Cell-cycle regulated expression and serine phosphorylation of the myristylated protein kinase C substrate, SSeCKS: correlation with culture confluency, cell cycle phase and serum response

We recently identified a novel myristylated protein kinase C (PKC) substrate, named SSeCKS (pronounced essex), whose transcription is suppressed > 15 fold in src- or ras-transformed rodent fibroblasts, but not in raf-transformed cells [1, 2]. SSeCKS associates with and controls the elaboration of a cortical cytoskeletal matrix in response to phorbol esters [2], and overexpression of SSeCKS causes growth arrest of untransformed NIH3T3 cells [3]. Our preliminary data suggested that SSeCKS functions as a negative mitogenic regulator by controlling cytoskeletal architecture and that serine phosphorylation of SSeCKS by kinases such as PKC alters its interaction with cytoskeletal matrices and its ability to control mitogenesis. Here, we determine the effects of culture confluency, growth arrest and serum response on the steady-state abundance of SSeCKS RNA and protein and on the relative level of phosphoserine-free SSeCKS. SSeCKS transcription is initially induced by serum factors and by contact-inhibited growth rather than by cell-cycle arrest induced by serum starvation, hydroxyurea or nocodazole, and following serum-induced G1/S progression, SSeCKS transcription is suppressed. SSeCKS protein is hyperphosphorylated on serine residues during G1/S progression but not during the G2/M phase. Finally, we show that the induction of SSeCKS protein expression by contact inhibition is independent of SSeCKS' serum responsiveness. These data suggest that SSeCKS expression and function can be controlled at either the transcriptional or post-translational level in response to serum factors and culture confluency. The data strengthen the notion that SSeCKS plays an important, yet transient, role in cell cycle progression from G0 to G1 that differs from its role in controlling contact-inhibited growth.

Characterization of nephropathy induced by immunization with high molecular weight dextran

BACKGROUND

Injection of DEAE dextran into Lewis rats can produce proteinuria and has been reported as a model of IgA nephropathy.

METHODS

Cationic diethyl aminoethyl (DEAE) dextran of molecular weight 500 kDa was injected into male Lewis rats. After a pre-immunization period of 3 weeks, the animals were divided into two groups: group 1 (n = 14) received daily i.v, injections of 3.5 mg of antigen, group 2 (n = 14) was injected with 1.5 mg three times per week for a total period of 6 weeks. I.v. treatment was initiated with gradually increasing doses of DEAE dextran in both groups for 1 week, after which the maintenance dose was reached.

RESULTS

We observed the appearance of proteinuria in a nephrotic range after 5 weeks of i.v. injections in group 1 (urinary excretion: 332 +/- 83 mg/24 h, controls: 53 +/- 14 mg/24 h). In group 2, the proteinuria was almost equal to protein excretion of healthy rats of the same weight (67 +/- 20 mg/24 h). The serum and urine creatinine were normal. By light microscopy of kidney biopsies, the presence of focal and segmental proliferation of mesangial cells after 6 weeks of i.v. injections was identified. Immunohistochemistry revealed no deposition of IgA, IgM, IgG, or C3. Using anti-ED1 antibodies, there was no evidence of interstitial infiltration of monocytes/macrophages after 6 weeks of i.v. injections. Staining for proliferating cell nuclear antigen (PCNA) did not show the presence of proliferating cells either in glomeruli or in the interstitium. Staining with FITC-WGA lectin revealed focal and segmental loss of the negative charge in the capillary wall. By electron microscopy there was deposition of dextran in the basal membrane and segmental and focal damage of the podocyte foot processes. As the chemokine RANTES may be involved in glomerular injury, we examined the kidneys of proteinuric and non-proteinuric rats for the presence of RANTES. By indirect immunofluorescence only the proteinuric rats showed RANTES deposition in the mesangium.

