Memory Lymphocyte Subsets Research Articles

#41: Mechanistic Immune Correlates of Protection Following Vaccination Against Rift Valley Fever Virus

Abstract Background Rift Valley fever virus (RVFV) is a zoonotic arbovirus endemic to large areas of Africa and the Arabian peninsula that causes a significant annual burden of disease in ruminant animals, and is associated with periodic outbreaks in human populations. RVFV causes a wide spectrum of disease in infected patients ranging from a self-limiting febrile illness to hepatitis, encephalitis, hemorrhagic fever, and death. Despite the significant economic and public health impact of RVFV, there are no currently available vaccines or therapeutics available for RVFV. Methods Previous work has established that vaccination with an attenuated strain of RVFV, RVFV-ΔNSs, confers protection against subsequent lethal challenge in a murine model of infection. To characterize mechanistic immune correlates of protection, we vaccinated C57BL/6 mice with RVFV-ΔNSs then depleted vaccinated mice of various memory lymphocyte subsets, including CD4+, CD8+, CD4+/CD8+ T-cells before challenging mice with a lethal dose of WT RVFV. To assess for the role of antibodies in providing protection, we depleted mice of their B cells prior to vaccination with RVFV-ΔNSs, confirmed the lack of RVFV specific antibodies, and then challenged them with lethal WT RVFV. To determine the minimal immunologic factors required for protection, we vaccinated a series of donor mice, transferred either immunoglobulins or splenocytes to naïve recipient mice, then challenged them with WT RVFV. Results Vaccination with RVFV-ΔNSs protected mice from subsequent challenge, and this protection was not abrogated by depletion of CD4+, CD8+, or combined CD4+ and CD8+ lymphocytes, suggesting that RVFV-specific T-cells are dispensable for protection in the presence of virus specific antibodies. Vaccinated mice depleted of CD20+ B-cells were also protected against WT challenge, suggesting that B-cells/antibodies are also dispensable for protection in the presence of an intact T-cell response. Passive transfer of antibodies from vaccinated mice to recipient mice protected them against subsequent WT challenge, demonstrating that antibodies are sufficient for protection. Adoptive transfer of total splenocytes protected mice against subsequent WT challenge, indicating that lymphocytes are also sufficient to mediate protection. Conclusions In this study we defined the mechanistic immune correlates of protection following vaccination with attenuated RVFV-ΔNSs against WT RVFV in a murine model. Here, we have shown that both humoral and cellular immunity are sufficient to mediate protection in recipient animals, and can compensate for each other when one is missing. These results further our understanding of the protective immunologic response to infection by RVFV, and will help inform further vaccine development efforts against this important emerging pathogen.

Cell-intrinsic regulation of peripheral memory-phenotype T cell frequencies.

Memory T and B lymphocyte numbers are thought to be regulated by recent and cumulative microbial exposures. We report here that memory-phenotype lymphocyte frequencies in B, CD4 and CD8 T-cells in 3-monthly serial bleeds from healthy young adult humans were relatively stable over a 1-year period, while Plasmablast frequencies were not, suggesting that recent environmental exposures affected steady state levels of recently activated but not of memory lymphocyte subsets. Frequencies of memory B and CD4 T cells were not correlated, suggesting that variation in them was unlikely to be determined by cumulative antigenic exposures. Immunophenotyping of adult siblings showed high concordance in memory, but not of recently activated lymphocyte subsets. To explore the possibility of cell-intrinsic regulation of T cell memory, we screened effector memory-phenotype T cell (TEM) frequencies in common independent inbred mice strains. Using two pairs from these strains that differed predominantly in either CD4 TEM and/or CD8 TEM frequencies, we constructed bi-parental bone marrow chimeras in F1 recipient mice, and found that memory T cell frequencies in recipient mice were determined by donor genotypes. Together, these data suggest cell-autonomous determination of memory T niche size, and suggest mechanisms maintaining immune variability.

Multi-color flow cytometry for evaluating age-related changes in memory lymphocyte subsets in dogs

While dogs are increasingly being utilized as large-animal models of disease, important features of age-related immunosenescence in the dog have yet to be evaluated due to the lack of defined naïve vs. memory T lymphocyte phenotypes. We therefore performed multi-color flow cytometry on peripheral blood mononuclear cells from young and aged beagles, and determined the differential cytokine production by proposed memory subsets. CD4+ and CD8+ T lymphocytes in aged dogs displayed increased cytokine production, and decreased proliferative capacity. Antibodies targeting CD45RA and CD62L, but less so CD28 or CD44, defined canine cells that consistently exhibited properties of naïve-, central memory-, effector memory-, and terminal effector-like CD4+ and CD8+ T lymphocyte subsets. Older dogs demonstrated decreased frequencies of naïve-like CD4+ and CD8+ T lymphocytes, and an increased frequency of terminal effector-like CD8+ T lymphocytes. Overall findings revealed that aged dogs displayed features of immunosenescence similar to those reported in other species.

