Iron deficiency anemia is an extra-stomach disease experienced in H. pylori carriers. Individuals with type A blood are more prone to suffering from H. pylori infection than other individuals. To clarify the molecular mechanisms underlying H. pylori-associated anemia, we collected erythrocytes from A, B, O, and AB blood donors and analyzed morphology, the number of erythrocytes with H. pylori colonies attached to them, and iron contents in erythrocytes and H. pylori (NCTC11637 and SS1 strains) by means of optical microscopy, scanning electron microscopy, and synchrotron radiation soft X-ray imaging. The number of type A erythrocytes with H. pylori attached to them was significantly higher than that of other erythrocytes (P<0.05). Far more iron distribution was observed in H. pylori bacteria using dual energy analysis near the iron L2, 3 edges by soft X-ray imaging. Iron content was significantly reduced in host erythrocytes after 4 hours of exposure to H. pylori. H. pylori are able to adhere more strongly to type A erythrocytes, and this is related to iron shift from the host to the bacteria. This may explain the reasons for refractory iron deficiency anemia and elevated susceptibility to H. pylori infection in individuals with type A blood.
Citation: Wang Z, Zhang L, Guo Z, Liu L, Ji J, Zhang J, et al. (2012) A Unique Feature of Iron Loss via Close Adhesion of Helicobacter pylori to Host Erythrocytes. PLoS ONE7(11): e50314. https://doi.org/10.1371/journal.pone.0050314
Editor: Michael Glogauer, University of Toronto, Canada
Received: July 18, 2012; Accepted: October 18, 2012; Published: November 21, 2012
Copyright: © 2012 Wang et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: This work was supported by the National High Tech Program (2012AA02A504, 2012AA02A203 and 2011ZX09307-001-05), National Natural Science Foundation of China (81172329, 30973486), the Program of Shanghai Subject Chief Scientist (11XD1403600), Key Research Project from Shanghai Science and Technology Commission (09DZ1950101, 09JC1409600) and Dr. Innovation Fund Projects from Shanghai Jiao Tong University School of Medicine (BXJ 201210). The authors also thank beamline BL08U1A of the Shanghai Synchrotron Radiation Facilities (SSRF) for providing the beam time. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Helicobacter pylori (H. pylori) is a Gram-negative microanaerobic bacillus, which colonized the human gastric mucosa. Persistent infection by H. pylori causes chronic inflammation, ulcers, and even stomach neoplasm in infected individuals. Chronic infection with H. pylori also leads to extradigestive diseases, such as autoimmune disease and diabetes mellitus. Iron deficiency anemia is one of the most common diseases outside the stomach, especially in children and adolescents , , , , , , . A meta-analysis of epidemiological studies revealed a correlation between H. pylori and iron deficiency anemia (OR, 2.22; 95% CI: 1.52–3.24). H. pylori-related iron deficiency anemia is defined as follows: (1) Patients lack obvious gastrointestinal manifestations; (2) patients lack bleeding mucosa lesions under the endoscopic examination; (3) no evidence that iron intake is insufficient; (4) detectable H. pylori infection in patients with chronic gastritis; (5) poor response to iron agent supplementation; (6) dramatic response to eradication therapy targeting H. pylori, even when no iron agent replenishment is given, even to the point of serum iron level recovery in some patients. In general, iron deficiency anemia tends to be attributed to insufficient iron intake, chronic blood loss, malabsorption, and hemolysis. However, another important cause of iron deficiency anemia may be H. pylori infection.
Nakao and colleagues reported that both H. pylori infection and stomach disease are closely associated with genotypes of human ABO blood groups. They demonstrated that the rates of H. pylori infection, chronic atrophic gastritis, and gastric cancer were higher in individuals with type A blood than in other individuals . As early as 1953, Aird found an increased susceptibility to gastric cancer among individuals with type A blood . So far, there has been no reasonable explanation for the special clinical phenomena on a molecular level. In order to uncover the possible mechanisms of H. pylori-related iron deficiency anemia, and of increased risk for H. pylori infection in type A individuals, we collected erythrocytes from donors in A, B, O, and AB blood groups and observed interactions between those erythrocytes and H. pylori ex vivo using optical microscopy, scanning electron microscopy, and third-generation synchrotron radiation.
