Artículo Original
Association of IL-1β +3954 G>A and IL-6
-174 G/C polymorphisms in congenital toxoplasmosis
Asociación de polimorfismos de IL-1β +3954 G>A e IL-6-174 G/C en la
toxoplasmosis congénita
Nuha M. Mousa1* ORCID: https://orcid.org/0000-0003-1564-0361
Hameed M.
Jasim2 ORCID: https://orcid.org/0000-0001-5966-0554
1 Al-Muthana
University, College of Science, Iraq.
2 Al-Nahrain
University, College of Biotechnology, Iraq.
Autor para correspondencia: nuhamoh@mu.edu.iq
ABSTRACT
Toxoplasmosis is caused by
infection with the protozoan parasite Toxoplasma
gondii, that has the capacity to infect all warm-blooded animals worldwide.
The purpose of this investigation was to determine the distribution of
genotypes and alleles in miscarriages woman as a result of Toxoplasma gondii infection associated with interleukin-1β and
interleukin-6 polymorphisms. A total of 125 miscarriage women suspected of
toxoplasma infection and 50 healthy pregnant without previous miscarriage as
control were enrolled in this study. The cases were screened for
anti-toxoplasma IgM and IgG by ELISA test. Among the 125 miscarriage women,
only 50 were positive to anti-Toxoplasma
gondii IgG and IgM antibodies. The present study focused on assay the
genotypes at IL-6 -174 G/C and IL-1β +3954 G>A to establish the associations
between genetic polymorphisms and infection with Toxoplasma gondii. Results showed that the altered IL-1β GA, AA
genotypes were high significant elevated in miscarriage women with
toxoplasmosis (P=0.03), OR = 10 and 95% confidence intervals (1.32-81.48);
(P=0.0007), OR = 0.07 and 95% confidence interval (0.01-0.32). The genotype GC at
IL-6 (G/C) appears to be highly correlated with infection (P=0.01); OR = 3.18
and 95% confidence interval, (1.22- 8.30). In terms of allelic heterogeneity, C
alleles were significantly more common in infected than uninfected cases for
IL-6, while A allele is common in IL-1β single nucleotide polymorphisms (P
=0.050). Furthermore, this study demonstrates that there is a strong and highly
significant association between two forms of single nucleotide polymorphisms
and the increased risk for toxoplasmosis. Genotypes of these polymorphism
should be considered when evaluating genetic effects on toxoplasmosis incidence.
However, to improve the prediction of this disease predisposition, a further
study based on a larger cohort of patients is warranted.
Keywords: Toxoplasma
gondii; Single nucleotide polymorphisms; genotype.
RESUMEN
La
toxoplasmosis es causada por la infección con el parásito protozoario Toxoplasma gondii, que tiene la
capacidad de infectar a todos los animales de sangre caliente en todo el mundo.
El propósito de esta investigación fue determinar la distribución de genotipos
y alelos en mujeres con abortos espontáneos como resultado de la infección por Toxoplasma gondii asociada con
polimorfismos de interleucina 1β e interleucina 6. Se inscribieron en este
estudio un total de 125 mujeres con aborto espontáneo sospechosas de infección
por toxoplasma y 50 embarazadas sanas, sin aborto espontáneo previo, como control.
Los casos se examinaron para detectar IgM e IgG anti-toxoplasma mediante la
prueba ELISA. Entre las 125 mujeres que sufrieron un aborto espontáneo, solo 50
fueron positivas a anticuerpos IgG e IgM anti-Toxoplasma gondii. El presente estudio se centró en analizar los
genotipos de IL-6-174 G/C e IL-1β +3954 G>A para establecer las asociaciones
entre polimorfismos genéticos e infección por Toxoplasma gondii. Los resultados mostraron que los genotipos
alterados de IL-1β GA, AA fueron significativamente elevados en mujeres con
aborto espontáneo con toxoplasmosis (P = 0,03), OR = 10 e intervalos de
confianza del 95% (1,32-81,48); (P = 0,0007), OR = 0,07 e intervalo de
confianza del 95% (0,01-0,32). El genotipo GC de IL-6 (G/C) parece estar
altamente correlacionado con la infección (P = 0.01); OR = 3,18 e intervalo de
confianza del 95%, (1,22- 8,30). En términos de heterogeneidad alélica, los
alelos C fueron significativamente más comunes en los casos infectados que en
los no infectados para la IL-6, mientras que el alelo A es común en los
polimorfismos de nucleótido simple de IL-1β (P = 0.050). Además, este estudio
demuestra que existe una asociación fuerte y altamente significativa entre dos
formas de polimorfismos nucleótido simple y el mayor riesgo de toxoplasmosis.
