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Bahmaie N, Faghihzadeh S, Esmaeilzadeh A, Amini B. Immunomodulatory Effects of Helicobacter Pylori on Pro and Anti-Inflammatory Cytokines Production in Peripheral Whole Blood Cells Culture.Biosci Biotech Res Asia 2016;13(4).
Manuscript received on : 13 May 2016
Manuscript accepted on : 16 July 2016
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Immunomodulatory Effects of Helicobacter Pylori on Pro and Anti-Inflammatory Cytokines Production in Peripheral Whole Blood Cells Culture

Nazila Bahmaie1, Soghrat Faghihzadeh2, Abdolreza Esmaeilzadeh*3 and Bahram Amini4

1Department of Microbiology and Virology, Faculty of Medicine, Zanjan University of medical sciences, Zanjan, Iran.

2Department of Biostatistics and Epidemiology, Faculty of Medicine, Zanjan University of Medical Sciences, Zanjan,Iran.

3Department of Immunology and Cancer Gene Therapy Research Center, Faculty of Medicine, Zanjan University of Medical Sciences, Zanjan, Iran.

4Department of Microbiology and Virology, Faculty of Medicine, Zanjan University of Medical Sciences, Zanjan, Iran.

Corresponding Author E-mail: a46reza@zums.ac.ir

DOI : http://dx.doi.org/10.13005/bbra/2387

ABSTRACT: Recent documentations about sepsis as a systemic inflammatory response and inefficiency of some antimicrobial treatments in immunological disordersoutline that any intervention modifying the immune response with therapeutic intent, will be rational. Helicobacter Pylori (H.pylori), with major role in etiopathogenesis of duodenum peptic ulcer and gastric lymphoma, exerts itʼs immunomodulatory properties with long time intestinal colonization and protection against several certain inflammatory disorders. Due to theunclearness ofthis pathogenimmunomodulatory effects on whole blood cells culture, the aim of this study is evaluation of H.pylori whole body immunomodulatory effectson whole blood cells culture. In this study, after H.pyloriisolation from a pathological positive biopsy specimen, it was cultured in Brucella Blood Agar. Then, bacteria was co-cultured with whole blood cells in RPMI-1640 for 24h with CO2 incubation. At last, TNF-alpha and TGF-beta concentrations of supernatants were assayed by quantative ELISA. Finally, non-parametric tests were measured out for data analysis. Our results showed upregulation of TGF-betaand TNF-alphasecretion, exposure toH.pylori (p value 0.017 and 0.018, respectively) compared to their untreated cultureThese data show that immune response of H.pylori maypromote pro and anti-inflammatory responses. It seems that clinical applications of cytokines secretion, may be a promising window for further investigation leading to improvement of immune related diseases.

KEYWORDS: Immunomodulation; Helicobacter pylori; Whole blood cells; Cytokine

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Bahmaie N, Faghihzadeh S, Esmaeilzadeh A, Amini B. Immunomodulatory Effects of Helicobacter Pylori on Pro and Anti-Inflammatory Cytokines Production in Peripheral Whole Blood Cells Culture.Biosci Biotech Res Asia 2016;13(4).

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Bahmaie N, Faghihzadeh S, Esmaeilzadeh A, Amini B. Immunomodulatory Effects of Helicobacter Pylori on Pro and Anti-Inflammatory Cytokines Production in Peripheral Whole Blood Cells Culture.Biosci Biotech Res Asia 2016;13(4). Available from: https://www.biotech-asia.org/?p=16885

Introduction

According to the previous studies, it is demonstrated that infectious diseases are one of the major challenges for Health System in which, alteration in the soluble mediators function fails to induce an adequate immune response and is accompanied by hypo/hyper activity of immune responses. In addition, some problems as: reappearance of invasive pathogens and changing nature of infectious disease manifestation, add more considerations up for scientific researchers and physicians. Accordingly, in light of these problems, sepsis has been continued to be a worldwide dilemma with the prevalence of high mortality(1).

Also, indiscriminately usage of antibiotics has led to antibiotics resistance, multi drug resistant strainsreappearance and chronicity of the diseases, recently. Overall, these issues, visualize several severe gaps in clinical trials which led scientists to look for novel directionstoward immunobiology targeting (1). Therefore, it is expected that an optimistic insight and supportive point of view on other therapeutic strategies should be created. This is where, it is rational to interface with some elements contributing to the re-regulation of the dysregulated immune responses.

The term “Immunomodulation” refers to any intervention modifying the immune response with therapeutic intent.“Immunomodulators” are considered as active substances in immunotherapy based therapeutic methods. These agents are approved by the International Organization for Food and Drug Administration (FDA) with fewer side effects and less potential for drug resistance advantages. There are a wide variety of immunomodulators from natural and organic compounds to synthetic and recombinant ones (2-4).

In this strategy, activity of the host immune system, changes through the dynamic regulation of signaling molecules such as: antibodies, soluble receptors, bio drugs, hormones, acute or chronic stress, adhesion molecules, neurotransmitter peptides, cytokines and even bacterial extract (or cellular membrane fractions of bacteria). Generally, these changes include in immunostimulation, immunosuppression and immunological tolerance induction assisting to adjustment of the desired immunity level on the circumstances (1-3).

