Interleukin 18 is a primary mediator of the inflammation associated with dextran sulphate sodium induced colitis: blocking interleukin 18 attenuates intestinal damage.

BACKGROUND AND AIMS: Persistent inflammation observed in inflammatory bowel disease may be the consequence of an increased or aberrant immune response to normal gut constituents or an overall immune dysregulation and imbalance. Cytokines play an important role in immune regulation and interleukin 18 (IL-18) is one such cytokine that has emerged as being instrumental in driving CD4+ T cell responses towards a Th1-type. IL-18 can also directly mediate inflammation, moderate interleukin 1 activity, and can act on cell types other than T cells. It has been reported recently that IL-18 mRNA and protein are upregulated in gut tissue from IBD patients. The aim of this study was to understand more about the role of IL-18 in contributing to the pathology of IBD and to assess whether blocking IL-18 activity may be of therapeutic benefit as a treatment regimen for IBD. METHODS: Mice with dextran sulphate sodium (DSS) induced colitis were treated with recombinant IL-18 binding protein (IL-18bp.Fc), a soluble protein that blocks IL-18 bioactivity. Histopathological analysis was performed and RNA from the large intestine was analysed using the RNase protection assay and gene arrays. RESULTS: IL-18 RNA levels increased very early in the colon during DSS colitis. Treatment of mice with IL-18bp.Fc inhibited IBD associated weight loss and significantly inhibited the intestinal inflammation induced by DSS. IL-18bp.Fc treatment also attenuated mRNA upregulation of multiple proinflammatory cytokine genes, chemokine genes, and matrix metalloprotease genes in the large intestine that are commonly elevated during IBD. CONCLUSIONS: IL-18bp treatment attenuated inflammation during DSS induced colitis in mice. Neutralising IL-18 activity may therefore be of benefit for ameliorating the inflammation associated with human intestinal diseases.

Enzyme-catalyzed acylation of homoserine: mechanistic characterization of the Haemophilus influenzae met2-encoded homoserine transacetylase.

The first unique step in bacterial and plant methionine biosynthesis involves the acylation of the gamma-hydroxyl of homoserine. In Haemophilus influenzae, acylation is accomplished via an acetyl-CoA-dependent acetylation catalyzed by homoserine transacetylase. The activity of this enzyme regulates flux of homoserine into multiple biosynthetic pathways and, therefore, represents a critical control point for cell growth and viability. We have cloned homoserine transacetylase from H. influenzae and present the first detailed enzymatic study of this enzyme. Steady-state kinetic experiments demonstrate that the enzyme utilizes a ping-pong kinetic mechanism in which the acetyl group of acetyl-CoA is initially transferred to an enzyme nucleophile before subsequent transfer to homoserine to form the final product, O-acetylhomoserine. The maximal velocity and V/K(homoserine) were independent of pH over the range of values tested, while V/K(acetyl)(-)(CoA) was dependent upon the ionization state of a single group exhibiting a pK value of 8.6, which was required to be protonated. Solvent kinetic isotope effect studies yielded inverse effects of 0.75 on V and 0.74 on V/K(CoA) on the reverse reaction and effects of 1.2 on V and 1.7 on V/K(homoserine) on the forward reaction. Direct evidence for the formation of an acetyl-enzyme intermediate was obtained using rapid-quench labeling studies. On the basis of these observations, we propose a chemical mechanism for this important member of the acyltransferase family and contrast its mechanism with that of homoserine transsuccinylase.

Identification and characterization of two members of a novel class of the interleukin-1 receptor (IL-1R) family. Delineation of a new class of IL-1R-related proteins based on signaling.

Two novel members of the interleukin-1 receptor (IL-1R) family, identified by homology searches of human genomic sequence data bases, are described. The genes have been named according to their structural features: TIGIRR-1 (three immunoglobulin domain-containing IL-1 receptor-related) and TIGIRR-2. TIGIRR-2 has recently been identified as causing mental retardation when mutated (Carrie, A., Jun, L., Bienvenu, T., Vinet, M. C., McDonell, N., Couvert, P., Zemni, R., Cardona, A., Van Buggenhout, G., Frints, S., Hamel, B., Moraine, C., Ropers, H. H., Strom, T., Howell, G. R., Whittaker, A., Ross, M. T., Kahn, A., Fryns, J. P., Beldjord, C., Marynen, P., and Chelly, J. (1999) Nat. Genet. 23, 25-31) and called IL1RAPL, a name we will also use henceforth. Neither receptor alone was able to mediate transcriptional activation of NF-kappaB in response to IL-1alpha, IL-1beta, or IL-18. In order to begin to elucidate the function of these and other orphan IL-1R family members, we have developed a functional assay utilizing a panel of chimeric receptors containing the extracellular and transmembrane domains of either type I IL-1R or IL-1R accessory protein (AcP) coupled to the cytoplasmic domains of all family members. Coexpression of each IL-1R chimera with each AcP chimera and an NF-kappaB-responsive reporter demonstrated that the cytoplasmic domains could be classified as IL-1R-like, AcP-like, or neither. Any IL-1R-like cytoplasmic domain could cooperate with any AcP-like cytoplasmic domain. The TIGIRR-1 and IL1RAPL cytoplasmic domains, however, were unable to signal as either IL-1R-like or AcP-like components, suggesting that they function as a new class of receptors within this family.