Se deben considerar los genotipos de estos polimorfismos al evaluar los efectos
genéticos sobre la incidencia de la toxoplasmosis. Sin embargo, para mejorar la
predicción de esta predisposición a la enfermedad, se justifica un estudio
adicional basado en una cohorte más grande de pacientes.
Palabras clave: Toxoplasma
gondii; Polimorfismo de Nucleótido Simple; genotipo.
Recibido: 8 de marzo de 2021
Aceptado: 12 de julio de 2021
Introduction
Toxoplasma
gondii is an obligate intracellular parasite that can infect almost all cells
with nucleus in warm-blooded animals.(1).It leads to congenital
diseases of the fetus and newborns upon first exposure to T. gondii
during pregnancy, which, in turn, stimulates the immune response that may cause
the fetus to be lost or deformed.(2) The host's responses to
infection, inflammation, and trauma are controlled by pro-inflammatory
cytokines, which can make disease worse in co-disease states.(3)
While its biological activities overlap on a large scale, IL-1β is developed
during early pregnancy by autotrophic cells at the interface between the fetus
and the mother and is involved in trophoblastic invasion and tissue repair.(4)
Whereas, IL-6 is a powerful
vascular cytokine that stimulates endothelial cell proliferation. In vitro, the
behavior of the female reproductive system and pregnancy tissues secreted by
groups of fallen cells are regulated.(5) It also plays a major role
in erection process or as anti-inflammatory. In helper T cells 17 (Th17), while
suppressing the production and regulatory function of T cells (Treg) in vitro,(6)
it is also known to enhance the differentiation between the germinal center B
cells and the follicular helper T cells, and thus are critical for the production
of antibodies anti-high affinity.(7) The sinusoidal polymorphism of
the nucleotide in the IL-6 gene
interferes with its transitional regulation, such as the -174G/C polymorphism.(8)
T. gondii inhibits IL-1 controlled by inflammation, a typical multivariate
complex consisting of caspase-1, an ASC (protein-like protein transformer for
apoptosis-associated protein) and acellular sensor, which can be either an
oligonucleotide domain as NLR receptor or a receptor that appears for AIM2.(9)
The problem of eradication of parasites, reactivation of pathogens, toxic
effects and emerging drug resistance in parasites makes long-term drug treatment
ineffective.(10).Therefore, the production of successful vaccines against
toxoplasmosis is important in order to fight against the parasite. There is no vaccine
for humans. Toxovax® (Intervet,
B.V), is the only vaccine on the market to prevent toxoplasmosis.(11)
The genetic variation in a single locus does not give an adequate explanation
for the inter-individual changes in the host's immune responses that lead to
different clinical manifestations.(12).In order to reduce the risk
to public health and livestock development, it is crucial to stablish novel
control and preventive toxoplasmosis strategies. Currently, the commercial
vaccine, based on live attenuated tachyzoites of T. gondii (strain S48),
is available for veterinary use in a small number of countries to minimize the
incidence of abortion in cattle.(13) Several experiments have been
carried out to test multi-component candidate vaccines combining GRA2 or GRA5
with other possible toxoplasmosis genes(14)and different adjuvant formulations,
for example: alum (Th2 inducer), IL-12 (Th1 inducer),(15).adjuvants commonly
used in subcutaneous injection like Freund’s complete adjuvant and Freund’s
incomplete adjuvant, liposomes. It is possible that genetic variation co-exists with parasitic
infections, therefore, this study was designed to analyze the association of IL-6
and IL-1β genetic polymorphism with the risk of recurrent miscarriage
associated with toxoplasmosis, leading to increased gene expression that affects
regulation of the immune response. These cytokines can be a target for vaccines
or used as adjuvants in the future.
