Brain endothelial cells increase the proliferation of Plasmodium falciparum through production of soluble factors

We here describe the novel finding that brain endothelial cells in vitro can stimulate the growth of Plasmodium falciparum through the production of low molecular weight growth factors. By using a conditioned medium approach, we show that the brain endothelial cells continued to release these factors over time. If this mirrors the in vivo situation, these growth factors potentially would provide an advantage, in terms of enhanced growth, for sequestered parasitised red blood cells in the brain microvasculature. We observed this phenomenon with brain endothelial cells from several sources as well as a second P. falciparum strain. The characteristics of the growth factors included: <3 kDa molecular weight, heat stable, and in part chloroform soluble. Future efforts should be directed at identifying these growth factors, since blocking their production or actions might be of benefit for reducing parasite load and, hence, malaria pathology.

Interleukin-18 deficiency and its long-term behavioural and cognitive impacts in a murine model of pneumococcal meningitis

Pneumococcal meningitis often results in death or neurological sequelae, but the underlying pathogenetic mechanisms remain poorly understood. In C57BL/6J mice subjected to intracerebroventricular (icv) challenge with Streptococcus pneumoniae, the chemokine CCL2 and cytokines interferon-γ, interleukin (IL)-1β, IL-6 and tumour necrosis factor were prominently expressed in the brain during the acute phase of the disease. The upregulation of these immune mediators was markedly diminished in IL-18-deficient mice. Uninfected IL-18(-/-) mice exhibited decreases in anxiety phenotype and licking behaviour, and an increase in behavioural habituation, in an automated monitoring system (the IntelliCage). Without antibiotic intervention, a majority of IL-18(+/+) mice developed irreversible disease after icv S. pneumoniae but this was significantly improved by deleting IL-18 gene function. IL-18(+/+) mice cured of pneumococcal meningitis with four doses of ceftriaxone, initiated at 20 h post-inoculation, showed enduring sequelae. These included abnormal behavioural phenotypes featuring diurnal hypoactivity and nocturnal hyperactivity, light phobia and disrupted cognitive function. While the hyperactive phenotype was absent in the corresponding IL-18(-/-) survivors, cognitive impairments and behavioural deficits were still present. Overall, the results suggest that the high levels of cytokines and/or chemokines released after pneumococcal challenge provoked a series of pathological events, ultimately causing acute death. Furthermore, since only a subset of behavioural phenotypes were ameliorated in the pneumococcus-infected IL-18(-/-) mice, the pathological pathways causing mortality may be, at least in part, distinct from those leading to long-term neurological sequelae.

A novel automated test battery reveals enduring behavioural alterations and cognitive impairments in survivors of murine pneumococcal meningitis

Pneumococcal meningitis, caused by Streptococcus pneumoniae infection, is a major form of lethal bacterial meningitis. Survivors are predisposed to developing lifelong disabling sequelae, including cognitive impairment, psychological problems and motor deficits. In our experimental model, ventricular inoculation of 10(5) colony-forming units of S. pneumoniae type 3 caused 90% of mice to develop life-threatening meningitis within 48 h. Antibiotic treatment with ceftriaxone 20 h post infection reduced the incidence of severe meningitis to <10%. At the time of treatment, upregulation of pro-inflammatory cytokines was detected, including interleukin-1β, interleukin-6 and tumour necrosis factor. We evaluated the long-term behavioural and cognitive sequelae in control mice and those surviving meningitis using an automated system (the IntelliCage) in which mice perform a range of behavioural and spatial tasks to obtain water rewards from conditioning units in their home cage. Surviving mice showed a number of altered behaviours relative to controls, including (i) hypoexploration when first exposed to the IntelliCage, (ii) altered activity patterns (fewer visits to conditioning stations during the light phase and more in the dark phase), (iii) avoidance of light (a constant or flashing LED stimulus), (iv) impaired spatial learning (a complex patrolling task), and (v) impaired discrimination reversal learning. Overall these results suggest photophobia and weakened learning ability in post-meningitic mice, particularly on tasks engaging hippocampal and prefrontal neural substrates. This study also demonstrates a standardised and comprehensive battery of tests that can be readily used to investigate neurological sequelae in undisturbed mice residing in a complex home cage environment.

CD40 and OX40 ligand are differentially regulated on asthmatic airway smooth muscle

BACKGROUND

CD40 and OX40 Ligand (OX40L) are cell-surface molecules expressed on airway smooth muscle (ASM) that can enhance inflammatory cell activation and survival. The aim of this study was to examine the effect of tumour necrosis factor-alpha (TNF-alpha) and interferon-gamma (IFN-gamma) on ASM CD40 and OX40L expression.

METHODS

CD40 and OX40L expression on human ASM cells from asthmatic and nonasthmatic donors following stimulation with TNF-alpha and/or IFN-gamma was measured using cell-surface enzyme-linked immunosorbent assay (ELISA) and flow cytometry. Involvement of signalling pathway was investigated with pharmacological inhibitors. Soluble TNF receptor levels were quantified by ELISA.

RESULTS

Interferon-gamma and TNF-alpha synergistically increased CD40 expression to a greater extent on asthmatic than on nonasthmatic ASM. In contrast, IFN-gamma reduced TNF-alpha-induced OX40L expression to a similar extent in both cell types. TNF-alpha and IFN-gamma induced CD40 via nuclear factor-kappaB (NF-kappaB) and signal transducer and activator of transcription-3 in both cell types and modulated OX40L via NF-kappaB and c-Jun N terminal kinase in nonasthmatic cells. Similar effects on the induction of OX40L in asthmatic cells were seen with NF-kappaB, but these were not statistically significant. The reduced OX40L expression with TNF-alpha and IFN-gamma involved extracellular regulated kinase 1/2 activation.

