Phosphoinositide 3-kinase activation regulates cell division time by coordinated control of cell mass and cell cycle progression rate

Cells must increase their mass in coordination with cell cycle progression to ensure that their size and macromolecular composition remain constant for any given proliferation rate. To this end, growth factors activate early signaling cascades that simultaneously promote cell mass increase and induce cell cycle entry. Nonetheless, the mechanism that controls the concerted regulation of cell growth and cell cycle entry in mammals remains unknown. The phosphatidylinositol 3-kinase (PI3K)/protein kinase B pathway regulates cell cycle entry by inactivating forkhead transcription factors and promoting cyclin D synthesis. PI3K/protein kinase B-derived signals also affect activation of p70 S6 kinase and the mammalian target of rapamycin, enzymes involved in cell growth control. We previously showed that enhancement of PI3K activation accelerates cell cycle entry, whereas reduction of PI3K activation retarded this process. Here we examined whether expression of different PI3K mutants affects cell growth during cell division. We show that diminishing or enhancing the magnitude of PI3K activation in a transient manner reduces or increases, respectively, the protein synthesis rate. Alteration of cell growth and cell cycle entry by PI3K forms appears to be concerted, because it results in lengthening or shortening of cell division time without altering cell size. In support of a central role for PI3K in growth control, expression of a deregulated, constitutive active PI3K mutant affects p70 S6 kinase and mammalian target of rapamycin activities and increases cell size. Together, the results show that transient PI3K activation regulates cell growth and cell cycle in a coordinated manner, which in turn controls cell division time.

T cell activation in vivo targets diacylglycerol kinase alpha to the membrane: a novel mechanism for Ras attenuation

Diacylglycerol kinase (DGK) phosphorylates diacylglycerol to produce phosphatidic acid, leading to decreased and increased levels, respectively, of these two lipid messengers that play a central role in T cell activation. Nine DGK isoforms, grouped into five subtypes, are found in higher organisms; all contain a conserved C-terminal domain and at least two cysteine-rich motifs of unknown function. In this study, we have researched in vivo the regulation of DGK alpha, using a transgenic mouse model in which injection of an antigenic peptide activates the majority of peripheral T cells. We demonstrate that DGK alpha, highly expressed in resting T lymphocytes, is subject to complex control at the mRNA and protein levels during in vivo T cell activation. Subcellular fractionation of T lymphocytes shortly after in vivo engagement of the TCR shows rapid translocation of cytosolic DGK alpha to the membrane fraction. At early time points, DGK alpha translocation to the membrane correlates with rapid translocation of Ras guanyl nucleotide-releasing protein (RasGRP), a nucleotide exchange activator for Ras that associates to the membrane through a diacylglycerol-binding domain. To demonstrate a causal relationship between DGK alpha activity and RasGRP relocation to the membrane, we determined RasGRP translocation kinetics in a T cell line transiently transfected with constitutive active and dominant-negative DGK alpha mutants. We show that membrane localization of DGK alpha is associated with a negative regulatory signal for Ras activation by reversing RasGRP translocation. This study is the first demonstration of in vivo regulation of DGK alpha, and provides new insight into the functional role of a member of this family of lipid kinases in the regulation of the immune response.

Degradation of cellular mRNA is a general early apoptosis-induced event

The fate of cellular mRNAs was analyzed in several cell lines of lymphoid origin, after induction of apoptosis by different mechanisms. Cytoplasmic mRNAs are specifically degraded as part of the early apoptotic response. This degradation is not species restricted and is independent of the cell line, the apoptotic stimulus, the intrinsic half-life of the mRNAs, and the transcriptional status of the gene (constitutive or inducible). mRNA degradation precedes DNA fragmentation and correlates with the appearance of phosphatidylserine in the outer cell membrane. In addition, apoptosis-induced mRNA degradation is an active process that can be dissected from other apoptotic hallmarks (degradation of annexin V, DNA, and poly(ADP-ribose) polymerase [PARP]), which suggests that apoptosis-induced mRNA degradation is controlled by a distinct signaling pathway. Furthermore, mRNA degradation also occurs in vivo, specifically during thymocyte apoptosis. Taken together, these data support the notion that degradation of mRNA is a general early apoptotic event that may become a new apoptotic hallmark.

