Acanthamoeba-mediated cytopathic effect correlates with MBP and AhLBP mRNA expression

Background In recent years, the concern of Acanthamoeba keratitis has increased since the infection is often associated with contact lens use. Partial 18S rRNA genotypic identification of Acanthamoeba isolates is important to correlate with pathophysiological properties in order to evaluate the degree of virulence. This is the first report of genotypic identification for clinical isolates of Acanthamoeba from corneal scrapings of keratitis in Malaysia. This study is also the first to correlate the mRNA expression of MBP and AhLBP as virulent markers for axenic strains of Acanthamoeba. Results In this study, ten clinical isolates were obtained from corneal scrapings. Rns genotype and intra-genotypic variation at the DF3 region of the isolates were identified. Results revealed that all clinical isolates belonged to the T4 genotype, with T4/6 (4 isolates), T4/2 (3 isolates), T4/16 (2 isolates) and one new genotype T4 sequence (T4/36), being determined. The axenic clinical isolates were cytopathogenic to rabbit corneal fibroblasts. MBP and AhLBP mRNA expression are directly correlated to Acanthamoeba cytopathic effect. Conclusions All ten Malaysian clinical isolates were identified as genotype T4 which is predominantly associated with AK. Measuring the mRNA expression of Acanthamoeba virulent markers could be useful in the understanding of the pathogenesis of Acanthamoeba keratitis. Electronic supplementary material The online version of this article (doi: 10.1186/s13071-017-2547-0) contains supplementary material, which is available to authorized users.


Background
Photophobia, severe pain, redness and tearing are the common symptoms of Acanthamoeba keratitis (AK). AK is a rare but sight-threatening corneal infection which is caused by the free-living amoebae of the genus Acanthamoeba [1]. These organisms are widely distributed in the air, soil, water and domestic water tap, etc. [2,3]. AK is characterized by severe pain due to radial neuritis, and a ring-like stromal infiltrate appears in the advanced stage of AK [4]. Poor vision or even visual loss occurs due to corneal scarring if proper treatment is delayed. In recent years, the concern of AK has increased since this infection is often associated with contact lens contamination, especially in urban areas. The increasing use of contact lenses for visual and cosmetic purposes, combined with improper cleaning and storage practices could be the reason for the increase in the number of AK infections [5,6]. The first reported AK case in Malaysia was also related with a contaminated contact lens [7].
Physiological properties and genotyping of Acanthamoeba should be studied simultaneously to evaluate the pathogenic potential of the isolates. Cytopathic tests could be used as a pathogenic marker to determine the degree of virulence of the interested Acanthaoeba isolates; virulent isolates are able to induce a cytopathic effect but nonpathogenic Acanthamoeba cannot [25]. The cytoadherence of Acanthamoeba to mannosylated glycoproteins on the corneal epithelial cells is a critical step to initiate the Acanthamoeba keratitis [26,27]. It has been shown that the adhesion of Acanthamoeba to host cells is mediated by the mannose binding protein (MBP) on the surface of trophozoites. Through MBP-mediated adhesion to host cells, the amoebae produce a contact-dependent mechanism which able to exhibit a cytopathic effect involving direct cytolysis, phagocytosis, apoptosis and proteolytic activity [28].
Acanthamoeba trophozoites are stimulated to produce 133 kDa mannose induced protein after exposure to the upregulated mannose-specific lectins in the ulcerated corneal epithelium and lead to the activation and upregulation of matrix metalloproteinases in corneal cells [29,30]. Besides that, the ability of Acanthamoeba to adhere on the laminin of the Bowman's membrane and extracellular matrix via its Acanthamoeba laminin binding protein (AhLBP), is also important to allow Acanthamoeba to invade the corneal stroma in AK [31]. Acanthamoeba were capable of adhering and invading the extracellular matrix components such as laminin and collagen type I [32]. Previous studies provided information on the role of MBP and AhLBP as the marker of pathogenicity, mostly in protein level and a few in DNA works [31,[33][34][35][36].
Genotyping of Acanthamoeba isolates is still underreported in Malaysia. This study, therefore, aimed to determine the Rns genotype of Malaysian clinical isolates from corneal scrapings by analyzing the intra-genotypic variation at the DF3 region. The characterization of morphological and cytopathic properties for Acanthamoeba isolates was studied. This study is the first evaluation of mRNA expression of MBP and AhLBP quantitatively for Acanthamoeba spp. and correlates both virulent markers and their growth rate with cytopathic effect.

