Granzyme A secretion by normal activated Lyt-2+ and L3T4+ T cells in response to antigenic stimulation

Granzyme A-immunoreactive cells in synovial fluid in reactive and rheumatoid arthritis

Perforin and granzyme A co-localize in the cytotoxic granules of killer cells like cytotoxic T lymphocytes (CTL). Perforin is the cytolytic pore-forming protein, whereas the function of the homodimeric serine protease granzyme A and other members of the granzyme family is still unclear. Granzyme A-immunoreactive cells formed 8 +/- 2% of the resting peripheral blood lymphocytes of healthy individuals. In contrast, granzyme A-positive cells formed 15% of peripheral blood mononuclear cells in patients with reactive or rheumatoid arthritis. However, 29 +/- 4% (p < 0.05 compared to normal peripheral blood) and 25 +/- 4% (p < 0.05) of all lymphocytes in synovial fluid in reactive and rheumatoid arthritis, respectively, were granzyme A-positive. This suggests involvement of cell-mediated cytolytic mechanisms in the articular pathogenic mechanisms. This involvement, however, does not differentiate between reactive and rheumatoid arthritis.

Differential expression of granzyme A and granzyme B proteases and their secretion by fresh rat natural killer cells (NK) and lymphokine-activated killer cells with NK phenotype (LAK-NK)

Granzymes A-G are a family of serine proteases localized in the cytoplasmic granules of cytotoxic T lymphocytes (Masson, D. et al. Cell 1987. 49: 679) and granzyme A is secreted by T lymphocytes in response to antigenic stimulation. Granzyme A is also expressed by natural killer (NK) and lymphokine-activated killer (LAK) cells. Here we show that fresh rat NK cells constitutively express granzyme B and that granzyme A and granzyme B are differentially regulated in unstimulated NK cells vs. LAK cells with NK phenotype (LAK-NK cells). We also show that both granzymes A and B are secreted in a calcium-dependent manner, by NK and LAK-NK cells in response to stimuli which trigger NK cell functions.

Analysis of naturally occurring delayed-type hypersensitivity reactions in leprosy by in situ hybridization

Analysis of tissue lesions of the major reactional states of leprosy was undertaken to study the immune mechanisms underlying regulation of cell-mediated immunity and delayed-type hypersensitivity (DTH) in man. In situ hybridization hybridization of reversal reaction biopsy specimens for INF-gamma mRNA expression revealed a 10-fold increase in specific mRNA-containing cells over that observed in unresponsive lepromatous patients. Expression of huHF serine esterase, a marker for T cytotoxic cells, were fourfold increased in reversal reaction and tuberculoid lesions above that detected in unresponsive lepromatous individuals. Immunohistology of reversal reactions confirmed a selective increase of Th and T cytotoxic cells in the cellular immune response. Of interest, the microanatomic location of these serine esterase mRNA-containing cells was identical to the distribution of CD4+ cells. Analysis of erythema nodosum leprosum (ENL) lesions revealed differences in the underlying immune processes in comparison with reversal reaction lesions. Although phenotypic Th cells predominated in ENL lesions, IFN-gamma and serine esterase gene expression were markedly reduced. We suggest that reversal reactions represent a hyperimmune DTH response characterized by a selective increase of CD4+ IFN-gamma producing cells and T cytotoxic cells, which result in the clearing of bacilli and concomitant tissue damage. In contrast, ENL reactions may be viewed as a transient diminution of Ts cells and activity leading to a partial and transient augmentation in cell-mediated immunity, perhaps sufficient to result in antibody and immune complex formation, but insufficient to clear bacilli from lesions.

Granzyme A expression by normal rat natural killer (NK) cells in vivo and by interleukin 2-activated NK cells in vitro

Granzyme A (TSP-1) is a serine esterase expressed in cytotoxic T and natural killer (NK) cell lines. Its presence in in vivo primed T cells is disputed at present. Here we show that normal rat NK cells contain granzyme A in vivo and that its expression is augmented by their short-term in vitro treatment with IL 2. Granzyme A expression in a NK cell population with LAK activity has also been examined.

Induction of T cell serine proteinase 1 (TSP-1)-specific mRNA in mouse T lymphocytes

An oligonucleotide probe corresponding to nucleotides of a cDNA encoding the T cell-associated proteinase 1 (TSP-1) was chosen to study the induction and expression of TSP-1-specific transcripts in mouse T lymphocytes and tissues. We demonstrate that TSP-1 mRNA is only expressed in activated T lymphocytes and is absent from all mouse tissues tested including those containing resting mature T lymphocytes. Expression of the TSP-1 gene was observed in T lymphocytes in vitro in response to either phorbolester (phorbol 12-myristate 13-acetate), Ca2+ ionophore (A23187), lectin or alloantigen. In general, TSP-1 mRNA appeared and peaked later compared to interleukin 2 transcripts. Furthermore, TSP-1 mRNA was inducible in vitro in both Ly-2+ and L3T4+ lymphocyte populations treated with alloantigen and/or lectin. The transcription of the TSP-1 gene was always accompanied by the expression of proteinase activity. High expression of TSP-1 transcripts was also observed in in vivo derived T effector cells specific for lymphocytic choriomeningitis virus. However, TSP-1 mRNA was predominantly associated with virus-specific Ly-2+ T cells and correlated with their proteinase and cytolytic activities. The data suggest that TSP-1 gene transcription is a useful marker to characterize T effector cells in vitro and in vivo.