CONCLUSION

Asthmatic ASM may modulate airway inflammation locally by increasing CD40 and OX40L expression in response to cytokines. IFN-gamma may regulate ASM pro-inflammatory actions by differentially modulating ASM CD40 and OX40L expression.

Control of pathogenic CD8+ T cell migration to the brain by IFN-gamma during experimental cerebral malaria

Previous studies have shown that IFN-gamma is essential for the pathogenesis of cerebral malaria (CM) induced by Plasmodium berghei ANKA (PbA) in mice. However, the exact role of IFN-gamma in the pathway (s) leading to CM has not yet been described. Here, we used 129P2Sv/ev mice which develop CM between 7 and 14 days post-infection with PbA. In this strain, both CD4(+) and CD8(+) T cells were involved in the effector phase of CM. When 129P2Sv/ev mice deficient in the IFN-gamma receptor alpha chain (IFN-gammaR1) were infected with PbA, CM did not occur. Migration of leucocytes to the brain at the time of CM was observed in wild type (WT) but not in deficient mice. However, in the latter, there was an accumulation of T cells in the lungs. Analysis of chemokines and their receptors in WT and in deficient mice revealed a complex, organ-specific pattern of expression. Up-regulation of RANTES/CCL5, IP-10/CCL3 and CCR2 was associated with leucocyte migration to the brain and increased expression of MCP-1/CCL2, IP-10/CCL3 and CCR5 with leucocyte migration to the lung. This shows that IFN-gamma controls trafficking of pathogenic T cells in the brain, thus providing an explanation for the organ-specific pathology induced by PbA infection.

Conventional and experimental treatment of cerebral malaria

The most severe complication of Plasmodium falciparum infection is cerebral malaria (CM). Cerebral malaria implies the presence of neurological features, especially impaired consciousness. The treatment of CM is limited to: (i) a few conventional anti-malarial drugs (quinine or artemisinins), (ii) adjunctive treatments (initial stabilisation, blood exchange transfusion, osmotic diuretics and correction of hypoglycaemia, acidosis and hypovolaemia) and (iii) immunomodulation. There are clear procedures concerning treatment of CM, which include the use of the anti-plasmodial drugs. Adjunctive treatments are permissible but there is no single official guideline and immune intervention is a possibility currently being examined in rodent models only. The suggested immunomodulation approach is based on the strong likelihood that CM is the result of an immunopathological process. P. falciparum initiates the multifactorial chain of events leading to lethal CM and, after a certain stage, it is impossible to stop the progression even by using anti-malarial drugs. We present evidence that CM is a result of a dysregulated immune response. Therefore, it might be prevented by early modulation of discrete factors that participate in this process. In experimental systems, some immunomodulators delay or prevent CM without affecting the parasitaemia. Therefore, in the future the ultimate treatment of CM may be a combination of an anti-malarial and an immunomodulator. However, the overall effect of an immunomodulator would need to be carefully examined in view of concomitant infections, especially in malaria endemic areas.

Phagocyte-derived reactive oxygen species do not influence the progression of murine blood-stage malaria infections

Phagocyte-derived reactive oxygen species have been implicated in the clearance of malaria infections. We investigated the progression of five different strains of murine malaria in gp91(phox-/-) mice, which lack a functional NADPH oxidase and thus the ability to produce phagocyte-derived reactive oxygen species. We found that the absence of functional NADPH oxidase in the gene knockout mice had no effect on the parasitemia or total parasite burden in mice infected with either resolving (Plasmodium yoelii and Plasmodium chabaudi K562) or fatal (Plasmodium berghei ANKA, Plasmodium berghei K173 and Plasmodium vinckei vinckei) strains of malaria. This lack of effect was apparent in both primary and secondary infections with P. yoelii and P. chabaudi. There was also no difference in the presentation of clinical or pathological signs between the gp91(phox-/-) or wild-type strains of mice infected with malaria. Progression of P. berghei ANKA and P. berghei K173 infections was unchanged in glutathione peroxidase-1 gene knockout mice compared to their wild-type counterparts. The rates of parasitemia progression in gp91(phox-/-) mice and wild-type mice were not significantly different when they were treated with l-N(G)-methylarginine, an inhibitor of nitric oxide synthase. These results suggest that phagocyte-derived reactive oxygen species are not crucial for the clearance of malaria parasites, at least in murine models.

Needle in a haystack: microdissecting the proteome of a tissue

Laser-assisted microdissection is a recent technology that enables cells to be harvested from tissue sections. Proteins can be extracted from the dissected cells for molecular analysis. This enables the analysis of proteins in specific cell types in an in vivo system. Although quantities of protein obtained from the dissected material can be small, it is possible to use established methods such as Western Blotting and 2D-PAGE, as well as newer technologies such as SELDI-MS, to analyse the proteins. This review describes the applications and technical considerations for using laser-assisted dissected cells in proteomics research.

Haptoglobin and malaria

Haptoglobin gene knockout mice and wild-type controls were infected with Plasmodium berghei ANKA or Plasmodium chabaudi. The peak parasitaemia and parasite burden were higher in Hp-/- mice than in Hp+/+ mice. The increase in spleen weight following malaria infection was smaller in Hp-/- mice than in Hp+/+ animals. The occurrence of cerebral malaria in P. berghei ANKA infection was not different in Hp gene knockout mice and their controls.