Regulation of mRNA expression in macrophages after Yersinia enterocolitica infection. Role of different Yop effectors

The Yop virulon, which comprises a complete type III secretion system and secreted proteins, allows bacteria from the genus Yersinia to resist the nonspecific immune response of the host. This virulon, which is encoded by a plasmid called pYV in Yersinia enterocolitica, enables extracellular bacteria to inject six Yop effectors (YopE, -H, -T, -O, -P, -M) into the host cell. To investigate the role of YopP, YopM, and the other pYV-encoded factors on the expression of the host cell genes, we characterized the transcriptome alterations in infected mouse macrophages using the microarray technique. PU5-1.8 macrophages were infected either with an avirulent (pYV(-)), a wild type (pYV(+)), or two knockout (yopP(-) and yopM(-)) mutants of Y. enterocolitica. Expression alterations in response to Y. enterocolitica infection were monitored for 6657 genes. Among those, 857 genes were affected, 339 of which were specifically regulated by the action of the Yop virulon. Further analysis of those 339 genes allowed identification of specific targets of YopP, YopM, or the other pYV-encoded factors. According to these results, the main action of the Yop virulon is to counteract the host cell pro-inflammatory response to the infection. YopP participates to this inhibition, whereas another pYV-encoded factor appears to also be involved in this down-regulation. Besides, YopM was found to induce the regulation of genes involved in cell cycle and cell growth, revealing for the first time an in vitro effect for YopM. In addition to YopM, other pYV factors distinct from YopP affected the expression of genes involved in cycling. In conclusion, these results provide new insight into the mechanisms of Yersinia pathogenicity by identifying the changes in host genes expression after infection and highlight the concerted actions of the different Yop effectors.

Global and specific translational control by rapamycin in T cells uncovered by microarrays and proteomics

Rapamycin has been shown to affect translation. We have utilized two complementary approaches to identify genes that are predominantly affected by rapamycin in Jurkat T cells. One was to compare levels of polysome-bound and total RNA using oligonucleotide microarrays complementary to 6,300 human genes. Another was to determine protein synthesis levels using two-dimensional PAGE. Analysis of expression changes at the polysome-bound RNA levels showed that translation of most of the expressed genes was partially reduced following rapamycin treatment. However, translation of 136 genes (6% of the expressed genes) was totally inhibited. This group included genes encoding RNA-binding proteins and several proteasome subunit members. Translation of a set of 159 genes (7%) was largely unaffected by rapamycin treatment. These genes included transcription factors, kinases, phosphatases, and members of the RAS superfamily. Analysis of [(35)S]methionine-labeled proteins from the same cell populations using two-dimensional PAGE showed that the integrated intensity of 111 of 830 protein spots changed in rapamycin-treated cells by at least 3-fold (70 increased, 41 decreased). We identified 22 affected protein spots representing protein products of 16 genes. The combined microarray and proteomic approach has uncovered novel genes affected by rapamycin that may be involved in its immunosuppressive effect and other genes that are not affected at the level of translation in a context of general inhibition of cap-dependent translation.

Reliability of mRNA profiling: verification for samples with different complexities

Normalization of mRNA profiling data remains an open issue, which turns critical when comparing divergent samples or mRNA populations with different complexities. To address this question, we generated samples with different RNA amounts and complexities by subcellular fractionation of cytoplasmic RNA into the mutually exclusive ribosome-free and polysome-bound RNA pools. For each of the 563 mRNAs analyzed, the hybridization signal corresponding to the cytoplasmic sample equals the sum of signals from the ribosome-free plus the polysome-bound targets (cytoplasmic mRNA = ribosome-free mRNA + polysome-bound mRNA). This intuitive equation was fulfilled only after data normalization following "spiking" of the samples with an exogenous RNA. This is the first demonstration that spiking allows one to correct not only for differences in reaction efficiencies but also to reflect the variations in amount and complexity between the initial mRNA populations.

