Shujun Ma

Department of Medical Oncology, Shandong University Affiliated Shandong Provincial Hospital, Jinan China

Research Progress on the Relationship Between Oral Microbial Community and Tumor

Shujun Ma

Department of Medical Oncology, Shandong University Affiliated Shandong Provincial Hospital, Jinan China

Oral microbial community; Oral squamous cell carcinoma; Human immunodeficiency virus;Helicobacter pylori

Significant progress was observed in studies of the relationship between oralHelicobacter pyloriand gastric cancer and tumors. Based on three distinct and close relationships,namely, the relationship between oralH. pyloriand gastric cancer, between oral microbial communities and oral squamous cell carcinoma, and between oral microbial communities of human immunodeficiency virus-infected patients and tumors, this work reviews the relationship between oral microbial communities and tumors. This research also provides reference for further analysis of the relationship between oral microorganisms and tumors to realize early diagnosis of tumor patients through detecting oral microorganisms under adjuvant therapy.

Microorganisms residing in the mouth include bacteria,fungi, and viruses, with bacteria representing dominant communities. Microorganisms compose one of the most complex microbial communities[1]. By the end of 19th century, researchers discovered that microbes cause some serious diseases. By controlling infection and transmission of microorganisms, significant progress was achieved in treatment of some diseases. Literature[2]proved that 20% of cancers are associated with microbial infection.For example,Helicobacter pyloriis closely associated with occurrence of gastric adenocarcinoma and mucosaassociated lymphoid tissue lymphoma; Epstein–Barr virus is associated with Burkitt lymphoma and nasopharyngeal carcinoma. These studies suggested that a close relationship may exist between oral microbial communities and tumors.To date, a large number of studies explored the relationship between oral microbial infection and tumor development.These investigations were limited to descriptive studies and possible mechanisms but provided possible direction to further strengthen studies of mechanism and to realize prevention and treatment of clinical tumors. This work mainly introduces three views. First,H. pyloriand gastritis and gastric cancer are related. Mouth is located at the front of digestive tract. The relationship betweenH. pyloriinfection in the mouth and gastritis and gastric cancer attracted considerable attention. Second, oral squamous carcinoma is the most common oral tumor. This research mainly focuses on relationship of oral squamous carcinoma with microbial community. Third, oral microbial communities of human immunodeficiency virus (HIV)-infected patient show specificity. Thus, HIV patients display high risks of suffering from tumors. Scholars constantly paid atention to the relationship between oral microbial communities and tumors.

Relationship between oral H. pylori and gastric cancer

Relationship between oral H. pylori and H. pylori infection in the stomach

H. pyloriis a Gram-negative, aerobic screw bacterium. Main routes ofH. pyloritransmission include fecal–oral, oral–oral,and gastric–oral routes[3]. Thus, oral health status directly or indirectly affectsH. pyloriinfection and reinfection of the stomach.H. pyloriis found in saliva, biomembrane on back of the tongue, dental plaques, oral ulcers, and oral cancers.Majmudaret al.[4]separatedH. pylorifrom dental plaques of 40 healthy individuals.H. pylorithat commonly exists in the mouth is associated with gastric colonization. Clinical research[5]showed thatH. pylorican be detected from the mouth of 97% of volunteers, whereas 26.2% of volunteers suffered fromH. pyloriinfection gastritis. Miyabayashiet al.[6]observed that effects of systemic antibacterial therapy onH. pyloriinfection gastritis is associated with colonization ofH. pyloriinfection in the mouth. Oral cavity is an important reservoir ofH. pyloriand significantly influencesH. pyloriinfection in the stomach.

Relationship between H. pylori and gastritis and gastric cancer

H. pyloriis related to chronic antral gastritis and peptic ulcer and is clearly related to gastric cancer[7]. In 1994, the World Health Organization consideredH. pylorias a class I carcinogen based on epidemiological investigations.H.pylorican directly regulate function of gastric epithelial cells through its virulence factors, and it can also cause inflammation, indirectly affecting gastric epithelial cells[8,9]. These two processes commonly promote occurrence and development of gastric cancer. In conclusion,H. pyloriin the oral cavity plays an important role in occurrence and development of gastric cancer.

Relationship between oral microorganisms and oral squamous carcinoma

Oral squamous carcinoma is the most common malignant tumor in the oral cavity. Prevalence of this condition accounts for more than 80% of oral cancers[10]. Research constantly center on the relationship between oral microorganisms and oral squamous carcinoma.

