Detrimental role for CD4+ T lymphocytes in murine diffuse peritonitis due to inhibition of local bacterial elimination.

BACKGROUND: Abdominal sepsis due to intestinal leakage of endogenous gut bacteria is a life-threatening condition. In healthy individuals, T lymphocytes have essential functions in balancing the immune response to the commensal gut flora. AIM: To determine how T lymphocytes shape the process of diffuse faecal peritonitis. METHODS: In colon ascendens stent peritonitis (CASP), a clinically relevant mouse model of diffuse peritonitis, the kinetics of systemic T cell activation were investigated by assessment of activation markers. CD4(+) T cells were then depleted with monoclonal antibodies, and survival, bacterial dissemination and cytokine concentrations were measured. T cell receptor signalling was blocked with tacrolimus. RESULTS: In diffuse peritonitis, CD4(+) T cells, both Foxp3(-) and Foxp3(+), became systemically involved within hours and upregulated CTLA-4 and other activation markers. Depletion of the CD4(+) T cells enhanced local bacterial clearance from the peritoneal cavity, reduced bacterial dissemination and improved survival. This was accompanied by increased immigration of granulocytes and macrophages into the peritoneum, indicating that CD4(+) T cells inhibit the local innate immune response. Blockade of T cell receptor (TCR) signalling by tacrolimus did not influence the survival in this peritonitis model, showing that the inhibitory effects of the CD4(+) T lymphocytes were independent of TCR-mediated antigen recognition. CONCLUSION: In diffuse peritonitis caused by commensal gut bacteria the CD4(+) T lymphocytes exert a net negative effect on the local anti-bacterial defence, and thereby contribute to bacterial dissemination and poor outcome.

LBP, CD14, TLR4 and the murine innate immune response to a peritoneal Salmonella infection.

In mice, defense against an intraperitoneal Salmonella infection depends on a vigorous innate immune response. Mutations which lead to an inadequate early response to the pathogen thus identify genes involved in innate immunity. The best studied host resistance factor, NRAMP-1, is an endosomal membrane protein whose loss leads to an inability of the animals to hold the infection in check. However, innate defense against Salmonella is not restricted to mechanisms which directly attack the pathogen within macrophages. Here we have examined the contribution of the LBP, CD14 and TLR4 gene products to innate defense against Salmonella. To this end, we have generated mice which carry a wild-type allele of NRAMP-1, but which are deficient for the LBP, CD14 or TLR4 genes. Loss of any of these genes leads to a susceptibility to Salmonella as dramatic as that seen in animals lacking functional NRAMP-1 protein. This indicates that LBP, CD14 and TLR4 are all critical elements required in the proper induction of this innate defense system.

CHO transfectants produce large amounts of recombinant protein in suspension culture.

Chinese hamster ovary (CHO) cells transfected with various genes are widely used as adherent cell monolayers to produce recombinant proteins. In this report we present a new culture technique for CHO cells transfected with the vector pPOL-DHFR-CD14 using a minifermenter (miniPERM, Heraeus) for the production of recombinant human endotoxin receptor CD14 (rCD14). The transfectants were cultured for 12-17 days under serum-free conditions and formed spheroids. From this system we harvested supernatants containing up to 3.1 mg/ml recombinant CD14 (rCD14). This represents a 200-fold increase of rCD14 yield compared to conventional adherent CHO cell culture.

An unusually stable DNA binding protein can locate its specific binding site in the presence of high concentrations of urea.

A sequence specific DNA binding protein has been demonstrated in extracts of Drosophila melanogaster third instar larval nuclei which binds close to a chromosome-scaffold associated region. This protein has proven difficult to work with because of its strong tendency to aggregate. Here I show that the protein can be readily maintained in solution in the presence of high concentrations of urea. Surprisingly, the protein turns out to be remarkably resistant to denaturation by urea. It is capable of mediating sequence specific DNA binding in the presence of urea at concentrations up to 8M. When incubated in 4M urea the binding activity appears to slowly degrade, but in 1.3M urea the protein is active, soluble and stable over extended periods of time at room temperature. The molecular basis of this unexpected finding must await the purification of the protein. The ability to keep the protein both soluble and active should now permit its isolation.