CONCLUSIONS

Injection of rats with DEAE dextran leads to dose-dependent proteinuria without deposition of immune complexes but with podocyte damage. This is associated with local expression of the chemokine RANTES which may play a role in proteinuria of glomerular disease.

RANTES chemokine expression in transplant-associated accelerated atherosclerosis

BACKGROUND

The pathogenesis of transplantation-associated accelerated atherosclerosis is poorly understood, but it is likely to be an alloimmune response involving infiltration of the vessel wall by T lymphocytes and monocytes leading to smooth muscle cell proliferation and extracellular matrix deposition. RANTES is a chemokine that selectively chemoattracts T lymphocytes, NK cells, monocytes, and eosinophils. The expression of RANTES in accelerated atherosclerosis was investigated by in situ hybridization and immunohistochemistry.

METHODS

Coronary arteries from six patients undergoing accelerated atherosclerosis were obtained at the time of retransplantation. Normal coronary arteries from two patients with idiopathic dilated cardiomyopathy were used as controls. Messenger RNA for RANTES was localized with digoxigenin-labeled complementary DNA probes. RANTES protein was detected by use of a monoclonal antibody and a three-step horseradish peroxidase method.

RESULTS

RANTES mRNA and protein were detected in the lymphocytes, macrophages, myofibroblasts, and endothelial cells of arteries undergoing accelerated atherosclerosis but not in normal coronary arteries.

CONCLUSIONS

In view of its in vitro biologic activity and in vivo expression pattern, RANTES may be a pivotal mediator of the cellular infiltrate seen in graft atherosclerosis. This information may help in the design of novel diagnostic and therapeutic approaches to this increasingly important disease process.

A novel src- and ras-suppressed protein kinase C substrate associated with cytoskeletal architecture

We previously identified a novel src- and ras-suppressed gene, 322, encoding a mitogenic regulatory function (Lin, X., Nelson, P. J., Frankfort, B., Tombler, E., Johnson, R., and Gelman, I. H. (1995) Mol. Cell. Biol. 15, 2754-2762). Here, we characterize the 322 gene product as an in vivo and in vitro substrate of protein kinase C (PKC). Hence, we named this product SSeCKS (pronounced essex) for Src Suppressed C Kinase Substrate. Rabbit polyclonal sera raised against glutathione S-transferase (GST)-SSeCKS recognized a myristylated 280/290-kDa doublet in Rat-6 fibroblasts. SSeCKS levels in src- and ras-transformed Rat-6 cells were 15- and 8-fold less, respectively, than those in untransformed cells. Short-term addition of phorbol ester resulted in a 5-fold increase in SSeCKS phosphorylation which was inhibited by bis-indolylmaleimide. In vitro phosphorylation of GST-SSeCKS by purified rabbit brain PKC-alpha was enhanced by phosphatidylserine and blocked by excess PKC pseudosubstrate inhibitor peptide. GST-SSeCKS bound purified PKC-alpha or PKC from Rat-6 lysates in a phosphatidylserine-dependent manner. Four SSeCKS domains containing Lys/Arg-rich motifs similar to the PKC phosphorylation site in MARCKS were phosphorylated in vitro by PKC. Immunofluorescence analysis showed SSeCKS present throughout the cytoplasm with enrichment in podosomes and at the cell edge. Short-term addition of phorbol esters caused the movement of SSeCKS from plasma membrane sites to the perinucleus coincident with a loss of actin stress fibers. These data suggest a role for SSeCKS in the control of cellular cytoskeletal architecture.

Identification of a novel regulatory region critical for expression of the RANTES chemokine in activated T lymphocytes

The RANTES chemokine is a T cell-expressed, proinflammatory cytokine recently implicated as a suppressive agent of HIV replication. We have identified tandem kappaB-like sequences within the promoter for RANTES that are critical for RANTES promoter-reporter gene activity in both the T cell tumor line Hut78 and in PHA-activated PBL. This region binds not only Rel family members (including p50-p65 heterodimers and p50-p50 homodimers) but also non-Rel factors up-regulated in PBL 3 to 5 days following activation. The expression of these "late" expressed nuclear factors correlates with an up-regulation of RANTES message found at this point in T cell activation. These factors are also constitutively expressed in functionally mature CD8+ T cells. We hypothesize that these apparently novel proteins are responsible in part for the temporal regulation of RANTES seen in peripheral blood T cells and represent a component of transcriptional regulatory machinery newly expressed at this "late" stage of peripheral T cell development.