Translation control: bridging the gap between genomics and proteomics?

mRNA profiling enables the expression levels of thousands of transcripts in a cell to be monitored simultaneously. Nevertheless, analyses in yeast and mammalian cells have demonstrated that mRNA levels alone are unreliable indicators of the corresponding protein abundances. This discrepancy between mRNA and protein levels argues for the relevance of additional control mechanisms besides transcription. As translational control is a major mechanism regulating gene expression, the use of translated mRNA in profiling experiments might depict the proteome more closely than does the use of total mRNA. This would combine the technical potential of genomics with the physiological relevance of proteomics.

Isolation of translationally controlled mRNAs by differential screening

Translationalregulation plays an important role in the control of gene expression. Changes in translation initiation rates are the most common translation-regulating mechanisms, resulting in alterations in mRNA loading of ribosomes. This differential mobilization of mRNAs onto polyribosomes was used in differential screening to directly identify cDNAs whose transcripts are translationally controlled during antigenic stimulation of primary human T lymphocytes. Ribosome-free and polysome-bound mRNAs were prepared from quiescent and activated T cells and used as templates to synthesize four cDNA pools. These in turn were used as probes to hybridize four identical replicas of a T cell library or, alternatively, four cDNA arrays. Translational activation was indicated by redistribution of the hybridization signals from the ribosome-free fraction in resting T cells to the polysome-associated fraction in activated T cells. Translational repression corresponded to the opposite hybridization pattern. Fifty-two cDNAs were identified as translationally controlled by screening 472 genes in a cDNA array; 12 additional ones were obtained by screening a cDNA library. Several of the transcripts corresponded to mRNAs previously reported to be translationally controlled, thus validating the method. For the majority, however, such regulation had not yet been described. Translational control was verified for representative examples by demonstrating the redistribution of the corresponding mRNAs on polysome gradients in response to T cell activation. Our strategy therefore provides an efficient tool to directly isolate or identify translationally controlled mRNAs in a variety of physiological situations. Moreover, differential screening using arrays enables simultaneous analysis of both transcriptional and translational regulation, further enhancing the power of gene expression analysis.

Presence or absence of TGF-beta determines IL-4-induced generation of type 1 or type 2 CD8 T cell subsets

CD8+ T cells often differentiate into highly cytotoxic cells, secreting a Th1-like or type 1 cytokine pattern characterized by the production of IFN-gamma. However, cytotoxic, and in some reports, noncytotoxic, type 2 cells that secrete IL-4, IL-5, or IL-10 instead of IFN-gamma, can be generated when CD8+ T cells are primed in the presence of IL-4. Here, we show that IL-4 can also generate typical CD8 type 1 responses. Indeed, while presence of TGF-beta biases the development of CD8 T cells that, then, produce little cytolytic activity and IFN-gamma, addition of IL-4 results in the recovery of cytotoxicity and IFN-gamma production. The cooperative effects of TGF-beta and IL-4 imply dual functions, not only for IL-4, but also for TGF-beta. Indeed, depending on the presence or absence of IL-4, TGF-beta either inhibits or induces the generation of type 1 CD8+ T cells. Physiologically, the ratio of local IL-4/TGF-beta concentration may therefore be a critical element in determining the outcome of T cell responses to pathogen and autoantigens. It allows CD8 T cells to switch from an immunotolerant state in the presence of only TGF-beta or IL-4, to an immunocompetent proinflammatory type 1 state in the absence or presence of both cytokines.