A synchrotron-based scanning transmission soft X-ray microscopy (STXM) is especially well-suited to the study of the distribution of organic K-edge and metal L-edge analysis. Previously, we used the new technique to study the imaging of biological samples and element distribution , . In the current study, we examined the interactions between H. pylori and human erythrocytes from ABO blood groups and to examine the distribution of iron. This is the first report to assess interactions between human erythrocytes and H. pylori pathogen using optical microscopy, scanning electron microscopy, and third-generation synchrotron radiation. Our research will provide a valuable reference for study of the crucial mechanisms underlying H. pylori-related iron deficiency anemia.
Materials and Methods
Erythrocytes from individuals with ABO blood types were identified using standard erythrocyte antiserum agglutination methods. A 5 ml fresh blood from healthy volunteers of A, B, O, and AB blood groups was centrifuged in anticoagulant tubes (3000 rpm for 10 min). Twenty-microliter samples of erythrocytes were washed twice with phosphate buffered saline (PBS, pH 7.4). Cells were counted on a hemacytometer before experiments.
Written informed consent in the study was obtained from all participants. The study protocol was approved by the ethics committee of Ruijin Hospital, Shanghai Jiao Tong University School of Medicine.
H. pylori preparation
H. pylori strains NCTC11637 and SS1 (both CagA- and VacA-positive) were provided by Professor Guo of the Department of Medical Microbiology and Parasitology, Institutes of Medical Sciences, Shanghai Jiao Tong University, School of Medicine. H. pylori strains were cultured routinely for 72 h on Columbia agar base (Biomerieux, France) with 5% sheep blood in mixed air containing 10% CO2, 5% O2, and 85% N2 at 37°C. Then, we converted H. pylori to liquid medium containing brain heart infusion (BD, U.S.), 10% sheep blood, and the same antibiotics as those used in Columbia agar base. The liquid medium was shaken on a shaking table (Forma Scientific, U.S.) with a constant rotation rate of 120 rpm. H. pylori were counted using a spectrophotometer (BioSpec-min, Shimadzu Scientific Instruments, Japan) and washed with sterile PBS (pH 7.4, 5000 rpm, 10 min) before use.
Co-culture of erythrocytes with H. pylori
Four types of erythrocytes (A, B, O, and AB) were seeded into six well plates at a density of 1×106 per well for each type of erythrocyte. Each type was seeded at quadruple wells. The ratio of the bacteria to erythrocytes was 100∶1. The six well plate was put into the cell culture incubator. After incubation for 4 hours, the mixture of erythrocytes and H. pylori was washed twice using sterile PBS (700 rpm for 5 min) and resuspended in 100 µl PBS.
We resuspended the erythrocytes by 100 µl PBS and smeared on glass slides sterilized by exposure to ultraviolet lamplight for 4 hours. Samples were air dried and slides were fixed by methanol for 2 min. Then reagent A of Wright-Giemsa was dropped onto the slides for 1 min (Baso Diagnostic Inc, Zhuhai, China) followed by reagent B for another 5 min. The slides were washed with distilled water, air dried, sealed using neutral balsam, and covered by cover slips. Interactions between H. pylori and erythrocytes were observed via light microscopy (Olympus BX51, Japan). Erythrocytes with H. pylori colonies attached to them were counted oil immersion lens. Ten random fields were counted for each type of erythrocyte.
Scanning electron microscopy
The mixtures of erythrocytes and H. pylori colonies were resuspended in 100 µl PBS and dropped on a piece of supporting slide (0.5 cm×0.5 cm) which had been sterilized by exposure to ultraviolet lamplight for 4 hours. Samples were air dried and slides were immersed in 2.5% glutaraldehyde in 0.1 M cacodylate buffer (pH 7.4) for 2 hours at room temperature. Then slides were washed 3 times (5 min for each time) in 0.1 M cacodylate buffer (pH 7.4). The slide was re-fixed in 1% osmium tetroxide (aqueous, pH 7.4) for 1 hour at room temperature in a dark container. They were then washed 3 times (5 min each) in 0.1 M cacodylate buffer (pH 7.4) and dehydrated using ethanol at different concentrations. The samples were subjected to critical point drying and mounted onto a metal stub using double-sided carbon tape. Finally, the samples were plated on a layer of metal (gold and palladium) using an automated sputter coater and observed using scanning electron microscopy (FEI, Netherlands).
