Targeted disruption of SHIP leads to hemopoietic perturbations, lung pathology, and a shortened life span

SHIP is a 145-kD SH2-containing inositol-5-phosphatase widely expressed in hemopoietic cells. It was first identified as a tyrosine phosphoprotein associated with Shc in response to numerous cytokines. SHIP has been implicated in FcgammaRIIB receptor-mediated negative signaling in B cells and mast cells and is postulated to down-regulate cytokine signal transduction in myeloid cells. To define further its role in the proliferation and differentiation of hemopoietic progenitors, as well as its function in mature cells, we have generated embryonic stem cells and mice bearing a targeted disruption of both SHIP alleles. Here we show that although SHIP null mice are viable and fertile, they fail to thrive and survival is only 40% by 14 weeks of age. Mortality is associated with extensive consolidation of the lungs resulting from infiltration by myeloid cells. Increased numbers of granulocyte-macrophage progenitors are observed in both the bone marrow and spleen of SHIP-/- mice, perhaps as a consequence of hyper-responsiveness to stimulation by macrophage-colony stimulating factor, granulocyte-macrophage colony stimulating factor, interleukin-3, or Steel factor as observed in vitro. In contrast, numbers of bone marrow lymphoid and late erythroid progenitors (CFU-E) are reduced. Thus, homozygous disruption of SHIP establishes the crucial role of this molecule in modulating cytokine signaling within the hemopoietic system and provides a powerful model for further delineating its function.

Mice bearing a targeted interruption of the homeobox gene HOXA9 have defects in myeloid, erythroid, and lymphoid hematopoiesis

Several homeobox genes of the HOXA and HOXB clusters are expressed in primitive blood cells, suggesting a role for HOX genes in normal hematopoiesis. The HOXA9 gene is expressed in CD34+ marrow cells and in developing lymphocytes. We examined blood-forming organs of mice homozygous for an interrupted HOXA9 allele to determine if loss of HOX gene function is deleterious to hematopoiesis. HOXA9-/- mice have approximately 30% to 40% reductions in total leukocytes and lymphocytes (P < .001) and a blunted granulocytic response to granulocyte colony-stimulating factor (G-CSF). Homozygous mice have significantly smaller spleens and thymuses. Myeloid/erythroid and pre-B progenitors in the marrow are significantly reduced, but no significant decreases are noted in mixed colonies, day 12 colony-forming units-spleen (CFU-S), or long-term culture-initiating cells (LTC-IC), suggesting little or no perturbation in earlier progenitors. Heterozygous animals display no hematopoietic defects. The abnormalities in leukocyte production are transplantable, indicating that the defect resides in the hematopoietic cells. These studies demonstrate a physiologic role for a HOX gene in blood cell differentiation, with the greatest apparent influence of HOXA9 at the level of the committed progenitor.

Impaired steel factor responsiveness differentially affects the detection and long-term maintenance of fetal liver hematopoietic stem cells in vivo

