Helicobacter pylori infection and colorectal carcinoma: is there a causal association?
Letter to the Editor

Helicobacter pylori infection and colorectal carcinoma: is there a causal association?

Sergei F. Tatishchev1, Christine VanBeek2, Hanlin L. Wang1

1Department of Pathology and Laboratory Medicine, David Geffen School of Medicine at University of California, Los Angeles, California, USA; 2Department of Pathology and Laboratory Medicine, Cedars-Sinai Medical Center, Los Angeles, California, USA

Corresponding to: Hanlin L. Wang, MD, PhD. UCLA Department of Pathology & Laboratory Medicine, 10833 Le Conte Avenue, Los Angeles, CA 90095, USA. Email: hanlinwang@mednet.ucla.edu.

Submitted Oct 29, 2012. Accepted for publication Oct 30, 2012.

doi: 10.3978/j.issn.2078-6891.2012.058


To the Editor,

We would like to thank Dr. Kapetanakis and his colleagues for their interest in our article (1). We specifically appreciate the attention they brought to the importance of environmental factors, particularly Helicobacter pylori (H. pylori) infection, in the development of sporadic colorectal carcinoma (CRC). While the focus of our article was on the pathologic aspects (2), we would like to take this opportunity to extend our discussion to H. pylori as a potential etiopathogenetic factor in colorectal tumorigenesis.

As mentioned by Dr. Kapetanakis and his colleagues, the development of sporadic CRC is associated with a variety of environmental factors including diet and lifestyle. Given that the colon harbors the largest number of microorganisms in the body, it is natural to assume that certain microbial species may play a role in colorectal tumorigenesis. The first reports connecting intestinal microflora with CRC were published back in the early 1950s. Streptococcus bovis septicemia was reported to be associated with carcinoma of the sigmoid colon (3). This association was subsequently supported by several publications (4-6). Animal studies have shown that S. bovis or its cell wall antigens promote the formation of hyperproliferative aberrant colonic crypts, enhance the expression of proliferation markers, and increase IL-8 production in the colonic mucosa (7). IL-8 is a proinflammatory cytokine that has been shown to promote the growth, angiogenesis and metastasis of colon cancer cells (8-11). Taken together, these observations suggest that S. bovis acts as a promoter of colorectal tumorigenesis.

Later on in the mid-1970s, experiments with germ-free rats further showed that intestinal microflora played a modifying role in colorectal tumorigenesis. Germ-free rats developed much fewer colonic tumors compared to conventional rats when challenged with carcinogens (12,13). Since then, a number of commensal bacteria have been linked to CRC, including Escherichia coli, Enterococcus faecalis, Bacteroides spp. (B. fragilis, B. vulgatus, B. stercoris), Eubacterium limosum, and Clostridium septicum (14-22).

Ever since the oncogenic properties of H. pylori were firmly established in the stomach, studies on its oncogenicity have extended to other parts of the gastrointestinal tract, particularly the colon (23). To date, the link between H. pylori infection and CRC remains inconclusive, with some reports showing an association (24-32) while others none (33-37). The results of two meta-analyses published in 2006 and 2008 both suggested a possible small increased risk of CRC in association with H. pylori infection (38,39).

Several hypotheses have been proposed to explain the possible link between H. pylori infection and CRC. These include: (I) hypergastrinemia, (II) change in colorectal microflora, (III) toxin production, and (IV) chronic inflammation secondary to direct H. pylori colonization in the colon.


Hypergastrinemia

Gastrin and gastrin-like peptides received considerable attention in the 1980s and 1990s because of their growth-promoting properties. Early in vitro studies demonstrated that gastrins had a direct mitogenic effect on cultured normal and neoplastic colonic cells (40-42). Later researches reported that induced hypergastrinemia resulted in hyperproliferation of colonic mucosa in transgenic mice (43-45). In addition, gastrin gene knock-out mice showed decreased proliferation of the colonic mucosa (46). Furthermore, several case-control studies observed elevated serum/plasma gastrin levels in patients with colorectal adenomatous polyps and/or adenocarcinoma (47-50). These observations suggest that hypergastrinemia in the setting of H. pylori-associated atrophic gastritis promotes colorectal tumorigenesis.

