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Introduction
Amoebiasis is an infection in humans caused by the protozoan Entamoeba histolytica, an extracellular parasitic species classified as a category B biodefense priority pathogen by the National Institute of Allergy and Infectious Diseases (NIAID)1,2. This parasitosis, considered the third leading cause of death by protozoa (resulting in 40,000 to 100,000 deaths per year)3-5, is prevalent in countries that have not yet achieved optimal health services. In other regions, such as Europe, Entamoeba infections are caused by travel activities to endemic regions or immigrants6. Worldwide, amoebiasis is considered one of the 15 leading causes of childhood diarrhea1 (in children < 2 years of age) because its primary involvement is at the colon (amoebic colitis).
The World Health Organization (WHO) estimates that 500 million people worldwide may be infected with Entamoeba, but only 10% are infected with E. histolytica2. Also, about 80-90% of individuals with amoebiasis are asymptomatic7. For symptomatic patients, amoebiasis severity is influenced by the patient’s genetics8,9, the genotype of the parasite10, and the microbiota or pathogenic microorganisms present in the gut11,12. These factors contribute to the spread of E. histolytica, leading to intestinal mucosa inflammation and tissue damage. Intestinal (dysentery) and extraintestinal (hepatic abscesses) complications are associated with mortality2.
Routine diagnosis of amoebiasis is based on microscopic techniques, such as observing tetranucleated cysts or hematophagous trophozoites (Figure 1), or immunological techniques, such as antigen or antibody detection. Unfortunately, the existence of other non-pathogenic infecting Entamoeba species (with cysts morphologically identical to those of E. histolytica) or the inability to differentiate a recent infection from previous ones makes both techniques ineffective for specific diagnosis13,14.
Figure 1 Forms of E. histolytica. Light microscopy images of tetranucleated cysts (top) and trophozoites (bottom) are shown.
For this reason, molecular tests have been developed based on the detection of parasite nucleic acids by the polymerase chain reaction and its variants (nested, multiplex, and real-time PCR). These techniques resolve aspects of identification, taxonomy, epidemiology, and clinical importance; they also provide knowledge on the genetic diversity of Entamoeba species15,16, which are associated with pathogenic ambiguity17,18. The application of this knowledge provides guidelines for the appropriate clinical management of amoebiasis.
The present review provides an overview of methodological strategies for diagnosing amoebiasis, a disease still considered undertreated in tropical and subtropical regions, by identifying E. histolytica, a species with morphology indistinguishable from other non-pathogenic species. We highlight the molecular techniques that have led to a better understanding of this parasitosis and the causative species.
Pathology of E. histolytica
Infection with E. histolytica occurs when food or water contaminated with the cyst form of the amoeba is consumed. Typically, the parasite is confined to the intestinal lumen of the host and feeds on bacteria, cellular debris, and food residues. In its trophozoite form, the amoeba can disperse along the intestinal mucosa as polyploid cells that adhere to the mucosa through the action of the lectin galactose/N-acetylgalactosamine (Gal/GalNAc), causing diarrhea and colitis19 (Figure 2).
Figure 2 Steps in the infectious process of E. histolytica. Amoeba cysts reach the intestinal lumen, develop into trophozoites and colonize the intestinal mucosa and epithelium. The release of amoebic components (dashed black arrows) leads to the pathogenesis of E. histolytica: cell death, inflammation (red line), and invasive colonization (solid black arrows). Occasionally, access to the bloodstream allows dissemination into specific organs, including the liver, producing amoebic liver abscesses (ALA). The techniques commonly used for diagnosis both types of amoebiasis are also listed. ECM, extracellular matrix; PG2, prostaglandins E2.
The production and secretion of glucosidases and cysteine proteases by E. histolytica (EhCPs) confer resistance to physicochemical barriers such as mucins, secreted immunoglobulin A (IgA), and other antimicrobial molecules20. Additionally, trophozoites produce several molecules, such as amoebapores, prostaglandin E2, mucopolysaccharidases, and phospholipase A219. These molecules are implicated in pathogenicity by producing effects such as contact-dependent and contact-independent cytotoxicity, hemolytic activity, phagocytosis, and trogocytosis19,21; the latter includes the participation of the AGC 1 family of kinases22. E. histolytica feeds on phagocytized erythrocytes and apoptotic and necrotic cells outside the intestinal lumen. This process apparently constitutes a virulence factor in avoiding detection by the immune system during tissue invasion2,23. The activity of EhCPs leads to disruption of extracellular matrix components and activation of metalloproteinases that destroy cell junctions to initiate extraintestinal invasion23. In some cases, the parasites can enter the portal vein and reach the liver, causing an amoebic liver abscess (ALA). In other cases, they infest the lungs or the brain, mainly in immunocompromised patients2,19. Untreated intestinal amoebiasis or ALA can lead to death2,19.