Growing number of scientific investigations and documentations indicate that certain biological agents, specially a well-known group of microorganisms, also exert immunomodulatory properties by modulating leukocyte function and circulating concentrations of proinflammatory cytokines as extracellular (glyco) protein key regulators and messengers of the immune system(5, 6).

Helicobacter Pylori(H.pylori), a spiral gram negative bacterial pathogen with long term colonization in the antrum and duodenum, is associated with gastric atrophy, duodenum peptic ulcers, gastrointestinal adenocarcinoma and Mucosal Associated Lymphoid Tissue (MALT) lymphoma(7-11). In addition of several bacterial virulence factors role for itʼs pathogenicity, host immune system responses help to gastric damage development. Immunopathology of H.pylorimainly depends on Th1 cells and their secreted cytokines. It is demonstrated that H.pylori confers protection against some extra gastric diseases such as: Asthma, Allergy, atopic diseases andchronic inflammatory disorders. This bacterium, presents itʼs immunomodulatory properties with deviation of adaptive immune system toward immune tolerance induction through CD4+ CD25+ Regulatory T cells, reprogramming of CD103+ Dendritic cells to tolerogenicity phenotype and associated interleukin-18 (IL-18)(8-20).

Anyway, our knowledge of the immunological communications about protection against pathogens is superficial. Subsequently, evaluation of immunopathophisiology of the pathogens, outstanding about cytokines activity and their receptors, cytokines cascades involved in microbial-host immune responses interactions, and recruitment of an appropriate immunomodulator to immunologic phase of diseases should be consideredto accelerate the realization of overcoming to diseases rate(2, 3). It seems that clinical applications of shifts in cytokines secretion due to the immunomodulators usage, may be a potentiated window for elimination of undesirable immunological reactions leading to improvement of immune levels for whom suffering from such immune related disorders.

Since that, there has been no study on whole blood cells with whole body of H.pylori in order to assess immunomodulation, the purpose of this research is conducting an in vitrostudyevaluating immunomodulatory properties of H.pylorion peripheral whole blood cells culture by cytokines assay.

Materials and Methods

Ethical Considerations

This study accessed ethic`s approval from the Zanjan University of Medical Sciences Research Ethic’s Committee (no. ZUMS.REC.1394.143). Among the medical faculty students, seven young healthy (H.pylori-non infected, without chronic inflammatory diseases history) volunteer women (range 20-25 years old) were recruited for the purpose of this study. First, by giving them explanations about moral confidence and biosafety, oral consent was reached and then, a written informed consent was achieved.

Study design

RPMI-1640 (complete medium) preparation

To the RPMI-1640as incomplete serum free cell culture medium((Gibco. KBC Company) With L-Glutamine and NaHCO3), penicillin- streptomycin solution 1% (100 U/mL penicillin, 100 μg/mL streptomycin) (Sigma-Aldrich) was added, which supplemented with 10% (vol/vol) heat inactivated (56°C for 30 min) Fetal Bovine Serum (FBS) (Gibco). This, was designated as a complete homogenous cell culture medium following gently inverting.

Immunomodulatory compound preparation

Bacterial strain culture

First, from a pure bacterial culture of an approved pathological positive biopsy endoscopyspecimen (CagA+,VacA+) belonged to a peptic ulcer patient, isolation of H. pyloriwas done. After transferring this bacterial culture petri dish into an equipped designated microbiology laboratory in a jar with gas pack C (Merck.KGaA. Germany), a loop of bacteria introduced into a Brain Heart Infusion (BHI) broth culture (Merck. Germany) as an enrichment/activator medium and incubated for 24 hours at 37°C in a microaerophilic condition.

Subsequently, Brucella Blood Agar (supplemented with 10% defibrinated sheep’s blood (Provided by ROSHD, Med Biotech, IRAN), 10µg/L vancomycin (DANA Pharmaceutical Company, IRAN), 5µg/L trimethoprim (Amin Pharmaceutical Company, IRAN), 2.5IU/L polymixin B and Brucella Agar (Merck. Germany))was considered as a reference culture medium. A further streak cultured plate of bacteria was prepared and incubated for 5 days at 37°C at a candle jar to ensure bacterial characteristics (Main stock cultures were kept at -20°C with 18% glycerol in BHI broth).

Then, colonies with tiny, round, raised, flat, transparent featuresand 0.5-1 millimeter in diameter,were observed and microbial tests such as Gram staining for purity and bacterial morphology assessments were done.

Ultimately, the nature of bacterial strain was confirmed through positive results for biochemical tests such as tube Urease (Urea Agar culture), slide Catalase and oxidase.

Here, viable counts of cultured bacterium (Colony Forming Unit) was measured at Optical Density (OD600nm) 1.3±0.1×109 (OD600nm at exponential growth phase of bacteria is equivalent to 3.4×109 after 28h incubation

Bacterial Solution Preparation

It should be noted that concentrations of whole bacteria used overall this experiment, were reached in our previous trials in order to induce immunomodulatory effects as follows:

Here, confirmed colonies were scrapped from Brucella Blood Agar surface and transferred into BHI broth. Next, 1.5 ml of 24 hours harvested H.pylori in BHI broth media was collected into an eppendorf microtube and centrifuged(during log growth phase of bacteria). Supernatant fluid was removed and remained pellets were once suspended in 1.5 ml of 0.01M ice-cold sterile PBS (Phosphate Buffered Saline, pH=7.28) (MERCK. Germany). The eppendorf microtube was again centrifuged.Next to discarding supernatant, 1.5 ml of RPMI-1640 was added which followed by gently mixing to reach homogenous bacterial solution. Concentration was determined by colony forming unit (CFU) counting.

