Figures
Abstract
Giardia duodenalis is a cryptic protozoan, which has eight assemblages (A-H). Assemblages A and B are the main genotypes reported from humans with probable anthroponotic and zoonotic transmission. The current study aimed to characterize G. duodenalis assemblages in tuberculosis (TB) patients and healthy subjects using multilocus genotyping (MLG). Thirty Giardia-positive stool samples, which were obtained from TB patients and healthy subjects were included in the study. After total DNA extraction, three β-giardin (bg), triosephosphate isomerase (tpi), glutamate dehydrogenase (gdh) genes were amplified and sequenced. Obtained sequences were compared to the GenBank database to characterize assemblages. Phylogenetic analysis using Maximum Likelihood (ML) and Tamura 3-parameter was performed for each gene. From 30 Giardia-positive subjects, 17 (57%) and 13 (43%) were from healthy and TB-infected subjects, respectively. There was no significant co-existence of Giardia and tuberculosis (P-value = 0.051). In addition, 14 (46.7%) and 16 (53.3%) of Giardia isolates were from asymptomatic and symptomatic subjects, respectively. PCR amplification was successful in 25 single samples (83.3%) consisted of 20 for tpi, 15 for bg, and 13 for gdh genes. Accordingly, 13/25 (52%) and 8/25 (32%) belonged to assemblage A and assemblages B, respectively, whereas 4/25 (16%) were either assemblage A or B with different genes at the same time. Significant correlation between assemblages and TB, age, and symptoms was not seen. The phylogenetic analyses represented no separation based on TB and gastrointestinal symptoms. Assemblage A was the predominant genotype in samples. The high frequency of assemblage AII indicated importance of anthroponotic transmission of Giardia in both healthy and TB patients. In addition, considering the exclusive reports of sub-assemblage AIII in wild ruminants, the presence of AIII in the current study have to be carefully interpreted. The inconsistency between the assemblage results of either bg or gdh loci with tpi gene signifies the insufficiency of single gene analysis and the necessity for MLG in molecular epidemiology of G. duodenalis.
Citation: Mohammad Rahimi H, Javanmard E, Taghipour A, Haghighi A, Mirjalali H (2023) Multigene typing of Giardia Duodenalis isolated from tuberculosis and non-tuberculosis subjects. PLoS ONE 18(3): e0283515. https://doi.org/10.1371/journal.pone.0283515
Editor: Bibi Razieh Hosseini Farash, Mashhad University of Medical Sciences, ISLAMIC REPUBLIC OF IRAN
Received: December 3, 2022; Accepted: March 11, 2023; Published: March 23, 2023
Copyright: © 2023 Mohammad Rahimi et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: All relevant data are within the paper. Generated sequences were submitted to the GenBank database under accession numbers OM115964 to OM115983, OM115984 to OM115998, and OM115999 to OM116011, for the tpi, bg, and gdh loci, respectively.
Funding: This study was financially supported by the Research Institute for Gastroenterology and Liver Diseases, Shahid Beheshti University of Medical Sciences with grant number: RIGLD-1143. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript. Hamed Mirjalali, Ali Haghighi, and Hanieh Mohammad Rahimi receive salary from Shahid Beheshti University of Medical Sciences.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Giardia duodenalis (syn. Giardia intestinalis, Giardia lamblia) is a cosmopolitan flagellated protozoan, which is reported from not only humans, but also a broad spectrum of animals. In addition to G. duodenalis, there are at least seven other species including G. agilis, G. ardeae, G. psittaci, G. muris, G. microti, G. peramelis, and G. cricetidarum, which colonize the intestine of a broad variety of animals from amphibians to birds [1]. Unlike other species, G. duodenalis is not limited to a specific host, and is reported from humans and domesticated/wild animals, which increases the probability of zoonotic transmission [2]. The main transmission rout of Giardia spp., in humans is fecal-oral via ingestion of infective cysts defecated by either humans or animals, as well as contaminated food and water [3–5].
Although infection by G. duodenalis in humans is mostly asymptomatic, variety of gastrointestinal manifestations such as bloating, nausea, flatulence, fatigue, weight loss, diarrhea, and steatorrhea might be reported [6–8]. The correlation between diarrhea, as the main symptom of giardiasis, and colonization of Giardia has been controversial [9, 10]. However, it is suggested that the presence of G. duodenalis may protect infected subjects from diarrhea due to other intestinal pathogens [6].