STXM imaging and Fe L-edge NEXAFS measurements was performed at the beamline BL08U1A of the Shanghai Synchrotron Radiation Facility (SSRF). Mixtures of erythrocytes with H. pylori colonies were resuspended in 100 µl PBS and dropped on a piece of silicon nitride windows (Shanghai NTI Co. Ltd, China) which had been sterilized by exposure to ultraviolet lamplight for 4 hours. The samples were air-dried and the silicon nitride window was immersed in 2.5% glutaraldehyde in 0.1 M cacodylate buffer (pH 7.4) for 2 hours at room temperature. Then the samples were mounted onto the sample holder of the device and observed by soft X-ray spectromicroscopy. The distribution map of iron element was obtained by digital division of two absorption-contrast images at dual photon energies of E1 = 704 eV and E2 = 707.8 eV, which are at and just before the edge of iron absorption. Single-energy images at selected energy levels were scanned and recorded as raw data. The cluster analysis method can be used to obtain not only Fe speciation maps but also the corresponding NEXAFS spectra. First, sequences of images (“stacks”) were recorded at a series of energies around the relevant absorption edge (695–720 eV for Fe L edge). Then they were aligned via spatial cross-correlation analysis. Finally, NEXAFS spectra were extracted from groups of pixels with similar absorption features within the image region of interest using the IDL package aXis2000.
Wright-Giemsa histochemical staining
Under Wright-Giemsa staining, H. pylori were visible in royal blue clusters. Erythrocytes were stained magenta (Figure 1). We counted the number of erythrocytes with H. pylori NCTC11637 strain attached to them in different blood groups. We found the average number of affected erythrocytes to be 6.0 for type A, 3.7 for type B, 3.1 for type O, and 2.8 for type AB (P<0.05). The average number of erythrocytes with H. pylori SS1 strain attached to them was 3.3 for type A blood cells, 1.9 for type B, 1.4 for type O, and 1.5 for type AB (P<0.05). The number of affected erythrocytes was significantly higher among type A cells than other cells (Figure 1A to 1D). No significant difference was found between blood groups B and O (P>0.05); blood groups B and AB (P>0.05); or blood groups O and AB (P>0.05).
(A) Type A erythrocytes. More type A erythrocytes have H. pylori attached to them (arrow). (B) Type O erythrocytes. These have fewer H. pylori attached to them (arrow). (C) The mean number of erythrocytes with H. pylori NCTC11637 strain in each ABO blood group is shown in the bar chart. * indicates that the number of type A erythrocytes is significantly higher than other groups (P<0.05). No significant difference is found between other blood groups. (D) The mean number of erythrocytes with H. pylori SS1 strain in each ABO blood group is shown in the bar chart. * indicates that the number of erythrocytes in blood group A was found to be significantly higher than in other groups (P<0.05). No significant difference is found between other groups (Wright-Giemsa, 1000×). In figure 1C and 1D, the values represent as mean ± standard deviation. The scale bar reprensents the 10 µm.
Scanning electron microscopy
Under scanning electron microscopy, normal erythrocytes appeared as biconcave disc shape with smooth surfaces and diameters of 5–7 µm (Figure 2A). After co-cultivation with H. pylori strains for 4 hours, small protrusions appeared on the surfaces of the erythrocytes (Figure 2B). We noticed, compared with type O erythrocyte, type A erythrocyte (Figure 2B) appeared swelling and rough with more H. pylori colonies attachment. The deformation of type A erythrocytes was more pronounced than that of type O erythrocytes(Figure 2C).
(A) The normal erythrocytes have biconcave disc shapes with smooth surfaces. (B) There are more H. pylori colonies closely attached to type A erythrocytes than to other erythrocytes after 4 hours of co-cultivation. The deformation of type A erythrocytes was more pronounced than that of type O erythrocytes. (C) Fewer H. pylori were attached to type O erythrocytes than to type A erythrocytes. Type O erythrocytes retained their original shapes. Only small protrusions appear on the surfaces of type O erythrocytes (10,000×).
