Humoral and cellular immune responses to influenza vaccination in children with cancer receiving chemotherapy
- Authors:
- Published online on: May 17, 2012 https://doi.org/10.3892/ol.2012.721
- Pages: 329-333
Abstract
Introduction
The influenza virus is a pathogen that causes respiratory disease in humans and has the potential to cause epidemics and pandemics (1). During the 1918 pandemic, 40–50 million individuals succumbed to the disease globally (2). During the 2009 pandemic, 17,483 mortalities were reported to the World Health Organization with an estimate of 200 million H1N1 influenza cases worldwide for December 2010 (3). In the United States, influenza is more frequent in winter and is associated with 36,000 mortalities annually (4). In Mexico, influenza has been associated with 7–12% of respiratory infections in certain areas (5,6).
Influenza infection is characterized by sudden respiratory symptoms (fever, myalgia, headache, coughing, pharyngeal aching and rhinitis) (7). The uncomplicated disease improves within 3–7 days. However, in certain individuals with risk factors, complications may present including viral pneumonia, secondary bacterial infections or coinfections, sepsis and even mortality. In young children, influenza infection may present as sepsis with a high fever (8). The risk factors include pneumopathy, cardiopathy and an immunocompromised state that may be observed among patients with cancer or human immunodeficiency virus (HIV) and steroid recipients (4,9–16).
Chemotherapy inhibits the ability of the immune system to develop an immune response to invading pathogens via vaccination or incidental exposure and acts by suppressing bone marrow production and decreasing the vital components of the immune system (17). There is controversy with regard to the humoral immune response to influenza vaccination in children with cancer who are receiving chemotherapy. Certain authors have reported an effective antibody response in such children, albeit at a lower proportion than among healthy individuals, especially when receiving chemotherapy at the moment of vaccination (18,19).
Certain studies have suggested that cellular immunity to an influenza vaccine is a useful predictor of protection against disease in the elderly (20). The cellular immune response to an influenza vaccine has been described as the expansion of CD8+ and CD4+ T lymphocytes with surface markers that classify them as effector or memory T cells based on the surface markers CD62L and CD45RA (21–24); other molecules, including CD27, are costimulatory and indicate activation (25). These surface markers have yet to be characterized in children with cancer who are receiving chemotherapy and who have been immunized with an influenza vaccine. The objective of this study was to characterize the cellular and humoral immune responses to influenza vaccination among children with cancer who are receiving chemotherapy.
Materials and methods
Ethics
This study was a prospective, quasi-experimental, comparative clinical trial with auto controls. The study was approved by the Institutional Review Board of the Hospital Infantil de México Federico Gómez (Mexico City, Mexico; HIM/2007/025) and the School of Medicine of the Universidad Nacional Autónoma de México (Mexico City, Mexico; 19–2007). Informed consent forms were signed by the parents or guardians of all the study participants. The study was conducted following the Good Clinical Practice and the International Conference of Harmonization standards.
Study population
The patients included in the study were 56 individuals with cancer who were aged 2–16 years and were receiving chemotherapy at the Oncology Department of the Hospital Infantil de México Federico Gómez, Mexico. Exclusion criteria were an allergy to egg protein, thrombocytopenia or the lack of a follow-up blood collection. The subjects received the inactivated trivalent influenza vaccine prior to chemotherapy administration. No participant had a history of influenza vaccination. Blood samples were obtained prior to and at 4 weeks after vaccination for humoral and cellular assays. The clinical symptoms were assessed over 14 days and on day 30.
Influenza vaccine and vaccine administration
Inactivated trivalent Vaxigrip vaccine (Sanofi Pasteur, Paris, France), containing 15 μg of hemagglutinin protein for each virus [A/New Caledonia/20/99 (H1N1), A/Wisconsin/67/2005 (H3N2) and B/Malaysia/2560/2004] was used for the winter season of 2006–2007. Fluarix vaccine (GlaxoSmithKline, Mexico) containing 15 μg of hemagglutinin protein for each virus [A/Solomon Islands/3/2006 (H1N1), A/Wisconsin/67/2005 (H3N2) and B/Malaysia/2560/2004] was used for the winter season of 2007–2008. The vaccine was administered intramuscularly over the deltoid area of the left arm.