Identification of a novel regulatory region critical for expression of the RANTES chemokine in activated T lymphocytes

The RANTES chemokine is a T cell-expressed, proinflammatory cytokine recently implicated as a suppressive agent of HIV replication. We have identified tandem kappaB-like sequences within the promoter for RANTES that are critical for RANTES promoter-reporter gene activity in both the T cell tumor line Hut78 and in PHA-activated PBL. This region binds not only Rel family members (including p50-p65 heterodimers and p50-p50 homodimers) but also non-Rel factors up-regulated in PBL 3 to 5 days following activation. The expression of these "late" expressed nuclear factors correlates with an up-regulation of RANTES message found at this point in T cell activation. These factors are also constitutively expressed in functionally mature CD8+ T cells. We hypothesize that these apparently novel proteins are responsible in part for the temporal regulation of RANTES seen in peripheral blood T cells and represent a component of transcriptional regulatory machinery newly expressed at this "late" stage of peripheral T cell development.

RANTES chemokine expression in diseased and normal human tissues

RANTES is a member of a large family of cytokines, called chemokines, which are thought to play a regulatory role in inflammatory processes. We have made recombinant human RANTES protein which was used to generate a panel of anti-RANTES monoclonal antibodies. Following characterization, select anti-RANTES monoclonal antibodies were used for immunohistologic staining of a large panel of normal, diseased and fetal tissue sections. Diseased tissues included eleven lymphomas and eight renal tumors. Most tissues were also tested in parallel for RANTES mRNA by in situ hybridization using RANTES mRNA specific oligomeric probes. As expected, most normal adult tissues contain few, if any, RANTES positive cells. In contrast, RANTES expression dramatically increases in inflammatory sites. In addition, megakaryocytes, some tumours, and select fetal tissues express high levels of RANTES message and protein. These results indicate a wider expression of RANTES than previously appreciated and suggest multiple physiologic roles for this soluble factor.

Kinetics of transcription factors regulating the RANTES chemokine gene reveal a developmental switch in nuclear events during T-lymphocyte maturation

RANTES is a chemoattractant cytokine (chemokine) whose gene is expressed immediately after stimulation of several cell types but upregulated late (3 to 5 days) after activation in normal T lymphocytes. Here we describe two cis-acting elements in the human RANTES promoter that act in T lymphocytes. One site interacts with NFIL6, which is activated within the first 24 h after T-cell activation. The second site binds an apparently novel complex that is upregulated later, between days 3 and 5. These data provide an explanation for the immediate-early expression of RANTES in some cell types and identify apparently novel factors contributing to late RANTES transcription in T cells. The results reveal a developmental switch occurring during normal T-cell maturation coincident with the onset of terminal differentiation and the binding of late-acting factors to sequences of the RANTES promoter.

Stimulus specificity of matrix metalloproteinase dependence of human T cell migration through a model basement membrane