Whole Blood Cells Preparation

To substructure TNF-alpha and TGF-beta expression manifestation in the response to antigenic stimulation (immunomodulator), human peripheral whole blood cells were chosen for our experiment`s end.

Participants (blood donors)

Median age and BMI of participants were shown in table2. All donors had antigens A on their erythrocytes surface (blood group A).

Blood Collection

Participants were pleased to come to the laboratory. Blood samples were withdrawn by an authorized supervisor with sterile gauge needles. Antecubital venous blood (7 ml) was collected into vacutainer blood collection tubes containing sodium heparin (Caspian Tamin Co. Iran).

Blood Analysis

Blood samples which were collected into heparinized tubes, first inverted several times to mix properly with anticoagulant agent. Then, they were delivered to hematology ward for hematological analysis immediately to achieve the best unbiased results by an automated hematology analyzer (Nihan Koden. Cell Tac E. Japan). Each sample was measured twice and the average value was recorded for all donors (Table2).

Study Procedure

After preparation of reagents, procedure of study was defined as below:

Whole blood cells culture stimulation

After confirmation about study design, first of all, stimulant was reconstituted by bringing it to room temperature up. As shown in Table 1, required volumes of RPMI-1640 were added into the culture wells of a 48 flat bottomed wells sterile-polystyrene cell culture plate (Jet Biofil. Guangdong, China (Mainland) (1.55 ml and 0.19-0.29 ml, Max and working well volume respectively) followed by 0.25 ml of heparinized whole blood cells (final estimation: 2×106 cells per ml). Next, followed by adding the appropriate amount of bacteria solution (Table1) in aseptic condition under biological safety cabinet(Laminar flow class II). Then, ingredient of each well was gently mixed by several times aspiration and ejection.

Table 1: Consumed volumes of RPMI-1640 and immunostimulants solution for each well

Well RPMI-1640 (Medium/Dilutor) (µl) Diluted bacterial solution (adjuvant) (µl Whole blood (target) (µl)
1* 1000
2* 750 250
3 725 25 250

Final volume for each well was considered 1000µl.

1* and 2*were blank for culture medium and blood cells, respectively.

Incubation conditions of treated whole blood cells

Thereafter, antigen stimulated specimens (table1), were incubated for 22h at 37°C and 5% CO2 atmosphere in a 90% humidified chamber (Time of incubation was set). After cultivation, and cell counting, viability assay was done for human whole blood cells.

Supernatant collection

After 22h incubation, supernatants of all samples were transferred into 1.5 ml microcentrifuge eppendorf tubes and spun for 5 min at 5000 rpm at room temperature (Sigma). Subsequently, supernatant phase of fluid for all samples, were collected into another new labelled eppendorf tubes and stored temporarily at -20°C freezer.

Measurement of cytokine secretion

First, supernatant fluids were removed from freezer and kept at room temperature for thermal equilibrium. Results of this study, were documented with scales of secreted cytokines (TGF-beta and TNF-alpha) profileof homogenated human peripheral whole blood cells stimulated by pathogenic isolate of H.pylorithrough an Enzyme Linked Immunosorbant Assay (ELISA) method. All assays were run in triplicate for all wells containing samples and the average scores were registered by a blind technologist.

ELISA for cytokine assay

TGF-beta1

The assay was performed in order to manufacturer`s instruction commercial kit for quantative detection of TGF-beta1cytokine (eBioscience. Bender Med System GmbH. Austria. REF BMS249/4/) in cell culture supernatants which was estimated as below:

Briefly, after pretreatment of samples with assay buffer 1x, 1N HCl and 1N NaOH, 100 µl of assay buffer 1x was added to blank well. 100 µl of each standard solutions was added to standard wells. Then, 60 µl of assay buffer 1x and 40 µl of vortexed pretreated samples were added to sample wells. After incubating for 2h at room temperature and 400 rpm (set on a microplate thermoshaker), the human anti TGFbeta1 coating antibodies which are adsorbed onto microwells, bind to human TGF-beta present in the samples and standards.

Next to washing, 100 µl of Biotin-Conjugated anti human TGF-beta detecting antibodywas added to each microwell strips and incubated as clarified recently in order to bind to complex which was made in previous step.

After washing, unbound biotin conjugates were removed and 100 µl diluted Streptavidin- Horse Radish Peroxidase (HRP) was added to all wells and incubated as said before, to bind to 3-fraction complex which was created in previous step.

After last washing for removing unbound Streptavidin-HRP, 100 µl of Tetra Methyl Benzidine (TMB) Substrate (as cromogene), was added to each well to associate to last 4-fraction complex. It was incubated for about 30 minutes at room temperature for color development without exposure to direct intense light. Color intensity is proportional to the HRP activity.

After that, as soon as the highest standard was reached to dark blue color and an OD of 0.90-0.95 for standard solution was recorded, enzyme-substrate reaction should be terminated by pipetting 100 µl of stop solution (Sulfuric Acid) into each well. This is where, changing pH of the medium by stop solution seems essential for inhibition of enzymatic reaction and stabilizing color development to reach an accurate intensity measurement. Absorbance of each well was read immediately on an ELISA MICROPLATE READER (Garni Company) using 450 nm (primary) and 620 nm (reference) wave lengths. Cytokines concentrations were calculated with a standard curve.