The results of previous studies have shown that the development of hematopoiesis during fetal life can occur in the absence of Steel factor (SF) signaling. On the other hand, impairment of this mechanism can severely compromise the ability of cells from adult bone marrow to regenerate hematopoiesis on their transplantation into myeloablated recipients. This apparent paradox could result from changes during ontogeny in the responsiveness of hematopoietic stem cells to regulators that may substitute for SF as well as from differences in the availability of such factors during embryogenesis and in the myeloablated adult. To investigate these possibilities, we studied the effect of W41 and W42 mutations on the numbers, phenotype, and posttransplant self-renewal behavior of primitive hematopoietic cells present in the fetal liver (FL) of 14.5-day-old mouse embryos. In W41/ W41 FL, day-12 spleen colony-forming units and long-term culture-initiating cells appeared both quantitatively and qualitatively similar to their counterparts in the FL of +/+ embryos. W41/W41 FL also contained near normal numbers (approximately 50% of controls) of transplantable lymphomyeloid stem cells with competitive reconstituting ability in myeloablated adult +/+ recipients (as assessed for up to at least 16 weeks posttransplant). Moreover, both the original phenotype of these W41/W41 competitive repopulating units (CRUs) and their clonal posttransplant output of mature progeny were normal. Similarly, when myeloablated adult +/+ mice were cotransplanted with 5 x 10(4) +/+ FL cells and a sevenfold to 70-fold excess of W41/W41 FL CRUs, the contribution of the +/+ FL CRUs to the circulating white blood cell count present 5 weeks later was markedly reduced as compared with that of mice that received only +/+ FL cells. However, over the next 3 months, the proportion of mature white blood cells that were derived from +/+ precursors increased significantly (P < .002) in all groups (to > or = 30%), indicating that the ability to sustain hematopoiesis beyond 5 weeks is more SF-dependent than the ability to initially reconstitute both lymphoid and myeloid compartments. Cells from individual FL of W42/+ matings also showed an initial ability (at 7 to 8 weeks posttransplant) to competitively repopulate both lymphoid and myeloid compartments of myeloablated +/+ adult recipients. However, in contrast to recipients of normal or W41/W41 FL cells, the repopulation obtained with the W42 mutant stem cells was transient. Secondary transplants confirmed the inability of the W42 mutant cells to regenerate or even maintain a population of transplantable stem cells. Taken together with previous results from studies of CRUs in adult W mice, these findings support the concept of changes in the way hematopoietic stem cells at different stages of development respond to the stimulatory conditions evoked in the myeloablated recipient. In addition, they provide the first definitive evidence that SF is a limiting physiological regulator of sustained hematopoietic stem cell self-renewal in vivo.

Overexpression of HOXB4 enhances the hematopoietic potential of embryonic stem cells differentiated in vitro

Little is known about the molecular mechanisms controlling primitive hematopoietic stem cells, especially during embryogenesis. Homeobox genes encode a family of transcription factors that have gained increasing attention as master regulators of developmental processes and recently have been implicated in the differentiation and proliferation of hematopoietic cells. Several Hox homeobox genes are now known to be differentially expressed in various subpopulations of human hematopoietic cells and one such gene, HOXB4, has recently been shown to positively determine the proliferative potential of primitive murine bone marrow cells, including cells with long-term repopulating ability. To determine if this gene might influence hematopoiesis at the earliest stages of development, embryonic stem (ES) cells were genetically modified by retroviral gene transfer to overexpress HOXB4 and the effect on their in vitro differentiation was examined. HOXB4 overexpression significantly increased the number of progenitors of mixed erythroid/myeloid colonies and definitive, but not primitive, erythroid colonies derived from embryoid bodies (EBs) at various stages after induction of differentiation. There appeared to be no significant effect on the generation of granulocytic or monocytic progenitors, nor on the efficiency of EB formation or growth rate. Analysis of mRNA from EBs derived from HOXB4-transduced ES cells on different days of primary differentiation showed a significant increase in adult beta-globin expression, with no detectable effect on GATA-1 or embryonic globin (beta H-1). Thus, HOXB4 enhances the erythropoietic, and possibly more primitive, hematopoietic differentiative potential of ES cells. These results provide new evidence implicating Hox genes in the control of very early stages in the development of the hematopoietic system and highlight the utility of the ES model for gaining insights into the molecular genetic regulation of differentiation and proliferation events.

Studies of W mutant mice provide evidence for alternate mechanisms capable of activating hematopoietic stem cells