Despite the similar morphology, eight assemblages (A-H) has been characterized based on the molecular diversity within G. duodenalis genomes. Accordingly, assemblages A and B are the major reported genetic lineages from humans and animals, while other six assemblages are exclusively reported from animals [11, 12]. Nevertheless, the majority of assemblages A and B in humans and high occurrence of host-adapted assemblages in companion animals suggest that the zoonotic transmission of G. duodenalis is less common than expected before [11].
To study the molecular characterizations and phylogenetic relationship of genetic lineages of G. duodenalis, several genetic markers have been investigated, so far. Accordingly, β-giardin (bg), triosephosphate isomerase (tpi), glutamate dehydrogenase (gdh), internal transcribed spacer (its), 18S ribosomal RNA (ssu rRNA), and elongation factor (ef) are candidates, in which the first three genetic markers are commonly employed for assemblage characterization of G. duodenalis [13–15].
The presence and assemblage distribution of G. duodenalis have been evaluated among different groups of healthy subjects and persons with background diseases. However, there are limited data about the assemblages of G. duodenalis in patients who suffer from tuberculosis (TB) [16–19]. Indeed, there is no data about distribution of assemblages in TB patients. Therefore, the current study aimed to characterize assemblages of G. duodenalis isolated from human subjects with and without TB.
Materials and methods
Ethics approval and consent to participate
All procedures in this study were according to the received approval from the Ethics Committee of the Shahid Beheshti University of Medical Science (SBMU), Tehran, Iran (IR.SBMU.MSP.REC.1395.323) and the Ethical Review Committee of the Research Institute for Gastroenterology and Liver Diseases, Shahid Beheshti University of Medical Sciences, Tehran, Iran (IR.SBMU.RIGLD.REC.1399.056).
Consent was informed to participates and verbal consent was obtained from all subjects and/or their legal guardian(s). For those patients with age≤16, informed consent was obtained from their respective parent(s)/guardian(s) as well.
Stool sample collection and DNA extraction
This study was conducted on 30 Giardia-positive samples, which had been obtained from 427 stool samples collected from our previous studies (261 TB patients) [19, 20], as well as samples, which were referred to the Foodborne and Waterborne Diseases Research Center, Research Institute for Gastroenterology and Liver Diseases, Shahid Beheshti University of Medical Sciences. All samples were either positive or suspected for G. duodenalis using lugol’s iodine staining and microscopically examination. Total DNA was extracted from stool samples using DNA stool extraction mini kit (Yekta Tajhiz, Tehran, Iran) with some modifications [21]. Purified DNA was stored at -20°C.
Multilocus genotyping
Nested PCR was employed to amplify the bg, gdh, and tpi genes among G. duodenalis isolates using primers and PCR conditions, which were mentioned elsewhere [22] (Table 1). To characterize assemblages of each isolate, PCR products were sequenced. Raw sequence data in forward direction was viewed using the Chromas Lite version 2.6 sequence analysis program (https://chromas.software.informer.com/2.6/). The nucleotides were checked and manually edited, where required. The BLAST tool (http://blast.ncbi.nlm.nih.gov/Blast.cgi) was used to compare nucleotide sequences with sequences previously submitted to the GenBank database.
Phylogenetic analyses
Generated sequences were trimmed and aligned based on appropriate reference sequences using BioEditv.7.2.6 software. Phylogenetic trees were constructed for targeted fragments of each tpi, bg, and gdh gene of G. duodenalis using the Maximum-likelihood algorithm and Tamura 3-parameter model in MEGAX software, together with a number of sequences, which were retrieved from the GenBank database to evaluate the molecular distance and phylogenetic relationships among isolates [23]. The reasons for choosing Tamura 3-parameter are the analyzing both transitional and transversional rates, G+C content bias, and correcting multiple hits (http://www.megasoftware.net/) [23]. The reliabilities of the trees were assessed using the bootstrap analysis with 1000 replications.