A poxvirus protein that binds to and inactivates IL-18, and inhibits NK cell response.

IL-18 induces IFN-gamma and NK cell cytotoxicity, making it a logical target for viral antagonism of host defense. We demonstrate that the ectromelia poxvirus p13 protein, bearing homology to the mammalian IL-18 binding protein, binds IL-18, and inhibits its activity in vitro. Binding of IL-18 to the viral p13 protein was compared with binding to the cellular IL-18R. The dissociation constant of p13 for murine IL-18 is 5 nM, compared with 0.2 nM for the cellular receptor heterodimer. Mice infected with a p13 deletion mutant of ectromelia virus had elevated cytotoxicity for YAC-1 tumor cell targets compared with control animals. Additionally, the p13 deletion mutant virus exhibited decreased levels of infectivity. Our data suggest that inactivation of IL-18, and subsequent impairment of NK cell cytotoxicity, may be one mechanism by which ectromelia evades the host immune response.

Enzyme-catalyzed acylation of homoserine: mechanistic characterization of the Escherichia coli metA-encoded homoserine transsuccinylase.

The first unique step in bacterial and plant methionine biosynthesis involves the activation of the gamma-hydroxyl of homoserine. In Escherichia coli, this activation is accomplished via a succinylation reaction catalyzed by homoserine transsuccinylase. The activity of this enzyme is closely regulated in vivo and therefore represents a critical control point for cell growth and viability. We have cloned homoserine transsuccinylase from E. coli and present the first detailed enzymatic study of this enzyme. Steady-state kinetic experiments demonstrate that the enzyme utilizes a ping-pong kinetic mechanism in which the succinyl group of succinyl-CoA is initially transferred to an enzyme nucleophile before subsequent transfer to homoserine to form the final product, O-succinylhomoserine. The maximal velocity, V/K(succinyl)(-)(CoA), and V/K(homoserine) all exhibited a bell-shaped pH dependence with apparent pK's of 6.6 and approximately 7.9. The enzyme was inhibited by iodoacetamide in a pH-dependent manner, with an apparent pK of the group being inactivated of 6.4. This suggests the presence of an active site cysteine which forms a succinyl-cysteine intermediate during enzymatic turnover. Solvent kinetic isotope effect studies yielded inverse effects of 0.7 on V and 0.61 on V/K in the reverse reaction only. On the basis of these observations, we propose a detailed chemical mechanism for this important member of the acyltransferase family.

Microinjection of anti-p21 antibodies induces senescent Hs68 human fibroblasts to synthesize DNA but not to divide.

Replicative senescence is characterized by irreversible growth arrest and has been defined by four genetic complementation groups. One of these groups is associated with the predominance of underphosphorylated, growth-suppressive retinoblastoma tumor suppressor protein (pRb). Although certain members of the cyclin-dependent kinase (cdk)/cyclin family, some of which phosphorylate pRb, are underexpressed in senescent cells, others are expressed but inactive. This lack of cdk activity and arrest in the G1 phase of the cell cycle is likely attributable to the induction upon senescence of the G1-S cdk/cyclin inhibitors p21 (WAF1/CIP1/Sdi) and p16INK4. In fact, in early presenescent normal diploid fibroblasts in which p21 is inactivated, senescence is bypassed or postponed. Moreover, in senescent cells in which p53 function was inhibited, DNA synthesis was reinitiated, an effect likely attributable, in part, to the dependence of p21 expression on p53. We report here that the apparent inactivation of p21 in senescent human fibroblasts through the introduction of inhibitory alpha-p21 antibodies causes these cells to reenter the S-phase of the cell cycle. The disruption of p21 activity affects the p21-Rb-E2F pathway in that the expression of genes transcriptionally regulated by E2F, such as cyclin A and cdc2, were found to be up-regulated in injected cells. No evidence of cell division was observed. This suggests that p21 plays an important role in the maintenance of senescence and in the inhibition of S-phase progression, but inhibition of p21 activity is insufficient to permit cells to complete the cell cycle.

Structure/function studies on enzymes in the diaminopimelate pathway of bacterial cell wall biosynthesis.