Restriction enzymes have limited access to DNA sequences in Drosophila chromosomes.

Sequence specific DNA binding proteins in eukaryotic cells must efficiently locate their binding sites in chromosomes. Restriction enzymes provide a simple model system with which to investigate the factors which influence this process. We have used P element mediated transformation to introduce a DNA fragment containing a set of characterized restriction sites into the Drosophila germline. Embryonic nuclei prepared from these transgenic animals were treated with restriction enzymes to probe the accessibility of the target restriction sites. The results show that the insert is within an accessible region of the chromosome and that restriction sites within the inserted sequence can be cut. However, the rate of cutting is biphasic. At each restriction site, a fraction of the chromosomes is cut rapidly after which the remainder is refractory. Similar levels of incomplete cutting are obtained when the same P element construct is examined at a different chromosomal location, when different sequence elements are introduced into the P element vector or when the experiment is carried out on nuclei from different embryonic stages. These results are discussed in terms of how sequence specific DNA binding proteins may locate their genomic targets in vivo.

An ectopic copy of the Drosophila ftz associated SAR neither reorganizes local chromatin structure nor hinders elution of a chromatin fragment from isolated nuclei.

In vitro assays using detergent extracted nuclei allow the operational definition of SARs--specific sequences in the chromosome which are thought to interact with a structural matrix or scaffold. This interaction results in the formation of large stable protein-DNA complexes. We have used P-element transformation to introduce a characterized SAR into the Drosophila genome. The standard assay, which uses detergent extracted nuclei, shows that the ectopic SAR is indeed bound to the scaffold. However, in unextracted nuclei, a chromatin fragment containing the SAR sequence is eluted from the nucleus as readily as a fragment which lacks an SAR. Furthermore, an analysis of the accessibility of the neighbouring chromosomal restriction sites in unextracted nuclei indicates that the introduction of this ectopic SAR does not influence the local structure of chromatin. We conclude that the ectopic SAR site is not attached to a nuclear scaffold or matrix in vivo.

The elusive nuclear matrix.

The structure of the interphase nucleus is a major area of current interest in cell biology. It is thought likely that the nucleus is organised around some form of structural matrix and that this matrix will play a role in processes as diverse as chromosome replication and the integration of gene expression. However, the structure of the matrix within the nucleus has remained elusive, largely because attempts to define it have been dogged by technical problems arising from the great complexity of this organelle. This situation is now being changed by the application of in situ analysis and of molecular genetic methodologies which are opening up this hitherto intractable field.

Idiotypic analysis of the response of C57BL/6 mice to the (4-hydroxy-3-nitrophenyl)acetyl group.

Strain C57BL/6 mice produce a highly restricted primary response to the (4-hydroxy-3-nitrophenyl)acetyl (NP) group. This response is composed of molecules having mu or gamma1 heavy chains and light chains of the lambda type. A guinea pig anti-idiotype was raised to the purified C57BL/6 primary anti-NP immunoglobulin. After suitable absorption, this anti-idiotype was shown to detect markers present on the primary anti-NP immunoglobulin only of those strains which express the Ig-1b allotype. Breeding experiments demonstrated that the marker segregated with the heavy chain linkage group.

Protein component from Drosophila larval nuclei showing sequence specificity for a short region near a major heat-shock protein gene.

Using a nitrocellulose filter binding assay we have detected a protein component in extracts prepared from the nuclei of D. melanogaster third instar larvae which shows sequence-specific binding to a short region on a cloned D. melanogaster DNA segment containing a copy of the major heat-shock protein gene. The specificity of binding was confirmed by direct visualization of the protein DNA complexes in the electron microscope. Protein blotting experiments demonstrated that three polypeptides in the extract were capable of such sequence-specific binding. The protein binding site detected in this cloned sequence lies 800-1000 bp upstream from the presumptive transcription start.

Restriction enzymes permit quantitative determination of defined chromatin structures within the chromosome.

