T-cells inhibit Friend murine leukemia virus infection of B-cells in vitro

The ability of splenic T-cells to regulate Friend murine leukemia virus replication in lipopolysaccharide-activated target B-cells infected in vitro was investigated. Removal of the T-cell fraction from spleen cells resulted in an 8- to 10-fold enhancement in the number of productively infected cells in the remaining B-cell-enriched fraction, as compared with unseparated spleen cells, and the addition of increasing numbers of purified T-cells to isolated B-cells prior to infection resulted in a directly proportional reduction in the number of B-cells releasing infectious progeny virus. Separation of splenic T-cells into Lyt 2- and Lyt 2+ T-cells before addition to infected B-cell cultures resulted in inhibition of infection only with the Lyt 2- T-cells; Lyt 2+ T-cells did not inhibit infection, even at high 1:1 ratios. Similarly, separation of splenic T-cells into L3T4+ and L3T4- T-cells before addition resulted in inhibition by L3T4+ but not L3T4- T-cells. Also, cytotoxic treatment of splenic T-cells with monoclonal anti-L3T4 antibody and complement before addition to B-cell cultures destroyed the regulatory effects. Finally, depletion of macrophages from both T-cells and B-cells before infection and coculture had no effect on the ability of T-cells to regulate B-cell infection. Collectively these results demonstrate that L3T4+ T-cells can inhibit Friend murine leukemia virus replication in target B-cells. Culture of isolated splenic T-cells with Friend murine leukemia virus in vitro resulted in the induction of alpha/beta but not interferon-gamma synthesis and in some experiments interferon-containing supernatants from T-cell-virus cultures were able to mediate suppression of B-cell infection with Friend helper virus; the addition of antibody specific for interferon-alpha/beta to cultures inhibited the ability of T-cells to regulate B-cell infection.     

Susceptibility to lipid peroxidation and accumulation of fluorescent products with age is greater in T-cells than B-cells

The age-related loss of immune function, which is primarily due to loss of T-lymphocyte function, is also associated with accumulation in spleen lymphocytes of autofluorescent products indicative of peroxidation damage. In this study, we examined T-cell membranes for age-related changes which could be related to lipid peroxidation. Using fluorescence spectroscopy of CHCl3:CH3OH membrane extracts, we observed that old T-cells have a 2-fold greater accumulation of fluorescent products than old B-cells and that young T-cells, when exposed to free radicals in an in vitro system, accumulate significantly more fluorescent products over time than young B-cells. We used fluorescence polarization to show that young T-cell membranes are more fluid than young B-cell membranes. However, T-cell membrane fluidity decreases with age, whereas B-cell membrane fluidity does not change; in old mice, T-cell membranes are significantly less fluid than old B-cell membranes. Using two-dimensional electrophoresis, we showed that membrane extracts of old T-cells contain many more proteins than extracts of young T-cells. Our results indicate that age-related changes occur in T-cell membranes which could be due to their increased susceptibility to lipid peroxidation and these changes may contribute to the age-related decline in immune function.     

CD19 target-engineered T-cells accumulate at tumor lesions in human B-cell lymphoma xenograft mouse models

Adoptive T-cell therapy with CD19-specific chimeric antigen receptors (CARs) is promising for treatment of advanced B-cell malignancies. Tumor targeting of CAR-modified T-cells is likely to contribute therapeutic potency; therefore we examined the relationship between the ability of CD19-specific CAR (CD19-CAR)-transduced T-cells to accumulate at CD19⁺ tumor lesions, and their ability to provide anti-tumor effects in xenograft mouse models. Normal human peripheral blood lymphocytes, activated with immobilized RetroNectin and anti-CD3 antibodies, were transduced with retroviral vectors that encode CD19-CAR. Expanded CD19-CAR T-cells with a high transgene expression level of about 75% produced IL-2 and IFN-γ in response to CD19, and lysed both Raji and Daudi CD19⁺ human B-cell lymphoma cell lines. Furthermore, these cells efficiently accumulated at Raji tumor lesions where they suppressed tumor progression and prolonged survival in tumor-bearing Rag2^−/−γc^−/− immunodeficient mice compared to control cohorts. These results show that the ability of CD19-CAR T-cells to home in on tumor lesions is pivotal for their anti-tumor effects in our xenograft models, and therefore may enhance the efficacy of adoptive T-cell therapy for refractory B-cell lymphoma.     