Presence or Absence of TGF-β Determines IL-4-Induced Generation of Type 1 or Type 2 CD8 T Cell Subsets

CD8+ T cells often differentiate into highly cytotoxic cells, secreting a Th1-like or type 1 cytokine pattern characterized by the production of IFN-γ. However, cytotoxic, and in some reports, noncytotoxic, type 2 cells that secrete IL-4, IL-5, or IL-10 instead of IFN-γ, can be generated when CD8+ T cells are primed in the presence of IL-4. Here, we show that IL-4 can also generate typical CD8 type 1 responses. Indeed, while presence of TGF-β biases the development of CD8 T cells that, then, produce little cytolytic activity and IFN-γ, addition of IL-4 results in the recovery of cytotoxicity and IFN-γ production. The cooperative effects of TGF-β and IL-4 imply dual functions, not only for IL-4, but also for TGF-β. Indeed, depending on the presence or absence of IL-4, TGF-β either inhibits or induces the generation of type 1 CD8+ T cells. Physiologically, the ratio of local IL-4/TGF-β concentration may therefore be a critical element in determining the outcome of T cell responses to pathogen and autoantigens. It allows CD8 T cells to switch from an immunotolerant state in the presence of only TGF-β or IL-4, to an immunocompetent proinflammatory type 1 state in the absence or presence of both cytokines.

Translational control: a general mechanism for gene regulation during T cell activation

Distributional changes of individual mRNAs between free ribonucleoprotein particles (mRNP) and ribosome-bound transcripts are used to assess translational control. Simultaneous analysis of many mRNA species is required to estimate the overall contribution of translation to the regulation of gene expression. To this purpose, total cytoplasmic RNA was fractionated in sucrose step gradients and poly(A)+ RNA was prepared from mRNP and ribosome-bound fractions. Since direct, simultaneous analysis of a profusion of mRNAs is not feasible, distribution of their in vitro translation products was examined after separation in 2-dimensional gels, followed by computer-based analysis of autoradiographs. When this analysis was applied to antigenically stimulated T cells, 36% of in vitro translation products showed a greater than 10-fold increase in intensity, suggesting transcriptional activation of the corresponding mRNAs. In comparison, 7.9% of individual mRNAs (54 of 685 species) were translationally activated. They were redistributed from free mRNP to ribosome-associated fractions; 4.7% (32 species) were translationally repressed, as indicated by the opposite pattern. The differential recruitment of 12.6% of mRNA species demonstrates specificity and the general significance of translational control during T cell activation, which implies that translation may play a similar role in regulating gene expression in a variety of physiological processes.

Structure and function of the iron-responsive element from human ferritin L chain mRNA

We report the cloning and functional characterization of the iron responsive element (IRE) of human ferritin light (L) chain mRNA from a cDNA library of primary human T lymphocytes. Comparison of this palindromic cDNA element to the IRE predicted from the reported genomic sequence revealed significant differences, resulting in a stem-loop structure with lower stability than the IRE of the heavy (H) chain mRNA. Nevertheless, the L subunit IRE mediated efficient binding of the iron regulatory protein (IRP) in a manner comparable to that of human ferritin H chain mRNA in vitro. In accordance with previous observations on H form transcripts, the cis-acting regulatory IRE motif of human ferritin L chain mRNA was capable of repressing translation under iron deprivation but permitted mobilization of the transcripts into polysomes following iron repletion in vivo.

Transcriptional and translational control of TNF-alpha gene expression in human monocytes by major histocompatibility complex class II ligands

While non-stimulated primary human monocytes exhibit very low levels of tumor necrosis factor (TNF)-alpha mRNA, direct binding of the staphylococcal exotoxin toxic shock syndrome toxin-1 (TSST-1) to major histocompatibility complex (MHC) class II molecules results in a fast (peak 1 h after stimulation), transient induction (sevenfold) of TNF-alpha mRNA. This induction correlates with a fourfold increase in transcription rates of the TNF-alpha gene, as detected by run-on assays, and does not require de novo protein synthesis. Mapping of DNase-I hypersensitive sites (DHS) discloses two constitutive DHS, one located far upstream (within the TNF-beta promoter) and the other centered at -39 +/- 40 bp relative to the major TNF-alpha transcription start site, suggesting that the TNF-alpha gene was transcriptionally competent even prior to MHC class II engagement. Furthermore, stimulation of human monocytes with either TSST-1 or lipopolysaccharide increases the translational efficiency of TNF-alpha mRNA, as shown by a shift in the distribution of this mRNA species in polysome gradients and the translation rates of TNF-alpha measured by immunoprecipitation from cells pulsed with [35S] methionine. The increase in translation efficiency of TNF-alpha mRNA is independent of the half-life of TNF-alpha transcripts, which under the conditions used is unchanged. Taken together, our data indicate that TNF-alpha expression is tightly regulated by MHC class II ligands, both at the transcriptional and translational levels.