Materials and Methods
Cases and
control
One hundred and twenty-five miscarriage women were
enrolled in the study, in addition to 50 healthy pregnant women who didn't have
history of miscarriage as a control group. Fifty recurrent miscarriage women
with toxoplasmosis were diagnosed by ELISA test from total miscarriage cases.
Matched patients for ethnicity and age were also
included in the study according to a pre-prepared questionnaire. The inclusion
criteria were: woman age 20-45 years, number of miscarriages and children
number. The exclusion criteria were autoimmune dysfunction, genetic anomalies,
inflammatory disease, and other systemic disorders.
The women's blood samples were collected in the period
between January to July, 2019 from women who attended delivery’s and children
hospital in Al Muthanna Governorate, Iraq.
Sample
collection
Blood samples were
collected by venipuncture from women experiencing one or more miscarriages on
her first hospital visit and from healthy women as control. Then the blood was
stored at 4°C until analysis. Five milliliters of blood were obtained by
venipuncture, transported to the laboratory, allowed to clot and later
centrifuged at 1,500 rpm for 10 min. The sera were aspirated after
centrifugation and stored in tubes at -70°C until tested.
Serological
Test
Sample analysis was carried out by Enzyme-linked
immunosorbent assay (ELISA). Anti-toxoplasma IgG and IgM were performed using
the Biotech, USA, kit following the manufacturer´s instructions. Negative and positive
controls and calibrator were ready to use. At first, 1:21 dilution of specimens
was prepared by adding 10 µL of the sample to 200 µL of sample diluent and
mixed well. Secondly, 100 µL of diluted sera, calibrator and controls were
dispensed into the appropriate wells. As reagent blank, 100 µL of sample
diluent in 1A well position were dispensed. After that, the holder was tapped
to remove air bubbles from the liquid and mixed well. An incubation for 20 min
at room temperature was followed and liquid was removed from all wells. After that,
wells were washed three times with 300 µL of 1X wash buffer. Then, 100 µL of
enzyme conjugate were dispensed to each well and incubated for 20 min at room
temperature. Enzyme conjugated was removed from all wells that were washed
three times with 300 µL of 1X wash buffer and 100 µL of
3,3',5,5'Tetramethylbenzidine (TMB). Then the substrate was dispensed and
incubated for 10 min at room temperature; at last 100 µL of stop solution were
added. All samples and standards were run in duplicates; the average value was
considered after reading optical density (OD) at 450 nm using ELISA reader
within 15 min. A dual wavelength is recommended with reference filter of
600-650 nm. Each standard OD (Y-axis) versus the corresponding standard
concentration (X-axis) were used to construct the standard curve that was drawn
on linear graph paper manually to obtain the best linear/linear curve to give
the most accurate results.
DNA isolation
and cytokine genotyping
Genomic
DNA was isolated from ethylene-diamine-tetraacetic acid (EDTA)-treated blood
from 2-mL peripheral blood volumes using the Miniprep DNA extraction kit
(Favorgen, Europe) according the commercial method. The obtained DNA was
diluted in 100 μL of elution buffer and stored at -20°C until further molecular
analyses. To determine the occurrence of IL-6 and IL-1β polymorphism from blood
samples of toxoplasmosis miscarriage and healthy women, polymerase chain
reaction (PCR) was performed to detect IL-6 -174G/C (rs1800795) and IL-1β +3954
G/A (rs1143634) single nucleotide polymorphisms (SNPs), using qPCR kit
(Favorgen, Europe). DNA was amplified using the forward and reverse primers
shown in Table 1. The conditions for amplification were achieved as follows:
initial denaturation at 95°C for 4 min; 35 cycles of denaturation at 95°C for
45s, annealing at 60°C for 30s and extension at 72°C for 60s; a single final
extension step at 72°C for 10 min.(16,17) PCR products were sent for
sequencing using ABI3730XL, an automated DNA sequencer by Macrogen
Corporation-Korea; the reference fragments of these genes were compared, using
BLASTN program for alignment of two (or more) sequences.