Is ischemia involved in the pathogenesis of murine cerebral malaria?

Sequestration of parasitized erythrocytes in the central nervous system microcirculation and increased cerebrospinal fluid lactate are prominent features of cerebral malaria (CM), suggesting that sequestration causes mechanical obstruction and ischemia. To examine the potential role of ischemia in the pathogenesis of CM, Plasmodium berghei ANKA (PbA) infection in CBA mice was compared to infection with P. berghei K173 (PbK) which does not cause CM (the non-CM model, NCM). Cerebral metabolite pools were measured by (1)H nuclear magnetic resonance spectroscopy during PbA and PbK infections. Lactate and alanine concentrations increased significantly at the terminal stage of CM, but not in NCM mice at any stage. These changes did not correlate with parasitemia. Brain NAD/NADH ratio was unchanged in CM and NCM mice at any time studied, but the total NAD pool size decreased significantly in the CM mice on day 7 after inoculation. Brain levels of glutamine and several essential amino acids were increased significantly in CM mice. There was a significant linear correlation between the time elapsed after infection and small, progressive decreases in the cell density/cell viability markers glycerophosphocholine and N-acetylaspartate in CM, indicative of gradual loss of cell viability. The metabolite changes followed a different pattern, with a sudden significant alteration in the levels of lactate, alanine, and glutamine at the time of terminal CM. In NCM, there were significant decreases with time of glutamate, the osmolyte myo-inositol, and glycerophosphocholine. These results are consistent with an ischemic change in the metabolic pattern of the brain in CM mice, whereas in NCM mice the changes were more consistent with hypoxia without vascular obstruction. Mild obstructive ischemia is a likely cause of the metabolic changes during CM, but a role for immune cell effector molecules cannot be ruled out.

Antioxidants inhibit indoleamine 2,3-dioxygenase in IFN-gamma-activated human macrophages: posttranslational regulation by pyrrolidine dithiocarbamate

Induction of the heme-containing indoleamine 2,3-dioxygenase (IDO) by IFN-gamma is implicated in anti-microbial and pro-inflammatory activities of human macrophages. Antioxidants can modulate the expression of immune and inflammatory genes, and pyrrolidine dithiocarbamate (PDTC) is a frequently used antioxidant to inhibit the transcription factor NF-kappaB. Here we show that IFN-gamma treatment of human monocyte-derived macrophages (hMDMs) increased the proportion of oxidized glutathione. PDTC attenuated this increase and inhibited IDO activity, although it increased IDO protein expression and did not affect IDO mRNA expression and enzyme activity directly. Other antioxidants, 2-ME, ebselen, and t-butyl hydroquinone, inhibited IDO protein expression. Similar to PDTC, the heme biosynthesis inhibitor succinylacetone (SA) and the iron-chelator pyridoxal isonicotinoyl hydrazone inhibited cellular IDO activity without affecting protein expression, whereas addition of hemin or the heme precursor delta-aminolevulinic acid increased IDO activity. Also, incubation of IFN-gamma-activated hMDM with delta-[(14)C]-aminolevulinic acid resulted in the incorporation of label into immunoprecipitated IDO, a process inhibited by PDTC and SA. Furthermore, supplementation of lysates from PDTC- or SA-treated hMDM with hemin fully restored IDO activity to control levels, and hemin also reversed the inhibitory action of SA but not PDTC in intact cells. Together these results establish a requirement for de novo heme synthesis for IDO activity in IFN-gamma-activated hMDM. They show that, similar to other pro-inflammatory proteins, the activity of IDO is modulated by antioxidants though in the case of PDTC this takes place posttranslationally, in part by limiting the availability of heme for the formation of holo-IDO.

NADPH oxidase, Nramp1 and nitric oxide synthase 2 in the host antimicrobial response

Using highly conserved, complex enzyme systems, leukocytes utilize the toxic nature of free radical intermediates, derived from oxygen and nitrogen, to control microbial pathogens as part of the innate immune response. Upon activation, NADPH oxidase generates superoxide anion radicals, which in turn give rise to further reactive oxygen intermediates. Similarly, activated nitric oxide synthase 2 catalyses the production of nitric oxide radicals, which leads to the formation of reactive nitrogen intermediates. Nitrogen- and oxygen-centered reactive intermediates can interact to form further reactive species. In addition, presence of the cationic transporter, Nrampl, may exacerbate the effects of these toxic compounds on invading microbes. While each of these antimicrobial systems can operate independently, the combination of their activities is synergistic in the successful containment of almost all invading pathogens. These systems are activated and modulated by microbial products and a series of temporally expressed cytokines. They also feed directly into the initiation of the adaptive immune response, which culminates in lasting specific immunity. The effector molecules, generated in the early innate immune response, are not specific to the invading pathogen and may also cause damage to the host. It is the critical balance of these processes in the initial stages of infection that determines the outcome of infectious disease.