Sample collection
Ten Acanthamoeba isolates are maintained cultures which were obtained from the Acanthamoeba Culture Laboratory of Parasitology Department, UKM. The source of the samples is described in Table 1. The isolates were cultured on a non-nutrient agar (NNA) plate and overlaid with 150 μl of heat-killed Escherichia coli at 30°C. A small piece of agar containing cysts was removed from the primary culture and transferred to another new NNA plate, which was continued until it was totally free from co-contaminant, and the culture is known as a xenic culture. Two week-old cysts were harvested from the NNA plate and washed with PAGE amoebic saline (PAS) solution twice and then incubated overnight with 0.5 N sterile HCl during the process of axenization. The cysts were washed with PAS solution three times and centrifuged at 500× g for 10 min to obtain the cyst pellet. The cyst pellet was suspended with enriched PYG medium (4% peptone, 4% yeast extract, 2% glucose) supplemented with 10% fetal bovine serum (FBS; Gibco, Grand Island, New York, USA), 1% antibiotic-antimycotic (Gibco) and cultured in a T-25 flask (Greiner Bio-One, Frickenhausen, Germany) at 37°C. The PYG medium was adjusted to pH 7.2. The axenic trophozoites were excysted in the PYG medium after 1 day of incubation. The axenic cultures were subcultured every 3 days.

Identification of Acanthamoeba
A wet smear of xenic cultures was observed under a light microscope for the morphology features of trophozoites and cysts. The diameter of cysts was measured using the VideoTest Morphology software (VideoTest, Saint Petersburg, Russia, version 5). Isolates were classified as Acanthamoeba spp. groups I, II or III according to the keys of Pussard & Pons [8].
The 18S rDNA identification of Acanthamoeba spp. was performed as per the following procedures. Acanthamoeba isolates with a density of 5 × 10 5 trophozoites were harvested from NNA plates and DNA was extracted with a commercially available AccuPrep® Genomic DNA Extraction Kit (Bioneer, Daejeon, Korea). The pelleted trophozoites were resuspended in 200 μl PAS solution, mixed with 20 μl proteinase K and 200 μl binding buffer and incubated at 60°C for 10 min. The lysate was transferred into the upper reservoir of the binding column tube after added 100 μl isopropanol. The tube was centrifuged at 8000× g for 1 min. The binding column tube was washed with 500 μl ethanol twice and the DNA was eluted with 200 μl elution buffer. After that, amplicon ASA.S1 was amplified by PCR using Platinum® Taq DNA Polymerase High Fidelity kit (Invitrogen, Carlsbad, CA, USA) following the recommended protocol with genusspecific primers JDP1 and JDP2 ( Table 2). The PCR reaction was started with incubation at 94°C for 3 min, followed with 35 cycles of 30 s at 94°C, 30 s at 61°C and 1 min at 72°C. Incubation for another 5 min at 72°C was done for final extension. Amplification products were visualized by ethidium bromide staining in 1.5% agarose gel electrophoresis and followed by gel extraction using PureLink™ quick gel extraction kit (Invitrogen). ASA.S1 PCR products were ligated into a plasmid vector by using The alignment of interesting sequences with homologous sequences from GenBank was conducted using BLAST (http://www.ncbi.nlm.nih.gov). Phylogenetic analyses were conducted in MEGA7 (Molecular Evolutionary Genetic Analysis software, version 7) [37]. The evolutionary history was inferred using the Neighbor-Joining method [38]. The bootstrap consensus tree inferred from 1000 replicates [39] was taken to represent the evolutionary history of the taxa analyzed [39]. Branches corresponding to partitions reproduced in fewer than 50% bootstrap replicates were collapsed. The percentage of replicate trees in which the associated taxa clustered together in the bootstrap test (1000 replicates) was shown next to the branches [39]. The tree was drawn to scale, with branch lengths in the same units as those of the evolutionary distances used to infer the phylogenetic tree. The evolutionary distances were computed using the Kimura 2-parameter method [40] and were in the units of the number of base substitutions per site. All positions containing alignment gaps and missing data were eliminated only in pairwise sequence comparisons. The alignment of DF3 sequences was performed using MEGA 7 with ClustalW. The reference sequences used in this study are available in Gen-Bank under the accession numbers shown in Table 1.