Translational control of interleukin 2 messenger RNA as a molecular mechanism of T cell anergy

T cell stimulation by triggering through the T cell receptor (TCR) in the absence of costimulatory signals or by calcium ionophore induces unresponsiveness in T cells to further stimulation, a phenomenon known as anergy. In freshly isolated T cells, calcium ionophore induces expression of interleukin (IL)-2 messenger (mRNA), but this mRNA is not translated and not loaded with ribosomes. In addition, while plate-bound anti-CD3 stimulation of resting T cells leads to IL-2 mRNA expression and IL-2 secretion, in cells pretreated with calcium ionophore before anti-CD3 stimulation, the IL-2 mRNA remains polysome unloaded and no IL-2 is produced. These observations show that IL-2 expression is controlled at the translational level, by differential ribosome loading. Furthermore, our data suggest that translational control of IL-2 mRNA may be a molecular mechanism by which anergy is attained.

CTX, a novel molecule specifically expressed on the surface of cortical thymocytes in Xenopus

CTX, a novel developmentally regulated type-I transmembrane protein is expressed specifically by a large fraction of cortical thymocytes in the amphibian Xenopus. This apparently monomeric 55-kDa glycoprotein is composed of two immunoglobulin domains, one variable (V) and one constant (C2 type), followed by a transmembrane and a 64-amino acid cytoplasmic domain. The first immunoglobulin domain is a V-J segment that is generated without gene rearrangement. In the genome, the V and C2 domains are both encoded by two half-domain exons. Two CTX loci are found per haploid genome, and they exhibit sequence differences with a high replacing/silent ratio in the CDR1-like region of the V domain, suggesting that these differences were selected. The cytoplasmic domain contains a motif that is highly conserved evolutionarily in several types of proteins, including adenylyl cyclases. Based on its unique tissue distribution, the variability of its V region and the motif of its cytoplasmic domain, CTX is a candidate for a new type of specific molecule involved in thymocyte selection.

Soluble and membrane-bound TNF-alpha are involved in the cytotoxic activity of B cells from tumor-bearing mice against tumor targets

Splenic B cells from BALB/c mice bearing mammary adenocarcinomas are capable of performing Ab-dependent cellular cytotoxicity. Effector-target conjugation after 18 h results in minimal cytoplasmic damage, whereas extensive nuclear disintegration is observed. To determine whether splenic B cells from tumor-bearing mice can effect direct cytotoxicity against tumor cells, L929 and WEHI 164 cells were used as targets. B lymphocytes from tumor-bearing mice, but not from normal animals, were capable of lysing these two types of tumor cells. However, only a low level of cytotoxicity could be detected when the nontumorigenic 3T3 cells were used as targets. To elucidate the mechanism of cytotoxicity of these killer B cells, RNase protection assays were performed using perforin, granzyme A, TNF-alpha, and lymphotoxin probes. No perforin, granzyme A, or lymphotoxin RNA could be detected in purified preparations of B cells from normal and tumor-bearing mice. B cells from normal mice did not have TNF-alpha RNA. In contrast, B cells from tumor bearers expressed TNF-alpha RNA. TNF-alpha could be detected in supernatants from both unstimulated and stimulated tumor bearers' splenic B cells, as measured by ELISA, and its lytic activity was neutralized by anti-TNF-alpha Ab. Western blots revealed the presence of TNF-alpha on the surface of the killer B cells. Paraformaldehyde-fixed B cells from tumor-bearing mice but not from normal animals were able to lyse TNF-alpha-sensitive tumor targets. This cytotoxicity was neutralized by anti-TNF-alpha Ab. These results suggest that TNF-alpha in soluble and membrane-bound forms may be involved in the mechanism of cytotoxicity exerted by B cells from tumor-bearing mice.