TNF-alpha

The main investigation procedure of TNF-alphaassay was done similarly to TGF-beta exception for sampling step (samples don’t any need to pretreatment and only should be diluted by adding sample diluent buffer) in order to manufacturer’s instruction (eBioscience. DX. Bender Med Systems GmbH. Austria. REF BMS223/4CE).

Two kits for mentioned cytokines were human specific with sensitivity of 8.6±2 pg/ml and 2.3±2 pg/ml for TGF-beta and TNF-alpha, respectively.

Statistical Analysis of data

The Statistical Package for the Social Sciences(SPSS) version 16.0 computer software (SPSS Inc., USA) was used for the statistical analysis of acquired data. Non-parametric statistical tests (Freidmann`s and Mann Whitney) and descriptive testswere applied for information and data of the experiment. Results were expressed as Mean plus minus Standard Deviation (SD). Statistical significance was considered at p value<0.05.

Results

Hematological parameters of blood samples

Table 2 indicates the Mean and SD scores recorded for hematological analysis of bloodsamples. All of these hematological parameters scores fell into the normal ranges.

Table 2: Descriptive Statistics results of hematological parameters recorded for blood samples at a glance

Parameters Age BMI HCT WBC RBC PLT NEU HGB LYMPH
Mean ±SD 22.42±2.14 23.89±1.53 42.12±0.15 4.60±0.24 4.77±0.10 172±4 2.46±0.03 13.97±0.2 2.02±0.3

 RBC= Red Blood Cells                     WBC= White Blood Cells            LYMPH= Lymphocyte               NEUT= Neutrophil

HCT= Hematocrit                             PLT= Platelet                                HGB= Hemoglobin                     BMI= Body Mass Index

Cytokines production by H.pyloristimulated whole blood cells culture TGF-betacytokine production by H.pyloristimulated whole blood cells culture

Table 3, shows the average concentrations of the TGF-betacytokines produced in the H.pyloristimulated whole blood cells culture meanwhile the nature of the wells were clarified after data statistical calculation.

Table 3: TGF-beta cytokine production (pg/ml) in response to H.pylori stimulated whole blood cells culture

Well RPMI-

1640

(1)

RPMI+whole blood

(2)

RPMI+whole blood+H.pylori

(3)

Mean±SD blank 25.28±2.87 43±1.73

As shown in Table 3, H.pylori significantly upraised TGF-beta cytokines secretion by whole blood cells after 22h incubation (well no.3) compared to control well (well no.2) (p value=0.017).

TNF-alphacytokine production by H.pyloristimulated whole blood cells culture

Table 4, shows the average concentrations of the TNF-alpha cytokines produced in the H.pylori stimulatedwhole blood cells culture meanwhile the nature of the wells were clarified after data statistical calculation.

Table 4: TNF-alphacytokine production (pg/ml) in response to H.pylori whole blood cells culture

Well RPMI-

1640

(1)

RPMI+whole blood

(2)

RPMI+whole blood+

H.pylori

(3)

Mean±SD 97±2.16 157.14±2.96

As shown in Table 4, H.pylorisignificantly upraised TNF-alphacytokine production by whole blood cells after 22h incubation (well no.3) compared to control well (well no.2) (p value=0.018).

Discussion

H.pyloriis a bacterium with colonization in gastric mucosa, has tight association to several adverse clinical sequelae like peptic ulcers, gastric cancers (metaplasia and dysplasia of gastric mucosa) induction, non- Hodgkin lymphoma, bacteremia (as a rare complication) and amazing ability for co-existence with humans for decades with subsequent evasion of chronic gastric inflammation(21-25). Persistence and severity of H.pylori infection, depends on bacterial components, host associated factors (such as susceptibility, immune responses and genetic factors) and environmental factors that determine bacterium switching to commensalism or pathogenicity variations(2, 21, 23-26).

This prolonged interaction between bacterium and host immune system, makes it as a feasible infectious agent for triggering autoimmunity which is characterized with loss of tolerance to self-antigens. There are strong documentations on H.pylori infection and it`s association with development of many extra gastric chronic autoimmune diseases such as: urticaria, psoriasis, Schoenline Henoch Purpura (SHP), vasculitis, scleroderma, typhoid fever, chronic Hepatitis C, Coronary Artery Diseases (CADs), type 1 diabetes, chronic autoimmune thyroiditis (Hashimoto’s)  and Graves` Diseases. Infection with H.pylori elicits a significant immunomodulation(23, 27-34).

In addition, it is demonstrated that H.pylorichronic infection may also be beneficial to host immune system for conferring protection against allergy, rhinitis, asthma, atopic dermatitis (Eczema) and Inflammatory Bowel Diseases (IBD) which is highly associated with suppressive Treg cells function(9, 12-14, 18, 20, 24, 35-47).

Inducible Treg cells are considered to immune tolerance maintenance through induction of anergy and deletion of autoreactive T cells and believed to be generated by tolerogenic semi mature Dendritic Cells (DCs) which are highlighted for us with converting naïve T cells into Foxp3 Treg via antigen presentation in the absence of co-stimulatory molecules. Reprogramming of H.pylori experienced DCs to tolerogenic phenomenon, requires inflammasome and caspase-1 activation, secretion of IL-18, and a TGF-beta dependent manner (23, 24, 36, 48).