Cytopathic effect
Rabbit corneal fibroblasts were isolated from the cornea of New Zealand white strain rabbits as described in the previous study [41]. The rabbit heads were bought from the slaughter farm in Ijok, Malaysia. The corneal stroma was digested using collagenase type I solution in order to isolate the corneal fibroblasts. The corneal fibroblasts were then cultured on a 24 × 24 mm coverslip in 35 mm tissue culture dishes (Orange Scientific, Braine-L' Alleud, Belgium) with F12:DMEM supplemented with 10% FBS, 1% Glutamax, 1% antibiotic-antimycotic (Invitrogen) at 37°C with atmospheric O 2 and 5% CO 2 level. The cell culture medium contained sodium bicarbonate and HEPES solution which was used as buffer to maintain the media at pH 7.2-7.6. The 100% confluent cells were treated with 3 densities of axenic trophozoites, which were 10 4 , 10 5 and 10 6 trophozoites per dish/well for triplicates at 3 time intervals (3, 6 and 24 h). The cells were fixed using 4% paraformaldehye and stained with giemsa. The area of remaining cells after cytolysis was observed under a light microscope and measured using the VideoTest Morphology software. The percentage of cytopathic effect (CPE) was calculated based on the surface area of empty spaces in the culture.

Growth rate of trophozoites
The growth rate of axenic trophozoites was performed in triplicates based on the trypan blue exclusion method using a haemocytometer (Weber Scientific International Ltd., Teddington, UK). Each axenic isolate was seeded with 1 × 10 5 trophozoites per well into 6-well plate (Nunc™, Wiesbaden, Denmark) and cultured with PYG medium at 37°C for 24 h. The harvested trophozoites were stained with trypan blue vital dye (Gibco) and then directly counted. The formula for the growth rate was: difference between the final live trophozoite count and initial seeding, divided by the surface area (9.6 cm 2 ) and days of confluence (1 day). Each sample with 1 million axenic trophozoites was lysed using 1 ml TRI reagent in order to preserve the total RNA.  synthesis included 10 μl of 2× reaction mix, 5 μl total RNA, 3 μl diethylpyrocarbonate-treated water and 2 μl reverse transcriptase enzyme. The reverse transcription was initiated with 10 min at 23°C for primer annealing, 60 min at 50°C for reverse transcription and 5 min at 85°C for reaction termination. The primers (forward and reverse) were designed from NIH GenBank using Primer Output 3 software (Table 2). Acanthamoeba actin related protein 2 (ARP2) is used as housekeeping gene in this study [42,43]. Quantitative polymerase chain reactions were performed using MyiQ cycler (Bio-Rad, Hercules, CA, USA) with iQ™ SYBR® Green Supermix

Statistical tests
Quantitative data were tested for statistical significance using the Statistical Package for Social Sciences version 20 (IBM Corporation, Armonk, New York, USA). Student's t-test for independent samples was performed for normally distributed data, while the Mann-Whitney U-test was used as a non-parametric test. Correlation between two variables was analysed using Pearson's correlation coefficient. The results were presented as the mean ± standard error mean (SEM). P < 0.05 was considered to be statistically significant.

Identification of Acanthamoeba
In this study, all the Malaysian clinical isolates from corneal scrapings were identified as Rns genotype T4. Currently, there were 35 T4 subgenotypes with deposited GenBank data and published in the articles, which were T4/1 to T4/ 10 [12], T4/11 to T4/21 [10] and T4/22 to T4/28 [44]. Another study also independently reported the same designation of T4/22 and T4/23 on the same year [45]. Therefore, Risler et al. [46] Table 1 and Table 3 and the phylogenetic tree is shown in Fig. 1. The T4 subgenotyping result is shown in Fig. 2. All sequences generated in this study were submitted to the GenBank database under the accession numbers KY964312-KY964321 (Table 1). Based on Pussard & Pons' [8] morphological classification, the result indicated that only four isolates (UKMAC1, UKMAC2, UKMAC3 and AC20) belonged to Group III with the cyst size < 18 μm and a smooth endocyst. The range of cyst diameters are represented in Table 3. Another six isolates belonged to Group II, where the cyst sizes were < 18 μm and a polygonal endocyst with 6-7 arms (Fig. 3 and Table 3). Xenic samples were able to excyst and proliferate robustly at 37°C. Only five isolates (AC20, UKMAC2, UKMAC4, UKMAC7 and UKMAC8) were able to be axenized and grown well in the liquid medium at human body temperature (37°C).