Soft X-ray spectromicroscopy at SSRF
The structure and iron distribution of erythrocytes after exposure to H. pylori were analyzed by soft X-ray spectromicroscopy at BL08U1A beamline of SSRF (Figure 3A). The beam is focused by a zone plate to the sample with a beam size greater than 30 nm. We imaged erythrocytes that had been exposed to H. pylori at E1 = 704 eV and E2 = 707.8 eV, which are just below and at the absorption edge of iron. These two images were analyzed using dual-energy contrast analysis. Figure 3B shows absorption-contrast images of NCTC11637 and SS1 strains of H. pylori. Figure 3C show typical absorption-contrast images of human type O and type A erythrocytes at two photon energies. In Figure 3, the color bar disclosed 16 different color from bottom to top, which corresponds the iron element content. For instance, the purple represents lower iron content, and the orange represents higher iron content. From Figure 3C we noticed, before incubation with H. pylori, the iron content of erythrocyte is rather high (orange to yellow). However, after incubation with H. pylori, the iron content of erythrocyte is obviously low (purple). The color bar represents the relative content changes. The reduction of iron content in type A erythrocytes is more pronounced than in type O erythrocytes. Type A erythrocytes were also found to rupture (Figure 3C, down). We used a stack scan to analyze the chemical valence of iron in H. pylori colonies and found the iron inside bacteria to be mainly ferric iron, as compared to standard sample of Fe3O4, and the concentration of iron inside bacteria is higher than in the bacterial membrane (Figure 4).
(A) Schematic layout of the BL08U beamline. OSA is the order-sorting-aperture. PMT is photomultiplier tube. (B) Dual-energy (707.8 eV and 704 eV) contrast images of H. pylori and iron element. Colored bar on the left side indicates the iron content. From bottom to top, the gradient colors indicate increased iron content. The NCTC11637 strain is shown on the left and the SS1 strain is shown on the right. Two strains appear orange-yellow or light yellow, which means that these H. pylori contained more iron than nearby erythrocytes. (C) Dual-energy (707.8 eV and 704 eV) contrast images of erythrocytes with the iron element. Colored bars on the right side indicate iron content. Type O erythrocyte is on the left and type A erythrocyte is on the right. The color bar represents relative content changes. It has 16 different colors from bottom to top, which correspond the iron element content. For instance, the purple represents lower iron content, and the orange represents higher iron content. From Figure 3C we noticed, before incubation with H. pylori, the iron content is rather high (orange to yellow). However, after incubation with H. pylori, the iron content of erythrocyte is obvious low (purple). Part of the cell membrane of the type A erythrocyte in the right lower corner is damaged.
(A) We selected a portion of the bacterial colonies (magnification on upper-right corner) for the stack scan. (B) Left: the image of photon absorption was obtained from this stack scan for standard Fe3O4. Right: the image of photon absorption was obtained from this stack scan for NCTC11637 strain. The horizontal labels indicate photon energy and the vertical axis indicates normalized absorption. The yellow, red, and blue lines corresponded to the color regions of the figure (A, magnification on upper-right corner) using L-edge soft X-ray imaging.
H. pylori is a pathogen closely related to chronic gastritis, ulcers, and stomach cancer. It has been defined as a class I carcinogen by the World Health Organization. The risk of gastric cancer is significantly reduced after eradication therapy of H. pylori . H. pylori is divided into two different phenotypes, strains that contain vacuolating toxin (VacA) and cytotoxin-associated gene (CagA), and strains that do not. The adhesion and colonization of H. pylori on host cells is a basic characteristic of the species. The outer membrane proteins play an important role in adhesion and colonization. More than 30 outer membrane proteins have been identified on H. pylori . Adhesion to host cells is attributable to proteins such as blood group antigen binding adhesin A and B (BabA, BabB), hop-related proteins B (HorB) and sialic acid-binding adhesin (SabA). . BabA mediates bacterial adherence to human blood group antigens in the gastric epithelium. It is encoded by the BabA2 gene . The BabA2-positive strain is correlated with the activity of gastritis in the antrum and corpus. Alterations in this gene have been found to have severe effects. Adherence of H. pylori via BabA appears to be of importance to efficient delivery of VacA and CagA and may play a role in the pathogenesis of severe histological changes associated with gastric lesions, including intestinal metaplasia and glandular epithelial atrophy . Yu and colleagues analyzed the association between the BabA2 gene and chronic gastritis in 104 H. pylori carriers and noted that increased epithelial proliferation in individuals infected with BabA2 (+) strains. The presence of BabA2 (+) H. pylori strains alone or in combination with CagA (+) and VacA (+) was associated with the presence of precancerous lesions .