Several studies investigated the role of declining in H.pyloriinfection prevalence at increased risk of celiac diseases(16, 49). Others, suggest earlier eradication of H.pylori for alteration in immunopathophisiology of neurodegenerative disorders including Multiple Sclerosis (MS), peripheral neuropathies, migraine, Parkinson’s Disease (PD), Alzheimer’s Disease (AD), epilepsy, Crohn`s diseases, and Ophthalmological disorders as: glaucoma and non-arteritic anterior ischemic optic neuropathy,even others such as Idiopathic Thrombocytopenic Purpura (ITP), eosinophilic esophagitis and HIV(50-60).

These already mentioned, had beenclinical studies based on H.pylori immunomodulation properties. So far, whole body of H.pylori effects on whole blood cells in order to immunomodulationassessment has remained unclear. Overall,in the present study aimed to investigation of H.pyloriimmunomodulatory impact on peripheral whole blood cellsculture, our results corroborated that H.pylori may trigger a strong modulation and upregulation on both TGF-beta and TNF-alphacytokines secretionin whole blood cells compared to control (p value= 0.017, 0.018, respectively).The amounts of secreted TNF-alpha by whole blood cells after exposure with H.pyloriwere more than TGF-beta. So, it seems that H.pylori can induce Th1 and Th2 responses which promote pro and anti-inflammatory actions.

There are no such as this study and our results are in accordance with some partially similar previous studies.M.Wiese et.al in their study aimed to investigation of Immunomodulatory effects of liveLactobacillus Planatarum and Helicobacter Pylori on some cytokines and cell surface markers induction in whole blood culture,showed that both,H. pylori alone and in combination with L. plantarum, had a strong modulatory effect on the synthesis of IL-10 and an inhibitory effect on IFN-gamma secretion (61).

Jay Lutheret.al showed that H pylori DNA has the ability to downregulate pro-inflammatory responses from DC and this may partly explain the inverseassociation between H pylori and IBD with lower systemic type 1 IFN(62).

Frank Meyeret.al indicated that Th1 polarization of the gastric immune response may be due in part to the direct effects of multiple different H. pylori components that enhance IFN-gamma and IL-12 production while inhibiting both IL-2 production and cell proliferation that may be necessary for Th2 responses(63).

Songhua Zhanget.al observed that antigen-specific functional differences between the T cell repertoires of H. pylori positive and -negative subjects for a set of 90 immunoinformatic-predicted T-cell epitopes from seven genetically diverse H. pylori strains. Cytokine ELISA measurements performed using in vitro PBMC culture supernatants, demonstrated significantly higher levels of TNF-alpha, IL-2, IL-4, IL-6, IL-10, and TGF-beta1 in the H. pylori-infected subjects, whereas IL-17A expression was not related to the subjects H. pylori-infection status(22).

Benedetta Romi et.al for finding if and how H. pylori could induce and modulate human T cell activation, studied direct interaction of live, but not killed bacteria with purified CD3+ T lymphocytes on lymphocytes freshly isolated from peripheral blood of H. pylori-negative donors. The results showed activation of CD3+ T lymphocytes, predominantly gamma-delta T cells, upregulation of CD69 and cytokines such as TNF-alpha and IFN-gamma favouring to inflammatory microenvironment leading to incompletely clearance of pathogen, local inflammation and eventually to the gastric and duodenal diseases(64).

In conclusion, to attribute and generalize results of this study to clinical manifestations, it should be noticed that there is a complex immune response to H.pylori.In addition, this pathogen has ability to induce Th1 and Th2 immune responses. Induction of TNF-alpha production as a multifunctional cytokine has a key role in apoptosis, cell survival and antitumor activity as well as in inflammation and immunity.Upregulation of TGF-betasecretion, stimulates Th2 responses differentiation, Th1-mediated autoimmune disease reduction, and appears immunological tolerance leading to Treg cell proliferation, multi-organ inflammationand autoantibodies development diminution.

Conclusion

According to results of our study, H. pylorihas a special modulatory impact on immune system responses with pro and anti-inflammatory cytokine induction.

Immune related anomalies have been still remained as a most common concerns for health care system. It appears that consideration of time for immune intervention, accurate understanding on immunopathophisiology of infectious related immune disorders, predomination of pro and/or anti-inflammatory cytokines and conditions of immune microenvironment which are pivotal to fulfill immunomodulation.

This study refers to an optimistic point of view provided to further investigation onclinical applications ofalteration in cytokines secretion due to the immunomodulators usage. This may be a promising window in order to elimination of undesirable immunological reactions and improvement of immune related diseases.

Acknowledgment

This project is financially supported and beholden by a grant from Zanjan University of Medical Sciences (approved code: 19/3-3/1198).