Characteristics of oral microflora in oral squamous carcinoma

Characteristics of microflora in oral squamous carcinoma tissuesAerobic bacteria dominate biomembrane on surface of healthy oral mucosa. Biomembrane on tumor surface of oral squamous carcinoma contains more aerobic and anaerobic bacteria than other organisms[11,12]. Compared with healthy mucosa, pathological changes in tumor tissues lead to changes in bacterial colonization, and microbial communities also change correspondingly. Tumor necrosis tissues provide adequate nutrients for growth and metabolism of microorganisms. In ulcerated and stealthy lacunae, oxidation–reduction potential is reduced, favoring growth of anaerobic bacteria. Decreased mucosal secretory function and rough surface of lesions affect cleaning effect of saliva. These factors also create favorable conditions for colonization and growth of anaerobic bacteria[13]. Hooperet al.[14,15]separated living bacteria from surface and depth of oral squamous carcinoma. Their results indicated that microbial environments favor bacterial colonization and survival.

Compared with healthy mucosa environment, type and quantity of bacteria residing in squamous cell carcinoma tissues change significantly. Pushalkaret al.[16]clinically analyzed diversity of bacteria in squamous carcinoma specimen by using 16S rRNA, denaturing gradient gel electrophoresis, and cloning sequencing. Their study results showed that strains highly correlated with tumor tissue includePeptostreptococcus stomatis,Streptococcus salivarius,Streptococcus gordonii,Gemella haemolysans,Gemella morbillorum,Johnsonella ignava, andStreptococcus suistype I. Numerous experiments confirmed colonization of oralStreptococciin squamous cell carcinoma[17,18].Populations of anaerobic bacteria, includingPrevotella,Veillonella,Porphyromonas, andCapnocytophaga, also increased significantly[18]. Kroghet al.[12]noted significantly increased amounts ofVeillonella, Cyperenal,Porphyromonas,Actinomyces,Clostridium,Haemophilus,Enterobacter, andStreptococcuson surface of squamous cell carcinoma tissues.Simultaneously, some rare bacteria, such asPlantibacterflavus,Clavibacter michiganensis, andThermus, exist in deep tissues of oral squamous carcinoma[14,15].

In these colonized bacteria,Streptococcus anginosusis particularly noteworthy.S. anginosusexists only in dental plaques and cannot be detected in saliva. Sasakiet al.[19]discovered high incidence of bacterial infection in patients with oral squamous cell carcinoma, and patients withS. anginosusdetected in canceration position were also diagnosed with oral squamous cell carcinoma, which showed the same genotype ofS. anginosusin squamous cell carcinoma region similar to that in dental plaques.

To date, squamous cell carcinoma tissues contain specific types and number of colonized bacteria. However,research on mechanism and clinical application are still lacking. Further studies should explore the role of microbial colonization in occurrence and development of tumors and treatment effects of controlling microbial infection on tumors to provide positive results for prevention and treatment of tumors.

Characteristics of microbial community of salivaChanges in microbial communities of saliva in oral squamous cell carcinoma patients bear significance in tumor diagnosis. Mageret al.[20]revealed significantly increasedCapnocytophaga gingivalis,Prevotella melaninogenica, andStreptococcus mitisin saliva of oral squamous cell carcinoma patients. These three bacteria act as diagnostic markers and can be used to diagnose approximately 80% of oral squamous cell carcinoma. These bacteria also feature potential in diagnosis of oral squamous cell carcinoma. However,verification of these findings still requires large-scale clinical research. Further research should elucidate causes of changes in salivary microorganisms in patients with squamous cell carcinoma. Such results may be related to secretion of secretory immunoglobulin A (sIgA). Research[13]showed significantly reduced sIgA content in saliva of patients with oral cancer and oral mucosa carcinoma precancerosis and lower secretion speed than healthy individuals. This finding may be favorable conditions for stimulating oral infection.Saliva sampling is easily achieved in clinical practice. Future research should consider achieving early diagnosis of oral squamous cell carcinoma by using change characteristics of salivary microbial communities.

Effects of oral microorganisms on occurrence of oral squamous cell carcinoma

Multiple factors cause oral squamous cell carcinoma. To date, specific risk factors of this disease include smoking and drinking. Other related factors comprise poor oral hygiene,periodontitis, chronic bacterial infection, virus infection,orCandidainfection[15]. Among these risk factors, oral microorganisms play an important role. Aside from infection,microorganisms are also closely related to periodontitis and oral hygiene and smoking and drinking.