If not lethal, amoebiasis negatively influences growth and cognitive development in children24-26. Therefore, proper diagnosis of this parasitosis is necessary for effective treatment and improvement in the quality of life.
Methods for routine diagnosis of amoebiasis
Table 1 summarizes the methods that have been reported for the routine diagnosis of amoebiasis, indicating the sensitivity of each method. Most of these methods are particular in their methodology and are based on direct visualization of cysts or trophozoites or the presence of antigens or antibodies. Mainly, immunological strategies are not considered the reference technique, although they are widely used and allow the identification of E. histolytica13.
Table 1 Sensitivity of conventional methods for the diagnosis of amoebiasis
| Diagnosis method | Identification of E. histolytica | Sample | Sensitivity | Detection | Time for analysis | Reference |
|---|---|---|---|---|---|---|
| Microscopy | No | Feces (fixed) | 25-60% | Trophozoites/cystsa | 1-2 h | 35 |
| Culture and isoenzyme analysisb | Yes | Feces/ALA aspirate | Gold-standard | Zymodeme | 7 days | 46 |
| 5 | ||||||
| Antigen detection | Yes | Feces | 85-100% | Fecal-antigens | 15-30 min | 46,58 |
| Yes | Serum | 95.7%c | Lectin Gal/GalNAc | 37 | ||
| Antibody detection | Yes | Serum | 78%d | IgM/IgG anti-lectin | 10 min | 37 |
| Yes | Serum | > 90e | 5 |
aHematophagous trophozoites suggest the presence of E. histolytica, usually in patients with acute dysentery.
bAxenic culture media TYI-S-33 and YI-S, specific for E. histolytica.
cSerological analysis was performed before treatment with metronidazole. Sensitivity decreases to 34.8% after treatment.
dSerum from patients with acute amebic liver abscess.
eSensitivity of 100% for patients with ALA and > 90% in serum from patients convalescing from infection. Ig, immunoglobulin.
Microscopy
The classic diagnostic technique for parasitic infections is microscopy, used to identify hematophagous trophozoites and tetranucleated cysts in fecal samples27, and also provides material for teaching and research28. Due to its simplicity is the method of choice in rural health centers in developing countries where amoebiasis is prevalent14. However, its efficacy depends on the skill of laboratory personnel in the correct identification of trophozoites since, in an immobile state, they can be confused with leukocytes, macrophages, and tissue cells. Additionally, rapid sample handling is required (20-30 min), as the trophozoites are destroyed, resulting in false negatives29,30.
Microscopy has a sensitivity of 60% because identifications are only assigned as “Entamoeba complex.” There is a limitation to differentiate species morphologically identical to E. histolytica at the level of the nucleus and tetranucleated cysts, such as E. dispar (non-pathogenic) and E. moshkovskii (of potential pathogenicity)18,27.
Innovations in this technique, such as using sample concentration by sedimentation31 or staining with ferric hematoxylin13, increase its sensitivity. For example, the use of hematoxylin allowed the differential identification of hematophagous trophozoites of E. histolytica in fecal samples and thus measured the prevalence (11%) of this species in rural areas in Lima, Peru32.
Biochemical method
This method was considered the gold standard, although it is currently used more in the research field than in the clinical settings30. It employs fecal culture, followed by electrophoretic analysis of some enzymes (hexokinase, malate dehydrogenase, glucose phosphate isomerase, phosphoglucomutase, among others) to establish zymodemes as markers. The technique can accurately differentiate the presence of E. histolytica or E. dispar since they have different hexokinase enzymes33. However, it has disadvantages for its application in epidemiology due to the long processing time (1 week), the requirement for special laboratory facilities, immediate processing of samples, interference from antiparasitic drugs in treated patients, and inability to identify other infecting Entamoeba species34. Additionally, the technique can give false-negative results opposite to those obtained by microscopy and has generally been used only for intestinal amoebiasis29.