Table 1. Primer sequences, annealing temperatures, and amplicon size for
amplification of IL-6 and IL-1β.
|
Gene |
Specific primer sequences
(5’- 3’) |
Tm (˚C) |
Product
Size (bp) |
|
IL-6 |
F:
CAGAAGAACTCAGATGACTG R:
GTGGGGCTGATTGGAAACC |
58 |
431 |
|
IL-1B |
F:
GTTGTCATCAGACTTTGACC R:
TTCAGTTCATATGGACCAGA |
59 |
291 |
Tm: temperature
Statistical
Analysis
All the statistical analyses were performed using the statistical package for the social
sciences (SPSS) software version 13.0 for Microsoft windows. The genotype and
alleles frequencies for SNPs were calculated directly by counting method.
Hardy-Weinberg equilibrium (HWE) for SNP was investigated via the use of the
online calculator of Michael H. Court (2005-2008). If the P-value was more than
0.05, the population was consistent with HWE. The odds ratio (OR) was estimated
for evaluating the risk related to genotypes and alleles; it was calculated by
chi-square and Fischer's exact probability via utilizing the statistical
software epidemiological (WINPEPI) version 11.65. Also, p-values were statistically
significant when less than (0.05). Genotype distributions of cytokine gene
polymorphisms were compared between cases and controls by chi-square test.
Statistical analysis was performed to determine odd ratio (OR) and 95%
confidence intervals (95% CI) associated with recurrent pregnancy loss, using
Finch TV version 1.4 to display DNA sequences.
Ethical
approval
This study
protocol was approved by the Ethics Committee of the Children's Health Memorial
Institute on Humans and a written consent from each participant has been
obtained No.1466 in 22/5/2019.
Results and Discussion
Serotyping
methods based on polymorphic polypeptides have the potential to become the
choice for typing T. gondii
in humans and animals. Detection of specific anti-Toxoplasma immunoglobulin
(IgM and IgG) discriminates chronic from reactivated infection. Present results
revealed infection with T. gondii in 50 miscarriage women with spontaneous abortion, due to their seropositivity to anti-T. gondii IgM and IgG antibodies. Cytokines are essential for the normal development of pregnancy, any
imbalance in the amount or location of expression can influence trophoblastic
and endometrial reactions leading to pregnancy complications.(16) Further
investigations focused on genome-wide association studies are needed to better
characterize the SNPs of the cytokine genes in the toxoplasma virulence effect.(7)
Logistic regression analysis was used to estimate genotype-toxoplasmosis
associated miscarriage risk under four genetic models (recessive, dominant,
codominant and over dominant). In the present study, results indicated in Table
2 showed the equivalence of percentage between alleles frequency of IL-6 in both G and C (it was 50%,
respectively) for infected miscarriage women, while in the control group, G
allele was 68% and C allele, 32%. These findings deal with the previous study
about GC heterozygosity associates with the disease incidence in TR patients.(16)
For IL-1β, the allele
frequency for G and A in toxoplasmosis were 32 (60%) and 18 (33.3%),
respectively. In a previous study, G allele in the site of polymorphism
(rs1800795), had more incidence of variant genotypes in miscarriage women with
toxoplasmosis.(17)
Recently, the polymorphic IL-6
-174 G>C was also detected associated with altered levels of encoded
cellular expression.(14) In
this study, three genotypes were observed in IL-6 -174 G>C (GG, CG, and CC)
with frequency of (32%), (40%), (28%), respectively in relation to control
group (Table 3). These results showed that the heterozygous GC were
significantly (P<0.01) associated with toxoplasmosis and an increased risk
of toxoplasmosis in the coded form, as this heterozygous was three times more
dangerous than the rest of the genotypes OR (3.18), 95% CI (1.22- 8.30) for GC
and CC genotypes in the dominant model, P <0.050; this deals with the
previous study of GC heterozygosity associated with disease incidence in TR
patients.(14) This result contrasts with a previous study on
rs1800795 which showed a high significant of (C/C) genotype leading to a
negative regulatory domain (225 to 164). Moreover, it is contained within a
sequence that carries partial nucleotide homogeneity with the Smad4 binding
component and the C allele may bind to Smad4 more effectively and thus inhibit
IL-6 transcription.(18)
Table 2. Distribution of
the allele frequency of IL-6
rs1800795 G/C, IL-1β rs1143634
G/A in study groups.