Previous studies have suggested that Steel factor (SF) can influence the behavior of many types of hematopoietic progenitor cells both in vivo and in vitro, although whether these may include the most primitive populations of totipotent repopulating cells remains controversial. To approach this question, we measured the number of Sca1+Lin-WGA+ cells, the number of cells with demonstrable myeloid (long-term culture-initiating cell [LTC-IC]) or both myeloid and lymphoid (LTC-IC(ML)) potential in 4- to 5-week-old long-term cultures containing irradiated primary marrow feeder layers, and the number of multilineage long-term in vivo repopulating cells (competitive repopulating unit [CRU]) present in the marrow of W42/+ or W41/W41 mice compared to +/+ controls. There was no significant effect of either of these W mutations on the number of Sca1+Lin-WGA+ cells and, in W41/W41 mice, neither LTC-IC nor LTC-IC(ML) populations appeared to be affected. On the other hand, although W41/W41 and W42/+ cells could both be detected in the in vivo CRU assay, their numbers were markedly reduced (17- and seven-fold, respectively) in spite of the fact that both of these W mutant genotypes contained near normal numbers of day-9 and -12 colony-forming units-spleen (CFU-S). In vitro quantitation of erythroid (burst-forming units-erythroid [BFU-E]), granulopoietic (CFU-granulocyte/macrophage [CFU-GM]), multilineage (CFU-granulocyte/erythrocyte/monocyte/macrophage [CFU-GEMM]), and pre-B clonogenic progenitors (CFU-pre-B) also revealed no differences in the numbers (or proliferative potential) of any of these cells when W41/W41 or W42/+ and normal mice were compared, although day 3 BFU-E from both types of W mutant mice showed no response to the typical enhancing effect exerted by SF on their +/+ counterparts. Taken together, these findings are consistent with the view that SF activation of c-kit receptor-induced signaling events is not a rate-limiting mechanism controlling red blood cell production during normal development until hematopoietic cells differentiate beyond the day-3 BFU-E stage. Nevertheless, normal hematopoietic stem cells do appear to be responsive to SF, since their W mutant counterparts display a disadvantage in the in vivo setting which is exaggerated under conditions of hematopoietic regeneration. On the other hand, alternative mechanisms also appear to contribute to the regulation of hematopoietic stem cell numbers in vivo and to their detection as LTC-IC in vitro.

Proteinases are involved in both DNA fragmentation and membrane damage during CTL-mediated target cell killing

A number of inhibitors with different specificities were used to probe the involvement of proteinases in the mechanism of cytotoxic T lymphocyte (CTL)-mediated lysis. N-Acetyl-L-tyrosine ethyl ester (ATEE) and N-benzoyl-L-arginine ethyl ester (BAEE) are reversible substrate inhibitors of proteinases with trypsin-like and chymotrypsin-like specificities, respectively. BAEE did not prevent either the chromium release or DNA fragmentation induced in mouse tumor target cells by a mixed lymphocyte population. In contrast, ATEE inhibited both processes. The irreversible proteinase inhibitor 3,4-dichloroisocoumarin (DCI) also blocked both chromium release and DNA fragmentation, but at significantly lower concentrations than ATEE. More importantly, chromium release was more susceptible to inhibition by DCI than DNA fragmentation. Addition of a combination of the endonuclease inhibitor aurintricarboxylic acid plus DCI resulted in virtually complete inhibition of both DNA fragmentation and chromium release when the drugs were added at the beginning of the incubation period. In contrast addition of DCI 15 or 30 min following initiation of the lytic cycle abolished the affect of DCI on fragmentation, but not lysis. A model which suggests a dual role for the proteinases in CTL-mediated target cell death is presented. First, proteinases are involved in the initiation of DNA fragmentation. Second, they have an ongoing function in membrane damage.

Characterization of a granule-independent lytic mechanism used by CTL hybridomas

The mechanism(s) by which CTL induce target cell lysis have not been clearly elucidated. Perforin and the cytotoxic cell proteinases (granzymes) contained within the granules of CTL and NK, have been implicated, but abundant evidence for the existence of alternate lytic pathways has accumulated. In this report we characterize the mechanism of killing used by two cytolytic hybridomas (PMM-1 and MD90) that express neither perforin nor the granzymes. These characteristics are compared with results obtained by using a representative Ag-dependent, granule-containing T cell clone in cytolysis assays. The major differences were that the granule-negative hybridomas could lyse a variety of target cells in the presence of cyclosporin and the absence of calcium. All the effectors could kill in the presence of protein synthesis inhibitors (cycloheximide and emetine) and induced DNA fragmentation in the target cells. The cytolytic hybridomas had to be stimulated to be cytolytic and this activation required the presence of calcium, was dependent on protein synthesis, and inhibited by the addition of cyclosporin. Although TNF was shown not be involved, the sensitivity of the target cells to lysis by the granule-negative killers correlated with the level of expression of Fas Ag. With the use of L1210 and an L1210 cell line transfected with Fas cDNA we demonstrated that these MD90 and PMM-1 kill the latter much more effectively and that this increase was effectively inhibited with anti-Fas Ab. Furthermore the lack of sensitivity to cyclosporin, cycloheximide, emetine, and EGTA was confirmed with these targets. We conclude that these two cytolytic hybridomas use the Fas lytic pathway to induce lysis in target cells.

