p52-Independent nuclear translocation of RelB promotes LPS-induced attachment.

The NF-kappaB signaling pathways have a critical role in the development and progression of various cancers. In this study, we demonstrated that the small cell lung cancer cell line (SCLC) H69 expressed a unique NF-kappaB profile as compared to other cancer cell lines. The p105/p50, p100/p52, c-Rel, and RelB protein and mRNA transcripts were absent in H69 cells but these cells expressed RelA/p65. The activation of H69 cells by lipopolysaccharide (LPS) resulted in the induction of RelB and p100 expression. The treatment also induced the nuclear translocation of RelB without the processing of p100 to p52. Furthermore, LPS-induced beta1 integrin expression and cellular attachment through an NF-kappaB-dependent mechanism. Blocking RelB expression prevented the increase in the expression of beta1 integrin and the attachment of H69. Taken together, the results suggest that RelB was responsible for the LPS-mediated attachment and may play an important role in the progression of some cancers.

Highly reduced protection against Streptococcus pneumoniae after deletion of a single heavy chain gene in mouse.

Phosphocholine (PC) is the immunodominant epitope found on the surface of Streptococcus pneumoniae (SPn). T15-idiotype Abs, whose heavy (H) chain variable region is encoded by the V1 gene, are dominant in the anti-PC response in adult mice and protect mice from lethal pneumococcal infection. The ability of anti-PC Abs using H chains other than the V1 H chain to protect against pneumococcal infection remains controversial. We generated V1(-/-) knockout mice to determine whether protective anti-PC Abs could be produced in the absence of the V1 gene. No anti-PC Abs were produced in V1(-/-) mice immunized with avirulent SPn; however, PC-BSA binding Abs were induced after immunization with PC-keyhole limpet hemocyanin but at significantly lower levels than those in wild-type mice. These Abs provided poor protection against virulent SPn; thus, <25% of V1(-/-) mice survived challenge with 10(4) bacteria as compared with 100% survival of V1(+/+) mice. The anti-PC Abs in V1(-/-) mice were heteroclitic, binding to nitrophenyl-PC better than to PC. None of nine hybridomas produced from V1(-/-) mice provided passive protection. However, the V1(-/-) mice produced normal amounts of Ab to SPn proteins that can partially protect mice against SPn. These data indicate that the V1 gene is critical for the production of anti-PC Abs providing optimum protection against infection with SPn, and the V1(-/-) mice could be useful in unmasking epitopes other than the immunodominant PC epitope on SPn capable of providing cross protection.

Autoreactive B cells escape clonal deletion by expressing multiple antigen receptors.

IgH and L chain transgenes encoding a phosphocholine (PC)-specific Ig receptor were introduced into recombinase-activating gene (Rag-2-/-) knockout mice. The PC-specific B cells that developed behaved like known autoreactive lymphocytes. They were 1) developmentally arrested in the bone marrow, 2) unable to secrete Ab, 3) able to escape clonal deletion and develop into B1 B cells in the peritoneal cavity, and 4) rescued by overexpression of bcl-2. A second IgL chain was genetically introduced into Rag-2-/- knockout mice expressing the autoreactive PC-specific Ig receptor. These dual L chain-expressing mice had B cells in peripheral lymphoid organs that coexpressed both anti-PC Ab as well as Ab employing the second available L chain that does not generate an autoreactive PC-specific receptor. Coexpression of the additional Ig molecules rescued the autoreactive anti-PC B cells and relieved the functional anergy of the anti-PC-specific B cells, as demonstrated by detection of circulating autoreactive anti-PC-Abs. We call this novel mechanism by which autoreactive B cells can persist by compromising allelic exclusion receptor dilution. Rescue of autoreactive PC-specific B cells would be beneficial to the host because these Abs are vital for protection against pathogens such as Streptococcus pneumoniae.

Leukoregulin induction of prostaglandin-endoperoxide H synthase-2 in human orbital fibroblasts. An in vitro model for connective tissue inflammation.