Statistical analysis
Statistical analyses, Pearson’s Chi-square (χ2) for independence and Fisher’s exact tests incorporated in SPSS version 23 software (SPSS Inc. Chicago, IL, USA) were employed to compare the frequency of G. duodenalis assemblages in symptomatic and asymptomatic subjects. Statistical significance was set as a P-value < 0.05.
Results
Prevalence and clinical data
From 427 tested stool samples, 227 (53.16%) and 200 (46.84%) were male and females, respectively. Indeed, 261 (61.12%) patients were TB positive and 166 (38.88%) were healthy people (non-TB group). From these samples, 30 (7.02%) were positive or suspected for Giardia using microscopy analysis including 17 (57%) and 13 (43%) for healthy and TB-infected subjects, respectively. A significant co-existence of Giardia and tuberculosis was not seen (P-value = 0.051). From Giardia-positive samples, 17 (57%) were males and 13 (43%) were females. There was no statistically significant correlation between the presence of Giardia and gender (P-value = 0.709). The mean age ± standard deviation (SD) and the median age of Giardia-positive subjects were 28.27±18.13 and 29, respectively. The age range of positive samples were from < 7 to 65 years. The highest frequency of Giardia infection was observed in the age group of 8–20 (26.6%; 8/30), while the age groups of <7 and 51–65 showed the lowest frequency (13.3%; 4/30). In addition, 14 (46.7%) of infected subjects were asymptomatic and 16 (53.3%) showed clinical symptoms including abdominal pain with diarrhea 12 (75%), diarrhea 3 (18.75%), and nausea and vomiting 1 (6.25%) (Tables 2 and 3).
Molecular detection and genotyping
From 30 microscopically Giardia-positive samples, PCR products of all three genes was successfully amplified in 25 single samples (83.3%) consisted of 20, 15, and 13 for tpi, bg, and gdh genes, respectively. The sequence results of three bg and seven gdh genes showed high similarity to either bacteria or viruses. Consensus assemblage analysis showed that 13/25 (52%) and 8/25 (32%) were identified as assemblage A and assemblages B, respectively, whereas 4/25 (16%) were either assemblage A or B with different genes.
The bg gene analysis showed that 8/15 (53%) of isolates belonged to assemblage A with sub-assemblages AII and AIII, and 7/15 (47%) isolates belonged to assemblage B with sub-assemblage BIII. Result of the gdh gene showed that 7/13 (54%) were identified as assemblage A with sub-assemblages AII and AIII, and 6/13 (46%) were identified as assemblage B with sub-assemblages BIII and BIV. From 20 successful sequences for tpi gene, 13 (65%) belonged to assemblage A with sub-assemblage AII, and 7 (35%) were assemblage B with sub-assemblages BIII. Overall, AII was the most prevalent sub-assemblage detected in 8/25 (32%), followed by BIII in 5/25 (20%), AIII in 1/25 (4%), and BIV in 1/25 (4%). Non-consensus sub-assemblages were seen in five samples including AII/AIII in 4/25 (16%) and BIII/BIV in 1/25 (4%). In addition, non-consensus assemblages/sub-assemblages AII/BIII and BIII/BIV/AII were characterized in 3/25 (12%) and 1/25 (4%), respectively (Table 4).
Among TB patients, from 13 Giardia-positive samples, assemblages A and B were characterized among seven (53.84%) and three (23.07%), respectively, while three (23.07%) of remained samples did not amplified or were failed in sequencing. From 17 Giardia-positive samples, Assemblages A and B were characterized among six (35.29%) and five (29.41%) of non-TB subjects, respectively, while four (23.53%) samples were assemblage A or B with different genes and two (23.07%) did not amplified or were failed in sequencing.
Phylogenetic analyses
Phylogenetic analysis of bg, tpi, and gdh genes revealed that assemblages A and B were clearly separated and grouped with reference assemblages retrieved from the GenBank database for each gene (Fig 1). Moreover, the phylogenetic analysis of sequences of all three genes represented that there was no separation based on the presence of TB, gastrointestinal symptoms, sources, and geographical areas.