Selective phosphotyrosine phosphatase inhibition and increased ceramide formation is associated with B-cell death by apoptosis

Bis(maltolato)oxovanadium(IV) (BMOV), a protein phosphotyrosine phosphatase inhibitor, selectively induced apoptosis (as quantitated by TUNEL staining) in a B-cell line (Ramos) but not in a T-cell line (Jurkat). The pattern of BMOV-induced protein tyrosine phosphorylation was different in B-cells versus T-cells. Further, BMOV induced a 2-fold increase in ceramide levels in B-cells but not in T-cells and this resembled the ceramide increase following activation of the B-cell antigen receptor. A 2-fold increase in the ratio of ceramide to sphingomyelin in B-cells treated with BMOV suggested that sphingomyelinase activation was the result of the sustained tyrosine phosphorylation of specific proteins and activated the cell death pathway.     

Simultaneous detection of B-cells and T-cells by a double immunohistochemical technique using immunogold-silver staining and the avidin-biotin-peroxidase complex method

A new double immunohistochemical technique for the simultaneous detection of B-cells and T-cells was investigated, using tissue preparations obtained from human axillary lymph nodes and rejected renal allografts. The specimens were immunostained first for the demonstration of B-cells, by the immunogold-silver staining (IGSS) method using Leu-12 monoclonal antibody, and then for T-cells by the avidin-biotin-peroxidase complex (ABC) method using Leu-1 monoclonal antibody. With the present methods, both B-cells and T-cells were clearly detected and distinctively identified without cross-linking of antibodies or double reaction of enzymes.     

Synthetic immunogens constructed from T-cell and B-cell stimulating peptides (T:B chimeras): preferential stimulation of unique T- and B-cell specificities is influenced by immunogen configuration.

In our effort to develop synthetic immunogens as vaccines, we have focused on the combination of a known T-cell stimulating peptide with putative B-cell stimulating peptide epitopes derived from the sequences of respiratory syncytial (RS) virus proteins. The T-cell stimulating peptide consists of residues 45 through 60 of the 1A protein of RS virus, and it also contains an overlapping antibody binding (B-cell) site. Herein, we have combined the 1A T-cell stimulating peptide with a putative B-cell peptide epitope derived from the viral G glycoprotein using linear synthesis or using chemical crosslinking. The chimeric immunogens were compared to each other and to free peptides for their T- and B-cell stimulating properties. Both chimeras had potent T-cell stimulating and antibody-inducing activity. However, T-cells primed to free peptide differentially recognized the two chimeras and immunization with the chimeras primed T-cells with different specificity. Most strikingly, the two chimeras had opposite antibody-inducing properties: The chimera constructed by linear synthesis overwhelmingly elicited antibody directed against the G peptide, whereas the chimera constructed by chemical crosslinking overwhelmingly elicited antibody directed against the 1A peptide. Competition blocking studies revealed that the chimeras adopted different configurations in solution. The resulting antibody response, and hence the B-cell clone elicited, was consistent with the antibody accessibility of the individual peptide epitope.     

B cells--masters of the immunoverse

The immune system involves the complex interplay between many different cell types. Over the last decade, T cells, dendritic cells (DC) and macrophages have all been implicated as the key regulator cells of the immunological response, linking innate and adaptive immunity. The forgotten cell in this discourse has been the B-cell. Long considered as simple antibody production units dictated to by T-cells, recent years have begun to shift this assumption. The discovery that numerous B-cell subsets exist, with specific regulatory functions capable of modulating T-cell and chronic inflammatory responses has revealed a hitherto unappreciated role of B-cells. In particular, these ideas have been developed in light of the surprisingly successful responses delivered in autoimmune settings following depletion of B-cells with the anti-CD20 antibody rituximab. Here we summarise the history of the humble B-cell and discuss some of the key recent findings that lead us to propose it as an important regulator of ongoing immune responses and as such, one of the masters of the immunoverse.     

Molecular pathogenesis of chronic lymphocytic leukemia

Chronic lymphocytic leukemia (CLL) is unique among malignancies since it represents an accumulation of B-lymphocytes resistant to apoptosis. Several factors are thought to confer this unusual feature to a CLL B-cell. Misbalance between cytoplasmic pro-survival and pro-death molecules, such as Bcl-2, Mcl-1 and alike, appears to be one of the key factors defining B-cell longevity. Autocrine pathways, such as vascular endothelial growth factor-receptor pathway, also contribute to survival. The role of B-cell receptor (BCR) is less straightforward. In the last decade it became clear that CLL does not constitute a uniform disease, but, based on the prevalence of mutations in the BCR heavy chain (IgVH), can be classified into two distinct subgroups. Several molecular markers correlate with IgVH mutations. Some of them, like zeta-chain associated protein kinase, are also involved in BCR signaling and influence cell cycle. Yet the primary pathogenic event leading to increased proliferation and survival in CLL is difficult to ascertain. Molecules involved in BCR signaling pathways and cytoplasmic pro-survival players probably act in concert to confer resistance to apoptosis. In this respect, the role of the B-CLL environment, which includes nurse-like cells and T-cells, cannot be underestimated. Nurse-like cells provide stimuli necessary for perpetuation of life in CLL. On the other hand, abnormal T-cell function, whether it is excessive immunosuppression delivered by regulatory T-cells or insufficient anti-tumor immunity rendered by T-helpers, allows malignant CLL cells to go unnoticed by the cellular immune system.     