Several proinflammatory cytokines can increase prostaglandin E2 (PGE2) synthesis in a variety of cell types, constituting an important component of the inflammatory response. We demonstrate here that leukoregulin, a 50-kDa product of activated T lymphocytes, dramatically increases PGE2 synthesis in cultured human orbital fibroblasts. This up-regulation is mediated through an induction of prostaglandin-endoperoxide H synthase-2 (PGHS-2), the inflammatory cyclooxygenase. Steady-state levels of PGHS-2 mRNA are increased within 1.5 h of leukoregulin addition and are near maximal by 6 h, when they are 50-fold or higher above basal levels. The increase in PGHS-2 mRNA levels is partially blocked by cycloheximide, suggesting de novo synthesis of an intermediate protein may be required for a maximal leukoregulin response. Nuclear run-on studies indicate PGHS-2 gene transcription is up-regulated by leukoregulin 2-fold after 2 and 6 h. PGHS-2 protein, as assessed by Western blotting and two-dimensional protein gel analysis, is increased dramatically in orbital fibroblasts. This lymphokine-dependent expression of PGHS-2 is blocked by dexamethasone, and the increase in PGE2 and cAMP levels following leukoregulin treatment is also blocked by indomethacin and by SC 58125, a newly developed PGHS-2-selective cyclooxygenase inhibitor. The dramatic increase in cAMP levels causes marked alteration in orbital fibroblast morphology. PGHS-2 expression in dermal fibroblasts is also increased by leukoregulin; however, the response is considerably less robust, and these cells do not undergo a change in morphology. Both orbital and dermal fibroblasts express high levels of PGHS-1 mRNA and protein, the other abundant form of cyclooxygenase. In contrast to its effects on PGHS-2 expression, leukoregulin fails to alter PGHS-1 levels in either orbital or dermal fibroblasts, suggesting that PGHS-1 is not involved in cytokine-dependent prostanoid production in human fibroblasts. The increased PGHS-2 expression elicited by leukoregulin in orbital fibroblasts may be a consequence of both transcriptional and post-transcriptional effects. These observations help clarify the pathogenic mechanism relevant to the intense inflammation associated with Graves' ophthalmopathy. Lymphocytes trafficked to orbital tissues have a putative role, through the cytokines they release, in the activation of fibroblasts in this autoimmune disease.

Mapping of the immune interferon gamma gene (IFNG) to chromosome band 12q14 by fluorescence in situ hybridization.

The human immune interferon gamma gene (IFNG) was localized to chromosome band 12q14 by fluorescence in situ hybridization. This correction of a previous localization resolves the discrepancy between the syntenic maps of human chromosome 12 and mouse chromosome 10 and facilitates linkage analysis and identification of gene interactions near this region of chromosome 12 as well as further genetic studies of interferon-gamma immune-associated diseases.

Partial dissociation of subgroup C phenotype and in vivo behaviour in feline leukaemia viruses with chimeric envelope genes.

Feline leukaemia viruses (FeLVs) are classified into subgroups A, B and C by their use of different host cell receptors on feline cells, a phenotype which is determined by the viral envelope. FeLV-A is the ubiquitous, highly infectious form of FeLV, and FeLV-C isolates are rare variants which are invariably isolated along with FeLV-A. The FeLV-C isolates share the capacity to induce acute non-regenerative anaemia and the prototype, FeLV-C/Sarma, has strongly age-restricted infectivity for cats. The FeLV-C/Sarma env sequence is closely related to that of common, weakly pathogenic FeLV-A isolates. We now show by construction of chimeric viruses that the receptor specificity of FeLV-A/Glasgow-1 virus can be converted to that of FeLV-C by exchange of a single env variable domain, Vr1, which differs by a three codon deletion and nine adjacent substitutions. Attempts to dissect this region further by directed mutagenesis resulted in disabled proviruses. Sequence analysis of independent natural FeLV-C isolates showed that they have unique Vr1 sequences which are distinct from the conserved FeLV-A pattern. The chimeric viruses which acquired the host range and subgroup properties of FeLV-C retained certain FeLV-A-like properties in that they were non-cytopathogenic in 3201B feline T cells and readily induced viraemia in weanling animals. They also induced a profound anaemia in neonates which had a more prolonged course than that induced by FeLV-C/Sarma and which was macrocytic rather than non-regenerative in nature. Although receptor specificity and a major determinant of pathogenicity segregate with Vr1, it appears that sequences elsewhere in the genome influence infectivity and pathogenicity independently of the subgroup phenotype.