Phylogenetic trees of A) bg, B) tpi, and C) gdh genes of G. duodenalis obtained from this study together with reference sequences retrieved from GenBank. The trees were constructed based on the Maximum likelihood (ML) method and the Tamura 3-parameter model in MEGAX. Bootstrap values lower than 75 were omitted. Our sequences were indicated with black-filled triangles (▲).
Discussion
Giardia duodenalis is a prevalent protozoan, particularly in developing region, which infects humans and a board range of animals [13]. The prevalence of G. duodenalis in Iran has been even reported more than 30%; however, the prevalence rate may vary regarding the studied population and employed diagnostic methods [24–28]. Although among epidemiological surveys, G. duodenalis is one of the most frequently reported protozoan, our knowledge is still insufficient about the molecular epidemiology and circulating assemblages of the parasite in Iran. The current study is one of the rare research mining the molecular characterization and assemblages of G. duodenalis in TB patients using multilocus genotyping (MLG) in the world.
Assemblage characterization of G. duodenalis is a challenge, since multi-copy genes, like ssu rRNA gene, are not discriminative enough to identify assemblages and sub-assemblages [29, 30]. Besides, success rate for amplification of single copy genes, which are discriminative, varies from 11 to 90% [31]. Therefore, multigene typing is a valid model for molecular characterization of G. duodenalis at assemblage and sub-assemblage level [13]. Among reliable genes for assemblage characterization of G. duodenalis, three loci tpi, gdh, and bg are well-known genetic targets [13]. In the current study, from 30 microscopically positive samples, 25 samples were amplified by each/two/all genes including 20, 15, and 13 samples for tpi, bg, and gdh, respectively. This observation is in accordance to previously published papers indicating inconsistency between the prevalence of G. duodenalis-positive samples in microscopy and molecular amplification [32–34]. This discrepancy could be related to the quality of extracted DNA, the copy number of targeted genes, and the presence of PCR inhibitors [31, 34].
In the current study, three and seven sequences of bg and gdh genes were highly similar to bacteria (Bifidobacterium, Feacalibacterium, Pseudomonas, Kinneretia and Escherichia coli) and virus (Siphoviridae), while none of tpi locus sequences were identical to non-Giardia sequences. Such results highlight the concern for false positive results of non-specific target gene amplification by PCR without sequencing [31].
As a result, assemblage A was the most prevalent genotypes in the current study. Assemblage A is the predominant genetic lineage of G. duodenalis in humans in most of molecular studies in Iran [28, 34, 35]. In a study conducted by Sarkari et al. [36], assemblage A was identified among 74.4% of Giardia-positive samples based on the amplification followed by restriction fragment length polymorphism (RFLP) of partial fragment of gdh gene. Mahmoudi et al. [28] reported assemblage A as the major genotype based on the partial amplification and sequencing of gdh gene. In addition, Bahramdoust et al., [35] designed and evaluated a real-time PCR coupled with high resolution melting curve analysis (HRM) to detect and characterize G. duodenalis in humans and dogs, and reported assemblage A as the major genotype in humans. Although assemblage A seems to be the predominant genotype in humans in Iran [37–39], there are controversial results, as well. For example, in a MLG study conducted in Iran, the presence of assemblages A and B were similar [34]. Most of assemblage A and all of assemblage B were AII and BIII/BIV, respectively, which are supposed to be responsible for anthroponotic transmission [2, 34]. Interestingly, an inconsistency between AII and AIII was observed in sub-assemblage analysis by different genes. In addition, all sub-assemblage AIII were identified based on bg gene sequencing. However, AIII was supposed to be exclusively reported from wild ruminants [40, 41], and the presence of this sub-assemblage in this study may be attributed to the misassigned sequences, which have been submitting to the GenBank database, and have to be carefully interpreted. Furthermore, it is suggested to employ either/both tpi or/and gdh genes alongside with bg locus for sub-assemblage analysis.
Regarding our results, significant correlation was not seen between clinical symptoms and certain assemblage. Furthermore, there was no correlation between certain assemblage and tuberculosis. Actually, a little is known about the correlation between genetic variability of Giardia and presentation of clinical symptoms. Although there are reports demonstrating an association between assemblages and type of symptoms [42, 43], most of studies failed to link genetic variability of Giardia with symptoms [34, 44, 45].