Immunosuppressive Activity of Streptonigrin in Vitro and in Vivo

The immune system is composed of various cells with distinct functions. Thus, highly selective immunomodulators are necessary for artificial regulation of immune reactions. We screened microbial products for such immunomodulators and we identified streptonigrin as a selective suppressor of B-cell proliferation induced by lipopolysaccharide. Streptonigrin directly suppressed the late phase of proliferation of B-cells. The inhibition of topoisomerase II was implicated as the mechanism of the B-cell-selective suppression. In cultured cell lines, however, streptonigrin preferentially suppressed the growth of an interleukin-3-dependent myeloid cell line rather than B-cell lines. In addition, the treatment with streptonigrin in vivo suppressed T-cells more significantly than B-cells and dramatically reduced the spleen weight. These results suggest that streptonigrin preferentially suppresses myeloid T-cell precursors in vivo.     

ALVAC-mediated gene transfer is efficient in lymphoid malignancies of T-and early B-cell origin, but not in tumors arising from mature B-cells

Natural attenuation of ALVAC virus in mammals makes it an attractive vector for cancer vaccine therapy of immunocompromised hosts, such as patients with lymphoid malignancies. However, the transduction efficiency of ALVAC constructs in lymphoid tumors has not yet been characterized. We studied a wide spectrum of human T- and B-cell leukemia and lymphomas and found significant heterogeneity of the ALVAC-mediated gene product expression in these tumors. While ALVAC-B7.1, ALVAC-B7.2, or ALVAC-luciferase vectors effectively expressed recombinant genes in malignancies arising from T- or early B-cell precursors, negative or low expression of ALVAC recombinant genes occurred in tumors arising from mature B-cells. We showed that ALVAC-encoded B7.1 or B7.2 was continuously expressed on the infected, and subsequently irradiated, leukemia cells, and only cells with ALVAC-mediated expression of costimulatory molecules (but not unmodified leukemia cells or those infected with the ALVAC-parental vector) induced significant proliferation and IFN-gamma production by alloreactive T-cells. These data provide the rationale for clinical studies using the ALVAC vector system for gene transfer into lymphoid tumors of T- and early B-cell origin to render them more immunogenic, while alternative strategies should be considered for immunotherapy of mature B-cell malignancies.     

Isolation and characterization of membrane receptors for pokeweed mitogens from mouse lymphocytes.

The major glycoproteins that bind pokeweek B-cell mitogen (Pa-1) and pokeweed T-cell mitogen (Pa-2) were isolated and identified from bone-marrow-derived lymphocytes (B-cells) and thymus-derived lymphocytes (T-cells) of C3H/He mice. The surfaces of the cells were 125I-labelled by using the enzyme lactoperoxidase, and the plasma membranes were isolated from the 125I-labelled cells. These membranes were solubilized with Triton X-100 and subjected to affinity chromatography on the affinity adsorbent prepared by coupling mitogen Pa-1 or Pa-2 to activated Sepharose 4B. The glycoproteins specifically eluted with di-N-acetylchitobiose from the affinity adsorbents were analysed according to their mobility on polyacrylamide-gel electrophoresis in sodium dodecyl sulphate. These glycoproteins were further identified by immunoprecipitation with specific antisera. Immunoglobulins, possibly immunoglobulins M and D, were identified in the eluate from the B-cell membranes, but they were not detected in the eluate from the T-cell membranes. The histocompatibility-2-complex proteins (H-2D, H-2K and Ia antigens) were found to be major receptor sites for the pokeweed mitogens on both B-cells and T-cells. However, mitogen Pa-1 (B-cell) has a stronger affinity to Ia antigens than does mitogen Pa-2 (T-cell).     