Chemotaxis of human T lymphoblastoma cells of the Tsup-1 line, which migrate similarly to blood T cells, through a layer of basement membrane-like Matrigel on a polycarbonate micropore filter was evoked by vasoactive intestinal peptide (VIP; concentration for a maximal response, 10(-7)M), IL-2 (10(-9)M), and the chemokines RANTES (10(-10)M) and macrophage inflammatory protein-1 alpha (10(-10)M). Chemotactic concentrations of each factor increased Tsup-1 cell secretion of matrix metalloproteinase-9 (MMP-9), with significant responses by 4 h for VIP, IL-2, and IL-4, but only after 24 h for macrophage inflammatory protein-1 alpha and RANTES, as quantified by Western blots and zymography. 3H-Labeled type IV human collagen incorporated in the Matrigel layer was degraded by migrating Tsup-1 cells, as assessed by release of radioactive fragments of the collagen. The in situ degradation of type IV collagen in Matrigel by migrating Tsup-1 cells was enhanced most significantly by VIP, IL-2, and IL-4 after 4 h at concentrations that increased the secretion of MMP-9 optimally, but only after 24 h by macrophage inflammatory protein-1 alpha and RANTES. The specific MMP inhibitor GM6001 suppressed Tsup-1 cell MMP activity evoked by all stimuli, as determined by zymography and in situ degradation of 3H-Labeled type IV human collagen. The chemotactic migration of Tsup-1 cells through Matrigel, but not through a filter alone, in response to optimal concentrations of VIP, IL-2, and IL-4, but not the chemokines, was inhibited by GM6001, with a concentration dependence similar to that for suppression of MMP activity. Thus elicitation of T cell chemotactic migration through a model basement membrane by stimuli that increase MMP activity early in the response depends on degradation of matrix proteins by MMP, whereas stimuli that recruit MMP late may rely on early activation of other proteases.

Stimulus specificity of matrix metalloproteinase dependence of human T cell migration through a model basement membrane

Chemotaxis of human T lymphoblastoma cells of the Tsup-1 line, which migrate similarly to blood T cells, through a layer of basement membrane-like Matrigel on a polycarbonate micropore filter was evoked by vasoactive intestinal peptide (VIP; concentration for a maximal response, 10(-7)M), IL-2 (10(-9)M), and the chemokines RANTES (10(-10)M) and macrophage inflammatory protein-1 alpha (10(-10)M). Chemotactic concentrations of each factor increased Tsup-1 cell secretion of matrix metalloproteinase-9 (MMP-9), with significant responses by 4 h for VIP, IL-2, and IL-4, but only after 24 h for macrophage inflammatory protein-1 alpha and RANTES, as quantified by Western blots and zymography. 3H-Labeled type IV human collagen incorporated in the Matrigel layer was degraded by migrating Tsup-1 cells, as assessed by release of radioactive fragments of the collagen. The in situ degradation of type IV collagen in Matrigel by migrating Tsup-1 cells was enhanced most significantly by VIP, IL-2, and IL-4 after 4 h at concentrations that increased the secretion of MMP-9 optimally, but only after 24 h by macrophage inflammatory protein-1 alpha and RANTES. The specific MMP inhibitor GM6001 suppressed Tsup-1 cell MMP activity evoked by all stimuli, as determined by zymography and in situ degradation of 3H-Labeled type IV human collagen. The chemotactic migration of Tsup-1 cells through Matrigel, but not through a filter alone, in response to optimal concentrations of VIP, IL-2, and IL-4, but not the chemokines, was inhibited by GM6001, with a concentration dependence similar to that for suppression of MMP activity. Thus elicitation of T cell chemotactic migration through a model basement membrane by stimuli that increase MMP activity early in the response depends on degradation of matrix proteins by MMP, whereas stimuli that recruit MMP late may rely on early activation of other proteases.

Isolation and characterization of a novel mitogenic regulatory gene, 322, which is transcriptionally suppressed in cells transformed by src and ras

