolates. Parsa et al, conducted a study on animal and human samples in Khorramabad city, and reported all as sheep strain, which is similar to the results of the present study. Perhaps, a reason for not obtaining camel isolates in Iran’s west and south western areas is that camel is not slaughtered in Khuzestan abattoirs, while G3 and G6 strains have been reported in central Iran,.
In the present study, obtained COX1 gene subunit (400 bp) was compared with reference sequence DQ062857 for G1, and results showed significant homology results. Moreover, an NAD1 gene subunit (450 bp) was also compared with a reference sequence registered at Genebank, such as AJ237632 for G1 strain, and showed significant homology up to 97% to 99% compared to reference genotypes. The phylogenetic results presented here confirmed that the variation between the sequences obtained herein resulted because they belonged to different E. granulosus sens lato isolates.
The present study results using PCR –RFLP of ITS1 and genetic sequencing are in line with previous studies on animals and ITS1 gene sequence, and the sheep strain was also confirmed in this case. As an important point, in Iran, genotypes of intermediate hosts are in line with definitive host of E. granulosus. For example, in a molecular study, Parsa et al. 2012, revealed the presence of G1 genotype (sheep strain) of E. granulosus sensu stricto as dominant genotype in dogs.
In conclusion, the dominant strain in southwest region of Iran (and also other parts of the country), is G1 or sheep strain, which can invade human liver, lung, and even parotid glands. Thus, the important role of dog-sheep life cycle in the region is recognized. Educating those who are in contact with dogs, gathering and housing stray dogs, and ongoing treatment of pet dogs can be significantly effective in controlling the disease.
Conflict of interest statement
We declare that we have no conflict of interest.
The authors would like to thank Dr Jasem Saki for his help in analysis of the samples.
SK, AR and IR conceived and designed the experiments; EY performed the experiments; SK, EY and MF wrote the paper.
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[Figure 1], [Figure 2], [Figure 3], [Figure 4]
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