Cytopathic effect
Cytopathic effect of 5 axenic isolates was carried out for three time intervals (3, 6 and 24 h) with three different densities of trophozoite (10 4 , 10 5 and 10 6 trophozoites/well) on corneal fibroblasts as shown in Fig. 4. There was no cytopathic effect been observed after 24 h co-incubation with Fig. 1 Evolutionary relationships of taxa. The evolutionary history was inferred using the neighbor-joining method for the 18S rDNA partial sequences of clinical isolates (black dots). The optimal tree with the sum of branch length = 1.25072993 is shown. The percentage of replicate trees in which the associated taxa clustered together in the bootstrap test (1000 replicates) is shown next to the branches. The tree is drawn to scale, with branch lengths in the same units as those of the evolutionary distances used to infer the phylogenetic tree. The evolutionary distances were computed using the   the density of 10 4 trophozoites/well. The cytopathic effect of corneal fibroblasts was observed after 6 h co-incubation with 10 5 trophozoites and 3 h co-incubation with 10 6 trophozoites. Sample AC20 exhibited the highest CPE percentage in both densities of 10 5 and 10 6 trophozoites/well throughout the three time intervals. The trophozoites accumulated at the edge of corneal fibroblasts and multiple small lesions were formed due to its cytopathic effect (Fig. 5). The empty spaces between the corneal fibroblasts were increased due to the cytolysis. The corneal fibroblasts had fully been lysed (100%) after 24 h co-incubation with 10 6 trophozoites. The cells were replaced by trophozoites and a few cysts which were either attached on the well surface or floating in the medium.

Cytopathic effect correlates with MBP and AhLBP gene expression
Sample AC20 is the most virulent strain in this study due to it having the highest trophozoite growth rate, gene expression of MBP, and cytopathic effect (Fig. 6). In comparison, the growth rate of trophozoites and gene expression of MBP were the lowest for the strain UKMAC4 among 4 axenic isolates. This study showed a positive correlation between growth rate and cytopathic effect, r (15) = 0.889, P < 0.0001. There was a positive relationship between MBP gene expression and cytopathic effect, r (15) = 0.864, P < 0.0001. There was also a strong relationship between AhLBP gene expression and cytopathic effect, r (15) = 0.934, P < 0.0001. Specific primers of  Table 1. Sequences were aligned by similarity. Asterisks denote similar positions and gaps are represented as dashes. Samples of the present study are indicated in bold Fig. 4 Cytopathic effect of Acanthamoeba trophozoites on corneal fibroblasts. The seeding density of Acanthamoeba was 10 5 (a) and 10 6 trophozoites (b) for 3, 6 and 24 h co-culture. AC20 had a significantly higher CPE than all other isolates (*P < 0.05) Fig. 3 Morphology of cysts and axenic trophozoites of group II and III Acanthamoeba stained with methylene blue and observed under phase contrast microscopy (magnification ×1000). a Thick ectocyst and polygonal endocyst in Group II. b Thin ectocyst adjacent to the endocyst in Group III. c, d Acanthamoeba trophozoites with characteristic acanthapodia, contractile vacuole and prominent nucleus. Scale-bars: 20 μm the studied genes produced a single melt peak in melting curve analysis (Additional file 1: Fig. S1) and a single band of PCR product in 1.5% agarose gel electrophoresis (Fig. 7). The statistical results of growth rate, virulent gene expression and CPE are shown in Additional file 2: Table S1.