|
|
Allele frequency No.(%) |
|
|
|
|
Gene |
Toxoplasmosis cases (50) |
Control (50) |
OR (CI 95%) |
p-value |
|
IL-6 -174 G/C rs1800795 |
G:25 (50) ref C:25 (50) |
G:34 (68) C:16 (32) |
1 (0.41 -2.428) 2.12 (0.94-4.78) |
1 0.0691 |
|
IL-1β+3954 G/A rs1143634 |
G:32 (60) ref A:18 (33.3) |
G:42 (82) A:8 (9.5) |
1 (0.52- 1.91) 0.338 (0.13- 0.87) |
1 0.025* |
ref: base found in the reference genome.
To date, for IL-6 -174G>C SNP, the C allele has been documented to
generate new binding sites for transcription factors for NF1 and Smad4 that
were not reported in the presence of the G allele.(16)
These results don’t agree with(19) who observed that CC
carriers, among recurrent spontaneous abortion (RSA) patients with polycystic ovary syndrome
(PCOS), were 10% compared to controls (3%) and the GG genotype in RSA women
with PCOS was significantly different (60%) compared to control subjects; while
the present study agrees with the GC genotype (30%) they reported for RSA
patients with PCOS.
Results of sequencing
illustrated that the guanine nucleotide was substituted by cytosine in the site
of guanine in toxoplasmosis miscarriage women and no displacement or deletion
occurred in adjacent bases, as shown in Figure 1.
Fig. 1. IL-6 DNA
sequence chromatogram of IL-6
(rs1800795C/G) showing the heterozygous genotype of each SNP in toxoplasmosis
miscarriage women.
Table 3. Genotype
frequencies of IL6-174 G/C rs (1800795) in the study groups.
|
|
Genotype incidence rates, No. (%) |
|
|
|
|
Gene |
Toxoplasmosis
cases (50) |
Control (50) |
OR (95% Cl) |
p-value |
|
IL-6 codominant |
GG: 16 (32) ref GC: 20 (40) CC:14 (28) |
GG: 28
(56) GC: 11(22) CC: 11(22) |
3.18 (1.22-8.30) 2.22(0.819-6.05) |
0.0179* 0.116 |
|
Dominant |
GG:16 (32) ref GC-CC:34 (68) |
GG: 28
(56) GC-CC:22 (44) |
0.36 (0.16 - 0.83) |
0.0168 |
|
Recessive |
GG-GC:34 (68) ref CC: 14 (28) |
GG-GC:39 (78) CC: 11 (22) |
0.6850 (0.27-1.70) |
0.117 |
|
Over dominant |
GG-CC:30 (60) ref GC:20 (40 ) |
GG-CC:39 (78) GC:11 (22) |
0.4 (0.20- 0.95) |
0.0179 |
ref: base found in the reference genome. *Significant (P < 0.01)
On the other hand, the polymorphism and amplification product for IL-1β gene agree with(20) who stated that the
amplification of the IL-1β gene
rs 1143634 showed the amplified product was 249 bp, despite using self-designed
nested PCR assays. Several epidemiological studies have found rates of
toxoplasmosis in miscarriage cases; in this regard, several factors can be
proposed, including genetic make-up variation, age group, target DNA region,
and other risk factors such as genetic predisposition to miscarriage and
immunodeficiency, which may influence the prevalence of toxoplasmosis.(21)
Results in Figure 2 showed the guanine nucleotide was substituted by
adenine at the site of polymorphism (rs 11146343) in toxoplasmosis women, after
sequencing PCR product according to the sanger method. IL-1β plays a significant role in reproductive
physiology and has been implicated in ovulation, fertilization, and embryo
implantation as a critical regulatory factor.(22). IL-1β increases the expression of adhesion molecules
such as ICAM-1 on the surfaces of endothelial cells and others.(22)
Results in Table 2 showed the percentage of G allele was higher than A
allele. The frequency of A and G allele in toxoplasmosis miscarriage women was
33.3% and 60%, respectively; while in healthy women it was 9.5% and 82%,
respectively. Similar results were obtained in other studies where the