Within the past 18 months work has continued on the structure and mechanisms of enzymes involved in the diaminopimelic acid/lysine biosynthetic pathway. A novel structure has been determined for a PLP-independent epimerase, and structures with bound substrates have been solved for two other enzymes. Additionally, new studies have appeared describing the chemical mechanisms of three enzymes in the pathway.

Cloning of a novel receptor subunit, AcPL, required for interleukin-18 signaling.

We have identified a novel member of the interleukin-1 (IL-1) receptor family, which we have termed AcPL. In transient transfection assays, we were unable to demonstrate a role for AcPL in IL-1-induced activation of NFkappaB. Interleukin-18 (interferon-gamma-inducing factor) is another member of the IL-1 family of cytokines, and it has recently been shown that IL-18 has a weak affinity for IL-1R-rp1. We examined whether AcPL might function alone or in concert with IL-1R-rp1 to mediate IL-18 signaling. We found that both IL-1R-rp1 and AcPL expression were required for induction of NFkappaB activity and for activation of c-Jun N-terminal kinase in response to IL-18. Furthermore, a dominant negative version of AcPL specifically inhibited IL-18 signaling. In vitro immunoprecipitation assays demonstrated that AcPL alone was unable to bind IL-18 with any appreciable affinity. We propose that although IL-1R-rp1 binds the cytokine, IL-1R-rp1 and AcPL proteins are both required for IL-18 signaling, analogous to the requirement for both IL-1R and IL-1RAcP in IL-1-mediated responses.

Hydrolysis of N-succinyl-L,L-diaminopimelic acid by the Haemophilus influenzae dapE-encoded desuccinylase: metal activation, solvent isotope effects, and kinetic mechanism.

Hydrolysis of N-succinyl-L,L-diaminopimelic acid by the dapE-encoded desuccinylase is required for the bacterial synthesis of lysine and meso-diaminopimelic acid. We have investigated the catalytic mechanism of the recombinant enzyme from Haemophilus influenzae. The desuccinylase was overexpressed in Escherichia coli and purified to homogeneity. Steady-state kinetic experiments verified that the enzyme is metal-dependent, with a Km for N-succinyl-L,L-diaminopimelic acid of 1.3 mM and a turnover number of 200 s-1 in the presence of zinc. The maximal velocity was independent of pH above 7 but decreased with a slope of 1 below pH 7. The pH dependence of V/K was bell-shaped with apparent pKs of 6.5 and 8.3. Both L,L- and D,L-diaminopimelic acid were competitive inhibitors of the substrate, but d,d-diaminopimelic acid was not. Solvent kinetic isotope effect studies yielded inverse isotope effects, with values for D2OV/K of 0.62 and D2OV of 0.78. Determination of metal stoichiometry by ICP-AES indicated one tightly bound metal ion, while sequence homologies suggest the presence of two metal binding sites. On the basis of these observations, we propose a chemical mechanism for this metalloenzyme, which has a number of important structurally defined homologues.

Elevated cyclins and cyclin-dependent kinase activity in the rhabdomyosarcoma cell line RD.

An important early event in the differentiation of skeletal muscle cells is exit from the cell cycle, after which full expression of the muscle phenotype occurs. Rhabdomyosarcoma (RMS), a tumor of skeletal muscle origin, expresses a number of muscle-specific proteins, including MyoD; however, these cells fail to arrest or differentiate when cultured in differentiation medium (DM). To determine the basis for the failure of RMS cells to differentiate or arrest, we studied the molecular response of the embryonal RMS cell line, RD, to culture in DM. Under these conditions, the retinoblastoma protein (RB) was primarily in the hyperphosphorylated state. This is in contrast to myoblasts cultured in DM, in which the hypophosphorylated form of RB is exclusively present. Measurements of the expression and activities of cyclin-dependent kinases (cdks) cdk2 and cdk4 indicated that RD cells maintained higher levels than do myoblasts, and the activity and abundance of these proteins did not significantly decrease upon culture in DM in RD cells, as they did in myoblasts. Similarly, elevated expression of cyclins D1, E, and A was observed in RD cells. Interestingly, cdk inhibitors are expressed in RD cells, with p16ink4 expression markedly elevated relative to myoblasts. Ectopic expression of p21cip1, p16ink4, or p27kip1 caused a growth arrest of RD cells but not detectable expression of a myogenic marker. Furthermore, a constitutively active RB protein could also inhibit the growth of RD cells without inducing myogenic differentiation. Taken together, these data suggest that the elevated levels of cdk2 and/or cdk4 observed in RD cells contribute to the inability of RD cells to growth arrest when cultured in DM but that these activities alone are not responsible for the failure of RD cells to differentiate.

Positive regulation of cdc2 gene activity by protein phosphatase type 2A.