Discussion
Rns genotypic identification for Acanthamoeba is important in studying the epidemiology of Acanthamoeba keratitis, providing the correlation between genotype and infection [10]. Previous studies found that the T4 genotype is the most predominant causative agent for AK and also morphologically belonging to Group II and III [13]. In this study, all clinical isolates from corneal scrapings were also assigned to genotype T4, thus providing evidence to support the genotype T4 as a dominant sequence associated with AK in Malaysia. Based on DF3 sequence determination, four isolates (T4/6), three isolates (T4/2), two isolates (T4/16), and one new genotype T4 sequence were identified. The new genotype T4 was suggested as a subgenotype T4/36 in this study. Results revealed that genotype T4/2 and T4/6 were common in keratitis isolates in Malaysia and similar results had been reported from Hong Kong [12], North China [48], France [49] and the USA [10]. Our studied isolates were mainly phylogenetically identical to A. culbertsoni Diamond [14]. From the previous study, 4 out of 11 Acanthamoeba isolates (19.05%) from air-conditioners in Kuala Lumpur, Malaysia were genotypically identical to A. culbertsoni Diamond from keratitis, Ohio, USA [50]. This explained that the distribution of Acanthamoeba with a specific genotype also plays a vital rule in the occurrence of AK. T4 isolates are more prevalent and geographically widespread across the world and this dominant sequence is mostly associated with human infection [14,24,51].
A significant issue with the use of contact lenses is that of corneal ulcers, arising from the prolonged wearing of the lens. Contaminated contact lenses or exposure to Acanthamoeba accidentally from the environment could be a risk factor for AK. Acanthamoeba can easily invade the cornea in the event of an ulcer or trauma because mannose glycoprotein would be upregulated in response to the corneal abrasion, and thus increasing the affinity of Acanthamoeba trophozoites in adhering to the corneal epithelium [30]. This reveals that improper contact lens cleaning practices is most likely to be the reason of AK infection [52]. Contact lenses are a good vehicle to transport the Acanthamoeba to the cornea. The biofilm of contact lenses and carbohydrate residues secreted by host could be a good breeding ground and food source for Acanthamoeba to multiply and attach to the contact lens [53]. Moreover, wearing contaminated contact lenses increases the exposure period of Acanthamoeba on the cornea, thus increasing the possibility of AK, especially for those with corneal abrasion or injury.
The density of trophozoites is highly important in causing a cytopathic effect on the monolayer cells in vitro. No cell damage was observed when small inoculums of amoeba were used in the cytopathic effect test [54,55]. In this study, 10 4 trophozoites failed to cause a Fig. 5 Cytopathic effect of AC20 isolate on the corneal fibroblasts with seeding of 10 6 trophozoites. a The corneal fibroblasts are fusiform; the Acanthamoeba trophozoites with prominent contractile vacuoles were feeding on the edge of cells and thus forming multiple small lesions on the monolayer cells after 3 h co-culture. b The gaps between keratocytes were increased with the time due to the cytopathic effect of trophozoites after 6 h co-culture. c All corneal fibroblasts were lysed by trophozoites after 24 h co-culture and only left trophozoites in the vessel. Giemsa staining (magnification ×100). Scale-bars: 200 μm cytopathic effect even when the incubation time was prolonged to 1 week. The cut off point for corneal fibroblasts is the seeding density of 10 5 trophozoites needed to demonstrate the cytolysis. This revealed that other than the susceptibility of Acanthamoeba to binding with corneal receptors, the ability to multiply and adapt in the cornea is also important in the development of AK. The sequential events of CPE were demonstrated as similar to the previous studies [55,56]. Cell shrinkage and gaps were observed at the initial phase of CPE, then some cells were rounded and either engulfed by trophozoites or floating off. The trophozoite-mediated cytopathic effect is due to three independent mechanisms: direct cytolysis, phagocytosis and apoptosis [57]. The clinical strain of Acanthamoeba induced a cytopathic effect on human corneal fibroblasts mainly via apoptosis after direct adhesion rather than through soluble factors [58]. The cytopathic effect was in a dose-dependent manner after co-culture with Acanthamoeba, T4 Acanthamoeba isolates from AK patients and exhibited a similar cytopathic effect on human corneal fibroblasts [58].