Characterization of a granule-independent lytic mechanism used by CTL hybridomas

The mechanism(s) by which CTL induce target cell lysis have not been clearly elucidated. Perforin and the cytotoxic cell proteinases (granzymes) contained within the granules of CTL and NK, have been implicated, but abundant evidence for the existence of alternate lytic pathways has accumulated. In this report we characterize the mechanism of killing used by two cytolytic hybridomas (PMM-1 and MD90) that express neither perforin nor the granzymes. These characteristics are compared with results obtained by using a representative Ag-dependent, granule-containing T cell clone in cytolysis assays. The major differences were that the granule-negative hybridomas could lyse a variety of target cells in the presence of cyclosporin and the absence of calcium. All the effectors could kill in the presence of protein synthesis inhibitors (cycloheximide and emetine) and induced DNA fragmentation in the target cells. The cytolytic hybridomas had to be stimulated to be cytolytic and this activation required the presence of calcium, was dependent on protein synthesis, and inhibited by the addition of cyclosporin. Although TNF was shown not be involved, the sensitivity of the target cells to lysis by the granule-negative killers correlated with the level of expression of Fas Ag. With the use of L1210 and an L1210 cell line transfected with Fas cDNA we demonstrated that these MD90 and PMM-1 kill the latter much more effectively and that this increase was effectively inhibited with anti-Fas Ab. Furthermore the lack of sensitivity to cyclosporin, cycloheximide, emetine, and EGTA was confirmed with these targets. We conclude that these two cytolytic hybridomas use the Fas lytic pathway to induce lysis in target cells.

DNA fragmentation induced by cytotoxic T lymphocytes can result in target cell death

Cytotoxic T lymphocyte (CTL)-mediated lysis is accompanied by fragmentation of target cell DNA into an oligonucleosome ladder, a hallmark of apoptosis. Is this a fortuitous coincidence, or could CTL be inducing lysis by activation of the suicide signal? In this report we demonstrate that CTL-mediated target cell death can be blocked with the drug aurintricarboxylic acid (ATA). The abrogation of death correlates with the inhibition of DNA fragmentation. While ATA prevented DNA fragmentation, it failed to significantly alter protein, RNA, or DNA synthesis in the cell lines over the dose range used. In addition, there was no inhibition of cell-cell interaction or granule exocytosis during CTL-mediated killing. ATA also significantly inhibited the cytolysis and DNA fragmentation mediated by isolated cytolytic granules, as well as the granular protein fragmentin. We developed an assay in which target cells could be separated from CTL after binding and programming for lysis. Once they had received the "kiss of death," target cells could be rescued from lysis (as indicated by inhibition of DNA fragmentation and increased target cell viability) by treatment with ATA. These results suggest that ATA blocks target cell death by inhibition of DNA fragmentation, and further, that chromatin degradation is a cause rather than a result of cell death in CTL-mediated lysis.

Induction of a proteoglycan core protein mRNA in mouse T lymphocytes

The mouse T lymphocyte cell line EL4.E1 synthesizes a proteoglycan core protein (PGCP) mRNA which is identical to serglycin mRNA found in mouse bone marrow-derived mast cells and a mouse mastocytoma cell line. PGCP mRNA was strongly induced in EL4.E1 cells by phorbol myristate acetate, which also induces mRNAs for several cytokines in these cells. In contrast to the induction of cytokine mRNAs, however, the induction of PGCP mRNA was not inhibited by Cyclosporine. PGCP mRNA was also inducible by allogeneic stimulation of normal mouse spleen cells, and by Con A stimulation of an Interleukin 2-producing T hybridoma cell line. A number of other cell lines expressed an identical or similar, mRNA, including two cytotoxic T cell lines, and three tumor cell lines related to bone marrow-derived cells. The levels of several proteoglycans have previously been reported to increase in cells of bone marrow origin under activating conditions, but this appears to be the first report of an induction of the corresponding PGCP mRNA by immune stimulation of T lymphocytes.

