Defense against infectious agents and other external aggressions is guaranteed by a complex immune system in which the lymphocytes are the main protective elements ­ with the mission of identifying the foreign antigens pertaining to the exogenous agents, and of producing specific antibodies against them, while at the same time recognizing as own all the endogenous substances produced by the human body. Primary failure of these defense mechanisms gives rise to a broad range of disorders (primary immune deficiencies), the main origin of which is represented by genetic defects that are increasingly better identified and related to each of these diseases1. Secondary immune deficiencies in turn appear late, in the course of many serious illnesses, in which the associated deterioration also affects the host immune system. This situation is generally taken advantage of by the so-called opportunistic microorganisms2. Another example of secondary immune deficiency is that associated with HIV infection, characterized by well known alterations in the patient immune response.

Separate mention must be made of those diseases that develop as a result of failure to recognize the body components as own ­ thus resulting in the generation of autoantibodies that ultimately cause tissue damage. The consequence of such situations is the development of autoimmune pathology, with etiopathogenic features that have not been fully clarified, though both environmental and genetic factors (particularly relating to the major histocompatibility complex (MHC) genotype) are clearly significant3. Naïve lymphocytes can react with autoantigens, thereby triggering the mechanisms that activate the T and/or B lymphocytes4. At present, a new factor has been related to autoimmune pathology ­ particularly rheumatoid arthritis and multiple sclerosis. This new factor is represented by the so-called Th17 lymphocytes, which are different from the Th1 and Th2 cells, and which produce interleukin 17 (IL-17). The latter in turn appears to be implicated in the pathogenesis of such diseases5.

At present, the participation of two additional factors in autoimmune processes is being debated. In effect, TNF-alpha and possibly also other cytokines related with it are implicated at least in perpetuation of the inflammatory cascade. Specific block of this factor has been effective in reducing the symptoms of rheumatoid arthritis and perhaps also systemic lupus erythematosus6. In contrast, interferon-beta type 1 (T1IFN-β), the first choice treatment for multiple sclerosis with the main function of promoting innate immunity, could prevent the progression of some autoimmune disorders, since it promotes the production of a series of cytokines (IL-4, IL-5 and IFN-γ)7.

There is controversy regarding the role which infection caused by certain germs might play in the induction of autoimmune diseases ­ despite the fact that such an association has been observed in a good number of cases, such as for example in reactive arthritis following infection by different strains of Shigella, Salmonella or Yersinia, or in rheumatic fever secondary to Streptococcus A when the patient carries the aforementioned genetic predisposing factors (MHC genotype)3. At present, special mention also should be made of Helicobacter pylori (HP), which may be responsible for another range of disorders (chronic urticaria, vascular diseases, etc.)8,9.

First identified in Australia in 1983, HP is a gramnegative bacterium found in a large proportion of the healthy population, though its prevalence has been associated with lower socioeconomic levels ­ affecting an estimated 13-70 % of individuals under 20 years of age. This figure reaches 94 % in older age groups, and is considerably lower in the more developed parts of the world. Since its discovery, this bacterium has been related to gastrointestinal disorders (gastritis and ulcers), produced by autoantibody action, and which in susceptible individuals could constitute the basis for other autoimmune disorders10-12, in addition to the risk of gastric neoplastic processes over the long term.

It is currently debated whether HP is related to other generalized autoimmune processes (both systemic and organ-specific) following gastric atrophy as a first step in the production of autoantibodies against the proprietary host antigens. Among the different related disease processes (hepatitis, pancreatitis, neutropenia), the most notorious may be pernicious (megaloblastic) anemia, thrombocytopenic purpura and autoimmune thyroiditis (Graves' disease and Hashimoto's disease) ­ the possible inclusion of Sjögren's syndrome and rheumatoid arthritis being the subject of debate.

Pernicious anemia is associated with atrophy of the gastric body secondary to an autoimmune process. The most significant feature is the lack of vitamin B12 (cobalamin) absorption due to the absence of intrinsic factor within the gastric mucosa. Among other authors, Annibale et al.13 have found HP in 60 % of the patients with pernicious anemia, with the presence of functional and histological alterations. Similar results have been reported by Serin et al.14, though a more significant observation is the clinical improvement and increase in serum cobalamin levels recorded by Kaptan et al.15 in patients after the eradication of HP.

Different studies have reported the presence of HP in patients with thrombocytopenic purpura, though the pathogenic relationship in this case has not been well established, and there are evident differences from one country to another. The efficacy of eradication of the microorganism is controversial (Kuwana et al.16), despite the fact that some studies have published increases in platelet count after eradication17,18.

A large percentage of patients with autoimmune thyroiditis are infected with HP. In this sense, it has been suggested that monoclonal antibodies targeted against CagA+ strains (the most pathogenic) may exhibit cross-reactivity with the thyroid follicular cells19. Moreover, in these patients there have been reports of high titers of antimicrosomal and antithyroglobulin antibodies20. Both observations appear to correlate the infection to the pathogenesis of thyroiditis, though there are no conclusive studies in this sense. Larizza et al. have suggested the eradication of HP in children with autoimmune thyroiditis and susceptible HLA alleles, and even in those with the these alleles but who have not yet developed the disease ­ in view of the risk of developing the latter over the long term21.

Another two autoimmune processes, Sjögren's syndrome and rheumatoid arthritis, have been the subject of different studies, in an attempt to determine the implication of HP in the pathogenesis of these two disorders, and the eradication of the germ as a possible treatment option. The results to date are contradictory and not definitive. As a result, and for the time being, anti-infectious treatment does not seem indicated in daily clinical practice ­ though further studies are needed in this field22-25.

In sum, the participation of Helicobacter pylori in the etiopathogenesis of autoimmune processes is subject to controversy, though eradication of the germ proves promising in some cases ­ particularly among genetically susceptible patients (MHC), in whom the development of a disorder of this kind could even be avoided provided treatment is administered as soon as the presence of the bacterium in the stomach is detected3,26.