ERK activation and mitogenesis in human airway smooth muscle cells

Asthmatic airways are characterized by an increase in smooth muscle mass, due mainly to hyperplasia. Many studies suggest that extracellular signal-regulated kinases 1 and 2 (ERK1 and ERK2, respectively), one group of the mitogen-activated protein (MAP) kinase superfamily, play a key role in the signal transduction pathway leading to cell proliferation. PGE(2) and forskolin inhibited mitogen-induced ERK activation. Inhibition of MAP kinase kinases 1 and 2 (MEK1 and MEK2, respectively), which are upstream from ERK, with the specific MEK inhibitor U-0126 blocked both cell proliferation and ERK activation. In addition, U-0126 inhibited mitogen-induced activation of p90 ribosomal S6 kinase and expression of c-Fos and cyclin D1, all of which are downstream from ERK in the signaling cascade that leads to cell proliferation. Antisense oligodeoxynucleotides directed to ERK1 and -2 mRNAs reduced ERK protein and cell proliferation. These results indicate that ERK is required for human airway smooth muscle cell proliferation. Thus targeting the control of ERK activation may provide a new therapeutic approach for hyperplasia seen in asthma.

Central nervous system in cerebral malaria: 'Innocent bystander' or active participant in the induction of immunopathology?

Cerebral malaria (CM) is a major life-threatening complication of Plasmodium falciparum infection in humans, responsible for up to 2 million deaths annually. The mechanisms underlying the fatal cerebral complications are still not fully understood. Many theories exist on the aetiology of human CM. The sequestration hypo-thesis suggests that adherence of parasitized erythrocytes to the cerebral vasculature leads to obstruction of the microcirculation, anoxia or metabolic disturbances affecting brain function, resulting in coma. This mechanism alone seems insufficient to explain all the known features of CM. In this review we focus on another major school of thought, that CM is the result of an over-vigorous immune response originally evolved for the protection of the host. Evidence in support of this second hypothesis comes from studies in murine malaria models in which T cells, monocytes, adhesion molecules and cytokines, have been implicated in the development of the cerebral complications. Recent studies of human CM also indicate a role for the immune system in the neurological complications. However, it is likely that multiple mechanisms are involved in the induction of cerebral complications and both the presence of parasitized erythrocytes in the central nervous system (CNS) and immunopathological processes contribute to the pathogenesis of CM. Most studies examining immunopathological responses in CM have focused on reactions occurring primarily in the systemic circulation. However, these also do not fully account for the development of cerebral complications in CM. In this review we summarize results from human and mouse studies that demonstrate morphological and functional changes in the resident glial cells of the CNS. The degree of immune activation and degeneration of glial cells was shown to reflect the extent of neurological complications in murine cerebral malaria. From these results we highlight the need to consider the potentially important contribution within the CNS of glia and their secreted products, such as cytokines, in the development of human CM.

Dichloroacetate (DCA) reduces brain lactate but increases brain glutamine in experimental cerebral malaria: a 1H-NMR study

Recent findings that levels of brain lactate and alanine were elevated in murine cerebral malaria led us to investigate the effect of dichloroacetate (DCA; 60 mg/kg), an activator of pyruvate dehydrogenase, on the levels of brain metabolites, and on the survival of mice infected with Plasmodium berghei ANKA which normally causes lethal cerebral malaria. DCA significantly reduced brain lactate and alanine levels when administered to infected mice, had no effect on the TCA cycle-related metabolites glutamate, GABA and aspartate and was associated with increased brain glutamine levels: 40% of mice thus treated survived the normally lethal infection.

Tissue distribution of indoleamine 2,3-dioxygenase in normal and malaria-infected tissue

An immunohistochemical method was developed, using a polyclonal antibody, to detect the enzyme indoleamine 2,3-dioxygenase (IDO) in normal and malaria-infected tissue. Plasmodium berghei ANKA, a cerebral malaria (CM) model, and P. berghei K173, a non-cerebral malaria (NCM) model, were used. It was found that vascular endothelial cells were the primary site of IDO expression in both models of malaria infection and that this response was systemic, with the vascular endothelium of brain, heart, lung, spleen and uterus all staining positive. These results suggest that IDO is part of a systemic host response to parasite infection. Although high levels of IDO production alone may not cause pathology, it is possible that when its production is combined with other features of CM, such as breakdown of the blood-brain barrier (BBB), metabolites of the kynurenine pathway may be able to influence the otherwise tightly regulated, immunologically privileged site of the CNS and cause some of the symptoms and pathology observed.

The intracellular oxidation of 2',7'-dichlorofluorescin in murine T lymphocytes

Intracellular reactive oxygen species (ROS) production by activated murine T lymphocytes was investigated by analyzing intracellular dichlorofluorescin (DCFH(2)) oxidation in lymph node cells (LNC). An increase in DCFH(2) oxidation in LNC induced by phorbol myristate acetate (PMA) was detected by flow cytometry. It was confirmed that this increase was present in Thy1(+) LNC. We examined the contribution to intracellular DCFH(2) oxidation of ROS released by leukocytes other than T cells present in the LNC suspension. Superoxide dismutase, catalase, and glutathione/glutathione peroxidase inhibited the PMA-induced increase in intracellular DCFH(2) oxidation. Furthermore, PMA failed to elicit DCFH(2) oxidation in LNC isolated from mice lacking a functional NADPH oxidase (gp91(phox) gene knockout mice), but this response could be restored in these cells by the addition of T cell-depleted LNC from wild-type litter mates. This study highlights the necessity for caution in using the DCFH(2) assay to demonstrate specific intracellular ROS production in heterogeneous cell populations. It also suggests that cells other than T cells in lymph node populations may, through production of ROS, influence the intracellular redox state of T lymphocytes.