Immunological techniques
The enzyme-linked immunosorbent assay (ELISA) technique is based on detecting E. histolytica antigens in fresh fecal samples. This technique has higher sensitivity (80 to 94%) and specificity (94 to 100%) than microscopy and culture35. The most commonly used antigen is the Gal/GalNac adhesion lectin, detected by monoclonal antibodies in symptomatic and asymptomatic patients35. This lectin is highly conserved in E. histolytica and has antigenic characteristics different from the E. dispar lectin36. ELISA also allows the detection of serum antigen levels. However, its sensitivity is reduced (by 16%) when there is prior treatment with antibiotics such as metronidazole, used to treat ALA37. Over the past 20 years, the use of ELISA kits has replaced both microscopy and the gold-standard method for clinical purposes because of the rapid results, the ability to differentiate E. histolytica and E. dispar, sensitivity and specificity, affordability, and large-scale diagnostic capability38,39.
Furthermore, along with other serological methods such as immunodiffusion, counterimmunoelectrophoresis, indirect hemagglutination, and immunoelectrophoresis, ELISA has been used to detect antibodies in the case of extraintestinal amoebiasis29. These methods detect anti-lectin Gal/GalNac IgG antibodies produced at high levels by patients infected with E. histolytica and absent in those infected with E. dispar. In acute E. histolytica infection, about 75-85% of patients develop high levels of antibodies, and more than 90% develop them once the infection is resolved (convalescent titers)40,41.
The detection of IgG usually favors epidemiological studies in regions with amoebiasis seroprevalences above 50%; however, it limits the diagnosis of acute infections, so the combined application of this method with antigen detection is necessary37,42. Alternatively, the detection of IgM antibodies can be used; these antibodies do not persist over time and can be detected in periods of less than one week43.
Molecular methods
The application of methods based on amplifying DNA fragments to diagnose amoebiasis solved the problem of differentiating E. histolytica from other species44 and determining its prevalence and genetic differences45. PCR has greater sensitivity and specificity than microscopy and antigen detection44,46 and allows early detection of amoebiasis for timely treatment47. Species differentiation is achieved by amplifying DNA regions corresponding to single- or multi-copy genes.
The small ribosomal unit gene (18S rRNA) is the most widely used PCR marker for taxonomic differentiation between E. histolytica and E. dispar6,38. Other genes used are 30kDa antigen48, hemolysin (HLY6)49, serine-rich E. histolytica protein (SREHP)50, actin51, cysteine protease 8 (CP8)3, and adhesin (adh112)52.
With the use of PCR, it has been possible to identify new parasitic species in humans, such as E. moshkovskii (present among infants in Bangladesh)53, E. bangladeshi (in symptomatic and asymptomatic patients)54, and the species E. coli, E. hartmanni, and E. polecki (commensal species), with morphology identical to E. histolytica and even with shared virulence factors55,56. Additionally, this technique detects mixed infections of E. histolytica and E. moshkovskii or E. dispar, the confluence of which is associated with gastrointestinal complications57. Table 2 shows the main PCR protocols and variants used as a reference for current studies.