Determination of frequency of T cells expressing the T cell-specific serine proteinase 1 (TSP-1) reveals two types of L3T4+ T lymphocytes

TSP-1 is a murine T cell-specific serine proteinase which is exclusively expressed in activated but not in resting T lymphocytes. Among T lymphocyte clones tested so far the enzyme was found to be associated with all Ly-2+ but only with a fraction of L3T4+ lines. Here we have applied a limiting dilution system to determine the frequency of precursor cells of resting L3T4+ and Ly-2+ lymphocytes which can be induced in vitro by antigen/lectin to express TSP-1. T cell subsets were either positively enriched by flow cytofluorometry cell sorting or by negative selection using monoclonal antibodies and complement. Following stimulation of lymphocytes in vitro, individual microwells were tested for growth by visual examination and for the TSP-1 protein/enzyme by analyzing cell lysates using either a specific rabbit anti-TSP-1 antiserum and/or the chromogenic model peptide substrate H-D-Pro-Phe-Arg-p-nitroanilide. Moreover, a large panel of L3T4+ and Ly-2+ T lymphocyte clones generated from primary cultures were similarly investigated. In some cell cultures the presence of TSP-1 was also tested on the mRNA level using a TSP-1-specific oligonucleotide probe. The data show that the majority, if not all, of antigen/lectin-induced-Ly-2+ T cells expressed TSP-1. In contrast, only 12%-27% of the growing lectin or antigen-reactive L3T4+ lymphocytes were positive for the enzyme. Studies performed in parallel with L3T4+ and Ly-2+ lymphocyte populations sensitized in bulk culture showed that under these conditions similar levels of TSP-1-specific mRNA and enzyme activity are detected in both subsets. The finding of primary L3T4+ T lymphocyte clones with distinct patterns of TSP-1 production provides evidence for the existence of two types of L3T4+ effector cells with different functional capacities. The data also suggest a cooperation between distinct L3T4+ lymphocytes for induction of optimal TSP-1 activity in L3T4+ T cells.

Perforin-dependent and -independent pathways of cytotoxicity mediated by lymphocytes

There is little doubt at the present time that both perforin-dependent and -independent pathways are important in mediating the cytotoxicity associated with lymphocytes. The cell distribution of perforin, initially thought to include both CTL and NK cells, now must be viewed with caution because all previous biochemical studies on CTL have been conducted with cell lines propagated in long-term cultures in the presence of T cell growth factors (IL-2 and perhaps some still undefined factors). Under these conditions, CTL are known to assume a broader, NK-like specificity in target cell killing and may thus differ significantly from primary CTL generated in the body. Accordingly, perforin does not seem to be present in primary CTL activated directly through mixed lymphocyte reactions. It remains to be shown how primary CTL lyse target cells in vivo. Initial studies conducted in several laboratories have already provided some clues. It now seems that even in cultured, perforin-containing CTL, the perforin pathway is not an obligatory mechanism required for target cell killing. Other pathways, possibly involving TNF/lymphotoxin-like molecules, may play a direct role in this type of cytotoxicity. Other still unidentified factors now also need to be sought, including membrane polypeptides that may develop cytotoxicity directly upon cell contact and binding. Although from the studies reviewed here it is clear now that perforin has a more limited role in cell killing than originally proposed, it is still intriguing that it should share structural and functional homologies with complement proteins, drawing paradoxical analogies between two systems (the cellular and the humoral immune systems) which have evolved to become specialized to carry out separate immunological tasks. The cloning of the genes for perforin and for all the C proteins that comprise the MAC should reveal important information on how these genes originated and then diverged during evolution. The cellular distribution of other granule products, such as serine esterases, also must be viewed with caution. A serine esterase activity was initially thought to be CTL-specific. This information stimulated an intensive research activity in many laboratories that resulted in both the purification of a serine esterase family and the cloning of several serine esterase transcripts. It is becoming clear from recent evidence that this group of enzymes is not truly CTL-specific and therefore would not be expected to develop any function rendered absolutely necessary for cytolysis.(ABSTRACT TRUNCATED AT 400 WORDS)