Relationship between oral microorganisms and smoking and drinkingSmoking and drinking represent two major risk factors for oral cancer. Ethanol and smog exhibit no carcinogenic effects. Both can be converted into strong carcinogens under the action of oral microorganisms.For example, ethanol is converted to acetaldehyde, a clear mutagenic and carcinogenic substance, which can interfere with synthesis and repair of DNA and induce sister chromosome exchange to generate gene mutations and cell damage[21]. Research showed significant dose–response relationship between frequency and time of ethanol intake and risk of oral squamous cell carcinoma.Gene polymorphism involved in alcohol-metabolizing enzymes can partially explain differences in susceptibility to cancer and may be one of the causes of alcohol metabolism[21]. Similarly, oral microorganisms can activate nitrosodiethylamine in tobacco[17], forming carcinogenic substances. Smoking can also lead to increased concentration of acetaldehyde in saliva[22], posing synergistic effects with drinking[23].

Studies[24]indicated that cysteine can interfere with acetaldehyde-related carcinogenesis and provided possible programs for controlling this risk factor. Cysteine can form thiazole carboxylic acid complex by combining with acetaldehyde, thus eliminating local carcinogenesis. When chlorhexidine is used for gargling before drinking, it can reduce microorganism content and 50% of acetaldehyde in saliva[21].

Influence of oral microorganisms and chronic inflammation on occurrence of squamous cell carcinomaOral microorganisms and their metabolites, including endotoxin, protease, collagenase, fibrinolysin, phospholipase,hydrogen sulfide, ammonia, and faty acid with toxic effects on host cells, can directly induce cell mutation or indirectly change signal transduction pathway of cells to affect cell proliferation and activity of epithelial cells[25]. Chronic inflammation is the most direct characteristic of oral microbial infection. Chronic inflammation can indirectly activate host cells, generating hydrogen peroxide, oxygen-free radical, nitric oxide, malondialdehyde, 4-hydroxynonenal,matrix metalloproteinase, and other virulence factors, which cause cell DNA damage[26]. DNA damage caused by free radicals is the main pathological mechanism of cancer[27].Changes in reactivity of cytokines also play an important role in cancer development.

Sasakiet al.[19]observed that oralStreptococcusinfection can induce synthesis of nitric oxide and cyclooxygenase-2,increase DNA damage, and promote occurrence of oral cancer. Some bacterial toxins can also interfere with signal transduction of cells and promote occurrence of tumors. For example, toxin ofPasteurella multocidaand cytotoxic necrosis factor ofEscherichia colican activate signal transduction of Rho family, causing activation of cyclooxygenase-2,which participates in multiple stage tumor development[28].Mitogens can activate transduction pathway of mitogenactivated protein kinase signaling and D1 cycle to increase gene mutation ratio and probability of cell metastasis and tumor development[29].

In many cell signaling pathways, Toll-like receptor 5(TLR5) shows relatively clear mechanism in occurrence of oral squamous cell carcinoma. Most cells of the immune system can express TLR5 pattern recognition receptors,which can identify bacterialflagellin and stimulate immune reactions. In malignant cells, TLR5 not only promotes inflammatory responses but also stimulates invasion and migration of malignant cells and secretion of chemotactic cytokines. This receptor can provide conditions for development and spread of cancer[30]. Kauppilaet al.[31]detected expression of TLR5 in cancerous sites. Results showed that compared with adjacent healthy epithelium,TLR5 in cancer cells was expressed by basal layer squamous cells. Thus, expression rate of TLR5 significantly increased.Multivariate analysis showed that increased expression of TLR5 is significantly correlated to cancer incidence and cancer-related mortality.

Relationship between oral microorganism in HIV-infected patients and tumors

HIV-associated tumors and non-HIV-associated tumors

HIV infection was a significant research topic for many years.To date, HIV-positive patients are at high risk for cancer.HIV-associated tumors include non-Hodgkin’s lymphoma,Kaposi’s sarcoma, and invasive cervical cancer[32]. Non-Hodgkin’s lymphoma and Kaposi’s sarcoma may occur in the oral cavity. In recent years, with widespread use of highly active antiretroviral therapies, life of HIV-positive patients is prolonged. Prevalence increases for non-HIV-associated tumors, including oral squamous cell carcinoma.