References

  1. Masihi KN. Immunomodulators in infectious diseases: panoply of possibilites. International journal of immunopharmacology. 2000;22(12):1083-91.
    CrossRef
  2. Muhamad AS, Gleeson M. The in vitro Effects of Various Immunomodulatory Nutritional Compounds on Antigen-Stimulated Whole-Blood Culture Cytokine Production. in vitro. 2014;1:9999747.
  3. Spelman K, Burns J, Nichols D, Winters N, Ottersberg S, Tenborg M. Modulation of cytokine expression by traditional medicines: a review of herbal immunomodulators. Alternative Medicine Review. 2006;11(2):128.
  4. Gea-Banacloche JC. Immunomodulation. Principles of Molecular Medicine: Springer; 2006. p. 893-904.
    CrossRef
  5. Tkalčević VI, Hrvačić B, Pašalić I, Haber VE, Glojnarić I. Immunomodulatory effects of azithromycin on serum amyloid A production in lipopolysaccharide-induced endotoxemia in mice. Journal of antibiotics. 2011;64(7):515-7.
    CrossRef
  6. Sheikhi A, Shakerian M, Giti H, Baghaeifar M, Jafarzadeh A, Ghaed V, et al. Probiotic Yogurt Culture Bifidobacterium Animalis Subsp. Lactis BB-12 and Lactobacillus Acidophilus LA-5 Modulate the Cytokine Secretion by Peripheral Blood Mononuclear Cells from Patients with Ulcerative Colitis. Drug research. 2016.
  7. Amberbir A, Medhin G, Abegaz WE, Hanlon C, Robinson K, Fogarty A, et al. Exposure to Helicobacter pylori infection in early childhood and the risk of allergic disease and atopic sensitization: a longitudinal birth cohort study. Clinical & Experimental Allergy. 2014;44(4):563-71.
    CrossRef
  8. Aydogdu S, Cakir M, Yuksekkaya HA, Tumgor G, Baran M, Arikan C, et al. Helicobacter pylori infection in children with celiac disease. Scandinavian journal of gastroenterology. 2009.
  9. Blaser MJ, Chen Y, Reibman J. Does Helicobacter pylori protect against asthma and allergy? Gut. 2008;57(5):561-7.
    CrossRef
  10. Lee SP, Lee SY, Kim JH, Sung IK, Park HS, Shim CS, et al. Correlation between Helicobacter pylori infection, IgE hypersensitivity, and allergic disease in Korean adults. Helicobacter. 2015;20(1):49-55.
    CrossRef
  11. Luther J, Dave M, Higgins PD, Kao JY. Association between Helicobacter pylori infection and inflammatory bowel disease: a meta‐analysis and systematic review of the literature. Inflammatory bowel diseases. 2010;16(6):1077-84.
    CrossRef
  12. Arnold IC, an d Anne Müller IH. The immunomodulatory properties of Helicobacter pylori confer protection against allergic and chronic inflammatory disorders. Research Advances in the Study of Campylobacter, Helicobacter & Related Organisms. 2012:135.
    CrossRef
  13. Arnold IC, Dehzad N, Reuter S, Martin H, Becher B, Taube C, et al. Helicobacter pylori infection prevents allergic asthma in mouse models through the induction of regulatory T cells. The Journal of clinical investigation. 2011;121(8):3088-93.
  14. Engler DB, Reuter S, van Wijck Y, Urban S, Kyburz A, Maxeiner J, et al. Effective treatment of allergic airway inflammation with Helicobacter pylori immunomodulators requires BATF3-dependent dendritic cells and IL-10. Proceedings of the National Academy of Sciences. 2014;111(32):11810-5.
    CrossRef
  15. Jin X, Chen Y, Chen S, Xiang Z. Association between Helicobacter Pylori infection and ulcerative colitis–a case control study from China. Int J Med Sci. 2013;10(11):1479-84.
    CrossRef
  16. Lebwohl B, Blaser MJ, Ludvigsson JF, Green PH, Rundle A, Sonnenberg A, et al. Decreased risk of celiac disease in patients with Helicobacter pylori colonization. American journal of epidemiology. 2013:kwt234.
    CrossRef
  17. Müller A, Arnold I, Hitzler I. The Immunomodulatory Properties of Helicobacter pylori Confer Protection Against Allergic and Chronic Inflammatory Disorders. Frontiers in Cellular and Infection Microbiology. 2012;2:10.
  18. Taye B, Enquselassie F, Tsegaye A, Medhin G, Davey G, Venn A. Is Helicobacter Pylori infection inversely associated with atopy? A systematic review and meta‐analysis. Clinical & Experimental Allergy. 2015;45(5):882-90.
    CrossRef
  19. Wjst M. Does Helicobacter pylori protect against asthma and allergy? Gut. 2008;57(8):1178-9.
  20. Zevit N, Balicer RD, Cohen HA, Karsh D, Niv Y, Shamir R. Inverse Association Between Helicobacter pylori and Pediatric Asthma in a High‐Prevalence Population. Helicobacter. 2012;17(1):30-5.
    CrossRef
  21. Larussa T, Leone I, Suraci E, Imeneo M, Luzza F. Helicobacter pylori and T Helper Cells: Mechanisms of Immune Escape and Tolerance. Journal of immunology research. 2015.
    CrossRef
  22. Zhang S, Desrosiers J, Aponte-Pieras JR, DaSilva K, Fast LD, Terry F, et al. Human immune responses to H. pylori HLA class II epitopes identified by immunoinformatic methods. PloS one. 2014;9(4):e94974.