Peritoneal exudate lymphocyte and mixed lymphocyte culture hybridomas are cytolytic in the absence of cytotoxic cell proteinases and perforin

We have utilized the sensitive polymerase chain reaction (PCR) to determine whether cytotoxic T lymphocyte (CTL) hybridomas generated from peritoneal exudate lymphocytes (PEL) and mixed lymphocyte cultures (MLC) express transcripts for perforin and the cytotoxic cell proteinases CCP1 to CCP5. We could readily detect less than one transcript per cell using this methodology. Cytolytic activity could be induced to varying levels in four of the five hybridoma clones tested. With the exception of low level CCP2 expression in the MLC hybridoma MD45 following antigen stimulation, all of the hybridomas could be stimulated to function as potent cytolytic cells in the complete absence of perforin or CCP transcripts. PCR analysis utilizing actin primers indicated that all samples contained material which could be reverse transcribed and PCR-amplified. These results support the argument that populations of lymphocytes do exist that are capable of target cell lysis by an alternative mechanism not involving perforin and CCP.

Calreticulin in T-lymphocytes. Identification of calreticulin in T-lymphocytes and demonstration that activation of T cells correlates with increased levels of calreticulin mRNA and protein

Ca2+ is an essential second messenger for T cell activation, but the exact mechanisms of its action are poorly understood. The cytosolic Ca2+ concentration is significantly increased upon the stimulation of T cells with either mitogen, cross-linking antibodies, or their cognate ligands. In this study, expression of calreticulin, a major Ca(2+)-binding (storage), KDEL protein of the endoplasmic reticulum was examined in resting and concanavalin A (ConA)-stimulated mouse and human T-lymphocytes. Both resting, mouse and human lymphocytes contain very low levels of calreticulin mRNA and protein. Mouse splenocytes stimulated with ConA exhibited an induction in calreticulin mRNA which peaked by Day 4. A 5-fold increase in the immunoreactive calreticulin protein band was also observed in the cells during this period of stimulation. Similarly when human lymphocytes were cultured with ConA a significant increase in the levels of the calreticulin mRNA and protein was observed. The peak of calreticulin mRNA was observed at Day 1 rather than Day 4 as seen for the mouse. These results clearly demonstrate the presence of calreticulin, a Ca(2+)-binding protein originally characterized in muscle tissue, in activated T-lymphocytes. Furthermore, we show that expression of calreticulin correlates with T-lymphocyte activation. Our results suggest that calreticulin may be involved in the signaling pathway for the induction of Ca(2+)-dependent processes and may represent one regulatory mechanism operating in activation of T-lymphocytes.

Two cytotoxic cell proteinase genes are differentially sensitive to sodium butyrate

The 5'-flanking regions of two cytotoxic cell protease genes, CCP1 and 2, are sufficient to confer cytotoxic T lymphocyte-specific expression when fused to a reporter gene. The two regulatory regions are, however, differentially sensitive to treatment of the recipient cell, MTL 2.8.2, with sodium butyrate. With CCP1 a six-fold increase in cat expression was observed, whereas CCP2 was insensitive to the butyrate treatment. One major butyrate-sensitive regions was defined in the CCP1 5'-flanking sequence between -243 to -112 and another less effective one between-682 to -427. These fragments of DNA were also able to confer responsiveness to butyrate when ligated to a heterologous fos promoter. These sequences within the 5' flank of CCP1 share homology with other elements that have been defined as butyrate-responsive. We believe that our results argue against a pleiotropic affect of butyrate such as histone acetylation. More likely sodium butyrate is mediating a specific stimulation of transcription through modification of the activities of selected transcriptional regulatory proteins that in turn affect their interactions with proteins bound to the promoter.