Phylogenetic analysis showed that all sequences were clearly separated based on the assigned assemblages and grouped with their reference sequences for each gene. However, an inconstancy was appeared between the assigned assemblages by either bg or gdh genes and tpi. In another word, in four G. duodenalis sequences, which were characterized as assemblages either A or B with two bg and gdh genes, the results of tpi gene was conflicting. This issue could be related to the segregation sites, the number of mutation, single nucleotide polymorphisms (SNPs), and discriminatory power of each target gene [13]. This finding highlights the insufficiency of a single target gene screening and the need for MLG investigation for molecular epidemiology studies of Giardia.
Conclusion
This study is the first analyzing G. duodenalis assemblages in TB patients using MLG approach. The assemblage A was the predominant genotype in our isolates, but a significant correlation between certain assemblage with symptoms and TB was not observed. The high prevalence of assemblage AII indicated the importance of anthroponotic transmission of Giardia in both healthy and TB-infected subjects. In addition, considering the exclusive reports of sub-assemblage AIII in wild ruminants, the presence of AIII in the current study have to be carefully interpreted. The inconsistency between the assemblage results of either bg or gdh genes and tpi gene signify the insufficiency of single gene analysis and the necessity of MLG in molecular epidemiology of G. duodenalis.
Acknowledgments
The authors thank all members of the Foodborne and Waterborne Diseases Research Center for their collaborations.
References
- 1. Ryan U, Zahedi A. Molecular epidemiology of giardiasis from a veterinary perspective. Adv Parasitol. 2019;106:209–54. pmid:31630759
- 2. Cacciò SM, Lalle M, Svärd SG. Host specificity in the Giardia duodenalis species complex. Infect, Gen Evol: journal of molecular epidemiology and evolutionary genetics in infectious diseases. 2018;66:335–45.
- 3. Barlaam A, Sannella AR, Ferrari N, Temesgen TT, Rinaldi L, Normanno G, et al. Ready-to-eat salads and berry fruits purchased in Italy contaminated by Cryptosporidium spp., Giardia duodenalis, and Entamoeba histolytica. Int J Food Microbiol. 2022;370:109634.
- 4. Hatam-Nahavandi K, Mohebali M, Mahvi AH, Keshavarz H, Mirjalali H, Rezaei S, et al. Subtype analysis of Giardia duodenalis isolates from municipal and domestic raw wastewaters in Iran. Environ Sci Pollut Res Int. 2017;24:12740–7. pmid:26965275
- 5. Javanmard E, Mirsamadi ES, Olfatifar M, Ghasemi E, Saki F, Mirjalali H, et al. Prevalence of Cryptosporidium and Giardia in vegetables in Iran: a nineteen-years meta-analysis review. J Environ Health Sci Engin. 2020;18:1629–41.
- 6. Allain T, Buret AG. Pathogenesis and post-infectious complications in giardiasis. Adv Parasitol. 2020;107:173–99. pmid:32122529
- 7. Dixon BR. Giardia duodenalis in humans and animals—transmission and disease. Res Vet Sci. 2021;135:283–9. pmid:33066992
- 8. Certad G, Viscogliosi E, Chabé M, Cacciò SM. Pathogenic mechanisms of Cryptosporidium and Giardia. Trend Parasitol. 2017;33:561–76. pmid:28336217
- 9. Ryan U, Hijjawi N, Feng Y, Xiao L. Giardia: an under-reported foodborne parasite. Int J Parasitol. 2019;49:1–11.
- 10. Leung AKC, Leung AAM, Wong AHC, Sergi CM, Kam JKM. Giardiasis: an overview. Recent Pat Inflamm Allergy Drug Discov. 2019;13:134–43. pmid:31210116
- 11. Cai W, Ryan U, Xiao L, Feng Y. Zoonotic giardiasis: an update. Parasitol Res. 2021;120:4199–218. pmid:34623485
- 12. Feng Y, Xiao L. Zoonotic potential and molecular epidemiology of Giardia species and giardiasis. Clin Microbiol Rev. 2011;24:110–40.