Table 2 Types of PCR tests and parameters used for the diagnosis of amoebiasis (continued)
| Method | Species in which it is used | Target gene | Product (bp) | Primers (5’- 3’) used | Amplification protocol | Ref | Disadvantages |
|---|---|---|---|---|---|---|---|
| Conventional PCR | E. histolytica | 30 kDa antigen | 100 | P-11 5’- GGAGGAGTAGGAAAGTTGAC-3’ | Denaturation: 94°C x 2 min 45 cycles (denaturation: 94°C x 60 s; hybridization: 55°C x 90 s; extension: 72°C x 90 s) | 48 | Electrophoresis-dependent technique, with risk of contamination and unquantifiable results |
| P-12 5’- TTCTTGCAATTCCTGCTTCGA-3’ | |||||||
| E. histolytica | HLY 6 | 256 | Eh6F 5’- GACCTCTCCTAATATCCTCGT-3’ | Denaturation: 94°C x 2 min 35 cycles (denaturation: 94°C x 60 s; hybridization: 55°C x 60 s; extension: 72°C x 60 s) | 49 | ||
| Eh6R 5’- GCAGAGAAGTACTGTGAAGG-3’ | |||||||
| E. histolytica | 18S rRNA | 166 | EnF 5’- ATGCACGAGAGCGAAAGCAT-3’ | Denaturation: 94°C x 3 min 35 cycles (denaturation: 94°C x 60 s; hybridization: 58°C x 60 s; extension: 72°C x 60 s) | 67 | ||
| EhR 5’- GATCTAGAAACAATGCTTCTCT-3’ | |||||||
| E. dispar | 752 | EnF 5’- ATGCACGAGAGCGAAAGCAT-3’ | |||||
| Ehd 5’- CACCACTTACTATCCCTA CC-3’ | |||||||
| E. moshkovskii | 580 | EnF 5’- ATGCACGAGAGCGAAAGCAT-3’ | |||||
| Enm 5’- TGACCGGAGCCAGAGACAT-3’ | |||||||
| Conventional multiplex PCR | E. histolytica | 18S rRNA | EntaF, 5’- ATGCACGAGAGCGAAAGCAT-3’ | Denaturation: 94°C x 3 min 30 cycles (denaturation: 94°C x 60 s; hybridization: 58°C x 60 s; extension: 72°C x 60 s) | 62, 64, 67 | ||
| 166 | EhR, 5’- GATCTAGAACTCACACTTATGT-3’ | ||||||
| E. dispar | 752 | EdR, 5’- CACCACTCCCTACTATTATC-3’ | |||||
| E. moshkovskii | 580 | EmR, 5’- TGAGCCCCAGAGGAGACAT-3’ | |||||
| Multiplex nested PCR | SSU-rRNA | 900 | E-1F, 5’- TTTGTATTAGTACAAA-3’ | Denaturation: 92°C x 60 s 30 cycles (denaturation: 92°C x 60 s; hybridization: 55°C x 60 s; extension: 72°C x 60 s)a | 53, 54 | Under the single format, it is tedious for
each amplification process. Under the multiplex format, there is a possibility of false positives. In both cases, the results are not quantifiable |
|
| E-2R, 5’- GTA[A/G] TATTGATATACT-3’ | |||||||
| E. histolytica | 550 | Eh-1F, 5’- AATGGCCAATTCATTCAATG-3’ | |||||
| Eh-2R, 5’- TTTAGAAACAATGCTTCTCT-3’ | |||||||
| E. moshkovskii | 200 | Ed-1F, 5’- AGTGGCCAATTTATGTAAGT-3’ | |||||
| Ed-2R, 5’- TTTAGAAACAATGTTTCTTC-3’ | |||||||
| E. dispar | 260 | Em-1F, 5’- CTCTTCACGGGGAGTGCG-3’ | |||||
| Em-2R, 5’- TCGTTAGTTTCATTACCT-3’ | |||||||
| 18S rRNA | 900 | E-1F, 5’- TAAGATGCACGAGAGCGAAA-3’ | Denaturation: 96°C x 2 min 30 cycles (denaturation: 96°C x 60 s; hybridization: 56°C x 60 s; extension: 72°C x 90 s)b | 68697071 | |||
| E-2R, 5’- GTACAAAGGGCAGGGACGTA-3’ | |||||||
| E. histolytica | 439 | EH-1F, 5’- AAGCATTGTTTCTAGATCTGAG-3’ | |||||
| EH-2R, 5’- AAGAGGTCTAACCGAAATTAG-3’ | |||||||
| E. moshkovskii | 553 | Mos-1F, 5’- GAAACCAAGAGTTTCACAAC-3’ | |||||
| Mos-2R, 5’- CAATATAAGGCTTGGATGAT-3’ | |||||||
| E. dispar | 174 | ED-1F, 5’- TCTAATTTCGATTAGAACTCT-3’ | |||||
| ED-2R, 5’- TCCCTACCTATTAGACATAGC-3’ | |||||||
| Real-time PCR with multiplex platform | 18S rRNA | 231 | Ehd-239F, -ATTGTCGTGGCATCCTAACTCAc | Denaturation: 95°C x 3 min 40 cycles (denaturation: 95°C x 15 s; hybridization: 60°C x 30 s; extension: 72°C x 30 s) | 75 | High implementation and operational costs.