In an attempt to isolate novel regulatory and/or tumor suppressor genes, we identified cDNAs whose abundance is low in NIH 3T3 cells and further decreased following the expression of the activated oncogene, v-src. The transcription of one such gene, 322, is suppressed at least 15-fold in src-, ras-, and fos-transformed cells and 3-fold in myc-transformed cells but is unaffected in raf-, mos-, or neu-transformed cells. Activation of a ts-v-src allele in confluent 3Y1 fibroblasts resulted in an initial increase in 322 mRNA levels after 1 to 2 h followed by a rapid decrease to suppressed levels after 4 to 8 h. Morphological transformation was not detected until 12 h later, indicating that the accumulation of 322 transcripts is regulated by v-src and not as a consequence of transformation. Addition of fetal calf serum to starved subconfluent NIH 3T3 or 3Y1 fibroblasts resulted in a similar biphasic regulation of 322, indicating that 322 transcription is responsive to mitogenic factors. Sequence analysis of a putative full-length 322 cDNA clone (5.4 kb) identified a large open reading frame (ORF) encoding a 148.1-kDa product. In vitro transcription and translation of the 322 cDNA from a T7 promoter resulted in a 207-kDa product whose electrophoretic mobility on a sodium dodecyl sulfate-polyacrylamide gel electrophoresis gel was unaffected by digestion with endoglycosidase F. The discrepancy in predicted versus measured molecular weights may result from the high percentage of acidic residues (roughly 20% Glu or Asp) in the 322 ORF product. Comparison of the 322 cDNA ORF with sequences in data banks indicates that this gene is novel. The 322 ORF product contains a potential Cys-1-His-3 Zn finger, at least five nuclear localization signals of the adenovirus E1a motif K(R/K)X(R/K), and alternating acidic and basic domains. Overexpression of the 322 cells resulted in the selection of rapidly growing cells which had lost the transduced 322 cDNA. Thus, 322 represent a novel src- and ras-regulated gene which encodes a potential regulator of mitogenesis and/or tumor suppressor.

Patterns of HIV-1 mRNA expression in transgenic mice are tissue-dependent

To explore tissue-specific factors that may be important in HIV-1 transcriptional and post-transcriptional regulation, we examined a transgenic mouse model containing a mutant provirus deleted in the gag and pol region. The level of transgene expression was tissue-dependent. Skin, muscle, and tail consistently expressed the transgene abundantly; intestine, kidney, and thymus exhibited variable but generally low levels of expression; while liver expression was undetectable by Northern analysis. Individual mRNAs within the family of singly and multiply spliced messages were determined by reverse transcription (rt) of RNA samples from mouse tissues, polymerase chain reaction (PCR) amplification, and Southern hybridization with exon-specific probes. The exact percentage of Tat-coding mRNA that was multiply spliced was also determined by competitive rtPCR. When 2-, 4-, or 7-kb (full-length) mRNA species were calculated as a percentage of the total mRNA, two phenotypes of distribution were detected. Lymphoid tissue (thymus and spleen) and kidney had significantly greater amounts of unspliced message (P < 0.001) regardless of the level of expression. All other tissues expressed the multiply spliced messages encoding Tat, Rev, and Nef predominantly. Furthermore, utilization of the three major second exon splice acceptor sites for tat, rev, and nef was the same in transgenic mice as has been demonstrated in human cells but the splice acceptor site for the vpu/env was different in murine tissue. The marked tissue-dependent patterns of HIV mRNA expression suggest a potential mechanism for the organ-specific manifestations of AIDS.

Perforant path kindling alters dentate gyrus field potentials and paired pulse depression in an age-dependent manner

The effects of rapid perforant path kindling on field potentials and paired pulse depression were studied in the dentate gyrus of rats at four developmental stages: 14-16 days, 20-22 days, 27-29 days and 40-60 days (adult). In rats 14-29 days kindling was associated with sustained potentiation of population spike amplitude and population EPSP slope; in adults a progressive decline was seen in both measures. Inhibitory circuitry as assessed by paired pulse depression was intact at all ages studied. Kindling produced no lasting changes in this measure at 14-22 days; in the older age groups a significant increase in paired pulse depression was seen. Thus immature animals differed from adults in that they manifested persistent facilitation of excitatory transmission as a result of kindling and failed to mount a compensatory inhibitory response. These results suggest that the balance between excitation and inhibition is more readily shifted toward excitation in immature animals in a manner that may contribute to their unique vulnerability to epileptogenesis.