- 13. Capewell P, Krumrie S, Katzer F, Alexander CL, Weir W. Molecular epidemiology of Giardia infections in the genomic era. Trend Parasitol. 2021;37:142–53. pmid:33067130
- 14. Cacciò SM, Ryan U. Molecular epidemiology of giardiasis. Mol Biochem Parasitol. 2008;160:75–80. pmid:18501440
- 15. Heyworth MF. Giardia duodenalis genetic assemblages and hosts. Parasite (Paris, France). 2016;23:13. pmid:26984116
- 16. Dwarakanath AD, Welton M, Ellis CJ, Allan RN. Interrelation of strongyloidiasis and tuberculosis. Gut. 1994;35:1001–3. pmid:8063205
- 17. Li XX, Zhou XN. Co-infection of tuberculosis and parasitic diseases in humans: a systematic review. Parasit Vector. 2013;6:79. pmid:23522098
- 18. Manuel Ramos J, Reyes F, Tesfamariam A. Intestinal parasites in adults admitted to a rural Ethiopian hospital: Relationship to tuberculosis and malaria. Scandinavian J Infect Dis. 2006;38:460–2. pmid:16798694
- 19. Taghipour A, Tabarsi P, Sohrabi MR, Riahi SM, Rostami A, Mirjalali H, et al. Frequency, associated factors and clinical symptoms of intestinal parasites among tuberculosis and non-tuberculosis groups in Iran: a comparative cross-sectional study. Trans R Soc Trop Med Hyg. 2019;113:234–41. pmid:30624729
- 20. Taghipour A, Azimi T, Javanmard E, Pormohammad A, Olfatifar M, Rostami A, et al. Immunocompromised patients with pulmonary tuberculosis; a susceptible group to intestinal parasites. Gastroenterol Hepatol Bed Bench. 2018 Winter;11(Suppl 1):S134–S139. pmid:30774820
- 21. Mohammad Rahimi H, Mirjalali H, Zali MR. Molecular epidemiology and genotype/subtype distribution of Blastocystis sp., Enterocytozoon bieneusi, and Encephalitozoon spp. in livestock: concern for emerging zoonotic infections. Sci Rep. 2021;11:17467. pmid:34471179
- 22. Ryan U, Cacciò SM. Zoonotic potential of Giardia. Int J Parasitol. 2013;43:943–56. pmid:23856595
- 23. Kumar S, Stecher G, Li M, Knyaz C, Tamura K. MEGA X: Molecular evolutionary genetics analysis across computing platforms. Mol Biol Evol. 2018;35:1547–9. pmid:29722887
- 24. Abbaszadeh Afshar MJ, Barkhori Mehni M, Rezaeian M, Mohebali M, Baigi V, Amiri S, et al. Prevalence and associated risk factors of human intestinal parasitic infections: a population-based study in the southeast of Kerman province, southeastern Iran. BMC Infect Dis. 2020;20:12. pmid:31906872
- 25. Daryani A, Hosseini-Teshnizi S, Hosseini SA, Ahmadpour E, Sarvi S, Amouei A, et al. Intestinal parasitic infections in Iranian preschool and school children: A systematic review and meta-analysis. Act Trop. 2017;169:69–83. pmid:28130101
- 26. Hemmati N, Razmjou E, Hashemi-Hafshejani S, Motevalian A, Akhlaghi L, Meamar AR. Prevalence and risk factors of human intestinal parasites in Roudehen, Tehran Province, Iran. Iran J Parasitol. 2017;12:364–73. pmid:28979346
- 27. Kasaei R, Carmena D, Jelowdar A, Beiromvand M. Molecular genotyping of Giardia duodenalis in children from Behbahan, southwestern Iran. Parasitol Res. 2018;117:1425–31.
- 28. Mahmoudi MR, Mahdavi F, Ashrafi K, Forghanparast K, Rahmati B, Mirzaei A, et al. Report of Giardia assemblages and giardiasis in residents of Guilan province-Iran. Parasitol Res. 2020;119:1083–91.
- 29. Brynildsrud O, Tysnes KR, Robertson LJ, Debenham JJ. Giardia duodenalis in primates: Classification and host specificity based on phylogenetic analysis of sequence data. Zoonoses Public Health. 2018;65:637–47. pmid:29654656
- 30. Wielinga CM, Thompson RC. Comparative evaluation of Giardia duodenalis sequence data. Parasitology. 2007;134:1795–821.