Influenza antibody assay
IgG anti-influenza antibodies were detected by the hemagglutination inhibition (HI) technique. Briefly, the serum was separated by centrifugation and frozen at −70°C until tested in parallel. Aliquots of serum (50 μl) treated with enzyme-destroying receptor overnight in several dilutions were placed in duplicate 24-well plates. A concentration of 8 hemagglutination units (HU) for each virus (A H1N1, A H3N2 and B) was added for 30 min. A 0.85% suspension of turkey erythrocytes was added for 20 min until inhibition of hemagglutination was observed. A titer of ≥1:40 was considered a positive response.
Cell proliferation measured by 3H-thymidine
Fresh peripheral blood mononuclear cells (PBMC) were separated from whole blood by Ficoll-Hypaque gradients and added to 96-well microtiter plates at a concentration of 3×105 cells/well in RPMI-1640 medium (Gibco, Gaithersburg, MD, USA) containing 10% normal human serum (Sigma-Aldrich, St. Louis, MO, USA). The influenza antigen, prepared from infected Madin-Darby Canine Kidney (MDCK) cell lysates or an uninfected cell control, was added at dilutions of 1:4, 1:8 and 1:16 in triplicate wells. T-cell proliferation was measured by adding 3H-thymidine (2.5 μCi per well) after 5 days for 6–18 h. The stimulation index (SI) was calculated as the mean counts per minute (cpm) in the influenza antigen-stimulated wells divided by the mean cpm in the control wells. Phytohemagglutinin (Difco, Detroit, MI, USA) and tetanus toxoid (Calbiochem, La Jolla, CA, USA) were used as positive controls.
Cell populations measured by flow cytometry
Separated PBMC were added to 96-well microtiter plates at a concentration of 3×105 cells/well in RPMI-1640 (Gibco) with 10% normal human serum (Sigma-Aldrich). The cells were stimulated with the inactivated influenza antigen or an uninfected cell control (MDCK cells); concanavalin A was used as a mitogen control. After 5 days, the cells were stained with monoclonal antibodies conjugated to CD8-Pe-Cy7, CD4-PeCy5 and CD19-PE cells and with markers related to activation and memory CD45RA-PE and CD27-FITC cells (BD Pharmigen, La Jolla, CA, USA). The cell frequencies were measured using flow cytometry in the FacsCanto II cytometer (Becton Dickinson and Company, Franklin Lakes, NJ, USA).
Statistical analysis
Geometric mean titers (GMT), mean cpm values and the mean cell frequencies prior to and at 1 month after vaccination were compared using the non-parametric Mann-Whitney U test. The percentages were compared using Chi-square tests and p<0.05 was considered to indicate a statistically significant result. Results are expressed as the means ± standard deviation (SD) and the antibody response as geometric mean titers with 95% confidence intervals (CI).
Results
Study population and clinical characteristics
A total of 56 children were included in the study, recruited in the winter seasons between December 2006 and February 2007 (33 individuals) and between October 2007 and February 2008 (23 individuals). The mean age (±SD) was 6.6±3.6 years, the mean weight was 22.4±10.1 kg and the mean height was 1.1±0.2 m. The underlying diagnosis was acute lymphoblastic leukemia (ALL) in 75, solid tumors in 23 and lymphoma in 2% of the patients. All 56 children were receiving chemotherapy at the moment of vaccination. Among the patients with ALL, 19% were on the induction phase and 81% on the maintenance phase of chemotherapy. Of the 56 patients, 25% were on one chemotherapy drug, 40 on two, 16 on three, 16 on four and 3 on five. The majority of patients were receiving either methotrexate or vincristine alone or in combination with other chemotherapy agents: 53% received vincristine, 47% methotrexate, 19% cytarabine, 19% daunorubicin, 25% L-asparaginase, 15% cyclophosphamide, 15% mercaptopurine, 15% dexamethasone, 6% etoposide, 6% actinomycin and 3% carboplatin.