Highly trained personnel |
|
| Ehd-88R, -GCGGACGGCTCATTATAACAc | |||||||
| E. histolytica | FAM-UCAUUGAAUGAAUUGGCCAUUU-BHQ1 | ||||||
| E. dispar | HEX-UUACUUACAUAAAUUGGCCACUUUG-BHQ1 | ||||||
| 18S rRNA | EntaF, 5'-ATG CAC GAG AGC GAA AGC AT-3' | Denaturation: 94°C x 3 min 30 cycles (denaturation: 94°C x 60 s; hybridization: 58°C x 60 s; extension: 72°C x 60 s) | 67 | ||||
| E. histolytica | 166 | EhR, 5'-GAT CTA GAA ACA ATG CTT CTC T-3' | |||||
| E. dispar | 752 | EdR, 5'-CAC CAC TTA CTA TCC CTA CC-3' | |||||
| E. moshkovskii | 580 | EmR, 5'-TGA CCG GAG CCA GAG ACA T-3' | |||||
| E. histolytica | 18S rRNA | 133 | HEX -GTTTGTATTAGTACAAAATGGC -BHQ1 | Denaturation: 95°C x 2 min and 50°C x 2 min 40 cycles (denaturation: 95°C x 15 s; extension: 55°C x 60 s) | 81 | ||
| E. dispar | 134 | Cy5 -GTATTAGTACAAAGTGGCCAA -BHQ3 | |||||
| E. moshkovskii | 145 | FAM -CTCGAGGTGGTTAACTCCAC -BHQ1 | |||||
| E. bangladeshi | 132 | TAMRA -GGGTGTTTAAAGCAAAACATTAA-BHQ2 | |||||
| LAMP | E. histolytica | SSU-rRNA | 166 | EhF, 5’- ATGCACGAGAGCGAAAGCAT-3’ | Amplification: 63°C x 120 min, and final heating of 90°C x 1 mind | 94 | The critical point of T° must be estimated
for the correct performance of the test. It depends mainly on the specificity of the primers |
| EhR, 5’- GATCTAGAACTCACACTTATGT-3’ | |||||||
| External primers | Ehd1-F3-5’- AAAGATAATACTTGAGACGA TCC-3’ | ||||||
| Ehd1-B3-5’- TCGTTATCCGTTATAATCTTGG-3’ | |||||||
| Internal primers | FIP-5’- CATCCTAACTCACTTAGAATGTCAAGTACAAAATGGCCAATTCATTC-3’ | ||||||
| BIP-5’- CACGACAATTGTAGAACACACAGTTCCTC GATACTACCAACTGAT-3’ | |||||||
| E. histolytica | HLY6 | External primers | Eh-2F3, 5’- GCACTATACTTGAACGGATTG-3’ | Amplification: 63°C x 60 min, and final heating of 90°C x 60 se | 93 | ||
| Eh-2B3, 5’- GTTTGACAAGATGTTGAGTGA-3’ | |||||||
| Internal primers | Eh-2FIP, 5’- TCGCCCTATACTCAAATATGACAAGACTTTGGTGGAAGATTCACG-3’ | ||||||
| Eh-2BIP, 5’- ATCTAGTAGCTGGTTCCACCTGAACACCTAATCATTATCTTTACCAATC-3’ | |||||||
| Additional primers | Eh-2F2, 5’- ACTTTGGTGGAAGATTCACG-3’ | ||||||
| Eh-2B2, 5×-CACCTAATCATTATCTTTACCAATC-3’ | |||||||
| LAMP-NALFIA triplex | E. histolytica | SREHP | Internal primers | Eh-FIP-SER GCTTCGTTCTTTAAAAATACACCGTCATTCTTGATTTGGATCAAGAAGT | Amplification: 63°C x 60 min, and final heating of 80°C x 5 minf | 50 | |
| Eh-BIP-SER-FITC 5’- AGTAGCTCAGCAAAACCAGAATCACTTGCTTTTTCATCTTCATCA-3’ | |||||||
| External primers | Eh-F3-SER 5’- TGCATTCACTAGTGCAACT-3’ | ||||||
| Eh-B3-SER 5’- GCTTGATTCTGAGTTATCACTTG-3’ | |||||||
| Primer loop | Eh-LB-SER-Biotin 5’- AAGTTCAAATGAAGATAATGAA-3’ | ||||||
| E. dispar-E. moshkovskii | LSU-rRNA | Internal primers | Eh-FIP-HLY 5’- TACGCCATTTCGTTTCCTTACTCGATTTCTTAACTGATACTCGACCG-3’ | ||||
| Eh-BIP-HLY-FITC 5×-AGATTGAAACTGTCCTTAGTGCAGCAGTTCTAAGATGTTTTTTTCCTC-3’ | |||||||
| External primers | Eh-F3-HLY 5’- CCTGAAAATGGATGGCATTA-3’ | ||||||
| Eh-B3-HLY 5’- CCCTAATCCAAGTAATGTTGTT-3’ | |||||||
| First loop | Enta-LB-HLY-Tex 5’- CTTGGTGGTAGTAGCAAATACTAAG-3’ |
aThe nested PCR used 1.0 µL of product from the first PCR under the same conditions, but changing the hybridization temperature to 62°C.