RANTES chemokine expression in cell-mediated transplant rejection of the kidney

RANTES (regulated upon activation, normal T cell expressed and secreted) is a chemotactic cytokine (a chemokine) for memory T lymphocytes, monocytes, and eosinophils. RANTES expression was studied in renal allograft biopsy specimens. Although RANTES was not expressed in samples taken one hour after transplantation, or in native renal biopsy specimens from patients with cyclosporin nephrotoxicity, it was expressed during cell-mediated transplant rejection. RANTES mRNA was detected in infiltrating mononuclear cells and renal tubular epithelium, and RANTES protein was localised to mononuclear cells, tubular epithelium, and vascular endothelium. This suggests RANTES has a role in allograft rejection.

Monocyte haptotaxis induced by the RANTES chemokine

BACKGROUND

Soluble mediators and inducible cell-surface molecules coordinate the ordered cascade of events giving rise to inflammation. The specific mechanisms underlying the attraction of antigen-specific cells into a site of inflammation remain sketchy, however. In particular, it is unclear how chemoattractants cause rapidly moving immune cells to adhere to the blood vessel wall and to enter inflamed tissues.

RESULTS

Here we show that RANTES, a potent chemo-attractant for monocytes and T lymphocytes, is inducibly expressed within an inflamed organ, binds to endothelial cells, and promotes haptotaxis, the migration of cells induced by surface-bound gradients.

CONCLUSION

These findings lead us to propose a model for the role of RANTES in the migration of antigen-specific immune cells into an inflammatory site.

TNF alpha induces expression of the chemoattractant cytokine RANTES in cultured mouse mesangial cells

We investigated the effect of several immune-relevant cytokines on expression of the chemoattractant intercrine/chemokine RANTES in a mouse mesangial cell line (MMC). Fifty ng/ml recombinant tumor necrosis factor alpha (TNF alpha) induced a marked increase in RANTES transcripts after two hours. RANTES mRNA remained elevated for 24 to 48 hours after stimulation, and could be abolished by co-incubation with 30 micrograms/ml of a neutralizing rabbit anti-TNF alpha antibody. Protein expression of RANTES, as assessed by indirect immunofluorescence and Western blotting, increased in MMCs 24 hours after TNF alpha stimulation. Interleukin-1 beta, tumor necrosis factor beta (TNF beta), and lipopolysaccharide (LPS) also increased expression of RANTES mRNA. In addition, RANTES mRNA expression was stimulated in glomeruli harvested from rats following renal in vivo perfusion with TNF alpha. Our results indicate that mesangial cells produce the small cytokine RANTES. This factor, in concert with other chemoattractants, may play a role in the glomerular recruitment of inflammatory cells like macrophages/monocytes.

Genomic organization and transcriptional regulation of the RANTES chemokine gene

RANTES is a member of a large supergene family of pro-inflammatory cytokines called CC chemokines that appear to play a fundamental role in inflammatory processes. The RANTES protein causes release of histamine from basophils and is a chemoattractant for CD45RO/CD4+ "memory" T lymphocytes, monocytes, and eosinophils. Although expression of RANTES was first thought to be limited to activated T cells, recent data have shown that it is produced by a variety of tissue types in response to specific stimuli. RANTES mRNA is expressed late (3 to 5 days) after activation of resting T cells whereas in fibroblasts, renal epithelial and mesangial cells, RANTES mRNA is quickly up-regulated by TNF-alpha stimulation. In order to gain a better understanding of the molecular mechanisms that regulate expression of the RANTES locus, we have characterized the RANTES gene and determined a putative promoter region. The RANTES gene spans approximately 7.1 kb and is composed of three exons of 133, 112 and 1075 bases and two introns of approximately 1.4 and 4.4 kb with the position of intron/exon boundaries conserved relative to the other CC chemokine family members. Approximately 1 kb of DNA from the immediate 5' upstream region of RANTES was sequenced and found to contain a large number of potential consensus elements for specific T cell/hemopoietic, myeloid, muscle, and ubiquitously expressed DNA-binding factors. RANTES-promoter-luciferase gene fusion assays demonstrate high levels of reporter gene activity in a "mature" T cell line Hut78, the erythroleukemic cell line HEL, and the rhabdomyosarcoma cell line RD, with little or no activity in the "early" T cell line Jurkat, the gamma delta T cell line PEER, the thymic tumor Molt4, or the pre-erythroid cell line K562. Deletion analysis of the promoter region indicates that different transcriptional mechanisms control expression of RANTES in the various tissues studied.