Reactive changes of retinal microglia during fatal murine cerebral malaria: effects of dexamethasone and experimental permeabilization of the blood-brain barrier

Microglial activation and redistribution toward blood vessels are some of the earliest observable events occurring within the central nervous system (CNS) during fatal murine cerebral malaria (FMCM). To investigate stimuli that might modulate microglial reactivity during FMCM we have performed two experimental manipulations and observed microglial responses in retinal whole mounts. First, to determine whether increased blood-brain barrier (BBB) permeability in the absence of the malaria parasite initiates the microglial changes, BBB function was compromised experimentally by intracarotid injection of arabinose and retinae were examined 12, 24, or 36 hours later. Second, to determine whether the immune response against the malaria parasite modulates microglial reactivity, infected mice were treated with dexamethasone before day 4 postinoculation. This treatment regime ameliorates cerebral complications without affecting parasite growth. We observed that increased BBB permeability was sufficient to elicit thickening of microglial processes and redistribution of microglia toward the vasculature, characteristic of the early stages of FMCM. However, despite the presence of plasma constituents in the CNS for up to 36 hours, microglia with amoeboid and vacuolated morphology were not observed. Dexamethasone treatment inhibited the up-regulation of alpha-D-galactose expression and reactive morphological changes in microglia during FMCM. These results suggest that disruption of the CNS milieu by entry of plasma constituents, or circulating malaria parasites in the absence of an immune response, by themselves are insufficient to induce the reactive microglial changes that are characteristic of FMCM. In addition, dexamethasone-sensitive event(s), presumably associated with immune system activation, occurring within the first few days of malaria infection are essential for the development of reactive microglia and subsequent fatal neurological complications.

Soluble TNF-alpha receptors bind and neutralize over-expressed transmembrane TNF-alpha on macrophages, but do not inhibit its processing

Tumor necrosis factor alpha (TNF-alpha) is initially synthesized as a type II integral membrane protein (transmembrane TNF-alpha) after macrophage activation. In this study we have investigated some aspects of the regulation of expression and biological activity of transmembrane TNF-alpha by both soluble TNF-alpha receptors (sTNF-alphaR) and inhibitors of TNF-alpha processing. We show, using the technique of receptor-mediated ligand precipitation (RMLP), that a dimeric construct of the type I sTNF-alphaR binds to transmembrane TNF-alpha, expressed on the mouse macrophage cell line RAW264.7, under cell culture conditions. This interaction between sTNF-alphaR and transmembrane TNF-alpha does not prevent processing and release of soluble TNF-alpha. A specific hydroxamic acid-based inhibitor of processing, BB1101 (British Biotech), was found to increase the total cellular levels of whole-cell, 26-kDa, precursor TNF-alpha by 2.2-fold. However, the inhibitor increased the levels of precursor TNF-alpha present solely on the cell surface (i.e., transmembrane TNF-alpha) by 5.1- to 7.5-fold. This increase in the levels of transmembrane TNF-alpha on the activated human monocytoid cell line mono mac 6 was associated with a similar (6.7-fold) increase in TNF-alpha-mediated cytotoxicity toward the human adenocarcinoma cell line Colo 205, which is sensitive only to the transmembrane form of TNF-alpha. Mono mac 6 cells, expressing transmembrane TNF-alpha, were found to be killing the Colo 205 target cells through apoptosis. This cytotoxicity could be neutralized by pre-incubating the mono mac 6 cells with either sTNF-alphaR or polyclonal anti-TNF-alpha serum.

Use of fixed cells in cell contact-dependent cytotoxicity assays for TNF: a cautionary report

The use of fixed effector cells or cell membrane preparations in assays to study cell surface TNF-mediated immunological effects has been widespread for more than a decade. The assumption has always been made that observed effects of fixed cells are due to the cell surface TNF molecule. Here we report that paraformaldehyde-fixed, LPS-stimulated RAW264.7 cells release a factor that causes cytotoxicity against TNF sensitive WEHI-164 cells. The factor was neutralized by soluble TNF receptors as well as antibody and could not be removed by ultracentrifugation at 100,000 x g, and is therefore likely to be a form of soluble TNF. This has important implications for the interpretation of these assays, given that cell surface TNF is thought to exert biological effects through a different signaling mechanism than soluble TNF.

A casein kinase I motif present in the cytoplasmic domain of members of the tumour necrosis factor ligand family is implicated in 'reverse signalling'

We have identified a putative signalling feature of the cytoplasmic domains of the tumour necrosis factor (TNF) family members based on available amino acid sequence data. A casein kinase I (CKI) consensus sequence is conserved in the cytoplasmic domain of six of 15 members of the type II integral membrane TNF ligand family. We examined the phosphorylation state of transmembrane tumour necrosis factor-alpha (mTNF) with [32P]orthophosphate labelling and in vitro kinase assays, in lipopolysaccharide-stimulated RAW264.7 cells. A dimeric form of the type I soluble TNF receptor (sTNFR) was found to dephosphorylate mTNF. This effect could be prevented by treatment with phosphatase inhibitors. Recombinant CKI was able to phosphorylate mTNF that had been dephosphorylated by sTNFR ligation in vivo, and this was less effective if phosphatase inhibitors had been used to prevent mTNF dephosphorylation. A mutated form of mTNF, lacking the CKI recognition site, cannot be phosphorylated by the enzyme. Binding of sTNFR to mTNF induced an increase in intracellular calcium levels in RAW264.7 cells, implying the presence of an associated signalling pathway. We predict that this CKI motif is phosphorylated in other TNF ligand members, and that it represents a new insight into the mechanism of 'reverse signalling' in this cytokine family.