    CrossRef
  23. Magen E, Delgado J-S. Helicobacter pylori and skin autoimmune diseases. World journal of gastroenterology: WJG. 2014;20(6):1510.
    CrossRef
  24. Oertli M, Müller A. Helicobacter pylori targets dendritic cells to induce immune tolerance, promote persistence and confer protection against allergic asthma. Gut microbes. 2012;3(6):566-71.
    CrossRef
  25. Peleteiro B, Bastos A, Ferro A, Lunet N. Prevalence of Helicobacter pylori infection worldwide: a systematic review of studies with national coverage. Digestive diseases and sciences. 2014;59(8):1698-709.
    CrossRef
  26. Figueiredo CA, Marques CR, dos Santos Costa R, da Silva HBF, Alcantara-Neves NM. Cytokines, cytokine gene polymorphisms and Helicobacter pylori infection: Friend or foe? World journal of gastroenterology: WJG. 2014;20(18):5235.
    CrossRef
  27. Kutlubay Z, Zara T, Engin B, Serdaro lu S, Tüzün Yn, Yilmaz E, et al. FIND ISSUES. Hong Kong Med J. 2014;20(4):317-24.
  28. Xiong L-J, Mao M. Current views of the relationship between Helicobacter pylori and Henoch-Schonlein purpura in children. World journal of clinical pediatrics. 2016;5(1):82.
    CrossRef
  29. El-Eshmawy MM, El-Hawary AK, Gawad SSA, El-Baiomy AA. Helicobacter pylori infection might be responsible for the interconnection between type 1 diabetes and autoimmune thyroiditis. Diabetology & metabolic syndrome. 2011;3(1):1.
    CrossRef
  30. Delitala AP, Pes GM, Malaty HM, Pisanu G, Delitala G, Dore MP. Implication of Cytotoxic Helicobacter pylori Infection in Autoimmune Diabetes. Journal of Diabetes Research. 2016;501:7347065.
  31. Vareki SM, Zarkesh-Esfahani H, Behjati M. Helicobacter pylori’s Evasion of the Immune System Could Establish an Inflammatory Environment That Potentially Induces the Development of Coronary Artery Disease. Jundishapur Journal of Microbiology. 2013;6(3):242-7.
    CrossRef
  32. Bassi V, Santinelli C, Iengo A, Romano C. Identification of a correlation between Helicobacter pylori infection and Graves’ disease. Helicobacter. 2010;15(6):558-62.
    CrossRef
  33. Shi W-J, Liu W, Zhou X-Y, Ye F, Zhang G-X. Associations of Helicobacter pylori infection and cytotoxin-associated gene A status with autoimmune thyroid diseases: a meta-analysis. Thyroid. 2013;23(10):1294-300.
    CrossRef
  34. Troch M, Woehrer S, Streubel B, Weissel M, Hoffmann M, Müllauer L, et al. Chronic autoimmune thyroiditis (Hashimoto’s thyroiditis) in patients with MALT lymphoma. Annals of oncology. 2008;19(7):1336-9.
    CrossRef
  35. Gibson DJ, Ryan EJ, Doherty GA. Keeping the bowel regular: the emerging role of Treg as a therapeutic target in inflammatory bowel disease. Inflammatory bowel diseases. 2013;19(12):2716-24.
    CrossRef
  36. Oertli M, Sundquist M, Hitzler I, Engler DB, Arnold IC, Reuter S, et al. DC-derived IL-18 drives Treg differentiation, murine Helicobacter pylori–specific immune tolerance, and asthma protection. The Journal of clinical investigation. 2012;122(3):1082-96.
    CrossRef
  37. Major G, Spiller R. Irritable bowel syndrome, inflammatory bowel disease and the microbiome. Current Opinion in Endocrinology, Diabetes and Obesity. 2014;21(1):15-21.
    CrossRef
  38. Oertli M, Noben M, Engler DB, Semper RP, Reuter S, Maxeiner J, et al. Helicobacter pylori γ-glutamyl transpeptidase and vacuolating cytotoxin promote gastric persistence and immune tolerance. Proceedings of the National Academy of Sciences. 2013;110(8):3047-52.
    CrossRef
  39. Wang Q, Yu C, Sun Y. The Association Between Asthma and Helicobacter pylori: A Meta‐Analysis. Helicobacter. 2013;18(1):41-53.
    CrossRef
  40. Hussain K, Letley DP, Greenaway AB, Kenefeck R, Winter JA, Tomlinson W, et al. Helicobacter pylori-Mediated Protection from allergy is associated with il-10-secreting Peripheral Blood regulatory T cells. Frontiers in Immunology. 2016;7.
    CrossRef
  41. Holster IL, Vila AMJ, Caudri D, den Hoed CM, Perez‐Perez GI, Blaser MJ, et al. The impact of Helicobacter pylori on atopic disorders in childhood. Helicobacter. 2012;17(3):232-7.
    CrossRef
  42. Imamura S, Sugimoto M, Kanemasa K, Sumida Y, Okanoue T, Yoshikawa T, et al. Inverse association between Helicobacter pylori infection and allergic rhinitis in young Japanese. Journal of gastroenterology and hepatology. 2010;25(7):1244-9.
    CrossRef
  43. Kienesberger S, Cox LM, Livanos A, Zhang X-S, Chung J, Perez-Perez GI, et al. Gastric Helicobacter pylori Infection Affects Local and Distant Microbial Populations and Host Responses. Cell reports. 2016;14(6):1395-407.
    CrossRef