bMultiplex nested PCR used a set of multiple primers under the same conditions as the initial PCR, but changing the hybridization temperature to 48°C.
cGeneral primers for E. histolytica/E. dispar.
dProducts were evaluated by agarose gel electrophoresis (2.0%) and fluorescent detection.
eProducts were detected by turbidity, SYBR green staining change, fluorescence, and agarose gel electrophoresis (1.5%).
fThe products were captured by proteins fixed on a nitrocellulose membrane. HLY 6, hemolysin gene; LAMP, loop-mediated isothermal amplification; LSU-rRNA, long subunit of ribosomal RNA; NALFIA, nucleic acid lateral flow immunoassay with dry reagent; PCR, polymerase chain reaction; SREHP, serine-rich protein gene; SSU-rRNA, small subunit of ribosomal RNA.
DNA extraction
Like other molecular tests, the diagnosis of amoebiasis requires DNA of high purity and in sufficient quantity. Stool, the primary sample used, is a complex source of contaminants due to the presence of bacteria and human cells and a variety of metabolically derived substances, such as bile salts, which can interfere with or inhibit the amplification process57. Pre-incubation with bovine serum albumin is effective in removing some of these contaminants55. Another factor to consider is the thickness of cyst walls, which makes them resistant to chemical and physical lysis58. For example, in the case of Cryptosporidium spp., the combination of thermal treatments (freezing and rapid thawing) showed good results in the fragmentation of the cyst walls59.
As a general protocol, the combined use of cetyltrimethylammonium bromide (CTAB), proteinase K, and heat treatments effectively destroy cysts and trophozoites. The resulting DNA can then be precipitated with phenol/chloroform/isoamyl alcohol60.
In addition, there are commercial stool DNA extraction systems, such as the QIAamp Stool Mini Kit (QIAGEN), used for the differential diagnosis of Entamoeba species, which can correctly identify samples in 88% of cases57.
Conventional PCR
The use of conventional PCR marked two fundamental milestones in the diagnosis of amebiasis: 1) the ability to determine the actual prevalence of the species E. histolytica and E. dispar, which routine methods had not been able to resolve61, and 2) to provide an effective diagnosis for the adequate treatment of the infection38. In fact, in patients with a positive microscopy diagnosis of E. histolytica-E. dispar, PCR—through the 18S rRNA gene—allowed the identification of E. dispar as the most prevalent species61.
After the first report of E. moshkovskii in humans, the application of PCR for the diagnosis of amoebiasis became more important62. The development of new protocols for the simultaneous detection of E. histolytica, E. dispar, and E. moshkovskii species is based on a differential pattern of the core region size of the 18S rRNA gene63. Studies based on this technique corroborate the high global prevalence of E. dispar, followed by E. moshkovskii at the regional level64, the latter being associated with diarrhea in children65.
Conventional PCR has higher specificity, sensitivity (97-99%), and positivity than routine methods, including ELISA61,66, even when using small amounts of DNA obtained from fecal or culture samples44,67.
A variant of conventional PCR, PCR coupled to denaturing gradient gel electrophoresis (PCR-DGGE), employs urea and formaldehyde to create denaturing conditions and reliably discriminates E. histolytica from E. dispar52.
Nested PCR
Nested PCR protocols are generally used to increase detection sensitivity. They use previously amplified products as a template to perform a second PCR in which regions are amplified using internal anchor primers.
Nested PCR has been applied in different parts of the world to determine the actual prevalence of E. histolytica and the other species. This technique provided the first report of E. moshkovskii infection in Bangladesh by diagnosing amoebiasis in fecal samples from children54. The technique shows the differential size of 18S rRNA of E. histolytica, E. dispar, and E. moshkovskii by sequencing and correlating the results with the polymorphic sequences of the ArgTCT tRNA gene of the three species53.