However, the link between hypergastrinemia and CRC has been in question from the beginning. Animal studies showed that drug-induced hypergastrinemia had no stimulatory effect on the growth of colonic mucosa or CRC progression (51-53). In fact, omeprazole was found to inhibit colorectal tumorigenesis induced by azoxymethane in rats despite causing hypergastrinaemia (54). In humans, chronic hypergastrinemia caused by proton pump inhibitors also showed no effect on the development of colonic adenomas (55). Patients with Zollinger-Ellison syndrome does not show an increased risk of developing CRC despite prolonged and marked plasma elevation of all forms of gastrin (56). Several studies demonstrated that serum/plasma gastrin levels were not significantly different between subjects with and without colorectal neoplasia, and thus unlikely to play a significant role in colorectal tumorigenesis (57-61). It is interesting to note that some studies have demonstrated that CRC tumor cells express gastrins that may function as autocrine growth factors (62-66). In that scenario, gastrin secretion by tumor cells is likely the source of hypergastrinemia observed in CRC patients. In support of this notion, several studies demonstrated a fall in serum/plasma gastrin values in CRC patients following surgical resections of the tumors (48,67,68). While these data may further support a role of hypergastrinemia in colorectal tumorigenesis, they argue against a direct association with H. pylori infection.


Change in colorectal microflora

Gastric acid barrier is an important regulator of the population and composition of the intestinal microflora (69-72). Atrophic gastritis secondary to H. pylori infection is associated with reduced acid production, which permits a greater number and variety of microbial species to enter and colonize the intestinal tract. It has been proposed that shifts in the composition of colorectal microflora resulted from H. pylori atrophic gastritis may facilitate selective growth of bacteria such as B. fragilis, E. faecalis, and others that are linked to the development of CRC (14-16,18-20). Supporting this hypothesis are studies showing an increased CRC risk following gastric surgery for benign peptic ulcer disease (73,74). However, other studies failed to confirm the association between gastrectomy and subsequent CRC development (75-78).


Toxin production

There are different H. pylori strains, some of which are more virulent and more carcinogenic than the others. For instance, patients infected with H. pylori organisms that express cagA gene are more likely to develop gastric cancer than those infected with cagA-negative strains (79,80). Shmuely et al. tested patients with various malignancies for serum antibodies against H. pylori and CagA protein and found that CagA seropositivity was associated with an increased risk not only for gastric adenocarcinoma but also for colonic adenocarcinoma, when compared with CagA-seronegative controls (81). However, as the authors pointed out, the findings should be interpreted with caution because the tests for H. pylori and CagA were performed at the same time of cancer diagnosis, which raised the question about the temporal relationship between the two conditions. The conclusions of the study were drawn under the assumption that H. pylori infection occurred before CRC development, as for gastric adenocarcinoma. A reasonable argument would be that CRC patients may have an altered immune status, which allows H. pylori organisms, especially the more virulent strains, to have a greater chance to successfully establish infection in these patients.

If infection by cagA-positive H. pylori strains does in fact precede and contribute to the development of CRC, the underlying mechanisms remains elusive. It has been shown that infection by cagA-positive strains is associated with higher levels of gastrin than that by cagA-negative strains (82,83). Overproduction of IL-8, which is known to be a growth factor for human colon carcinoma cells (8-11), may also be implicated (81,84,85). In addition, infection with cagA-positive H. pylori strains is associated with an increased likelihood of developing atrophic gastritis (86-88), which would be expected to sustain a more drastic disruption of the gastric acid barrier function to allow for an abnormal bacterial colonization in the lower intestinal tract as discussed above.


Chronic inflammation secondary to direct H. pylori colonization in the colon

Chronic mucosal inflammation is believed to be a predisposing factor for CRC development, as evidenced by inflammatory bowel disease. Given H. pylori’s well-established proinflammatory and carcinogenic effect in the stomach, a “chronic inflammation → dysplasia → neoplasia” sequence, similar to that for inflammatory bowel disease, may occur in the colon initiated by direct H. pylori colonization.