Soluble and membrane-bound TNF-alpha are involved in the cytotoxic activity of B cells from tumor-bearing mice against tumor targets

Splenic B cells from BALB/c mice bearing mammary adenocarcinomas are capable of performing Ab-dependent cellular cytotoxicity. Effector-target conjugation after 18 h results in minimal cytoplasmic damage, whereas extensive nuclear disintegration is observed. To determine whether splenic B cells from tumor-bearing mice can effect direct cytotoxicity against tumor cells, L929 and WEHI 164 cells were used as targets. B lymphocytes from tumor-bearing mice, but not from normal animals, were capable of lysing these two types of tumor cells. However, only a low level of cytotoxicity could be detected when the nontumorigenic 3T3 cells were used as targets. To elucidate the mechanism of cytotoxicity of these killer B cells, RNase protection assays were performed using perforin, granzyme A, TNF-alpha, and lymphotoxin probes. No perforin, granzyme A, or lymphotoxin RNA could be detected in purified preparations of B cells from normal and tumor-bearing mice. B cells from normal mice did not have TNF-alpha RNA. In contrast, B cells from tumor bearers expressed TNF-alpha RNA. TNF-alpha could be detected in supernatants from both unstimulated and stimulated tumor bearers' splenic B cells, as measured by ELISA, and its lytic activity was neutralized by anti-TNF-alpha Ab. Western blots revealed the presence of TNF-alpha on the surface of the killer B cells. Paraformaldehyde-fixed B cells from tumor-bearing mice but not from normal animals were able to lyse TNF-alpha-sensitive tumor targets. This cytotoxicity was neutralized by anti-TNF-alpha Ab. These results suggest that TNF-alpha in soluble and membrane-bound forms may be involved in the mechanism of cytotoxicity exerted by B cells from tumor-bearing mice.

Switch of CD8 T cells to noncytolytic CD8-CD4- cells that make TH2 cytokines and help B cells

CD8+ T cells are a major defense against viral infections and intracellular parasites. Their production of interferon-gamma (IFN-gamma) and their cytolytic activity are key elements in the immune response to these pathogens. Mature mouse CD8+ T cells that were activated in the presence of interleukin-4 (IL-4) developed into a CD8-CD4- population that was not cytolytic and did not produce IFN-gamma. However, these CD8- cells produced large amounts of IL-4, IL-5, and IL-10 and helped activate resting B cells. Thus, CD8 effector functions are potentially diverse and could be exploited by infectious agents that switch off host protective cytolytic responses.

Perforin expression in human peripheral blood mononuclear cells. Definition of an IL-2-independent pathway of perforin induction in CD8+ T cells

Perforin gene expression upon in vitro stimulation was studied at the mRNA level in normal human PBMC and in subpopulations. Freshly isolated PBMC express low levels of perforin mRNA. Increased perforin expression is rapidly induced by the calcium ionophore A23187 and by rIL-2. Phorbolesters (PMA), by comparison, are poor inducers of perforin RNA. Perforin induction by Ca-ionophore, unlike granzyme 2 and IL-2 induction, did not synergize with phorbolesters in PBMC or in purified T cells. Instead, perforin mRNA induction by A23187 in purified T cells requires the presence of adherent cells. Ca-ionophore plus adherent cell-induced perforin occurred in CD8+ T cells and was abolished by depletion of CD8+ T cells but not by depletion of CD4+ T cells. Adherent cells alone did not express perforin under any condition. Perforin mRNA induction by both A23187 and by rIL-2 is independent of de novo protein synthesis. The half-life of perforin mRNA induced by either stimulus is approximately 100 min. Cyclosporin A completely abrogates perforin induction by A23187 but only slightly inhibits the effect of rIL-2 on perforin mRNA expression. These data show that A23187 activates perforin gene expression in CD8+ cells by an IL-2-independent pathway and that the molecular mechanism of perforin expression may be different from the one induced by IL-2. Granzyme 2 (human leukocyte protease-HLP, homologous to murine granzyme B) mRNA expression was studied in comparison to perforin. Granzyme 2 in contrast to perforin responds to the synergistic action of phorbolester and Ca-ionophore in PBMC. In addition, the kinetics of the induction of granzyme and perforin mRNA, by various signals are different. Our data suggest that situations in vivo may exist that allow perforin expression in CD8+ cells in the absence of cytokines by a combination of Ca signals and accessory receptor ligation. The same signals may not be sufficient for granzyme 2 expression in any T cell subpopulation.