Over the last few decades, several studies have shown that the individuals with H. pylori infection always experience unexplained, even refractory iron deficiency anemia , , , . The possible causes of this phenomenon include the following: (1) The bacteria cause chronic gastrointestinal bleeding and decrease iron storage. However, bleeding lesions are rarely observed under the endoscopic examination, and fecal occult blood tests are usually negative. This does not support the conclusion that chronic bleeding is the cause of H. pylori-related iron deficiency anemia , , , , . (2) Atrophic gastritis induced by H. pylori reduces HCl secretion and interferes with iron absorption. In human beings, the duodenum and jejunum are major areas of iron absorption. Two forms of dietary iron exist in nature, heme-iron, which is found in meat, and non-heme-iron, which is found in vegetables and grains. The former is more easily absorbed than the latter. HCl plays a role in the dissolution and absorption of non-heme-iron. Acid can convert ferric iron to ferrous iron to facilitate transport through the cell membrane . (3) The ascorbic acid in the gastric juices may promote the absorption of iron. However, the level of ascorbic acid in H. pylori carriers is much lower than in uninfected individuals .
This study explored the interactions between H. pylori and erythrocytes from individuals with different ABO blood types from multiple energy perspectives. Light microscopy, scanning electron microscopy, synchrotron radiation soft-x-ray were all used to scan the distribution and content of iron element both in bacteria and host cells. We first found that H. pylori had different binding capacities for host erythrocytes with different ABO blood antigens. H. pylori were able to bind to type A cells much more readily than to other cells. It was significantly more difficult for them to bind to type O cells than to other cells. H. pylori became closely attached to the erythrocyte membranes, causing significant cellular deformation. Erythrocytes co-cultivated with H. pylori for 4 hours also showed significant iron loss. We here propose a new probable mechanism of H. pylori–related anemia: the tight adhesion of H. pylori to host cell membrane facilitates the transfer of iron from the host cell to the bacterium (depicted in Figure 5). Optical microscopy, scanning electron microscopy, and synchrotron radiation analysis suggested that host-H. pylori interaction is most intense when the host cells were type A erythrocytes. This is why cell damage is more serious in individuals with type A blood than in other individuals. These findings provide a valuable explanation of the higher incidence of iron-deficiency anemia and H. pylori infection in individuals with type A blood than in other individuals.
In case of H.Pylori infection, the demand for iron element of Helicobacter is increased. H.Pylori colonized in stomach competitively absorbs iron with host. The dietary iron is continuously absorbed by H.Pylori. At the same time, the iron within the host epithelial cells is flowed out and absorbed by H.Pyloris gathered on the surface of epithelial, leading to iron insufficient intake in host.
X-ray spectroscopy of synchrotron radiation is a non-invasive means of analyzing biological samples. Analysis is relatively simple and does not require complex pretreatment procedures. It is suitable for analysis of multiple elements. It has already been used in the initial analysis of many biological samples, including botanical samples , , . To date, there has been no report of any analysis of human red blood cells and H. pylori at a synchrotron radiation facility. This study is the first to explore the interaction and dynamics of the interplay between the iron element of human red blood cells after co-culture with H. pylori by means of the synchrotron radiation examination in a high-energy physics field. We established a double contrast method of image analysis of biological samples and identified the element using absorption edges at or below the previous energy level (E1 and E2, and E1>E2) . In this study, we demonstrated that higher concentrations of iron were present in bacteria than in human erythrocytes. This suggests that iron is an important nutrient for H. pylori. The stack scan analysis of the synchrotron radiation showed that ferric iron is the predominant form of iron in H. pylori, but there is also some ferrous iron. In the human body, ferrous iron is involved in the Fenton reaction, in which iron catalyzes hydrogen peroxide and superoxide to form hydroxyl radicals. Hydroxyl free radicals can injure cells through lipid peroxidation , , . H. pylori mediate iron loss via close adhesion on host cell membrane. It forms a microenvironment rich in free iron ions, and then catalyzes the formation of oxygen free radicals through the Fenton reaction. Bacteria are thereby rendered resistant to oxidative stress , , , , . Iron is not only an important component of proteins and enzymes in living organisms. It is also required for bacterial survival and virulence. Proteins related to iron metabolism have been identified as important factors in H. pylori virulence . The drift of iron from host cells to H. pylori may explain the mechanism underlying refractory anemia in H. pylori-infected individuals. We also provide a valuable clue for developing strategies toward H. pylori intervention and eradication.