Based on the sensitivity and specificity of nested PCR in diagnosing amoebiasis, the group of Fotedar et al.5 developed a protocol including primers for the differential detection of E. moshkovskii, with results showing discrimination of the three species. Subsequent sequencing analyses gave 98.5%, 99.7%, and 100% similarity percentages, with the sequences deposited at GenBank of E. dispar, E. histolytica, and E. moshkovskii, respectively5.
The innovation of multiplex nested PCR facilitates the simultaneous detection of E. histolytica, E. dispar, and E. moshkovskii, increasing the test’s sensitivity even in complex samples and minimum concentrations of 1000 parasites/0.05 g of feces68. The 18S rRNA gene (Table 2) in multiplex nested PCR allows differentiation of the three species, with a sensitivity and specificity of 94% and 100%, respectively68.
In the epidemiological context, nested PCR established a higher prevalence for E. histolytica (75%) over non-pathogenic species in Malaysian patients69. In contrast, in northwestern Iran, this technique placed E. dispar as the species with the highest prevalence (0.58%) and reported the presence of E. moshkovskii for the first time in the region70. Additionally, in the United Arab Emirates, this technique changed the previously reported prevalence for E. histolytica (by microscopy) from 72% to 10%71.
Real-time PCR
The real-time PCR (qPCR) or quantitative PCR method has gained interest in the field of amoebiasis diagnosis due to the optimization of the time used, the relative quantification of the number of parasites, and its high sensitivity72,73. In addition, this technique reduces the risk of contamination, the leading cause of false-positive results in conventional PCR amplification (dependent on electrophoresis74), and allows numerical understanding of the results75.
The technique employs primers and labeled probes that hybridize to specific sequences and are then detected and quantified through the fluorescence emitted after each amplification step. The probes show high performance in other nucleic acid detection platforms such as LUMINEX, achieving differential detection of Entamoeba species and other human protozoan parasites with a specificity similar to that obtained in simple real-time PCR76.
In diagnosing amoebiasis, probes (such as TaqMan) hybridize with the amplified products and achieve 100% efficiency in identifying E. histolytica75. In samples with low DNA concentrations, qPCR can detect up to 0.5 trophozoites/mL of stool, a concentration value that allows calculation of mean Ct values75. In the case of fecal samples, the method’s efficiency improves after applying freezing steps before extraction(-20°C/-80°C) to maximize DNA detection expressed in decreasing Ct values77.
The use of Eswab brushes or DNA dilutions in saline phosphate buffer improves the technique’s efficiency by reducing contaminants (soluble inhibitors) or normalizing sample volume, respectively78. Considering these factors and controlling the quality and quantity of extracted DNA, qPCR achieves remarkably low DNA detection limits of up to 0.2 pg for E. histolytica and 2 pg for E. dispar and E. moshkovskii, varying only the denaturation temperatures79.
Multiplex qPCR protocols (either duplex, triplex, or tetraplex) allow differential detection of the four Entamoeba species (E. histolytica, E. dispar, E. moshkovskii, and E. bangladeshi)80. These protocols use primers common to all four species and Taqman probes that hybridize with the products and differ according to the fluorescent molecules they contain (FAM, VIC, fluorescein, among others)76. Currently, primers have been designed in the multiplex qPCR platform that can be applied in conventional versions of PCR, thus maintaining specificity in identification81. This strategy would be optimal mainly for sites where qPCR cannot be applied due to its high cost81.
Currently, there are commercial qPCR panels, such as the singleplex and the arrays-TAG, which use Taqman probes and can detect up to 19 species of enteropathogens ranging from bacteria to helminths59,82. The detections are performed under universal conditions and use DNA extracted from bacteriophages to control the correct execution of DNA extraction and amplification, achieving a sensitivity of 85% and a specificity of 77% for detecting E. histolytica. Similarly, incorporating probes to detect E. dispar and E. moshkovskii is possible to provide additional diagnostic support compared to conventional PCR protocols59,82. Since E. histolytica, Giardia lamblia, and Salmonella spp. have been detected simultaneously in drinking water samples thanks to the protocols designed, the application of this methodology provides high levels of specificity83.
Loop-mediated isothermal amplification
Building on molecular methods based on polymerase amplification, researchers have developed other methodologies, such as nucleic acid sequence-based amplification (NASBA)84, self-sustained sequence replication (3SR)85, and strand displacement amplification (SDA)86. These techniques modify conventional amplification by eliminating heat denaturation and using a set of transcription, reverse transcription, or restriction enzyme digestion reactions to reduce detection times and increase sensitivity and specificity. However, despite the efficiency of these methods (detection of fewer than ten copies of DNA in approximately one hour), they have some shortcomings and require expensive equipment87.