Perforin expression in human peripheral blood mononuclear cells. Definition of an IL-2-independent pathway of perforin induction in CD8+ T cells

Perforin gene expression upon in vitro stimulation was studied at the mRNA level in normal human PBMC and in subpopulations. Freshly isolated PBMC express low levels of perforin mRNA. Increased perforin expression is rapidly induced by the calcium ionophore A23187 and by rIL-2. Phorbolesters (PMA), by comparison, are poor inducers of perforin RNA. Perforin induction by Ca-ionophore, unlike granzyme 2 and IL-2 induction, did not synergize with phorbolesters in PBMC or in purified T cells. Instead, perforin mRNA induction by A23187 in purified T cells requires the presence of adherent cells. Ca-ionophore plus adherent cell-induced perforin occurred in CD8+ T cells and was abolished by depletion of CD8+ T cells but not by depletion of CD4+ T cells. Adherent cells alone did not express perforin under any condition. Perforin mRNA induction by both A23187 and by rIL-2 is independent of de novo protein synthesis. The half-life of perforin mRNA induced by either stimulus is approximately 100 min. Cyclosporin A completely abrogates perforin induction by A23187 but only slightly inhibits the effect of rIL-2 on perforin mRNA expression. These data show that A23187 activates perforin gene expression in CD8+ cells by an IL-2-independent pathway and that the molecular mechanism of perforin expression may be different from the one induced by IL-2. Granzyme 2 (human leukocyte protease-HLP, homologous to murine granzyme B) mRNA expression was studied in comparison to perforin. Granzyme 2 in contrast to perforin responds to the synergistic action of phorbolester and Ca-ionophore in PBMC. In addition, the kinetics of the induction of granzyme and perforin mRNA, by various signals are different. Our data suggest that situations in vivo may exist that allow perforin expression in CD8+ cells in the absence of cytokines by a combination of Ca signals and accessory receptor ligation. The same signals may not be sufficient for granzyme 2 expression in any T cell subpopulation.

The mouse male germ cell-specific gene Tpx-1: molecular structure, mode of expression in spermatogenesis, and sequence similarity to two non-mammalian genes

Tpx-1 is a testis-specific gene that maps on mouse Chromosome (Chr) 17. The deduced TPX-1 protein shows 55% amino acid sequence similarity to acidic epididymal glycoprotein (AEG), assumed to be involved in sperm maturation. In the present study, we determined the genomic structure of the mouse Tpx-1 gene and the cellular localization of its transcripts. The gene was found to contain ten exons, with an unusually large intron (approximately 17.0 kilobase pairs) between exons 8 and 9. In situ hybridization of testicular sections showed that Tpx-1 is transcribed abundantly by haploid male germ cells. A computer search of protein databases revealed that deduced TPX-1/AEG proteins have significant sequence similarity (approximately 30%) to two non-mammalian proteins: "pathogenesis-related" proteins 1 of tobaccos, and venom sac proteins of white-face hornets, known as Dol m V. Amino acid residues encoded by exon 10 of the Tpx-1 gene and most of those encoded by exon 9 were absent in the non-mammalian proteins. This result suggests that the ancestor of Tpx-1 acquired exons 9 and 10 after its divergence from the ancestors of the plant and insect proteins.