Are reactive oxygen species involved in the pathogenesis of murine cerebral malaria?

To investigate the involvement of oxidative tissue damage in the pathogenesis of murine cerebral malaria (CM), brain levels of protein carbonyls, 3,4-dihydroxyphenylalanine (DOPA), o-tyrosine, and dityrosine were measured during Plasmodium berghei ANKA (PbA) and P. berghei K173 (PbK) infections. During PbA infection in a CM model, brain levels of the substances were similar to those in uninfected mice. The role of phagocyte-derived reactive oxygen species in the pathogenesis of CM was examined in gp91phox gene knockout mice. The course of CM in these mice was the same as in their wild type counterparts. To examine whether superoxide production in the central nervous system could have occurred via increased xanthine oxidase activity, brain concentrations of urate were measured in CM mice and in mice infected with PbK (which does not cause CM). Brain urate concentration increased significantly in both groups of mice, suggesting that purine breakdown is not specific to CM. These results indicate that reactive oxygen species probably do not contribute to the pathogenesis of murine CM.

Inhibition of drug-naive and -resistant leukemia cell proliferation by low molecular weight thiols

The aim of these studies was to investigate the ability of cysteamine and its congeners to arrest the proliferation of leukemic cells and to determine the physico-chemical properties responsible for this ability. Fifteen low molecular weight thiol-bearing compounds were shown to arrest the proliferation of CCRF-CEM cells and a methotrexate-resistant subline, with IC50 values between 10(-5) and 10(-4) M. Cysteamine arrested proliferation by slowing the passage of cells through S phase. These cells subsequently resumed cycling, although a proportion went on to die by apoptosis. The antiproliferative action of cysteamine was shown to depend, in part, on H2O2 production. This ability to generate peroxide is shared by many thiol compounds, and molecular modeling indicated that thiol groups were required for the antiproliferative actions of the congeners of cysteamine. Molecular modeling also revealed that the most efficacious antiproliferative agents were those that had their amino acid and thiol moieties separated by an intramolecular distance of 3.17 to 5.9 A, as exemplified by WR 1065 and the aminothiophenols. These findings indicate that thiol-bearing compounds may have some efficacy in the treatment of drug-naive and -resistant leukemia cells.

Radical-induced lipoprotein and plasma lipid oxidation in normal and apolipoprotein E gene knockout (apoE-/-) mice: apoE-/- mouse as a model for testing the role of tocopherol-mediated peroxidation in atherogenesis

Exposure of plasma from apolipoprotein E gene knockout (apoE-/-) and control (CBA or C57BL/6J) mice plasma to a constant rate of aqueous peroxyl radicals (ROO.) resulted in the depletion of ascorbate, urate and alpha-tocopherol (alpha-TOH), with substantial and little lipid peroxidation, respectively. Alpha-TOH levels were 3-times higher in plasma from apoE-/- than control mice and its addition enhanced the oxidizability of control mouse plasma. In apoE-/- mouse plasma, alpha-TOH was associated primarily with very low density lipoprotein (VLDL), whereas in plasma from control mice, the vitamin was located largely in high density lipoproteins. Oxidation of isolated lipoproteins by ROO. resulted in the accumulation of lipid hydroperoxides to an extent that reflected the plasma concentration and alpha-TOH content of the different lipoprotein fractions. Oxidation of 'plasma' reconstituted from components of apoE-/- mice and/or human plasma showed that human and apoE-/- mouse lipoproteins peroxidized with similar kinetics, although the initiation of lipid peroxidation was greater in the presence of mouse than human lipoprotein-deficient plasma. Also, the chain length of lipid peroxidation in apoE-/- mouse plasma after ascorbate depletion appeared to be independent of the rate of ROO. generation. Together, these results show that the ROO. induced peroxidation of plasma lipoproteins in atherogenesis-susceptible apoE-/- mice exhibits some, though not all, features of tocopherol-mediated peroxidation (TMP). Therefore, apoE-/- mice may represent a suitable animal model to test a role for TMP in atherogenesis and the prevention of this disease by anti-TMP agents.

Dramatic changes in oxidative tryptophan metabolism along the kynurenine pathway in experimental cerebral and noncerebral malaria

The pathogenesis of human cerebral malaria (CM) remains unresolved. In the most widely used murine model of CM, the presence of T lymphocytes and/or interferon (IFN)-gamma is a prerequisite. IFN-gamma is the key inducer of indoleamine 2,3-dioxygenase (IDO), which is the catalyst of the first, and rate-limiting, step in the metabolism of tryptophan (Trp) along the kynurenine (Kyn) pathway. Quinolinic acid (QA), a product of this pathway, is a neuro-excitotoxin, like glutamic acid (Glu) and aspartic acid (Asp). Kynurenic acid (KA), also produced from the Kyn pathway, antagonizes the neuro-excitotoxic effects of QA, Glu, and Asp. We therefore examined the possible roles of IDO, metabolites of the Kyn pathway, Glu, and Asp in the pathogenesis of fatal murine CM. Plasmodium berghei ANKA infection was studied on days 6 and 7 post-inoculation (p.i.), at which time the mice exhibited cerebral symptoms such as convulsions, ataxia, coma, and a positive Wooly/White sign and died within 24 hours. A model for noncerebral malaria (NCM), P. berghei K173 infection, was also studied on days 6 and 7 and 13 to 17 p.i. to examine whether any changes were a general response to malaria infection. Biochemical analyses were done by high-pressure liquid chromatography and gas chromatography/mass spectrometry/mass spectrometry (GC/MS/MS). IDO activity was low or absent in the brains of uninfected mice and NCM mice (days 6 and 7 p.i.) and was induced strongly in the brains of fatal murine CM mice (days 6 and 7 p.i.) and NCM animals (days 13 to 17 p.i.). This induction was inhibited greatly by administration of dexamethasone, a treatment that also prevented CM symptoms and death. Furthermore, IDO induction was absent in IFN-gamma gene knockout mice, which were also resistant to CM. Brain concentrations of Kyn, 3-hydroxykynurenine, and the neuro-excitotoxin QA were significantly increased in both CM mice on days 6 and 7 p.i. and NCM mice on days 13 to 17 p.i., whereas an increase in the ratio of brain QA to KA occurred only in the CM mice at the time they were exhibiting cerebral symptoms. Brain concentrations of Glu and Asp were significantly decreased in CM and NCM mice (days 13 to 17 p.i.). The results imply that neuro-excitation induced by QA may contribute to the convulsions and neuro-excitatory signs observed in CM.

