Varicella vaccination in pediatric oncology patients without interruption of chemotherapy.

BACKGROUND: Morbidity and mortality from primary varicella-zoster virus (VZV) infection is increased in immunocompromised children. Vaccination of VZV-seronegative cancer patients with live-attenuated varicella vaccine is safe when chemotherapy is interrupted. However, VZV vaccination without interruption of chemotherapy would be preferable. OBJECTIVE: To vaccinate VZV-seronegative pediatric oncology patients with live-attenuated VZV vaccine without interrupting their chemotherapy. STUDY-DESIGN: We performed a single-center prospective cohort study. RESULTS: Thirty-one patients with either a hematological malignancy (n=24) or a solid tumor (n=7) were vaccinated early during their course of chemotherapy. VZV IgG seroconversion occurred in 14 of the 31 patients (45%) after one vaccination. Only 20 patients were revaccinated after 3 months. These were patients who did not seroconvert (5 patients) and patients who serocoverted (15 patients) to induce or sustain seropositivity. Of these 20 patients the final seroconversion rate was 70%. Seven out of the 31 patients (23%) developed a mild rash of which 5 were treated with antivirals and recovered completely without interrupting chemotherapy, and 2 recovered untreated. Of these 31 immunized patients 26 were available for cellular testing. After one vaccination 20 of 26 patients (77%) tested positive for VZV-specific CD4(+) T cells, of which 7 patients had remained VZV-seronegative. After the second vaccination 11 of 11 patients showed VZV-specific CD4(+) T cells to sustain positivity, although 4 remained VZV-seronegative. CONCLUSIONS: This study indicates that live-attenuated VZV vaccine can be safely administered to closely monitored pediatric oncology patients without interruption of chemotherapy and adaptive immunity was induced despite incomplete seroconversion.

CD27 defines phenotypically and functionally different human NK cell subsets.

The absence of the TNF-receptor family member CD27 marks the stable acquisition of cytolytic effector functions by both CD4(+) and CD8(+) T cells. We found that the majority of circulating human NK cells was CD27(-). These cells were largely CD56(dim), contained high levels of perforin and granzyme B, and were able to exert strong cytotoxic activity. In contrast, circulating CD27(+) NK cells were mostly CD56(dim/bright), had significant lower levels of perforin and granzyme B, and had a low cytolytic potential. Primary and secondary lymphoid organs were markedly enriched for CD27(+) NK cells. When correlating the expression of CD27 to recently defined developmental stages of NK cells in tonsil, we observed that CD27 was exclusively found on mature CD94(+), stage 4 NK cells. On these cells, regulation of CD27 expression appeared to be controlled by the common gamma-chain cytokine IL-15, and down-regulation of CD27 was specifically induced by its ligand, CD70. Thus, the absence of CD27 expression allows the definition of cytotoxic effector cells within the known mature NK cell subsets in humans.

Persistent detection of varicella-zoster virus DNA in a previously healthy child after severe chickenpox.

In immunocompetent children with primary varicella-zoster virus (VZV) infection, peak viral loads are detected in peripheral blood near the onset of the vesicular rash. VZV DNA concentrations normally diminish and become undetectable within 3 weeks after the appearance of the exanthem. Here, we present a previously healthy, human immunodeficiency virus-negative, 4-year-old boy admitted with severe varicella. High viral loads (>340,000 copies/ml) were found in his blood, and the viral loads remained high for at least 1.5 years. Clinical recovery preceded complete clearance of the virus. General and VZV-specific immune reactivity were intact. NK cells and CD8(+) T cells were activated during acute infection, and VZV-specific CD4(+) T cells were detected at high frequencies. VZV DNA was initially detected in B cells, NK cells, and both CD4(+) and CD8(+) T cells. In contrast, during the persistent phase of VZV DNA detection, the viral DNA was primarily located in CD8(+) T cells. For the first time, we describe the persistent detection of VZV DNA in a previously healthy child.

Absence of circulating natural killer and primed CD8+ cells in life-threatening varicella.

Five pediatric patients with no history of immunodeficiency had a life-threatening course of varicella. Strikingly, natural killer (NK) cells were absent from the circulation in all children, and, despite active viral infection, up to 98% of the CD8(+) cells were naive. Primary immunodeficiencies were excluded--NK cells and primed CD8(+) cells reappeared in the circulation, granzymes were detectable in plasma early during infection, and no abnormalities could be detected in interleukin-15 receptor function. Our data indicate that varicella-zoster virus (VZV) has a unique capability to seclude primed CD8(+) cells and NK cells from the circulating lymphocyte pool. This may be the consequence of an overwhelming immune response to VZV that is influenced by factors such as infectious dose, age, and the presence of maternal antibodies during infancy. Because both homozygous twin sisters in the study had a severe course of varicella, particular genetic factors may contribute to severe varicella.

