Mouse lymphotoxin and tumor necrosis factor: structural analysis of the cloned genes, physical linkage, and chromosomal position

Lymphotoxin (LT) and tumor necrosis factor (TNF) are cytotoxic and immunoregulatory lymphokines which have similar activities but are produced by different cell types. We have cloned the murine LT and TNF genes from a lambda:mouse DNA recombinant library, using as probes synthetic oligonucleotides defined by portions of the human LT or TNF cDNA sequences. Analysis of the genomic clones indicates that the LT and TNF genes are physically linked, i.e., approximately 1.2 kb separates the 3' end of LT from the 5' end of TNF genes. By using, first, a series of recombinant inbred lines, and second, a series of H-2-recombinant congenic strains, we determined that the LT/TNF gene cluster lies on chromosome 17, closely linked to the H-2D end of the murine H-2 complex. Comparison of the primary sequence of murine and human LT revealed that the intron-exon structure of murine LT is similar in these two species. Comparison of the predicted amino acid sequences of murine and human LT indicates that the proteins are about 72% homologous with much greater sequence conservation in regions encoding the COOH-terminal portion. Comparison of the 5' flanking sequence of LT to a number of genes that are specifically expressed in activated T cells reveals a number of conserved sequences that may play a role in control of these genes.     

Human lymphotoxin and tumor necrosis factor genes: structure, homology and chromosomal localization.

Human Tumor Necrosis Factor and Lymphotoxin are cytotoxic proteins which have similar biological activities and share 30 percent amino acid homology. The single copy genes which encode these proteins share several structural features: each gene is approximately three kilobase pairs in length and is interrupted by three introns. In addition, these genes are closely linked and have been mapped to human chromosome 6. However, only the last exons of both genes, which code for more than 80 percent of each secreted protein, are significantly homologous (56 percent).     

Strategies for manipulating apoptosis for cancer therapy with tumor necrosis factor and lymphotoxin

Tumor necrosis factor (TNF) and lymphotoxin (LT), initially described as tumoricidal proteins, may be useful as adjuncts in cancer therapy. Treatment with TNF or LT was found to protect cells and animals against damage mediated by radiation or cytotoxic anticancer drugs. By contrast, tumor cells treated with TNF or LT were sensitized to these insults. We present a model in which TNF or LT induces both the synthesis of “protective” proteins such as manganous superoxide dismutase (MnSOD) and the activation of “killing” proteins, such as proteases, depending on the level of the inducing signal. Although the p55-TNF/LT receptor is structurally related to the Fas receptor, they can each signal apoptosis by distinct pathways. Furthermore, activation of both receptors acts synergistically in stimulating apoptosis. © 1996 Wiley-Liss, Inc.     

Cathepsin-G and leukocyte elastase inactivate human tumor necrosis factor and lymphotoxin

The addition of either cathepsin-G or leukocyte elastase to endotoxin-stimulated human peripheral blood monocytes decreased the immunoreactive tumor necrosis factor (TNF) detected in culture supernatants in a concentration-dependent manner. Both enzymes also induced a loss of supernatant cytolytic activity as determined on the WEHI-164 target cell line. Incubation of recombinant human TNF and lymphotoxin (LT) with either cathepsin-G or leukocyte elastase resulted in a loss of cytokine bioactivity. Examination of enzyme-treated recombinant cytokines by gel electrophoresis revealed that cathepsin-G cleaved LT into a 12.6-kDa fragment and leukocyte elastase fragmented LT into a 14.1-kDa product. On Western blots cathepsin-G and leukocyte elastase degraded TNF into 11- and 7.6-kDa fragments, respectively. Incubating leukocyte elastase with plasma elastase inhibitor alpha-1-antitrypsin prevented the loss of recombinant TNF bioactivity and blocked the degradation of this cytokine. This study suggests that two of the most abundant neutrophil proteases, cathepsin-G and leukocyte elastase, may be important regulators of TNF and LT bioactivity.     

Expression in Escherichia coli of DNA coding for human tumor necrosis factor

The variants of expression in Escherichia coli of artificial DNA coding for human tumor necrosis factor, an important immune modulator with selective cytotoxic action on a number of transformed cell lines have been described. The DNA was placed under control of either phage M13 promoter of gene for main coat protein or tandem of pair of E. coli tryptophane promoters. It has been shown that E. coli cells harbouring plasmids described with artificial TNF gene provide good level of protein biosynthesis. The protein has been purified by anion exchange chromatography near to homogeneity and used for preparation of monoclonals. As result three hybridomas effectively produced high affinity monoclonal anti-TNF antibodies have been obtained and characterized.     

Synergistic interactions between interleukin 1, tumor necrosis factor, and lymphotoxin in bone resorption

Cytokines with bone-resorbing activity include IL 1 beta (pI 7), IL 1 alpha (pI 5), tumor necrosis factor (TNF), and lymphotoxin (LT). Possible interaction between IL 1 beta, the major mediator with osteoclast-activating factor (OAF) activity, and other cytokines was studied. By itself, IL 1 beta was 13-fold more potent than IL 1 alpha and 1000-fold more potent than either TNF or LT in stimulating bone resorption. Suboptimal concentrations of IL 1 beta or IL 1 alpha in combination with suboptimal concentrations of TNF or LT resulted in synergistic bone-resorptive responses (1.5 to 10 times the expected responses if their effects were additive). Synergy between either form of IL 1 and TNF or LT resulted in a twofold increase in activity of IL 1, and a 100-fold increase in activity of TNF or LT. However, even with optimal synergy, IL 1 beta remained 20-fold more potent in inducing bone resorption than TNF or LT. Because IL 1 beta is considerably more potent than TNF and LT in stimulating bone resorption either alone or under synergistic conditions, it is unlikely that TNF and LT are responsible for more than a minor proportion of the total bone-resorbing activity formerly referred to as OAF.     