Quantitative interrelationships between the T- and B-cell populations of mouse lymphoid organs]

The number of thymocytes and splenic T-lymphocytes correlate negatively. After the treatment of mice with cortisol, this negative correlation changes for a positive one. It is proposed that the negative correlation between cortisone-sensitive thymocytes and splenic T cells is mediated by cortisone-resistant thymocytes. The negative correlations were also found between amounts of T-cells in mesenteric lymph nodes and in Peyer's patches, the positive correlations being seen between numbers of splenic and lymph nodes T-lymphocytes. No correlations between B-cell populations in different organs were revealed. Apparently, correlations between lymphocyte populations reflect some aspect of hierachic structure of the lymphoid system.     

CD57, a marker for B-cell activation and splenic ellipsoid-associated reticular cells of the chicken

We have demonstrated that the ellipsoid-associated reticular cells of chicken spleen express CD57, a marker for B-cell activation. These cells are characterised by their spindle-shaped morphology, tissue distribution and the absence of certain leucocyte-specific markers. They are phagocytotic and possess high endogenous non-specific esterase activity. Previous reports failed to detect CD57 expression on ellipsoid-associated reticular cells, probably because the tissue sections were differently treated before immunohistochemistry. CD57 is also expressed by a small number of T-cells in the spleen and the caecal tonsils. This number is highly variable between individual chickens depending on the activation state of the immune system. Moreover, CD57 is expressed by bursal lymphocytes (90% or more) but not by B-cells of the peripheral blood. More interestingly, we have been able to discriminate and quantify three B-cell populations of the secondary lymphoid organs, i.e. resting B-cells, germinal centre B-cells and plasma cells, based on their expression levels of CD57 and Bu-1 (a pan B-cell marker). Thus, CD57 should be considered as a B-cell activation marker, rather than as a marker for bursal B-cells; it is also a valuable marker for the immunohistochemical study of ellipsoid-associated reticular cells of chicken spleen.     

Chronic ICV infusion of neuropeptides alters lymphocyte populations in experimental rodents.

The sympathetic nervous system has been shown to influence immune function. Angiotensin II and substance P are two neurally active peptides that have been shown to increase sympathetic nervous system activity when injected centrally. Using osmotic minipumps, we chronically infused angiotensin II (1 microgram/h) and substance P (2 micrograms/h) into the brains of intact Sprague-Dawley rats for a period of 1 month and 2 weeks, respectively. Age-matched control animals were infused with artificial cerebrospinal fluid. We then examined the effect of this infusion on the percentage of different lymphocyte populations in the peripheral blood. The angiotensin II infused animals showed an increase in the percentage of total T-cells and a decrease in the percentage of B-cells relative to controls. The substance P treated animals also showed an increase in the percentage of T-cells present, but failed to show the decrease in the B-cell population seen with the angiotensin II infused group. This study shows that the central nervous system can influence the immune system. As shown in this study, these effects are most likely mediated via the sympathetic nervous system. These results add to the expanding body of data suggesting an important role of the central nervous in regulating immune function and our susceptibility to disease.     

The metabolism of deoxyguanosine and guanosine in human B and T lymphoblasts. A role for deoxyguanosine kinase activity in the selective T-cell defect associated with purine nucleoside phosphorylase deficiency.

Purine nucleoside phosphorylase (NP; EC 2.4.2.1) deficiency is associated with defective T-cell and normal B-cell immunity. Biochemical mechanisms were investigated by measuring deoxyguanosine and guanosine metabolism in normal T and B lymphoblasts and NP-deficient B lymphoblasts. Deoxyguanosine kinase activity was specifically measured by using an anti-NP antibody to prevent alternative-product formation. Kinase activity towards deoxyguanosine was significantly higher in T-cells, whereas NP activity was similar in both B- and T-cells. Only in T-cells was dGTP produced from exogenous deoxyguanosine, and this was prevented by the simultaneous addition of deoxycytidine, which resulted in a concomitant increase in GTP synthesis. Inhibition by 8-aminoguanosine of NP activity in T lymphoblasts increased formation of dGTP and decreased that of GTP from deoxyguanosine and decreased the formation of GTP from guanosine. These data suggest a central role for deoxyguanosine kinase activity in the T-cell selectivity of the immune defect.     