Effects of nongenetic factors on immune cell dynamics in early childhood: The Generation R Study

Numbers of blood leukocyte subsets are highly dynamic in childhood and differ greatly between subjects. Interindividual variation is only partly accounted for by genetic factors. We sought to determine which nongenetic factors affect the dynamics of innate leukocytes and naive and memory lymphocyte subsets. We performed 6-color flow cytometry and linear mixed-effects modeling to define the dynamics of 62 leukocytesubsets from birth to 6years of age in 1182 children, with 1 to 5 measurements per subject. Subsequently, we defined the effect of prenatal maternal lifestyle-related or immune-mediated determinants, birth characteristics, and bacterial/viral exposure-related determinants on leukocyte subset dynamics. Functionally similar leukocyte populations were grouped by using unbiased hierarchical clustering of patterns of age-related leukocyte dynamics. Innate leukocyte numbers were high at birth and predominantly affected by maternal low education level. Naive lymphocyte counts peaked around 1year, whereas most memory lymphocyte subsets more gradually increased during the first 4years of life. Dynamics of CD4+ T cells were predominantly associated with sex, birth characteristics, and persistent infections with cytomegalovirus (CMV) or EBV. CD8+ T cells were predominantly associated with CMV and EBV infections, and T-cell receptor γδ+ T cells were predominantly associated with premature rupture of membranes and CMV infection. B-cell subsets were predominantly associated with sex, breast-feeding, and Helicobacter pylori carriership. Our study identifies specific dynamic patterns of leukocyte subset numbers, as well as nongenetic determinants that affect these patterns, thereby providing new insights into the shaping of the childhood immune system.

A randomized double-blind trial on perioperative administration of probiotics in colorectal cancer patients

To investigate whether probiotic bacteria, given perioperatively, might adhere to the colonic mucosa, reduce concentration of pathogens in stools, and modulate the local immune function. A randomized, double-blind clinical trial was carried out in 31 subjects undergoing elective colorectal resection for cancer. Patients were allocated to receive either a placebo (group A, n = 10), or a dose of 10(7) of a mixture of Bifidobacterium longum (BB536) and Lactobacillus johnsonii (La1) (group B, n = 11), or the same mixture at a concentration of 10(9) (group C, n = 10). Probiotics, or a placebo, were given orally 2 doses/d for 3 d before operation. The same treatment continued postoperatively from day two to day four. Stools were collected before treatment, during surgery (day 0) and 5 d after operation. During the operation, colonic mucosa samples were harvested to evaluate bacterial adherence and to assess the phenotype of dendritic cells (DCs) and lymphocyte subsets by surface antigen expression (flow cytometry). The presence of BB536 and La1 was evaluated by the random amplified polymorphism DNA method with specific polymerase chain reaction probes. The three groups were balanced for baseline and surgical parameters. BB536 was never found at any time-points studied. At day 0, La1 was present in 6/10 (60%) patients in either stools or by biopsy in group C, in 3/11 (27.2%) in group B, and none in the placebo group (P = 0.02, C vs A). There was a linear correlation between dose given and number of adherent La1 (P = 0.01). The rate of mucosal colonization by enterobacteriacae was 30% (3/10) in C, 81.8% (9/11) in B and 70% (7/10) in A (P = 0.03, C vs B). The Enterobacteriacae count in stools was 2.4 (log10 scale) in C, 4.6 in B, and 4.5 in A (P = 0.07, C vs A and B). The same trend was observed for colonizing enterococci. La1 was not found at day +5. We observed greater expression of CD3, CD4, CD8, and naive and memory lymphocyte subsets in group C than in group A with a dose response trend (C > B > A). Treatment did not affect DC phenotype or activation, but after ex vivo stimulation with lipopolysaccharides, groups C and B had a lower proliferation rate compared to group A (P = 0.04). Moreover, dendritic phenotypes CD83-123, CD83-HLADR, and CD83-11c (markers of activation) were significantly less expressed in patients colonized with La1 (P = 0.03 vs not colonized). La1, but not BB536, adheres to the colonic mucosa, and affects intestinal microbiota by reducing the concentration of pathogens and modulates local immunity.

Reversible Effect of Magnetic Fields on Human Lymphocyte Activation Patterns: Different Sensitivity of Naive and Memory Lymphocyte Subsets

The aim of this study was to investigate the influence of 50 Hz magnetic or static magnetic fields of 0.5 mT on subsets of human CD4(+) T cells in terms of cytokine release/content, cell proliferation and intracellular free calcium concentration. CD4(+) T cells can be divided into different subsets on the basis of surface marker expression, such as CD45, and T cells can be divided into naive (CD45RA(+)) and memory (CD45RA(-)) cells. In this study, the effects of magnetic fields after 24 and 48 h of cell culture were analyzed. We found that the CD4(+)CD45RA(-) T subset were more sensitive after 2 h of exposure. Decreases in the release/content of IFN-gamma, in cell proliferation and in intracellular free calcium concentrations were observed in exposed CD4(+)CD45RA(-) T cells compared to CD4(+)CD45RA(+) T cells. The results suggest that exposure to the magnetic fields induces a delay in the response to stimulants and that modifications are rapidly reversible, at least after a short exposure.