The genes for tumor necrosis factor (TNF-alpha) and lymphotoxin (TNF-beta) are tandemly arranged on chromosome 17 of the mouse

We have isolated clones containing the gene for tumor necrosis factor (TNF-alpha) from a mouse genomic library. Four out of five clones containing the TNF-alpha gene also hybridized to a human lymphotoxin (TNF-beta) probe. We constructed a restriction enzyme cleavage map of a 6.4 kb region from one of the genomic clones. From partial sequencing data and hybridizations with exon-specific oligonucleotide probes, we conclude that this region contains the mouse TNF-alpha and TNF-beta genes in a tandem arrangement, that they are separated by only about 1100 bases, and that their intron-exon structure is very similar to that seen in man. We probed genomic blots of DNA from human/mouse hybrids containing single mouse chromosomes for the presence of the mouse TNF genes. The results show that the genes are located on mouse chromosome 17, which also contains the major histocompatibility complex. Therefore, both the mouse and the human TNF genes are tandemly arranged and located on the same chromosome as the MHC.     

Tumor necrosis factor and lymphotoxin in regulation of intestinal inflammation

Ulcerative colitis and Crohn’s disease are the major forms of inflammatory bowel disease. Cytokines of the tumor necrosis factor (TNF) family play an important role in the regulation of intestinal inflammation. In this review, we discuss the function of key cytokines of this family–TNF and lymphotoxin (LT)–in mucosal healing, IgA production, and in control of innate lymphoid cells (ILCs), novel regulators of mucosal homeostasis in the gut. TNF plays a central role in the pathogenesis of inflammatory bowel diseases (IBD). LT regulates group 3 of ILCs and IL-22 production and protects the epithelium against damage by chemicals and mucosal bacterial pathogens. In addition, we discuss major mouse models employed to study the mechanism of intestinal inflammation, their advantages and limitations, as well as application of TNF blockers in the therapy for IBD.     

Two conserved tryptophan residues of tumor necrosis factor and lymphotoxin are not involved in the biological activity

Each of the two highly conserved tryptophan residues in hTNF (positions 28 and 114) was converted into phenylalanine by site-directed mutagenesis and the mutant proteins were partially purified. A cytotoxicity assay on mouse L929 cells showed only a slight reduction in biological activity, strongly suggesting that neither of the two amino acids is involved in the active site.     

Studies on the differing effects of tumor necrosis factor and lymphotoxin on the growth of several human tumor lines

The relative ability of TNF and lymphotoxin (LT) to inhibit the growth of five human tumor cell lines was examined both in the presence and absence of IFN-gamma. Two adenocarcinoma lines, HT-29 and SK-CO-1, were 20- and 320-fold more sensitive to the inhibitory effects of TNF and LT in 3- to 4-day proliferation assays. In contrast, the breast carcinoma line BT-20 showed only a one- to twofold difference. The MCF-7 and ME-180 cell lines exhibited intermediate behavior. These results parallel the reported disparate potencies of TNF and LT in their effects on endothelial cells, hematopoietic development and their abilities to sustain a mixed lymphocyte response. Radiolabeled TNF binding studies showed two classes of receptors (Kd 0.04 to 0.15 nM and 0.2 to 1.0 nM) on the highly sensitive SK-CO-1 line. HT-29 cells also appeared to possess some high affinity-binding sites, whereas the BT-20 line completely lacked the high affinity form. Thus the presence of high affinity-binding sites correlated with increased sensitivity to the antiproliferative effects of TNF. Cold TNF competed with the binding of radiolabeled human TNF three- to fivefold better than LT for binding to all three lines. These relatively small differences between the TNF and LT receptor-binding characteristics are insufficient to explain the dramatic disparity in their antiproliferative properties. Likewise, the absolute concentrations of the unlabeled cytokines necessary to block the binding of 125I-TNF were 10- to 150-fold higher than the levels necessary to elicit the biologic response. Thus, the receptor binding data conflict with the growth inhibitory effects. This discrepancy is discussed in terms of either separate receptors for TNF and LT or more complex phenomena such as receptor cooperativity possibly resulting from multivalent interactions with the trimeric form of TNF.     

Inhibition by IL-1 of endothelial cell activation induced by tumor necrosis factor or lymphotoxin

Previous studies in this and other laboratories have demonstrated that IL-1, lymphotoxin (LT), and TNF rapidly stimulate a number of proinflammatory properties in cultured endothelial cells (EC) including cell-surface procoagulant activity and increased adhesivity for lymphocytes, monocytes, and polymorphonuclear leukocytes. In addition, we have demonstrated that LT and TNF, but not IL-1, stimulate increases in EC RNA synthesis, protein synthesis, and cellular volumes, changes which may correspond to the hypertrophy of EC seen at sites of inflammation in vivo. It is reported here that both human rIL-1 alpha and rIL-1 beta totally inhibit the increases in EC RNA synthesis, protein synthesis, and cell volumes induced by either TNF or LT. As little as 0.1 ng/ml of either IL-1 was sufficient to totally block the activation of EC induced by 100-fold higher concentrations (10 ng/ml) of either LT or TNF. The relevance of these findings to the regulation of inflammatory responses is discussed.