Several lines of evidence indicate that serine/threonine protein phosphatases may act as negative regulators of cellular growth. For example, treatment of cells with the tumor-promoter okadaic acid, an inhibitor of certain types of these phosphatases, resulted in the increased expression of several proto-oncogenes, indicating a negative role of the respective phosphatases in gene regulation. However, it was puzzling to find that okadaic acid-treated cells, even in the presence of highly expressed proto-oncogenes, did not proliferate, but were arrested at certain points of the cell cycle. To further analyze this discrepancy, we investigated the involvement of protein phosphatases in the control of other cell cycle regulatory genes, such as cdc2 which encodes an essential cell cycle regulatory kinase. We found that cdc2 gene expression was blocked by okadaic acid, but stimulated by protein phosphatase 2A. Protein phosphatase 2A is shown to be a positive regulator of cdc2 gene activity and to be required for cdc2 expression. Thus, our findings identify protein phosphatase 2A as a positive regulator of a major cell cycle regulatory gene and therefore suggest a stimulatory role of this enzyme in this aspect of cellular growth control.

4-(Fluoromethyl)phenyl phosphate acts as a mechanism-based inhibitor of calcineurin.

The compound 4-(fluoromethyl)phenyl phosphate (FMPP), recently shown to be a mechanism-based inhibitor of prostatic acid phosphatase (Myers, J.K., and Widlanski, T.S. (1993) Science 262, 1451-1453), was examined for its effect on calcineurin. This compound inhibits calcineurin in a time-dependent, first order manner. Inactivation with [3H]FMPP led to a specific labeling of the catalytic subunit with a stoichiometry of 0.75 mol of label/mol of protein. A related substrate, 4-methylphenyl phosphate, is able to protect calcineurin from FMPP-mediated inhibition. Scavenging nucleophiles, such as cysteine, do not affect the rate of inhibition when included in the reaction. In addition, extensive dialysis indicates that inhibition is essentially irreversible. These results demonstrate that FMPP inactivates calcineurin in a mechanism-based fashion by forming a covalent adduct with calcineurin A, the catalytic subunit.

c-Myc cooperates with activated Ras to induce the cdc2 promoter.

Expression of c-myc with constitutively active mutants of the ras gene results in the cooperative transformation of primary fibroblasts, although the precise mechanism by which these genes cooperate is unknown. Since c-Myc has been shown to function as a transcriptional activator, we have examined the ability of c-Myc and activated Ras (H-RasV-12) to cooperatively induce the promoter activity of cdc2, a gene which is critical for cell cycle progression. Microinjection of expression constructs encoding H-RasV-12 and c-Myc along with a cdc2 promoter-luciferase reporter plasmid into quiescent cells led to an increase in cdc2 promoter activity approximately 30 h after injection, a period which coincides with the S-to-G2/M transition in these cells. Expression of H-RasV-12 alone weakly activated the cdc2 promoter, while expression of c-Myc alone had no effect. Mutants of c-Myc lacking either the leucine zipper dimerization domain or the phosphoacceptor site Ser-62 could not cooperate with H-RasV-12 to induce the cdc2 promoter. These mutants also lacked the ability to cooperate with H-RasV-12 to stimulate DNA synthesis. Deletion analysis identified a distinct region of the cdc2 promoter which was required for c-Myc responsiveness. Taken together, these observations suggest a mechanistic link between the molecular activities of c-Myc and Ras and induction of the cell cycle regulator Cdc2.

Inhibition of calcineurin by cyclosporin A-cyclophilin requires calcineurin B.

The interaction of the immunosuppressive complex cyclosporin A-cyclophilin (CsA-CyP) with the Ca2+/calmodulin-dependent protein phosphatase calcineurin is investigated using a recombinant form of the A subunit of calcineurin (rCNA). Only in the presence of purified calcineurin B (CNB) does rCNA show the response of native calcineurin, i.e. 50% inhibition of rCNA phosphatase activity at 6 nM human cyclophilin B and 0.6 microM human cyclophilin A using [32P]casein as substrate, yet stimulation of activity with p-nitrophenyl phosphate as substrate. This study demonstrates that the B subunit is necessary to confer sensitivity of calcineurin to CsA-CyP.

A DNA sequence for the discrimination of Neisseria gonorrhoeae from other Neisseria species.

A 350 base pair Neisseria gonorrhoeae DNA restriction fragment was cloned after subtractive hybridization to Neisseria meningitidis DNA. This restriction fragment hybridized to 105 out of 106 N. gonorrhoeae strains tested. While three N. meningitidis strains did not hybridize to this probe, Neisseria mucosa DNA exhibited cross-hybridization. This particular clone was used to screen a N. gonorrhoeae genomic DNA library. A positive 2.4 kilobase pair clone was shown by DNA sequencing to contain two long open reading frames. One open reading frame did not hybridize to N. mucosa and other Neisseria species, while it retained specificity for the original 105 N gonorrhoeae strains. This open reading frame also showed significant homology to cytosine DNA methyltransferases.