In conclusion, this study is the first to demonstrate that increased susceptibility to H. pylori infection is associated with the host's genetic traits, specifically ABO blood group. The ability of H. pylori to adhere to type A blood cells is stronger than its ability to bind to cells from individuals with other blood types. Synchrotron radiation soft X-ray spectromicroscopy was used to explore the molecular mechanism of H. pylori-related iron deficiency anemia. Our findings may be helpful to interpret the unexplained iron deficiency anemia in H. pylori infections and support the conclusion that type A individuals are at higher risk of H. pylori infection.
Conceived and designed the experiments: ZW LZ ZG YY. Performed the experiments: LL JJ Jianian Zhang XC. Analyzed the data: QD XW BL Jun Zhang WZ. Contributed reagents/materials/analysis tools: BL Jun Zhang ZZ YY. Wrote the paper: ZW LZ YY.
- 1. Sherman PM, Lin FY (2005) Extradigestive manifestation of Helicobacter pylori infection in children and adolescents. Can J Gastroenterol 19: 421–424.
- 2. Nahon S, Lahmek P, Massard J, Lesgourgues B, Mariaud de Serre N, et al. (2003) Helicobacter pylori-associated chronic gastritis and unexplained iron deficiency anemia: a reliable association? Helicobacter 8: 573–577.
- 3. Barabino A (2002) Helicobacter pylori-related iron deficiency anemia: a review. Helicobacter 7: 71–75.
- 4. Crew KD, Neugut AI (2006) Epidemiology of gastric cancer. World J Gastroenterol 12: 354–362.
- 5. Qu XH, Huang XL, Xiong P, Zhu CY, Huang YL, et al. (2010) Does Helicobacter pylori infection play a role in iron deficiency anemia? A meta-analysis. World J Gastroenterol 16: 886–896.
- 6. Yuan W, Li Y, Yang K, Ma B, Guan Q, et al. (2010) Iron deficiency anemia in Helicobacter pylori infection: meta-analysis of randomized controlled trials. Scand J Gastroenterol 45: 665–676.
- 7. Ge R, Sun X (2012) Iron trafficking system in Helicobacter pylori. Biometals 25: 247–258.
- 8. Nakao M, Matsuo K, Ito H, Shitara K, Hosono S, et al. (2011) ABO genotype and the risk of gastric cancer, atrophic gastritis, and Helicobacter pylori infection. Cancer Epidemiol Biomarkers Prev 20: 1665–1672.
- 9. Aird I, Bentall HH, Roberts JA (1953) A relationship between cancer of stomach and the ABO blood groups. Br Med J 1: 799–801.
- 10. Xue C, Wang Y, Guo Z, Wu Y, Zhen X, et al. (2010) High-performance soft x-ray spectromicroscopy beamline at SSRF. Rev Sci Instrum 81: 103502.
- 11. Zhang XZ, Xu ZJ, Tai RZ, Zhen XJ, Wang Y, et al. (2010) Ratio-contrast imaging of dual-energy absorption for element mapping with a scanning transmission X-ray microscope. J Synchrotron Radiat 17: 804–809.
- 12. Wong BC, Lam SK, Wong WM, Chen JS, Zheng TT, et al. (2004) Helicobacter pylori eradication to prevent gastric cancer in a high-risk region of China: a randomized controlled trial. JAMA 291: 187–194.
- 13. Yamaoka Y, Kwon DH, Graham DY (2000) A M(r) 34,000 proinflammatory outer membrane protein (oipA) of Helicobacter pylori. Proc Natl Acad Sci U S A 97: 7533–7538.
- 14. Snelling WJ, Moran AP, Ryan KA, Scully P, McGourty K, et al. (2007) HorB (HP0127) is a gastric epithelial cell adhesin. Helicobacter 12: 200–209.
- 15. Gerhard M, Lehn N, Neumayer N, Boren T, Rad R, et al. (1999) Clinical relevance of the Helicobacter pylori gene for blood-group antigen-binding adhesin. Proc Natl Acad Sci U S A 96: 12778–12783.
- 16. Prinz C, Schoniger M, Rad R, Becker I, Keiditsch E, et al. (2001) Key importance of the Helicobacter pylori adherence factor blood group antigen binding adhesin during chronic gastric inflammation. Cancer Res 61: 1903–1909.