Antibody response to influenza vaccine
Seropositivity for the three serotypes (H1N1, H3N2 and B) prior to vaccination was observed in 43% of the patients and an increase to 73% was observed 1 month after vaccination. An individual analysis for each serotype of the virus at 1 month after vaccination demonstrated an increase in seropositivity from 43% prior to vaccination to 63% for the H1N1 serotype (p=0.02), from 68 to 85% following vaccination for the H3N2 serotype (p=0.05) and from 0 to 14% for the B serotype (p=0.006; Fig. 1). An increase in the GMT was observed from 31.35 (95% CI, 29–111) prior to vaccination to 143.45 (95% CI, 284–640) 1 month after immunization for all three serotypes (p<0.001). An individual analysis by serotype revealed an increase in the GMT for the H1N1 influenza virus from 47 (95% CI, 128–378) prior to vaccination to 138 (95% CI, 363–685) following immunization (p=0.009) and for the H3N2 virus from 99 (95% CI, 208–485) to 277 (95%, CI, 466–775; p=0.009). This contrasted with the influenza B virus, where no statistically significant increase in the GMT was observed, ranging from 10 (95% CI, 9–10) prior to vaccination to 14 (95% CI, 5–58) following immunization (p=0.11).
Cell-mediated immune response to influenza vaccine
We did not observe any increase in the mean SI value of 1.19±0.70 prior to vaccination compared with 1.65±1.03 following influenza immunization (p=0.31) using the lymphoproliferation assay measured by 3H-thymidine (Fig. 2A). No differences were observed in the percentages of CD4+ and CD8+ T cells prior to and following vaccination with or without influenza antigen stimulation. However, an increase was observed in the expression of CD45RA in CD4+ T cells with influenza antigen stimulation (0.07±0.05 without stimulation vs. 2.83±1.46 stimulated; p<0.001) and in CD8+ T cells (0.29±0.24 without stimulation vs. 6.80±1.74 stimulated; p<0.001) prior to vaccination and in CD8+ T cells following vaccination (0.18±0.15 without stimulation vs. 3.37±1.65 stimulated; p=0.01; Fig. 2B). An increase in expression of the CD27 molecule was observed in CD4−/CD8− cells when stimulated with influenza antigen prior to vaccination (0.01±0.007 without stimulation vs. 3.15±0.96 stimulated; p<0.0001), as well as following vaccination (0.21±0.16 without stimulation vs. 10.44±3.58 stimulated; p<0.0001). A difference in the expression of CD27 with influenza stimulation prior to vaccination was observed (3.15±0.96 vs. 10.44±3.58 following vaccination; p=0.05; Fig. 2C). These CD4−/CD8− cells were also CD56−/CD16− (data not shown).
Adverse effects
The vaccine was well tolerated by the individuals; no serious adverse effects were reported and no hospitalizations due to the influenza vaccination were reported. Most individuals presented with local symptoms: 70% with pain, 9% with erythema, 4% with swelling and 2% with redness in the injection area. General symptoms included 5% of children presenting with fever, 2% with rhinorrhea, 2% with malaise, 4% with myalgias, 5% with headache and 2% with coughing. The general symptoms resolved spontaneously within days following the administration of symptomatic treatment.
Discussion
Influenza is a significant disease worldwide due to its pathogenic characteristics and its ability to constantly change external surface proteins. The virus can cause severe disease and has the potential to cause epidemics and pandemics even when patients have had previous contact with related strains of the virus (26,27). A notable example is the 2009 influenza type A H1N1 pandemic first reported in Mexico. This pandemic was caused by a novel recombinant virus, with atypical manifestations in the first reported cases that developed fatal pneumonia (28–32). The disease is usually mild in healthy individuals, but immunocompromised patients may develop severe pneumonia and secondary bacterial infections and can succumb to the disease. Due to the potential severe disease and the associated complications, influenza vaccination is recommended annually for this high-risk population (26,27).