Mechanism of anti-DNA antibody formation. The functional modulation of helper T-subset plays the key role in both murine and human B-cell autosensitization

The mechanism(s) of anti-DNA antibody formation was comparatively investigated using in vitro human and murine B-cell culture systems. T-cell homogenate (TH) from SLE patients converted normal human B-cells to anti-DNA specific antibody-forming plasma cells (anti-DNA-SPC) when cultured with calf thymic native DNA as antigen. TH of normal human donors suppressed the formation of anti-DNA-SPC from normal human B-cell cultures even when SLE TH and DNA were added to the cultures. B-cells derived from SLE patients were insensitive to normal human TH, and resulted in the formation of many anti-DNA-SPC. TH of young and old NZB mice stimulated the formation of anti-DNA-SPC from not only NZB but also C57BL/6 murine bone marrow cultures in the presence of DNA antigen. Human and murine TH, and both B-cell cultures were reciprocally combined to test whether xenogeneic TH stimulated B-cell cultures from different species. Xenogeneic TH was effective in triggering differentiation of xenogeneic B-cells with respect to anti-DNA-SPC. The elimination of helper T-subsets (Th) resulted in the generation of fewer anti-DNA-SPC, whereas the elimination of suppressor T-subsets (Ts) caused the formation of many anti-DNA-SPC. Among organ homogenates, e.g., liver, kidney and, brain, and T-cells from old NZB mice, TH was most effective in the stimulation of anti-DNA-SPC. The effective substance was sensitive to RNase-A, but resistant to pronase and DNase-I. Phenol extracted T-cell RNA retained its activity. We concluded that the functional modulation of helper T-cells, which reflects RNA molecules, could be the main etiology of autoantibody formation against DNA by both human and murine B-cells.     

B- and T-cell tolerance induction in young-adult and old mice.

Young-adult and old (CS7BL × C3H)F₁ mice were injected with either of two tolerogens followed by challenge with dinitrophenylated human γ globulin (DNP-HGG). The primary IgM and IgG responses of spleen cells to the DNP determinant were evaluated by a modified hemolytic plaque assay. Carrier-specific thymus-derived cell (T-cell) tolerance was induced in mice with deaggregated HGG. Hapten-specific bursal-derived cell (B-cell) tolerance was induced with DNP coupled to isogeneic mouse IgG. The dose of these two tolerogens was successively decreased by 10-fold decrements until a response similar to that of control mice was achieved. The minimum tolerizing dose (MTD) was then determined for young-adult and aged B-and T-cells. We found that the MTD for old B-cells was 10 times greater than that obtained with young B-cells for both the direct and indirect PFC responses. No difference in MTD was observed between young and old T-cells when assessed by the indirect response; the MTD for old T-cells was 10-fold greater than that obtained for young-adult T-cells when the direct response was evaluated. A double threshold of tolerance was found for T-cells of young-adult mice.     

Functional CD4(+) and CD8(+) T-cell responses induced by autologous mitomycin C treated Epstein-Barr virus transformed lymphoblastoid cell lines

Epstein-Barr virus (EBV) gene expression in tumor cells of posttransplant lymphoproliferative disorder (PTLD) patients resembles that of EBV transformed B-cell lines (LCL). EBV-specific cytotoxic T-lymphocytes can be generated by stimulating peripheral blood lymphocytes with autologous LCL. We describe a standardized method for the growth inactivation and cryopreservation of LCL for optimal T-cell stimulation and analyzed the function and phenotype of responding T-cells. LCL growth was completely blocked by mitomycin C treatment (McLCL) and McLCL could be cryopreserved while retaining excellent APC function. McLCL stimulated both CD4(+) and CD8(+) T-cells as measured by HLA-DR and CD25 expression using FACS analysis. EBV-specific CTL activity and T-cell proliferation were induced and immunocytochemical staining showed CD4(+) and (granzyme B positive) CD8(+) T-cells rosetting with McLCL. Granzymes A and B, IFN-gamma, and IL-6 were detected at significant levels in the supernatant. Thus, ex vivo T-cell activation with cryopreserved McLCL results in activation of both CD4(+) and CD8(+) T-cells producing a Th1-like cytokine profile, making this a suitable protocol for adoptive therapy of PTLD.     

The lectin binding sites on the plasma membrane components of human lymphoblastoid cell lines.

The plasma membrane components of five human B-cell lines and three human T-cell lines were separated by dodecyl sulfate polyacrylamide gel electrophoresis, incubated with the radioactive labeled lectins from lentil, castor bean, wheat germ, Phaseolus bean, peanut, gorse and the Roman snail and the molecular weights of the binding sites determined. The lentil, castor bean and wheat germ lectin bound to multiple components from molecular weights (Mr) 20 000 to 200 000 within the plasma membranes, whereas peanut lectin bound preferentially to glycoproteins of Mr 150 000 and 83 000 in B-cells, and 150 000 and 130 000 in T-cells. The gorse lectin bound to a 220 000 component in B-cells which was not labeled in T-cells.