Open chromatin structures, operationally defined as nuclease-hypersensitive sites, are frequently found spanning the controlling regions of genes and they may ensure that trans-acting factors have ready access to their genomic substrates. The rapidity and extent of induction of a gene may be dependent on the probability that its promoter is folded into an open structure. We show that restriction enzymes can be used to estimate the probability that a given promoter region is contained within a defined structure in the chromosome. In the case of the Drosophila major heat-shock-protein gene, we show that an individual promoter element is folded in an accessible form in at least 75% of embryonic chromosomes. This efficient maintenance of the hypersensitive region may be a necessary precondition for a rapid heat-shock response.

Isolation of highly enriched human monocytes from ten ml samples of heparinised whole blood.

A detailed study of the immune dysregulation involved in systemic inflammation requires the analysis of the main inflammatory cells in the circulation - the monocytes. Blood samples available from patients are necessarily restricted so that a rapid and efficient method is required to isolate these cells. Here we present a protocol to isolate blood monocytes in high yield from small samples of heparinised blood. The method yields monocyte preparations with a purity greater than 96%.

Gene expression pattern in human monocytes as a surrogate marker for systemic inflammatory response syndrome (SIRS).

BACKGROUND: Systemic inflammatory response syndrome (SIRS) is a mild inflammatory episode which, in a minority of patients, may deteriorate into septic shock. In the mouse, injection of bacteria or bacterial endotoxin induces systemic inflammation through the activation of blood monocytes, which leads to lethal shock. A number of intervention strategies have been shown to prevent progression to shock in mouse model systems. However, recent clinical trials of a number of these therapeutic strategies in patients have been uniformly disappointing. In contrast to the situation in the mouse models, there may be many different ways to initiate systemic inflammation in patients and not all of them need necessarily involve activation of blood monocytes. If there is no unifying mechanism behind the induction of systemic inflammation in patients and no common rules governing its development, then it is unlikely that generally applicable therapeutic strategies will be found that can prevent progression into shock. MATERIALS AND METHODS: We used differential display to compare gene expression patterns in monocytes of recent-admission multi-trauma patients with clinically diagnosed SIRS to the patterns in monocytes of healthy controls. RESULTS: Of seven differentially displayed bands that were recovered and sequenced, five were associated with SIRS and two were preferentially expressed in the monocytes of healthy controls. CONCLUSION: The data show that monocytes of SIRS patients are in an activation state that is different from that of monocytes from the healthy controls, that monocytes from many individual patients share similar patterns of differentially expressed sequences, and that by this criterion, the multi-trauma SIRS patients are a remarkably coherent group.

Differences in innate defense mechanisms in endotoxemia and polymicrobial septic peritonitis.

Loss, reduction, or enhancement of the ability to respond to bacterial lipopolysaccharide (LPS) has no influence on survival of mice in a model of postoperative polymicrobial septic peritonitis induced by cecal ligation and puncture (CLP). This was demonstrated by using either mice with a defective Tlr4 gene, which encodes the critical receptor molecule for LPS responses, or mice deficient for LPS binding protein (LBP) or mice sensitized to LPS by Propionibacterium acnes. Though interleukin-12 (IL-12) and gamma interferon (IFN-gamma) play an important role in the sensitivity to LPS as well as in the resistance to several infections, loss of these cytokine pathways does not affect survival after CLP. Thus, neutralization of neither endogenous IL-12 nor IFN-gamma altered mortality. In addition, IFN-gamma receptor-deficient mice demonstrated the same sensitivity to CLP as mice with a functional IFN-gamma receptor. However, administration of IFN-gamma at the time of operation or pretreatment of both IFN-gamma-sensitive and IFN-gamma-resistant mice with IL-12 significantly enhanced mortality. This indicates that in the present infection model activation of innate defense mechanisms is not dependent on LPS recognition and does not require endogenous IL-12 or IFN-gamma function. Indeed, exogenous application of these two mediators had deleterious effects.

Gene inactivation in Drosophila mediated by the Polycomb gene product or by position-effect variegation does not involve major changes in the accessibility of the chromatin fibre.