Genomic organization and subchromosomal in situ localization of the murine granzyme F, a serine protease expressed in CD8+ T cells

Granzyme F belongs to a closely related family of seven murine serine proteases stored in cytoplasmic granules of lymphoid cell populations. In contrast to the murine granzymes A to E and G, granzyme F is exclusively expressed in the CD4-CD8+ subset of peripheral T cells. To characterize the genomic sequences responsible for its highly restricted expression, we isolated a cosmid clone and sequenced a 7.5-kb genomic fragment that contains the promoter region and all five exons of the murine granzyme F gene. A TATA box sequence is located at position -25 relative to the transcription initiation site, which was determined by RNase protection. The genomic organization of granzyme F is similar to that of granzyme B and granzyme C, leukocyte elastase, cathepsin G, rat mast cell protease II, and complement factor D (adipsin). By the use of two fluorochromes for simultaneous high resolution in situ hybridization, the granzyme F gene was localized in close proximity distally from the TCR alpha-chain locus on mouse chromosome 14.

Genomic organization and subchromosomal in situ localization of the murine granzyme F, a serine protease expressed in CD8+ T cells

Granzyme F belongs to a closely related family of seven murine serine proteases stored in cytoplasmic granules of lymphoid cell populations. In contrast to the murine granzymes A to E and G, granzyme F is exclusively expressed in the CD4-CD8+ subset of peripheral T cells. To characterize the genomic sequences responsible for its highly restricted expression, we isolated a cosmid clone and sequenced a 7.5-kb genomic fragment that contains the promoter region and all five exons of the murine granzyme F gene. A TATA box sequence is located at position -25 relative to the transcription initiation site, which was determined by RNase protection. The genomic organization of granzyme F is similar to that of granzyme B and granzyme C, leukocyte elastase, cathepsin G, rat mast cell protease II, and complement factor D (adipsin). By the use of two fluorochromes for simultaneous high resolution in situ hybridization, the granzyme F gene was localized in close proximity distally from the TCR alpha-chain locus on mouse chromosome 14.

Transforming growth factor type beta 1 (TGF-beta 1) down-regulates interleukin-2 production and up-regulates interleukin-2 receptor expression in a thymoma cell line

Transforming growth factor type beta 1 (TGB-beta 1) belongs to a family of polypeptides with regulatory effects on growth and differentiation of a variety of cell types. TGB-beta 1 plays an important role in regulation of immune response by acting as a negative control signal for T cell proliferation through still unknown mechanisms. In this study we have analysed the effects of TGB-beta 1 on EL 4-6.1, a variant of the murine EL 4 thymoma, which can be induced by phorbol 12-myristate 13-acetate (PMA) and/or interleukin 1 (IL-1) to secrete interleukin 2 (IL-2) and express IL-2 receptors (IL-2R). Using this defined model system, we show that TGB-beta 1 simultaneously down-regulates IL-2 expression and up-regulates the number of both high and low affinity IL-2R. These changes correlate with changes at the mRNA level, suggesting an effect at the pre-translational level. The specificity of both TGF-beta 1 effects was demonstrated using a neutralizing antiserum to TGF-beta 1. Our data also suggest that TGF-beta 1 does not interfere with early activation signals of PMA and/or IL-1. This model might be useful for elucidating the complex role of TGF-beta 1 in the regulation of T cell responses.

Cell specificity of granzyme gene expression

Granzymes are serine proteases present in secretory granules of cytolytic T lymphocyte lines. We have studied the expression of the granzyme family (granzyme A, B, C, D, E, F, and G) in different lymphoid cell populations and cell lines as well as in nonlymphoid cells and tissues. Our data show that with few exceptions expression of granzyme genes is restricted to T cells and their thymic precursors. In mature T cells granzymes are expressed only upon activation. The same is true for thymocytes, with the exception of grazyme A that is expressed also in non-stimulated cells. In T cells and thymocytes the distribution of mRNAs coding for different granzymes depends on the subpopulation tested and the activation protocol. Highly cytolytic PEL express granzymes A and B but none of the other granzymes.