In New York, non-HIV-associated tumors cause non-HIV-related death in HIV-infected individuals. This proportion reaches as high as 21%. Some studies[34]showed that incidence of head and neck cancer in people with HIV infection is two to three times higher than that of the general population. Compared with HIV-negative population,average age of oral cancer patients among HIV-positive population is young, but survival rate is low [35]. Thus,studies should focus on HIV-infected patients suffering from non-HIV-associated tumors.

Occurrence of non-HIV-associated tumors may be related to the virus itself and its immune deficiency. HIV can directly or indirectly induce malignant tumors and directly affect cell proliferation and growth and induce integration of genome and activate oncogenes; this virus can also inhibit expression of some cytokines. These resulting factors can increase risk of cancer. HIV infection can activate chronic B cell and inhibit host immune system, leading to increased risk of cancer[36].Immune deficiency can lead to increased risk of multiple oncogenic viral infections[37], including combined infection of HIV and human papilloma virus (HPV)16 and HPV18.HPV infection can further increase risk of HIV-infected patients suffering from tumors.

Effects of oral microorganisms on tumor occurrence of HIV-positive patients

To date, the relationship between oral microorganisms and tumorigenesis in HIV-positive patients remains unclear.However, compared with normal individuals, HIV-positive patients present specific oral microbial communities.Microbial specificity and high incidence of cancer may exhibit some correlation.

Oral Candida albicans

OralCandida albicansis one of oral resident bacteria.Candidainfection is rare in healthy population but the most common oral fungal disease in HIV-infected patients[38]. Research[39]indicated association ofCandida albicansinfection of HIV patients with oral precancerous lesions. To date, oralCandida albicansinfection is regarded an independent risk factor for HIV patients suffering from cancer[39]. Under HIV infection,bacteria are transformed from oral commensal bacteria to pathogenic bacteria. With phenotypic modifications and enhanced adhesion and invasion[40], these changes may cause cancer. Although carcinogenic mechanism ofCandida albicansrequires further studies, considerable attention is paid to its effects in terms of universality of HIV-positive infection in HIV-associated and non-HIV-associated tumors.Microbial community of periodontal tissues Rare and severe periodontal infections, such as linear erythematous gingivitis and necrotizing ulcerative periodontitis, occur in patients with HIV infection. Subgingival microbial composition presents specificity. Pasteret al.[41]noted that subgingival microorganisms of necrotizing ulcerative periodontitis of HIV-infected patients is very similar to that of non-HIV-infected individuals. However, no typical periodontal pathogens, such asPorphyromonas gingivalis,exists. Aaset al.[42]proved lower than normal levels of typical periodontal pathogens, includingTreponema denticola,Porphyromonas gingivalis, andTannerella forsythia,in subgingival microbial community of HIV-positive patients.Gamella,Bacteroides,Streptococcus, andVeillonellamainly comprised these communities. Mooreet al.[43]also discovered higher numbers ofLeptospiraand mycoplasma in subgingival flora of HIV-positive patients than those of HIV-negative individuals. These studies showed that subgingival flora in HIV-positive patients with specificity may harbor unknown specific microorganisms or microbial species that were previously thought to be incapable of causing periodontal infection. Specificity associated with high incidence of tumor requires further elucidation, but this phenomenon already caused widespread concern.

Krügeret al.[44]reported four cases of oral squamous cell carcinoma accompanied by chronic periodontitis with HIV infection. In addition to a possible pathogenic factor, which is chronic periodontitis in one case, no other carcinogenic factors were identified. Chronic periodontitis is associated with oral squamous cell carcinoma. Tezalet al.[45]observed that clinical attachment loss of HIV patient is associated with oral tumor and precancerous lesions. Periodontal disease may be a risk factor for oral cancer. A subsequent study[46]proved that chronic periodontitis is a risk factor for HIV patient suffering from cancer. Immunological studies showed significantly decreased T cells in gingival tissues of HIV-positive patients[47]. Modifications were also noted in local immune responses, such as increased inflammatory mediators and polymorphonuclear leukocyte accumulation.Changes in these immune factors are also risk factors for tumor development. Further research are required to identify the relationship between risk factors and tumor development.

In summary, oral microbial communities are closely related to occurrence and development of oral tumors.Studies on their relationship will provide a new direction and theoretical basis for early warning and biological treatment of tumor.

Declarations

Acknowledgements

No.

Competing interests

The author declares that he has no competing interest.

Authors’ contributions

SJ Ma made the literature analysis and wrote, discussed and revised the manuscript of this review.

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CorrespondenceShujun Ma,E-mail: sjmajn@163.com

10.1515/ii-2017-0123