Emergence of a CD4+CD28- granzyme B+, cytomegalovirus-specific T cell subset after recovery of primary cytomegalovirus infection.

Cytotoxic CD4(+)CD28(-) T cells form a rare subset in human peripheral blood. The presence of CD4(+)CD28(-) cells has been associated with chronic viral infections, but how these particular cells are generated is unknown. In this study, we show that in primary CMV infections, CD4(+)CD28(-) T cells emerge just after cessation of the viral load, indicating that infection with CMV triggers the formation of CD4(+)CD28(-) T cells. In line with this, we found these cells only in CMV-infected persons. CD4(+)CD28(-) cells had an Ag-primed phenotype and expressed the cytolytic molecules granzyme B and perforin. Importantly, CD4(+)CD28(-) cells were to a large extent CMV-specific because proliferation was only induced by CMV-Ag, but not by recall Ags such as purified protein derivative or tetanus toxoid. CD4(+)CD28(-) cells only produced IFN-gamma after stimulation with CMV-Ag, whereas CD4(+)CD28(+) cells also produced IFN-gamma in response to varicella-zoster virus and purified protein derivative. Thus, CD4(+)CD28(-) T cells emerge as a consequence of CMV infection.

Development of virus-specific CD4+ T cells on reexposure to Varicella-Zoster virus.

Immunity to childhood diseases is maintained for decades by mechanisms that, at present, are still unclear. We longitudinally studied immune responses in 16 adults exposed to children experiencing varicella (chicken pox). None of the individuals showed clinical signs of infection, and varicella-zoster virus (VZV) DNA could not be detected in peripheral blood or cultured from nasopharyngeal swabs. Exposure to VZV, however, induced expansion of antigen-specific CD4(+) T cells in peripheral blood, with concomitant changes in cytotoxic CD8(+) T cells and natural killer cells. VZV-specific memory CD4(+) T cells were uniformly CD45RA(-) and enriched for CD27(-) cells. The virus-specific cells produced interferon- gamma, tumor necrosis factor- alpha, and interleukin-2. These memory responses to VZV were compared with the primary immune responses of children experiencing varicella. VZV-specific memory CD4(+) T cell responses largely resemble the primary immune response to VZV.

Spontaneous outgrowth of EBV-transformed B-cells reflects EBV-specific immunity in vivo; a useful tool in the follow-up of EBV-driven immunoproliferative disorders in allograft recipients.

During immunosuppressive medication, Epstein-Barr virus (EBV) infection is associated with a risk of developing posttransplant lymphoproliferative disease (PTLD). The appropriateness of a spontaneous EBV B-cell transformation (SET) assay as a monitor of EBV-specific immunity was evaluated to investigate if it safely allows reducing immunosuppressive medication, thereby decreasing the risk of developing PTLD. PBMC were isolated longitudinally from 20 pediatric renal allograft recipients treated with prednisone and cyclosporine combined with either azathioprine or mycophenolate mofetil. Most significantly, EBV-peptide-specific CD8+ T cells were detectable in the blood of patients with negative SET assays, coinciding with significantly lower EBV loads, whereas these cells were less frequent in the blood of patients with positive SET assays. Reducing the levels of immunosuppression resulted in normalization of the SET assays. Therefore, the SET assay is a reflection of the interaction between viral replication, transformation of B cells, and EBV-specific immunity in vivo and hence a valuable screening test for EBV-driven lymphoproliferative phenomena in allograft recipients.

Viral immune evasion: a masterpiece of evolution.

Coexistence of viruses and their hosts imposes an evolutionary pressure on both the virus and the host immune system. On the one hand, the host has developed an immune system able to attack viruses and virally infected cells, whereas on the other hand, viruses have developed an array of immune evasion mechanisms to escape killing by the host's immune system. Generally, the larger the viral genome, the more diverse mechanisms are utilized to extend the time-window for viral replication and spreading of virus particles. In addition, herpesviruses have the capacity to hide from the immune system by their ability to establish latency. The strategies of immune evasion are directed towards three divisions of the immune system, i.e., the humoral immune response, the cellular immune response and immune effector functions. Members of the herpesvirus family are capable of interfering with the host's immune system at almost every level of immune clearance. Antibody recognition of viral epitopes, presentation of viral peptides by major histocompatibility complex (MHC) class I and class II molecules, the recruitment of immune effector cells, complement activation, and apoptosis can all be impaired by herpesviruses. This review aims at summarizing the current knowledge of viral evasion mechanisms.