In 2000, Notomi et al. developed LAMP87 for the detection of hepatitis B virus, improving detection limits of up to 6 DNA copies in 45 minutes by using a set of four specific primers: two internal direct (FIP) and two internal reverse (BIP) to amplify 6 HBs regions of the virus. Each primer contains two different sequences corresponding to the sense and antisense sequences of the target DNA, which hybridize to different regions of the DNA and are then amplified under isothermal conditions by Bst DNA polymerase. The improved specificity, compared to PCR, lies in the use of primers designed explicitly for each reaction, whose tm are between the optimal temperatures of the Bst enzyme (60-65°C) and which also recognize different sequences in the initial steps (without amplification). Subsequently, with two additional primers, the sequences present in the generated stem-loop are recognized87. A particular advantage of this technique is that the amplified DNA products can be observed with the naked eye as white precipitates in the reaction tube or by fluorescence if fluorescent intercalating dyes are incorporated.
Since its development, LAMP has been successfully applied to detect different gastrointestinal parasites such as Fasciola hepatica, Opisthorchis spp.88, Schistosoma japonicum89, Taenia spp.90, and protozoa such as Cryptosporidium spp. in fecal and water samples91. The design of specific primers, melting temperatures, and negative controls are critical to ensure that the amplification reaction is effective.
In the diagnosis of amoebiasis, LAMP allows the detection of E. histolytica up to one parasite per reaction, amplifying regions of the 18S rRNA gene (Table 2) with a sensitivity of 15 to 50 parasites compared to nested PCR and a specificity of 92%, which makes it the most uncomplicated technique to apply with high specificity92. Another LAMP-compatible marker is the hemolysin gene (HLY6), which achieves a sensitivity of five parasites per reaction and whose specificity was tested against E. dispar, Blastocystis hominis, and Escherichia coli, showing no results for these species. Positive reactions for E. histolytica were identified as tube turbidity or staining changes using SYBR green. Additionally, LAMP has demonstrated 100% specificity compared to nested PCR from ALA pus samples with detection limits of 1 pg DNA, even detecting new cases beyond those reported by PCR93.
Currently, LAMP has already been adapted to qPCR protocols94 and to the thermostabilized triplex strategy, which, together with a dry-reagent nucleic acid lateral flow immunoassay (NALFIA), allows the simultaneous and differential detection of E. histolytica, E. dispar, and E. moshkovskii, facilitating the visualization and interpretation of the amplicons produced by LAMP50. In LAMP-NALFIA, the primers for E. histolytica correspond to the specific sequences of the SREHP gene, while for E. dispar and E. moshkovskii, they correspond to the large subunit of the ribosomal RNA gene (LSU-rRNA) (Table 2), which are double-labeled by haptens and fluorescent molecules. The technique allows detection limits of ten E. histolytica trophozoites per reaction to be obtained with a specificity of 100%, although its ability to discriminate infecting species needs to be improved50. However, it has shown better performance than PCR, qPCR, and nested PCR95,96.
Considering that LAMP allows detection with high sensitivity and specificity without the need for expensive equipment compared to the PCR techniques described, its application for the diagnosis of amoebiasis is relevant in the development of protocols that allow differentiation between E. histolytica and E. moshkovskii. Furthermore, LAMP could be applied in ordinary circumstances, decreasing the risk of disease severity and identifying small outbreaks in countries where amoebiasis is endemic, and resources are scarce.
In conclusion, the impact of E. histolytica infections on children’s health in rural areas of developing countries requires effective diagnostic methodologies. Molecular methodologies have consistently contributed to the understanding of amoebiasis, for example, the actual prevalence of E. histolytica and the clinical significance that E. moshkovskii species may have. Furthermore, these techniques significantly reduce the time to obtain an accurate diagnosis with the added benefit of simultaneously detecting a broad panel of gastrointestinal parasites, bacteria, and viruses. However, the need for a practical diagnostic test is linked to the feasibility of its application, so the operational and logistical reality of health centers should be considered. In these circumstances, molecular techniques (PCR, qPCR, and nested PCR) have a restricted mass use. However, innovations such as LAMP offer opportunities for diagnosis with a higher degree of sensitivity and specificity than routine techniques, so it is necessary to evaluate their performance on site.