Chemokines in cutaneous allergic reactions: the SCID model as a powerful tool to evaluate their interest as therapeutical targets

Chemokines are small chemotactic molecules actingthrough G-protein-coupled receptors. Their functions are very diverse in homeostatic as well as in inflammatory conditions. Recently, it has been shown that chemokines and their receptors also help control the tissue specificity of memory lymphocyte subsets, which could lead to their use as therapeutic targets in selective tissue diseases such as allergic cutaneous reactions. Currently available animal models are not relevant to the human situation, which is a reason as to why we have developed an in vivo model of humanized immunodeficient mice grafted with human skin and mononuclear cells. This model will allow us to evaluate, in a pre-human context, the bonafide effects of chemokines and to test them as potential therapeutic targets.

Expression of the Chemokine Receptors CCR4, CCR5, and CXCR3 by Human Tissue-Infiltrating Lymphocytes

Differential expression of adhesion molecules and chemokine receptors has been useful for identification of peripheral blood memory lymphocyte subsets with distinct tissue and microenvironmental tropisms. Expression of CCR4 by circulating memory CD4(+) lymphocytes is associated with cutaneous and other systemic populations while expression of CCR9 is associated with a small intestine-homing subset. CCR5 and CXCR3 are also expressed by discrete memory CD4(+) populations in blood, as well as by tissue-infiltrating lymphocytes from a number of sites. To characterize the similarities and differences among tissue-infiltrating lymphocytes, and to shed light on the specialization of lymphocyte subsets that mediate inflammation and immune surveillance in particular tissues, we have examined the expression of CCR4, CXCR3, and CCR5 on CD4(+) lymphocytes directly isolated from a wide variety of normal and inflamed tissues. Extra-lymphoid tissues contained only memory lymphocytes, many of which were activated (CD69(+)). As predicted by classical studies, skin lymphocytes were enriched in CLA expression whereas intestinal lymphocytes were enriched in alpha(4)beta(7) expression. CCR4 was expressed at high levels by skin-infiltrating lymphocytes, at lower levels by lung and synovial fluid lymphocytes, but never by intestinal lymphocytes. Only the high CCR4 levels characteristic of skin lymphocytes were associated with robust chemotactic and adhesive responses to TARC, consistent with a selective role for CCR4 in skin lymphocyte homing. In contrast, CXCR3 and CCR5 were present on the majority of lymphocytes from each non-lymphoid tissue examined, suggesting that these receptors are unlikely to determine tissue specificity, but rather, may play a wider role in tissue inflammation.

A novel chemokine ligand for CCR10 and CCR3 expressed by epithelial cells in mucosal tissues.

Mucosae-associated epithelial chemokine (MEC) is a novel chemokine whose mRNA is most abundant in salivary gland, with strong expression in other mucosal sites, including colon, trachea, and mammary gland. MEC is constitutively expressed by epithelial cells; MEC mRNA is detected in cultured bronchial and mammary gland epithelial cell lines and in epithelia isolated from salivary gland and colon using laser capture microdissection, but not in the endothelial, hemolymphoid, or fibroblastic cell lines tested. Although MEC is poorly expressed in skin, its closest homologue is the keratinocyte-expressed cutaneous T cell-attracting chemokine (CTACK; CCL27), and MEC supports chemotaxis of transfected lymphoid cells expressing CCR10, a known CTACK receptor. In contrast to CTACK, however, MEC also supports migration through CCR3. Consistent with this, MEC attracts eosinophils in addition to memory lymphocyte subsets. These results suggest an important role for MEC in the physiology of extracutaneous epithelial tissues, including diverse mucosal organs.

Physiological and molecular mechanisms of lymphocyte homing.

The lymphoid system is functionally compartmentalized in vivo into discrete primary, secondary, and tertiary lymphoid organs. Primary lymphoid tissues--the bone marrow and thymus--are responsible for the production of mature "virgin" lymphocytes. Secondary lymphoid tissues--lymph nodes, the spleen, and gut-associated lymphoid tissues--are specialized for the accumulation and presentation of antigen to both virgin and memory lymphocyte subsets. The remainder of the body's tissues may be considered "tertiary" lymphoid tissues, in that they normally contain only a few lymphoid elements, but in the setting of inflammation can be induced to recruit unique subsets of primarily memory lymphocytes. Each lymphoid tissue is further subdivided into discrete microenvironments, each characterized by a distinct complement of lymphocyte subsets and stromal cells. Lymphocyte homing comprises the physiologic processes by which lymphocytes seek out and localize to particular tissues and to specific microenvironments therein. Homing mechanisms play a major role in the maintenance of these specialized microenvironments and are critical for the dispersal and targeting of naive and memory lymphocyte populations that are required for effective immune surveillance. Here, we provide a brief overview of mechanisms thought to control the homing of lymphocyte populations in vivo, focusing in particular on the adhesive interactions involved in lymphocyte-endothelial cell recognition and in the selective extravasation of lymphocyte populations into secondary and tertiary lymphoid tissues.