- 31. Thompson RCA, Ash A. Molecular epidemiology of Giardia and Cryptosporidium infections. Infect Genet Evol: journal of molecular epidemiology and evolutionary genetics in infectious diseases. 2016;40:315–23.
- 32. Maestrini M, Berrilli F, Di Rosso A, Coppola F, Guadano Procesi I, Mariacher A, et al. Zoonotic Giardia duodenalis genotypes and other gastrointestinal parasites in a badger population living in an anthropized area of central Italy. Pathogens (Basel, Switzerland). 2022;11.
- 33. Lee MF, Auer H, Lindo JF, Walochnik J. Multilocus sequence analysis of Giardia spp. isolated from patients with diarrhea in Austria. Parasitol Res. 2017;116:477–81.
- 34. Rafiei A, Baghlaninezhad R, Köster PC, Bailo B, Hernández de Mingo M, Carmena D, et al. Multilocus genotyping of Giardia duodenalis in Southwestern Iran. A community survey. PloS One. 2020;15:e0228317. pmid:32027684
- 35. Bahramdoost Z, Mirjalali H, Yavari P, Haghighi A. Development of HRM real-time PCR for assemblage characterization of Giardia lamblia. Act Trop. 2021;224:106109.
- 36. Sarkari B, Ashrafmansori A, Hatam GR, Motazedian MH, Asgari Q, Mohammadpour I. Genotyping of Giardia lamblia isolates from human in southern Iran. Trop Biomed. 2012;29:366–71. pmid:23018499
- 37. Mirrezaie E, Beiromvand M, Tavalla M, Teimoori A, Mirzavand S. Molecular Genotyping of Giardia duodenalis in humans in the Andimeshk county, southwestern Iran. Act Parasitol. 2019;64:376–83. pmid:30968348
- 38. Rayani M, Hatam G, Unyah NZ, Ashrafmansori A, Abdullah WO, Hamat RA. Phylogenetic analysis of Giardia lamblia human genotypes in Fars province, southern Iran. Iran J Parasitol. 2017;12:522–33.
- 39. Sepahvand A, Hosseini-Safa A, Yousofi HA, Tajedini MH, Pahlavan Gharehbabah R, Pestehchian N. Genotype characteristics of Giardia duodenalis in patients using high resolution melting analysis technique in Khorramabad, Iran. Iran J Parasitol. 2020;15:204–13.
- 40. Ballweber LR, Xiao L, Bowman DD, Kahn G, Cama VA. Giardiasis in dogs and cats: update on epidemiology and public health significance. Trends Parasitol. 2010 Apr;26(4):180–9. pmid:20202906
- 41. Seabolt MH, Roellig DM, Konstantinidis KT. Genomic comparisons confirm Giardia duodenalis sub-assemblage AII as a unique species. Front Cell Infect Microbiol. 2022 Oct 17;12:1010244.
- 42. Puebla LJ, Núñez FA, Fernández YA, Fraga J, Rivero LR, Millán IA, et al. Correlation of Giardia duodenalis assemblages with clinical and epidemiological data in Cuban children. Infect Genet Evol: journal of molecular epidemiology and evolutionary genetics in infectious diseases. 2014;23:7–12.
- 43. Puebla LJ, Núñez FA, García AB, Rivero LR, Millán IA, Prado RC. Prevalence of Giardia duodenalis among children from a central region of Cuba: molecular characterization and associated risk factors. J Parasit Dis: official organ of the Indian Society for Parasitology. 2017;41:405–13. pmid:28615850
- 44. Köster PC, Malheiros AF, Shaw JJ, Balasegaram S, Prendergast A, Lucaccioni H, et al. Multilocus genotyping of Giardia duodenalis in mostly asymptomatic indigenous people from the Tapirapé tribe, Brazilian Amazon. Pathogens (Basel, Switzerland). 2021;10.
- 45. Langbang D, Dhodapkar R, Parija SC, Premarajan KC, Rajkumari N. Molecular characterization of Giardia intestinalis assemblages in children among the rural and urban population of Pondicherry, India. Trop Parasitol. 2022;12:8–14. pmid:35923262