Genomic organization and transcriptional regulation of the RANTES chemokine gene

RANTES is a member of a large supergene family of pro-inflammatory cytokines called CC chemokines that appear to play a fundamental role in inflammatory processes. The RANTES protein causes release of histamine from basophils and is a chemoattractant for CD45RO/CD4+ "memory" T lymphocytes, monocytes, and eosinophils. Although expression of RANTES was first thought to be limited to activated T cells, recent data have shown that it is produced by a variety of tissue types in response to specific stimuli. RANTES mRNA is expressed late (3 to 5 days) after activation of resting T cells whereas in fibroblasts, renal epithelial and mesangial cells, RANTES mRNA is quickly up-regulated by TNF-alpha stimulation. In order to gain a better understanding of the molecular mechanisms that regulate expression of the RANTES locus, we have characterized the RANTES gene and determined a putative promoter region. The RANTES gene spans approximately 7.1 kb and is composed of three exons of 133, 112 and 1075 bases and two introns of approximately 1.4 and 4.4 kb with the position of intron/exon boundaries conserved relative to the other CC chemokine family members. Approximately 1 kb of DNA from the immediate 5' upstream region of RANTES was sequenced and found to contain a large number of potential consensus elements for specific T cell/hemopoietic, myeloid, muscle, and ubiquitously expressed DNA-binding factors. RANTES-promoter-luciferase gene fusion assays demonstrate high levels of reporter gene activity in a "mature" T cell line Hut78, the erythroleukemic cell line HEL, and the rhabdomyosarcoma cell line RD, with little or no activity in the "early" T cell line Jurkat, the gamma delta T cell line PEER, the thymic tumor Molt4, or the pre-erythroid cell line K562. Deletion analysis of the promoter region indicates that different transcriptional mechanisms control expression of RANTES in the various tissues studied.

Cytotoxic T lymphocytes show HLA-C-restricted recognition of EBV-bearing cells and allorecognition of HLA class I molecules presenting self-peptides

Human CTL have been isolated that show self-restricted recognition of autologous lymphoblastoid cell lines and allorecognition. The lymphoblastoid cell line ligand most likely used a peptide that is expressed in EBV-bearing cells when the virus enters the lytic cycle. This peptide is presented to CD8+ CTL by HLA-Cw7 molecules. The allogeneic ligand recognized on non-EBV-infected cells is composed of a class I glycoprotein and a naturally selected self-peptide. In previous studies we demonstrated that this ligand is determined by two MHC-linked genes: one gene encodes the allogeneic class I molecule whereas the other controls the self-peptide. Despite the use of different peptides and different class I molecules, seemingly equivalent structures are formed that enable these two ligands to function as antigenic mimics of each other. CTL with the same patterns of dual specificity could be isolated from four unrelated donors, indicating that HLA-Cw7 is frequently involved in self-restricted recognition of EBV-harboring cells. Such CTL could help not only to contain lytic virus during a primary infection but also may be maintained life-long to eliminate cells in which reactivated virus appears.