In Drosophila position effect variegation and Polycomb-dependent regulation of homeotic gene expression are phenomena in which genes are inactivated in a clonally inherited manner. In both processes inactivation involves proteins that interact with the chromosome at or close to the position of inactivated genes. Two models have been proposed to explain this form of genetic silencing. In one, cooperative concatamerisation of a large multisubunit protein complex packages the chromatin fibre into a higher order structure, which is inaccessible for the transcription apparatus. In the second, the chromatin fibre is left unaltered but the region to be silenced is assigned to a compartment within the nucleus to which not all transcription factors have access. To distinguish between these types of model we have used the ligation-mediated PCR procedure to quantitate the accessibility of restriction sites in the chromatin fibre in both the active and inactivated forms. By making use of appropriate mutations and tissues we show that the inactivation of genes by Polycomb or by position effect variegation is not accompanied by a substantial change in the accessibility of the fibre. These results favour models in which the inactivation is achieved by sequestration of the silenced region in a particular nuclear compartment rather than by a chromatin packaging model.

Different efficacy of soluble CD14 treatment in high- and low-dose LPS models.

BACKGROUND: About 50% of septic shock cases are attributed to Gram-negative bacteria or their cell wall compound lipopolysaccharide (LPS, endotoxin). An attractive therapeutic strategy could target the binding of LPS to its cellular receptors. In vitro the soluble form of the endotoxin receptor CD14 (sCD14) competitively prevents binding of LPS to membrane-bound CD14 and inhibits LPS-stimulated macrophage responses. METHODS: We tested the in vivo endotoxin-neutralizing capacity of human recombinant sCD14 using a mouse model of shock induced by 8 micrograms g-1 of LPS from Salmonella abortus equi. RESULTS: In this model, treatment with sCD14 reduced mortality if administered before or simultaneously with LPS. However, application of sCD14 had no effect on the secretion of early proinflammatory cytokines and did not protect the animals against the development of apparent shock symptoms and liver injury. sCD14 also failed to prevent LPS-inducible (7.5 ng g-1) liver injury in galactosamine-sensitized mice. CONCLUSION: In line with these findings, sCD14 did not block LPS-induced activation of Kupffer cells in vitro, which might explain why the compound only partially protected in vivo.

Both membrane-bound and soluble forms of CD14 bind to gram-negative bacteria.

Tissue macrophages and their precursors-the blood monocytes-respond rapidly to a bacterial infection with the release of inflammatory mediators. These mediators are involved in the recruitment of phagocytic cells, principally neutrophils, from the blood to the site of infection. To initiate this process macrophages and monocytes must be able to detect the presence of bacteria in a reliable, but nevertheless nonspecific, fashion. It is thought that this is achieved by means of receptors on the cell surface which recognize structures common to many different bacteria. One candidate for such a "pattern recognition element" is the cell surface glycoprotein CD14. CD14 has been shown to bind components of the Gram-positive cell wall and it also binds soluble lipopolysaccharide released from Gram-negative bacteria. In both cases the interaction with CD14 leads to an activation of the cell. Here we show that human peripheral blood monocytes can, in addition, bind intact Gram-negative bacteria in the presence of serum and this process involves CD14. When CD14 expression is induced on the myelomonocytic cell line U937 by treatment with vitamin D3 the cells concomittently acquire the capacity to bind bacteria. Furthermore, a non-monocytic cell line which does not bind bacteria acquires the capacity to do so when transfected with either the human or mouse CD14 gene. This binding can be inhibited by blocking the CD14 receptor with anti-CD14 antibody or by blocking the ligand on the bacteria with soluble CD14. Finally we demonstrate binding of sCD14 to Escherichia coli. We conclude that in the presence of serum both membrane-bound and soluble forms of CD14 can bind to Gram-negative bacteria. This suggests that CD14 may play a role in the detection and elimination of intact bacteria in vivo.

The essential role of lipopolysaccharide-binding protein in protection of mice against a peritoneal Salmonella infection involves the rapid induction of an inflammatory response.