In Mexico, there have been few studies concerning influenza infections prior to the 2009 pandemic and the data are scarce. The influenza surveillance network (FluNet) from the World Health Organization reported 97 cases of influenza virus in Mexico in 2006, 384 in 2007 and 118 in 2008; in contrast to 81,701 cases detected during the 2009 pandemic and 2,878 until June 2010 (33). Two groups in Mexico reported incidence of influenza prior to the pandemic of 7–12% (5,6). Although the present study had a small sample size, it was observed that 43% of the subjects expressed antibodies against influenza types A H1N1, A H3N2 and B prior to vaccination; this proportion increased to 73% following vaccination. The observation of 43% seropositivity prior to vaccination suggests an underreporting of influenza cases, the circulation of the virus and previous infection since no study participants had a history of influenza vaccination. Although these children were receiving chemotherapy during immunization, the antibody response increased following influenza vaccination to 73%. This is in contrast to the results of a previous study which suggested that chemotherapy limits the ability to develop a sufficient immune response to vaccination and reported a seropositivity level of 32% following vaccination (19).
An increase in the level of antibodies was observed 1 month after vaccination, in the absence of a cellular immune response detected by the 3H-thymidine cell proliferation assay. However, an increase in the expression of CD45RA+ in CD4+ and CD8+ cells prior to vaccination and CD8+ cells following vaccination was detected, suggesting activation prior to vaccination. CD45 in combination with CCR7 in CD8+ cells are markers of naïve cells (CD45RA+ CCR7+), effector cells (CD45RA−/CCR7−), central memory cells (CD45RA−/CCR7+), effector memory cells (CD45RA−/CCR7−) or RA effector memory cells (CD45RA+/CCR7−) (24). CD45RA alone with CD4 and CD8 are naïve cells, which react with a new antigen. This explains the increase in these cells prior to vaccination when stimulated with influenza virus. CD4+/CD45RA+ T cells increased with influenza stimulation following vaccination, contrary to a decrease observed in CD8+/CD45RA+ T cells stimulated after vaccination. The decrease in the two naïve populations may be explained by the effect of the chemotherapy agents, but the increase in the CD4 population may suggest a faster recovery of the naïve CD4 T cells rather than naïve CD8 T cells.
An increase in the expression of CD27 was also observed in CD4−/CD8−/CD19− cells when stimulated with influenza antigen and expression was higher following vaccination. These cells were CD56− to rule out natural killer cells (data not shown) and were then gated in the lymphocyte area in a flow cytometry forward side scatter plot, suggesting the activation of a precursor of T or B cells. Mature lymphocytes did not express this marker, only the CD4−/CD8− cells. Staining the cells with other precursor markers may have yielded noteworthy results, but the present study did not observe any increase in this population until the recruitment of the patients was already finished.
The lack of lymphoproliferative responses of mature lymphocytes, measured by 3H-thymidine and by flow cytometry, may be explained by the constant assault on the cells induced by chemotherapy. Chemotherapy is cytotoxic to lymphocytes and to the bone marrow (17). The bone marrow increases the production of blood cells that enter the circulation and precursors are located within the peripheral blood of children undergoing chemotherapy. This may explain the presence of lymphocyte precursors. However, in this study, the lymphocyte precursors associated with the activation marker CD27 (data not reported previously). Although chemotherapy is toxic to bone marrow and lymphocytes, the present study revealed that 43% of patients expressed influenza-specific antibodies prior to vaccination. This suggests that memory B cells or memory plasma cells in the bone marrow are not fully affected by chemotherapy.
These results suggest that immunization against influenza in children with cancer who are receiving chemotherapy may increase the seropositivity rates, the GMT values and cellular immune responses with the activation of probable lymphoid precursors. The influenza vaccine was well tolerated in this population.
Acknowledgements
We are grateful for the generous donation of influenza vaccine from GlaxoSmithKline, Mexico. We are grateful to the participants of the study and their parents and guardians, to the social worker Juana Rodríguez-Castillo and to the pediatric fellows at the Department of Infectious Disease Eneida Sanchez-Medina and Mildred Zambrano-Leal for their assistance with the patients' recruitment. This study was supported in part by a grant from the Fogarty International Center and the Office of Research on Women's Health (TW006193) and in part by a grant from the Federal Funds of the Hospital Infantil de México Federico Gómez (CO/2007/038). This study was presented as an abstract at the 48th Annual Interscience Conference on Antimicrobial Agents and Chemotherapy (ICAAC) and the Infectious Disease Society of America (IDSA) 46th Annual Meeting, Washington, DC, USA, October 2008 and the annual meeting of the Asociación Mexicana de Infectología y Microbiología, León, Guanajuato, México, May 2008.
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