- 17. Yu J, Leung WK, Go MY, Chan MC, To KF, et al. (2002) Relationship between Helicobacter pylori babA2 status with gastric epithelial cell turnover and premalignant gastric lesions. Gut 51: 480–484.
- 18. DuBois S, Kearney DJ (2005) Iron-deficiency anemia and Helicobacter pylori infection: a review of the evidence. Am J Gastroenterol 100: 453–459.
- 19. Cardamone M, Alex G, Harari MD, Moss WP, Oliver MR (2008) Severe iron-deficiency anaemia in adolescents: consider Helicobacter pylori infection. J Paediatr Child Health 44: 647–650.
- 20. Blecker U, Renders F, Lanciers S, Vandenplas Y (1991) Syncopes leading to the diagnosis of a Helicobacter pylori positive chronic active haemorrhagic gastritis. Eur J Pediatr 150: 560–561.
- 21. Yip R, Limburg PJ, Ahlquist DA, Carpenter HA, ONeill A, et al. (1997) Pervasive occult gastrointestinal bleeding in an Alaska native population with prevalent iron deficiency. Role of Helicobacter pylori gastritis. JAMA 277: 1135–1139.
- 22. Ashorn M, Ruuska T, Makipernaa A (2001) Helicobacter pylori and iron deficiency anaemia in children. Scand J Gastroenterol 36: 701–705.
- 23. Konno M, Muraoka S, Takahashi M, Imai T (2000) Iron-deficiency anemia associated with Helicobacter pylori gastritis. J Pediatr Gastroenterol Nutr 31: 52–56.
- 24. Kostaki M, Fessatou S, Karpathios T (2003) Refractory iron-deficiency anaemia due to silent Helicobacter pylori gastritis in children. Eur J Pediatr 162: 177–179.
- 25. Lombard M, Chua E, OToole P (1997) Regulation of intestinal non-haem iron absorption. Gut 40: 435–439.
- 26. Zhang ZW, Patchett SE, Perrett D, Katelaris PH, Domizio P, et al. (1998) The relation between gastric vitamin C concentrations, mucosal histology, and CagA seropositivity in the human stomach. Gut 43: 322–326.
- 27. Cardoso SC, Stelling MP, Paulsen BS, Rehen SK (2011) Synchrotron radiation X-ray microfluorescence reveals polarized distribution of atomic elements during differentiation of pluripotent stem cells. PLoS One 6: e29244.
- 28. Regvar M, Eichert D, Kaulich B, Gianoncelli A, Pongrac P, et al. (2011) New insights into globoids of protein storage vacuoles in wheat aleurone using synchrotron soft X-ray microscopy. J Exp Bot 62: 3929–3939.
- 29. Zowczak M, Iskra M, Paszkowski J, Manczak M, Torlinski L, et al. (2001) Oxidase activity of ceruloplasmin and concentrations of copper and zinc in serum of cancer patients. J Trace Elem Med Biol 15: 193–196.
- 30. Rice-Evans C, Burdon R (1993) Free radical-lipid interactions and their pathological consequences. Prog Lipid Res 32: 71–110.
- 31. McCord JM (1998) Iron, free radicals, and oxidative injury. Semin Hematol 35: 5–12.
- 32. Miller RA, Britigan BE (1997) Role of oxidants in microbial pathophysiology. Clin Microbiol Rev 10: 1–18.
- 33. Andrews SC (1998) Iron storage in bacteria. Adv Microb Physiol 40: 281–351.
- 34. Touati D, Jacques M, Tardat B, Bouchard L, Despied S (1995) Lethal oxidative damage and mutagenesis are generated by iron in delta fur mutants of Escherichia coli: protective role of superoxide dismutase. J Bacteriol 177: 2305–2314.
- 35. Lieu PT, Heiskala M, Peterson PA, Yang Y (2001) The roles of iron in health and disease. Mol Aspects Med 22: 1–87.
- 36. Toyokuni S (2009) Role of iron in carcinogenesis: cancer as a ferrotoxic disease. Cancer Sci 100: 9–16.
- 37. McGee DJ, Mobley HL (1999) Mechanisms of Helicobacter pylori infection: bacterial factors. Curr Top Microbiol Immunol 241: 155–180.