Separation of tumor necrosis factor alpha isoforms by two-dimensional polyacrylamide gel electrophoresis

The mouse macrophage cell-line RAW264.7, stimulated with lipopolysaccharide, was used as a model for the study of the production of tumor necrosis factor (TNF) isoforms. TNF is synthesised initially as a 26 kDa transmembrane precursor, which is then processed enzymatically by a protease to release a mature molecule of 17 kDa. Dose-dependent production of transmembrane TNF was assessed by fractionation of cell membranes and Western blot analysis followed by autoradiography and densitometry. Isoforms of both the precursor and mature molecules were separated using two-dimensional (2-D) electrophoresis with immobilised pH gradient 3-10 linear gels as the first dimension. After radiolabelling of cells with 35S, both cell-associated and supernate-associated TNF isoforms were immunoprecipitated. A large number of protein spots were visualised on the 2-D gel map, for both the transmembrane and mature TNF species, more than have been detected previously using one-dimensional sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE). The likelihood that these putative isoforms were the result of differential glycosylation was tested by preincubating the cells with tunicamycin. This had the effect of reducing the number of protein spots, notably the higher molecular weight species. There were a number of precursor TNF isoforms that were unchanged upon tunicamycin treatment and these presumably reflect protein modifications other than glycosylation.

Increased c-fos expression in the brain during experimental murine cerebral malaria: possible association with neurologic complications

Cerebral expression of c-fos protein was studied by immunocytochemistry in murine cerebral malaria (CM) and malaria without cerebral involvement (non-CM). c-fos expression, low in the brains of uninfected mice, increased in frequency, intensity, and distribution during the course of fatal CM (e.g., a 70-fold increase on day 7 after inoculation). These changes paralleled the timing and degree of the neurologic complications and histopathologic changes. Only a slight increase in c-fos expression was detectable in non-CM mice on day 7 after inoculation. Dexamethasone treatment (days 0 and 1 after inoculation) of the CM mice largely prevented the increased cerebral c-fos expression, histopathologic changes, cerebral complications, and death. Increased c-fos expression may indicate the specific neuronal pathways activated by the immunopathologic process of fatal murine CM and could be associated with the behavioral changes and neurologic complications in this model.

Tumor necrosis factor-alpha expression in the brain during fatal murine cerebral malaria: evidence for production by microglia and astrocytes

Fatal murine cerebral malaria (FMCM) is an immunopathological process. The depletion of CD4+ T cells, or the administration of antioxidants or antibodies against certain cytokines, protect the mice against cerebral complications. We previously have shown that astrocytes, microglia, and monocytes play a role in the development of FMCM, suggesting that an active immune response occurs locally within the central nervous system. We now have investigated the functional involvement of glia and monocytes in FMCM by assessing 1) the production, 2) the temporal appearance, and 3) the cellular source of cytokine mRNA and protein in the brain. Brain sections from uninfected and FMCM mice were analyzed for the presence of cytokine mRNA and protein by in situ hybridization and immunohistochemistry. Tumor necrosis factor (TNF)-alpha mRNA and protein were associated with microglia and astrocytes, monocytes, and the cerebral vascular endothelium in FMCM mice but not uninfected animals. TNF-alpha mRNA was first detected several days before the animals showed cerebral symptoms and died. Interleukin (IL)-1 beta mRNA was found in the brains of both uninfected and FMCM mice. However, IL-1 beta protein was associated only with monocytes, the meningeal vascular endothelium, and neurons in the fronto-parietal cortex in the FMCM brains. No IL-4 or IL-6 mRNAs were detected in either group. These results provide the strongest evidence to date that cytokines, in particular TNF-alpha, produced locally in the central nervous system play a role in the pathogenesis of FMCM.

Redox regulation of the mitogen-activated protein kinase pathway during lymphocyte activation

We have previously demonstrated an obligatory requirement for intracellular reactive oxygen species generation during T lymphocyte activation, and have proposed that intracellular reactive oxygen species may act as signalling agents in the regulation of certain cellular processes, for example, during cell cycle entry. To test this hypothesis, we have been interested to determine which, if any, cell cycle entry events are affected by oxidative signalling. In earlier studies, we have identified the transcription factors NF-kappa B and AP-1 as molecular targets for oxidative signalling processes during cell cycle entry, and have shown that oxidative signalling is involved in the regulation of early changes in gene expression during the G0 to G1 phase transition. To extend these initial observations, we have examined the effect of antioxidant treatment on the activity of the mitogen-activated protein kinases erk1 and erk2, as members of a signal transduction pathway known to directly regulate transcription factor function. Using as a probe cysteamine, an aminothiol compound with both antioxidant and antiproliferative activity, we have identified erk2, a key element of the MAP kinase pathway, as being responsive to oxidative signalling during lymphocyte activation. These observations provide further evidence to suggest a role for intracellular oxidant generation as a regulatory mechanism during cell cycle entry, and establish a link between oxidative signalling and other aspects of the intracellular signalling network that is activated in response to mitogenic stimulation.