A comparison of the flanking regions of the mouse cytotoxic cell proteinase genes

T lymphocyte activation correlates with the transcriptional induction of a variety of genes that encode proteins that are believed to play a role in specific effector functions of the mature cells. Transcripts corresponding to members of the cytotoxic cell proteinase (CCP) family of genes accumulate with different kinetics depending upon the nature of the T cell stimulus. The profile of expression for each family member is unique. Sequences corresponding to the 5' and 3' flanking regions of each of the CCP genes were isolated and sequenced. A comparison of these sequences reveal regions of conservation that are consistent with the differential expression observed and indicate potential regulatory elements.

Quantitative polymerase chain reaction analysis of cytotoxic cell proteinase gene transcripts in T cells. Pattern of expression is dependent on the nature of the stimulus

A quantitative polymerase chain reaction assay was developed that allowed us to monitor transcript levels corresponding to individual members of the cytotoxic cell proteinase (CCP) gene family during T cell activation. Selective expression was observed and shown to depend upon the mode of T cell antigen receptor stimulation. Mitogen or allogeneic stimulation of cells resulted in the appearance of transcripts corresponding to all the genes measured, whereas alpha CD3 antibody produced a response restricted to just two family members. This differential gene activation represents a heterogeneity in cytotoxic T lymphocytes that has not been recognized previously. It may indicate that the T cell branch of the immune system can distinguish between different forms of stimulation and respond by synthesizing a specific set of effector and ancillary molecules that is most appropriate for lysis of cells bearing that type of antigen. Only CCP1 transcripts correlated with cytotoxicity for all modes of stimulation. The patterns for the others are suggestive of distinct and ancillary, rather than direct effector, roles in the lytic mechanism.

The effect of influenza vaccination on IL2 production in healthy elderly: implications for current vaccination practices

Age-related senescence of T-cell mediated responses is well recognized. This study was designed to determine how aging affects the T-cell mediated Interleukin 2 (IL2) response to influenza vaccination. A group of healthy elderly individuals were compared to a control group of healthy young adults for their response to the 1990 influenza vaccine. Cultures of peripheral blood mononuclear cells (PBMC) were prepared from venous blood samples taken prevaccination (pre) and 8 and 12 weeks post-vaccination (post). PBMC cultures stimulated with inactivated A/Shanghai/16/89 (contained in the 1990 vaccine) and A/Philippine/2/82 (not contained in the vaccine) were assayed for peak IL2 activity. We find that after influenza vaccination, there was an insignificant increase in IL2 activity when PBMC from the young control group were stimulated with A/Shanghai/16/89 (pre, 5.14 U/mL/10(6) PBMC; post, 6.64 U/mL/10(6) PBMC) but there was a significant increase in IL2 activity when stimulated with A/Phillippine/2/82 (pre, 1.5 U/mL/10(6) PBMC; post, 8.3 U/mL/10(6) PBMC). In similar cultures of PBMC from the elderly group, there was a significant increase in IL2 response to both A/Shanghai/16/89 (pre, 1.6 U/mL/10(6) PBMC; post, 3.5 U/mL/10(6) PBMC) and A/Philippine/2/82 (pre, 0.86 U/mL/10(6) PBMC; post, 8.3 U/mL/10(6) PBMC). Measurements of CD4+/CD8+ populations were not affected by vaccination and were not significantly different in the two groups. Subgroup analysis of the elderly group revealed that previous influenza vaccination in 1989 did not significantly affect IL2 levels measured in the present study. This study shows that in healthy elderly, influenza vaccination effectively restores IL2 activity to normal. There appears to be an age-related decrease in the duration of T-cell memory.(ABSTRACT TRUNCATED AT 250 WORDS)

Development of precytotoxic T cells in cyclosporine-suppressed mixed lymphocyte reactions