In this study, the pathogenic potential of parasites in vitro is directly correlated with the expression level of the MBP. Pathogenic strains of Acanthamoeba, which produce robust amounts of MBP, bind to host cells and produce amoeba-induced cytopathic effects in a mannosedependent manner. In contrast, non-pathogenic strains, which produce little or no MBP, are unable to bind onto the host cells or produce CPE [27,28]. The ability of parasites to bind to host cells and produce CPE is directly correlated with the expression of the MBP. Acanthamoeba strains that expressed high level of MBP could bind strongly to host cells and produce potent CPE. The production of MBP was detected by affinity chromatography and western blot analyses [33]. The level of AhLBP mRNA expression was compared between the pathogenic and non-pathogenic Acanthamoeba [31]. Highly virulent strains expressed a higher level of AhLBP mRNA through northern blot analysis. The pathogenic strain has a higher affinity to attach on the extracellular matrix glycoprotein laminin when compared to the non-pathogenic strain in order to induce CPE [26]. Previous studies proved that the mannose-binding proteins and laminin-binding proteins on Acanthamoeba are the virulence proteins responsible for the pathogenesis of Acanthamoeba infection [26,31,35,59]. Pre-treated amoeba with the mannose showed a significant decrease in their adhesion and invasion on the collagen matrix and reduced their cytopathic effect [32,36]. Incubation amoeba with mannose sugars inhibited their attachment on inert surfaces in a dose-dependent way [59,60]. Acanthamoeba trophozoites pretreated with anti-MBP IgY antibody significantly inhibited the CPE. Pathogenic A. culbertsoni exhibited high attachment on laminin and cytopathic effect on normal human keratocytes regardless of incubation with or without laminin [26].
This study showed strong a correlation between virulent genes and growth rate. Virulent strains have a higher growth rate and as well as higher virulent gene expression. Physiological characteristics correspond to their degree of virulence. It is also plausible that more trophozoites will cause more cytopathic effect. Pathogenic potential usually correlates to a high growth rate of amoeba [61], although the rapid growth of amoeba on the cells was not necessarily comparable to their growth rate on the axenic culture [62]. Cytopathic potential per trophozoite is more important in affecting the degree of cytopathic effect when compared to their numbers [63].
Although samples UKMAC2 and AC20 have the same DF3, they have a different cytopathic effect, growth rate and expression level of virulent genes. DF3 was used to differentiate their genotype but did not reveal the same phenotype in this study. The difference of phenotypes could be a consequence of developmental variation [64]. Moreover, a complete sequence may be needed to study a relation between the sequence type and phenotypes. Previous studies showed that the sequences belonging to the same DF3 could be with a different V4 region [46]. The V5 variable region includes the highly variable DF3 region and the V4 region located within the genotypic Fig. 7 Agrose gel electrophoresis of PCR products. The products were for the target gene ASA.1 for ten Acanthamoeba isolates (a) and the housekeeping gene ARP2, Acanthamoeba virulent markers MBP and AhLBP genes (b). A single band of PCR product indicated the specificity of the synthesised primers extended fragment were examined to differentiate the Acanthamoeba genotypes [46,65].

Conclusions
This study is the first report of 18S rDNA identification for clinical isolates in Malaysia. All pathogenic strains belonged to genotype T4 and one new subgenotype T4/36 (UKMAC4) was identified. This study also showed the first correlation between mRNA expression of Acanthamoeba virulent markers MBP and AhLBP with cytopathic effect. The expression of virulent markers is directly correlated with the cytopathic effect. The detection of mRNA expression of genes MBP and AhLBP can be used to determine the pathogenicity of Acanthamoeba and to study the pathogenesis of Acanthamoeba keratitis.

Additional files
Additional file 1: Figure S1. Melt curve and melt peak of genes ARP2, MBP and AhLBP in qRT-PCR. a The melting points of genes ARP2, MBP and AhLBP were 86.5°C, 86.5°C and 87.5°C, respectively. b Specific primers of the studied genes produced a single melt peak for each PCR product. (TIFF 6503 kb) Additional file 2: Table S1. Statistically significant results of cytopathic effect, trophozoite growth rate and virulent gene expression. The Student's t-test was performed for normally distributed data, while the Mann-Whitney U-test was used as non-parametric test. (DOCX 15 kb)