Cytotoxic T lymphocytes show HLA-C-restricted recognition of EBV-bearing cells and allorecognition of HLA class I molecules presenting self-peptides

Human CTL have been isolated that show self-restricted recognition of autologous lymphoblastoid cell lines and allorecognition. The lymphoblastoid cell line ligand most likely used a peptide that is expressed in EBV-bearing cells when the virus enters the lytic cycle. This peptide is presented to CD8+ CTL by HLA-Cw7 molecules. The allogeneic ligand recognized on non-EBV-infected cells is composed of a class I glycoprotein and a naturally selected self-peptide. In previous studies we demonstrated that this ligand is determined by two MHC-linked genes: one gene encodes the allogeneic class I molecule whereas the other controls the self-peptide. Despite the use of different peptides and different class I molecules, seemingly equivalent structures are formed that enable these two ligands to function as antigenic mimics of each other. CTL with the same patterns of dual specificity could be isolated from four unrelated donors, indicating that HLA-Cw7 is frequently involved in self-restricted recognition of EBV-harboring cells. Such CTL could help not only to contain lytic virus during a primary infection but also may be maintained life-long to eliminate cells in which reactivated virus appears.

Gene expression in CD8 and CD4 T-cell populations following activation with the calcium ionophore A23187

We have hypothesized that functional maturation of T lymphocytes can be dissected into a series of discrete stages. For example, activation of T lymphocytes with the calcium ionophore A23187 drives CD8+ T cells to become dividing blasts, referred to as 'pre-effector' cells in that these blasts do not express cytolytic function but are driven by IL-2 to do so. Here we characterize via Northern blots the functional maturation of CD8+ and CD4+ T-lymphocyte populations which have been activated via A23187 followed by stimulation with IL-2. Previously we have reported that no detectable IL-2 was found in the supernatants of A23187-activated pre-effector blasts. However, these cells do express levels of IL-2 mRNA very similar to those of OKT3-activated blasts, from which IL-2 is easily detected in the supernatant. Translational control may account for these findings. A23187-activated CD8+ pre-effector blasts do not respond to stimulation with IFN-gamma nor do they express IFN-gamma mRNA following stimulation with IL-2. These observations suggest that IL-2 may be sufficient to stimulate maturation of these cells. Activation via A23187 results in lower expression of the proto-oncogene c-myb relative to that found in OKT3 activation. C-myb mRNA levels are higher in CD8+ than in CD4+ A23187-activated pre-effector blasts and the c-myb level in the CD8+ pre-effector blasts falls in response to IL-2. This decrease in c-myb mRNA coincides with an increase in proliferation, and the expression of cytolytic activity.

Molecular events in late stages of T-cell functional maturation

Peripheral blood lymphocytes activated with either the calcium ionophore A23187 or the combination of anti-CD2 monoclonal antibodies, 9.6 + VIT13, undergo blast formation and proliferation but do not develop cytolytic activity. These proliferating blasts, referred to as pre-effector blasts because they do not yet express cytolytic function, respond to stimulation with interleukin-2 (IL-2) by further proliferation and development of cytolytic activity, i.e. they become effector cells. Pre-effector blasts activated with 9.6 + VIT13, but not A23187-activated pre-effector blasts, also respond to stimulation with interferon-gamma (IFN-gamma) by becoming cytolytic effector cells. This report examines gene expression (by Northern blot analysis) in pre-effector blasts and during the transition from the pre-effector to the effector stage. The data presented here provide further support for the concept that A23187 activation drives T cells to become dividing blasts that are appropriately referred to as 'pre-effector' cells in that these blasts do not express transcripts for granzyme A or perforin mRNA but are driven by IL-2 to do so in parallel with the acquisition of cytotoxic function. Cells are apparently driven by 9.6 + VIT13 to a later stage of functional maturation than by A23187 activation; 9.6 + VIT13-activated pre-effector blasts express mRNA for both granzyme A and perforin, even though these blasts do not express cytolytic activity. Activation via A23187 results in lower expression of the proto-oncogene c-myb relative to that found in either 9.6 + VIT13 or OKT3-activated cells.