Cyclosporine (CsA) blocked the generation of cytolytic activity in a primary MLR of mouse spleen cells. As expected from the known mechanism of action of this drug, it also blocked the accumulation of IL-2 during the MLR. Addition of human rIL-2 did not overcome the inhibition of CTL generation, even when it was added daily to keep its level similar to that produced in a normal MLR. Daily addition was necessary, because the CsA-inhibited MLR consumed IL-2, either by utilization or degradation. The outcome of a 5-day MLR in the presence of CsA (CsA-MLR) depended on whether or not IL-2 was continuously present. In the presence of IL-2, there was no generation of CTL activity, probably because such cultures contained IL-2-dependent suppressive elements described previously. However, when day 5 CsA-MLR cells generated in the absence of IL-2 were washed and recultured with human rIL-2, there was a burst of CTL activity, with a more than 50-fold increase in alloantigen-specific cytotoxicity within 24 to 48 h. This increase is not explainable simply by the proliferation of existing effector CTL. The noncytotoxic cells produced in an MLR in the presence of CsA, and which can be rapidly activated to cytotoxic effector cells by IL-2, are termed "precursor-effector CTL" (peCTL). They could be detected by day 3 of a primary CsA-MLR culture. Their conversion to effector CTL by IL-2 was not inhibited by CsA. Exposure of peCTL to IL-4 also generated CTL activity, to a somewhat lesser degree than IL-2, but the IL-4-induced activation was inhibited by CsA, suggesting that it depended on the induction of another CsA-sensitive lymphokine. The intracellular levels of mRNA encoding the CTL-specific serine esterases CCP1 and CCP2 (granzymes B and C, respectively) increased rapidly during the IL-2-driven conversion of peCTL to effector CTL. This study demonstrates that in the presence of CsA precursors for CTL can accumulate, and that these can be rapidly converted to cytotoxic effector cells by IL-2.

Development of precytotoxic T cells in cyclosporine-suppressed mixed lymphocyte reactions

Cyclosporine (CsA) blocked the generation of cytolytic activity in a primary MLR of mouse spleen cells. As expected from the known mechanism of action of this drug, it also blocked the accumulation of IL-2 during the MLR. Addition of human rIL-2 did not overcome the inhibition of CTL generation, even when it was added daily to keep its level similar to that produced in a normal MLR. Daily addition was necessary, because the CsA-inhibited MLR consumed IL-2, either by utilization or degradation. The outcome of a 5-day MLR in the presence of CsA (CsA-MLR) depended on whether or not IL-2 was continuously present. In the presence of IL-2, there was no generation of CTL activity, probably because such cultures contained IL-2-dependent suppressive elements described previously. However, when day 5 CsA-MLR cells generated in the absence of IL-2 were washed and recultured with human rIL-2, there was a burst of CTL activity, with a more than 50-fold increase in alloantigen-specific cytotoxicity within 24 to 48 h. This increase is not explainable simply by the proliferation of existing effector CTL. The noncytotoxic cells produced in an MLR in the presence of CsA, and which can be rapidly activated to cytotoxic effector cells by IL-2, are termed "precursor-effector CTL" (peCTL). They could be detected by day 3 of a primary CsA-MLR culture. Their conversion to effector CTL by IL-2 was not inhibited by CsA. Exposure of peCTL to IL-4 also generated CTL activity, to a somewhat lesser degree than IL-2, but the IL-4-induced activation was inhibited by CsA, suggesting that it depended on the induction of another CsA-sensitive lymphokine. The intracellular levels of mRNA encoding the CTL-specific serine esterases CCP1 and CCP2 (granzymes B and C, respectively) increased rapidly during the IL-2-driven conversion of peCTL to effector CTL. This study demonstrates that in the presence of CsA precursors for CTL can accumulate, and that these can be rapidly converted to cytotoxic effector cells by IL-2.

Changes in the amounts of amino acids associated with nerve endings (synaptosomes) during synaptogenesis

Changes in the amounts of proteins and amino acids in synaptosomes and whole tissue from the olfactory bulb and cerebral cortex of rats were measured during the period 5-25 days postnatal. The amount of neurotransmitter type amino acids (such as GABA, glutamate and aspartate) associated with synaptosomes obtained from 1g of brain tissue increased dramatically with the age of the animals, whereas non-transmitter type amino acids (such as serine and glutamine) showed relatively little change. The results were in harmony with an earlier cessation of synaptogenesis in the olfactory bulb than in the cerebral cortex.