incidence of TR patients exhibited identical genotype distributions.(20)
Frequencies may increase among pregnant women, but not in toxoplasmosis in
miscarriage.(23) On the other hand, a recent study showed that
patients did not demonstrate any significant effect of these alleles on disease
susceptibility.(6) The A allele could be a risk factor for
increasing susceptibility to infection by toxoplasma, while G allele acts as a
prophylactic. The prevalence rates of GG, GA, and AA genotypes at IL-1β rs 1143634 G>A were 35 (70%), 13 (26%),
2 (4%), respectively; while among the control subjects, the prevalence rates of
the analyzed variants were 27 (54%), 1 (2%), 22 (44%),
respectively as shown in Table 4. These results referred that the GA
polymorphic heterozygous and AA polymorphic homozygous were significantly
associated (p<0.01) with the susceptibility to toxoplasmosis and increased
the risk to the infection with T. gondii, where the odd ratio was 10.02 (95% Cl=1.23-81.48)
in toxoplasmosis versus healthy pregnant women in the codominant model. On the
other hand, odd ratio for recessive GG vs GA+AA was 0.503 (95% Cl= 0.22-1.144)
with no significant (p<0.01) in toxoplasmosis
miscarriage women versus healthy pregnant women, while the odd ratio for
recessive AA vs GA+GG was 0.22 (0.08-0.63) with a highly significant difference in patient women
versus healthy pregnant women.
Fig. 2. IL-1β DNA sequence of IL-1β
(rs1143634 G>A) showing the heterozygous genotype of each SNP in toxoplasmosis
miscarriage women. The reference sequences of SNPs denoted with A.
The nature of the genetic changes observed suggests an active
relationship with congenital toxoplasmosis. This study indicated that A allele
could be a risk factor leading to increased susceptibility for infection, while G
allele acts as a preventive agent.
Table 4. Genotype
frequencies of IL-1β +3954 G/A rs1143634 in the study groups.
|
|
Genotype incidence rates, No. (%) |
|
|
|
|
Gene |
Toxoplasmosis cases (50) |
Control(50) |
OR (95%Cl) |
p-value |
|
IL1B Codominant |
GG:35 (70) GA: 13 (26) AA: 2 (4) |
GG: 27 (54) GA: 1 (2) AA:22 (44) |
10.02 (1.23- 81.48) 0.07 (0.01 -0.32) |
0.031 0.0007* |
|
Dominant |
GG: 35 (70) GA-AA: 15 (30) |
GG: 27 (54) GA-AA: 23 (46) |
0.503 (0.22- 1.144) |
0.101 |
|
over dominant |
GG-AA: 37 (71) ref GA: 13 (26) |
GG-AA: 49 (98) GA: 1 (2) |
17.21 (2.15- 137.57 |
0.0073** |
|
Recessive |
GG-GA:34 (98) AA:6 (2) |
GG-GA: 28 (56) AA:22 (44) |
0.22 (0.08 - 0.63) |
0.0046* |
ref: base found in the
reference genome. **Highly significant (P<0.01)
Despite the importance of IL-1β during the immune response to T. gondii,
no significant difference of the allelic frequencies of this polymorphism
between patients and controls were found. Another study suggested that the
presence of mutated T allele in the gene with IL-1β (C/T) SNP has a protective function against the development of
congenital toxoplasmosis.(21)
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Conflict of interest
The authors declare that
there is no conflict of interest.
Author’s
contributions
Nuha M. Mousa carried out the molecular study
and participated in data analysis.
Hameed M. Jasim conceived and coordinate the study and helped to draft
the manuscript.
All authors reviewed and approved the final version of
this manuscript for publication.
* Literature, Department of Biology, College of Science, Al-Muthana
University, Iraq.