In this regard, Kapetanakis et al. reported detection of H. pylori organisms in malignant tissues from 34 of 41 (82.9%) CRC patients by cresyl violet staining and immunohistochemistry (32). Using the same staining methods, the authors recently extended their study to 50 patients with CRC and 25 patients with colonic polyps and found that H. pylori organisms were present in 84% CRC tissues and 64% polyps (1). It is unclear, however, whether the authors have also included nonneoplastic colonic tissues for comparison in their studies, where the organisms were located in the tissues, and what staining characteristics they have observed for the organisms. Soylu et al. examined 51 colonic polyps (39 tubular adenomas, 3 tubulovillous adenomas, 5 villous adenomas, and 4 adenocarcinomas) by immunohistochemistry and demonstrated positive staining in 11 (21.6%) polyps. In 10 (90.9%) polyps, however, the positive staining was interpreted as equivocal and appeared nonspecific (89). Again, no nonneoplastic colonic mucosa was included for comparison. In the study by Jones et al., a total of 176 colorectal specimens (normal 58, adenoma 59, adenocarcinoma 59) were examined by H. pylori immunohistochemistry. Positive staining was seen in 1 (1.7%) normal sample, 9 (15.3%) adenomas, and 
10 (16.9%) adenocarcinomas (90). However, all the positive cases showed granular and dot-like staining patterns; none of the positive cases demonstrated an unequivocal spiral form of H. pylori organisms as typically seen in the stomach. It is thus difficult to determine whether the positive staining represents deformed (dead or partially degraded) organisms or simply staining artifact.

Employing a Helicobacter species-specific 16S rDNA PCR assay combined with pyrosequencing analysis, Grahn et al. detected the presence of Helicobacter DNA sequences in 21 of 77 (27%) CRC biopsy specimens (91). No nonneoplastic colorectal tissues were examined in the study because the authors did not have access to normal colorectal biopsy specimens according to the authors. However, in a different study using the same techniques, the researchers were able to detect H. pylori DNA in 5 of 19 colon samples biopsied from 3 patients with microscopic colitis. No H. pylori DNA was detected in 12 rectal biopsies that were histologically normal (92).

Although the exact route of H. pylori transmission has not been fully understood, person-to-person transmission via either oral-to-oral or fecal-to-oral route is most common. Since H. pylori organisms are shed in stools from infected individuals (93-95), it is not surprising that the organisms, which may just simply pass through the intestinal tract with digested contents, can be detected in colonic tissue samples. It should also be noted that H. pylori-associated gastric cancer is known to be the consequence of chronic active gastritis that leads to mucosal atrophy, intestinal metaplasia and dysplasia. However, there have been no reports of chronic or active colitis resulted from direct H. pylori infection in the colon. Based on our experience, the colonic mucosa in patients with H. pylori gastritis shows normal histology unless other medical conditions are present. Thus, simply identifying H. pylori organisms in colorectal tumor samples does not prove a causal relationship.


Conclusions

While the etiopathogenetic role of H. pylori in gastric cancer is well-established, its role in colorectal tumorigenesis remains controversial. H. pylori infection of the stomach may promote colorectal tumorigenesis indirectly in a variety of ways such as modulating intestinal microflora, enhancing cytokine production and increasing gastrin secretion. These effects may be more pronounced when infected by more virulent H. pylori strains. Detection of H. pylori antigens and/or DNA in colonic tissue samples does not necessarily mean colonic colonization by the organisms, and should not be viewed as direct evidence of causal association with colorectal tumorigenesis.


Acknowledgements

Disclosure: The authors declare no conflict of interest.


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Cite this article as: Tatishchev SF, VanBeek C, Wang HL. Helicobacter pylori infection and colorectal carcinoma: is there a causal association? J Gastrointest Oncol 2012;3(4):380-385. doi: 10.3978/j.issn.2078-6891.2012.058

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