Lymphocytotoxic strains of feline leukemia virus induce apoptosis in feline T4-thymic lymphoma cells.

Feline leukemia retrovirus (FeLV) strains with subgroup C env genes kill feline T4 lymphoma 3201 cells by 7 to 12 days after in vitro inoculation, whereas FeLV strains with subgroup A env genes do not. Neither FeLV-A nor FeLV-C kill feline fibroblasts. FeLV-C, but not FeLV-A, is replicated to higher titer by 3201 cells and productive infection precedes death by 3 to 7 days. Transcriptional activity of the FeLV-C long terminal repeat, as assessed by chloramphenicol acetyltransferase activity, is high in feline lymphoid cells but low in feline fibroblasts. Activity of the FeLV-A long terminal repeat is moderate in both cell types. FeLV-C-infected cells form aggregates 1 to 4 days before dying; ultrastructurally, virus particles can be seen approximating the clustered cells. Dying cells demonstrate nuclear condensation, surface blebbing, and fragmentation. DNA fragmentation and laddering compatible with apoptosis occur 1 to 2 days before massive cell death. In FeLV-C-infected 3201 cells, a shift from phospholipid to neutral lipid incorporation of [14C]oleic acid, increases in palmitic acid proportions and decreases in linoleic acid proportions occur 1 to 2 days before peak killing. Exposure of 3201 cells to ultraviolet-inactivated FeLV-KT (200-800 micrograms/10(6) cells) causes cytostasis within 2 days and death within 4 days. Blebbing and nuclear condensation occur but clusters do not form. The induction of programmed cell death in feline thymic lymphoma cells by subgroup C feline retroviruses may be relevant to the pathogenesis of FeLV-induced thymic atrophy, paracortical lymphoid depletion and acquired immunodeficiency in vivo.

A feline large granular lymphoma and its derived cell line.

A lymphoma cell line (MCC) was derived from an abdominal mass from a 13-yr-old castrated male cat. The cells resemble natural killer precursor cells, have membrane-bound granules, and are positive for chloroacetate esterase, alpha-naphthyl butyrate esterase, and tartrate-resistant acid phosphatase activities. The MCC cells are negative for rearranged feline T-cell receptor genes, negative for feline T-cytotoxic antigen, Ia, and surface mu, tau, and lambda chains and do not form E-rosettes. The MCC cell line is negative for the feline leukemia virus (FeLV); e.g., negative for exogenous FeLV (exU3) sequences, negative for cytoplasmic and surface FeLV major core protein of 27,000 daltons (p27) by indirect immunofluorescence assay, negative for helper FeLV by clone 81 assay, and negative for release of soluble FeLV p27 by enzyme-linked immunosorbent assay. Electron microscopy reveals budding type C retrovirus particles and MCC cells react with anti-RD-114 (anti-endogenous feline retrovirus) reference serum. After in vitro infection, MCC replicate FeLV readily, but replication is noncytopathic.

Column purification of adenovirus cores.

A simple and efficient technique for purifying adenoviral chromatin (nucleoprotein cores) with Sephacryl S-1000 is described. This method is significantly faster than previous methods and gives a higher degree of purity with an increased recovery of the nucleoprotein. In addition, the structural integrity of the cores is maintained.