  44. Rokkas T, Gisbert J, Niv Y, O’Morain C. The association between Helicobacter pylori infection and inflammatory bowel disease based on meta-analysis. United European gastroenterology journal. 2015;3(6):539-50.
    CrossRef
  45. Papamichael K, Konstantopoulos P, Mantzaris GJ. Helicobacter pylori infection and inflammatory bowel disease: is there a link. World J Gastroenterol. 2014;20(21):6374-85.
    CrossRef
  46. Lim JH, Kim N, Lim SH, Kwon J-W, Shin CM, Chang Y-S, et al. Inverse Relationship Between Helicobacter Pylori Infection and Asthma Among Adults Younger than 40 Years: A Cross-Sectional Study. Medicine. 2016;95(8).
    CrossRef
  47. Ali A, Ayman M, Mahmoud M. Helicobacter pylori Infection and its Potential Role in Childhood Eczema. Journal of Immunological Techniques in Infectious Diseases. 2016;2016.
  48. Koch KN, Müller A. Helicobacter pylori activates the TLR2/NLRP3/caspase-1/IL-18 axis to induce regulatory T-cells, establish persistent infection and promote tolerance to allergens. Gut microbes. 2015;6(6):382-7.
    CrossRef
  49. Crabtree J, O’Mahony S, Wyatt J, Heatley R, Vestey J, Howdle P, et al. Helicobacter pylori serology in patients with coeliac disease and dermatitis herpetiformis. Journal of clinical pathology. 1992;45(7):597-600.
    CrossRef
  50. Xiang Z, Chen Y-P, Ye Y-F, Ma K-F, Chen S-H, Zheng L, et al. Helicobacter pylori and Crohn’s disease: a retrospective single-center study from China. World J Gastroenterol. 2013;19(28):4576-81.
    CrossRef
  51. Boziki M, Grigoriadis N, Deretzi G, Lagoudaki R, Lourbopoulos A, Panayotopoulou E, et al. Helicobacter pylori immunomodulative properties in a mouse model of multiple sclerosis. Immunogastroenterology. 2012;1(1):34-9.
    CrossRef
  52. Suzuki T, Matsushima M, Takagi A, Mine T. Association between Helicobacter pylori Infection and Idiopathic Thrombocytopenic Purpura in Adults. Journal of Blood Disorders & Transfusion. 2014;2014.
  53. Hasni SA. Role of Helicobacter pylori infection in autoimmune diseases. Current opinion in rheumatology. 2012;24(4):429.
    CrossRef
  54. von Arnim U, Wex T, Link A, Messerschmidt M, Venerito M, Miehlke S, et al. Helicobacter pylori infection is associated with a reduced risk of developing eosinophilic oesophagitis. Alimentary pharmacology & therapeutics. 2016;43(7):825-30.
    CrossRef
  55. Farooq M, Bhatt A. Helicobacter pylori: neurological and ophthalmological disorders. Revista de Ciências Médicas e Biológicas. 2009;8(3):334-41.
  56. Kountouras J, Gavalas E, Zavos C, Stergiopoulos C, Chatzopoulos D, Kapetanakis N, et al. Alzheimer’s disease and Helicobacter pylori infection: defective immune regulation and apoptosis as proposed common links. Medical hypotheses. 2007;68(2):378-88.
    CrossRef
  57. Suwarnalata G, Tan AH, Isa H, Gudimella R, Anwar A, Loke MF, et al. Augmentation of Autoantibodies by Helicobacter pylori in Parkinson’s Disease Patients May Be Linked to Greater Severity. PloS one. 2016;11(4):e0153725.
    CrossRef
  58. Kountouras J, Deretzi G, Gavalas E, Zavos C, Polyzos SA, Kazakos E, et al. A proposed role of human defensins in Helicobacter pylori-related neurodegenerative disorders. Medical hypotheses. 2014;82(3):368-73.
    CrossRef
  59. Roubaud-Baudron C, Krolak-Salmon P, Quadrio I, Mégraud F, Salles N. Impact of chronic Helicobacter pylori infection on Alzheimer’s disease: preliminary results. Neurobiology of aging. 2012;33(5):1009. e11-. e19.
  60. Magen E, Elbirt D, Agmon-Levin N, Mishal J, Sthoeger Z. Eradication of Helicobacter pylori can facilitate immune reconstitution in HIV-1-infected immunological non-responders. International Journal of Infectious Diseases. 2010;14(4):e322-e7.
  61. Wiese M, Eljaszewicz A, Andryszczyk M, Gronek S, Gackowska L, Kubiszewska I, et al. Immunomodulatory effects of Lactobacillus plantarum and helicobacter pylori CagA+ on the expression of selected superficial molecules on monocyte and lymphocyte and the synthesis of cytokines in whole blood culture. Journal of Physiology and Pharmacology. 2012;63(3):217.
  62. Luther J, Owyang SY, Takeuchi T, Cole TS, Zhang M, Liu M, et al. Helicobacter pylori DNA decreases pro-inflammatory cytokine production by dendritic cells and attenuates dextran sodium sulphate-induced colitis. Gut. 2011;60(11):1479-86.
    CrossRef
  63. Meyer F, Wilson KT, James SP. Modulation of innate cytokine responses by products of Helicobacter pylori. Infection and Immunity. 2000;68(11):6265-72.
    CrossRef
  64. Romi B, Soldaini E, Pancotto L, Castellino F, Del Giudice G, Schiavetti F. Helicobacter pylori Induces Activation of Human Peripheral + T Lymphocytes. PloS one. 2011;6(4):e19324.
    CrossRef
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