Acute and chronic hyperinflammation are of major clinical concern, and many treatment strategies are therefore directed to inactivating parts of the inflammatory system. However, survival depends on responding quickly to pathogen attack, and since the adaptive immune system requires several days to adequately react, we rely initially on a range of innate defenses, many of which operate by activating parts of the inflammatory network. For example, LPS-binding protein (LBP) can transfer the LPS of Gram-negative bacteria to CD14 on the surface of macrophages, and this initiates an inflammatory reaction. However, the importance of this chain of events in infection is unclear. First, the innate system is redundant, and bacteria have many components that may serve as targets for it. Second, LBP can transfer LPS to other acceptors that do not induce inflammation. In this study, we show that innate defense against a lethal peritoneal infection with Salmonella requires a direct proinflammatory involvement of LBP, and that this is a major nonredundant function of LBP in this infection model. This emphasizes that blocking the LBP-initiated inflammatory cascade disables an essential defense pathway. Any anti-inflammatory protection that may be achieved must be balanced against the risks inherent in blinding the innate system to the presence of Gram-negative pathogens.

Metal-replacement studies in Bacillus stearothermophilus aldolase and a comparison of the mechanisms of class I and class II aldolases.

A comparison of the product-inhibition patterns during cleavage of D-fructose 1,6-diphosphate by aldolases from yeast, rabbit muscle and Bacillus stearothermophilus shows an ordered reaction sequence for all three enzymes, with dihydroxyacetone phosphate the last-leaving product. Addition of Zn2+, Co2+, Fe2+, Mn2+ or Cd2+ ions to the inactive apo-(Bacillus stearothermophilus aldolase) restores activity to different extents, whereas Ni2+, Mg2+ or Cu2+ ions have no effect. The cleavage activity of this aldolase is not enhanced by added K+ ion. The effects of metal replacement on thermal stability, Km and Vmax. are given and the possible role of the metal is discussed in the light of these results.

Mutation of amino acids 39-44 of human CD14 abrogates binding of lipopolysaccharide and Escherichia coli.

As a key receptor for lipopolysaccharide (LPS) on the surface of monocytes and macrophages, the CD14 molecule is primarily involved in non-specific host defense mechanisms against gram-negative bacteria. To delineate the structural basis of LPS binding, 23 mutants in the N-terminal 152 amino acids of human CD14 were generated and stably transfected into CHO cells. In each mutant, a block of five amino acids was substituted by alanine. Reactivity of the mutants with anti-CD14 mAbs, and their ability to interact with LPS and Escherichia coli were tested. 4 of 21 expressed CD14 mutants, ([Ala9-Ala13]CD14, [Ala39-Ala41, Ala43, Ala44]CD14, [Ala51-Ala55]CD14 and [Ala57, Ala59, Ala61-Ala63]CD14), are not recognized by anti-CD14 mAbs that interfere with the binding of LPS to human monocytes. However, only [Ala39-Ala41, Ala43, Ala44]CD14 is unable to react with fluorescein-isothiocyanate-labeled LPS or with FITC-labeled E. coli (055:B5). In addition, [Ala39-Ala4l, Ala43, Ala44]CD14 does not mediate LPS (E. coli 055:B5; 10 ng/ml)-induced translocation of nuclear factor kappaB in CHO-cell transfectants. The results indicate that the region between amino acids 39 and 44 forms an essential part of the LPS-binding site of human CD14.

Differential impact of substitution of amino acids 9-13 and 91-101 of human CD14 on soluble CD14-dependent activation of cells by lipopolysaccharide.

The soluble form of the endotoxin receptor CD14 is required for the LPS-induced activation of cells lacking membrane-bound CD14. It has been shown that a deletion mutant of human CD14 consisting of the N-terminal 152 amino acids has the capacity to mediate the stimulation of different cell types by LPS. To identify the structural domains of the molecule related to this functional property, we screened a set of alanine substitution mutants using CD14-negative U373 astrocytoma cells. We show that 3 of 18 soluble mutants of human CD14 failed to mediate the LPS-induced IL-6 production in U373 cells. These mutants were located in two regions of the molecule (aa 9-13 and 91-101) that are not essential for LPS binding. In addition, the mutants had a reduced capacity to mediate LPS-stimulated IL-6 production in human vascular endothelial and SMC. In contrast, the potential of sCD14(91-94,96)A, and sCD14(97-101)A to signal LPS-induced activation of human PBMC was not significantly reduced. These results show that the regions 9-13 and 91-101 are involved in the sCD14-dependent stimulation of cells by LPS but that the mechanisms by which different cell types are activated may not be identical.