Compromised blood-nerve barrier, astrogliosis, and myelin disruption in optic nerves during fatal murine cerebral malaria

We examined the optic nerve, as an analogous tissue to brain white matter, to assess possible relationships between changes in the blood-nerve barrier, axonal integrity, and astrocyte morphology in the central nervous system during fatal murine cerebral malaria (FMCM). In the FMCM model, namely, CBA mice infected with Plasmodium berghei ANKA, neurological symptoms begin around day 5 post-inoculation (p.i.) and mice become increasingly ill by day 7 p.i., at which time they lapse into coma and die. Using intravascular perfusion with horseradish peroxidase combined with light and electron microscopy, and GFAP immunohistochemistry, the optic nerves in malaria-infected mice were found to display i) breakdown of the blood-nerve barrier, detectable as early as day 3 p.i. (about 2 days before the onset of neurological symptoms) increasing to peak severity by day 7 p.i.; ii) monocytosis, vascular congestion, and monocyte adherence to the endothelium in the microvasculature during the later stages of the disease process; iii) an increased incidence of patchy axonal demyelination and degeneration, mostly associated with vascular changes and astrogliosis, beginning at day 5 p.i. and more evident by day 7 p.i.; and iv) an increased intensity of GFAP immunostaining, detectable from day 3 p.i. and peaking at day 7 p.i. These optic nerve changes were always seen in the infected individuals, though they varied in intensity. The temporal and anatomical coincidence between the compromised blood-nerve barrier, monocyte adherence to the vascular endothelium, astrocyte changes, neuronal degeneration, and demyelination in the optic nerve in FMCM suggests that these factors are mechanistically inter-related. These findings are consistent with the proposed immunopathological nature of FMCM and provide further evidence for the pivotal role of the CNS microvasculature in the disease process. This is the first investigation of involvement of the optic nerve in FMCM and the first demonstration, to our knowledge, of loss of axonal viability in this condition in any CNS tissue. The observed demyelination is consistent with reports by other workers on such changes in the brain in human cerebral malaria.

Early activation of microglia in the pathogenesis of fatal murine cerebral malaria

Microglia are pluripotent members of the macrophage/monocyte lineage that can respond in several ways to pathological changes in the central nervous system. To determine their role in the pathogenesis of fatal murine cerebral malaria (FMCM) we have conducted a detailed study of the changes in morphology and distribution of retinal microglia during the progression of the disease. Adult CBA/T6 mice were inoculated with Plasmodium berghei ANKA. These mice died 7 days post inoculation (p.i.) with the parasite while exhibiting cerebral symptoms, increased permeability of the blood-brain barrier, and monocyte adherence to the vascular endothelium. Mice were injected i.v. with Monastral blue 2 h prior to sacrifice to identify "activated" monocytes, and their isolated retinae were incubated with the Griffonia simplicifolia (GS) lectin or reacted for the nucleoside diphosphatase enzyme to visualize microglia and the vasculature. Changes in microglial morphology were seen within 2-3 days p.i., that is, at least 3 days prior to the onset of cerebral symptoms and 4 days before death. Morphological changes included retraction of ramified processes, soma enlargement, an increasingly amoeboid appearance, and vacuolation. There was also increased staining intensity and redistribution of "activated" microglia toward retinal vessels, but no increase in density of NDPase-positive cells. The GS lectin only labeled a small population of microglia in the uninfected adult mouse retina. However, there was a striking increase in the focal density of GS-positive microglia during the progression of the disease. Extravasation of monocytes also was observed prior to the onset of cerebral symptoms. These results provide the first evidence that microglial activation is a critical component of the pathological process during FMCM.

Oxidative signalling and gene expression during lymphocyte activation

We previously have demonstrated an obligatory requirement for intracellular reactive oxygen species (ROS) generation during T lymphocyte activation, and have proposed that ROS may act as signalling agents in the regulation of certain cellular processes, for example, during cell cycle entry. In order to test this hypothesis, we have been interested to determine which, if any, cell cycle entry events are affected by oxidative signalling. Given the requirement for both oxidative signalling and altered gene expression during the G0 to G1 phase transition, we have attempted to establish the extent to which oxidative signalling affects global gene expression patterns during cell cycle entry, and to isolate and characterize mRNAs whose expression patterns are responsive to oxidative signalling during this process. Using differential display in a phenotypic screening approach, we have identified 10 mRNA species whose expression patterns were altered in response to inhibition of oxidative signalling during cell cycle entry. The expression patterns of 4 of these 10 mRNAs were unaffected during cell cycle arrest caused by a different mechanism, cyclosporin A-induced interference with calcineurin-mediated signalling events, implying that the altered expression patterns seen were not simply a consequence of cell cycle arrest. This suggests that the expression of these 4 mRNAs is regulated by a mechanism both necessary for cell cycle entry and sensitive to oxidative signalling. RNAse protection assays confirmed that 2 of these 4 mRNAs were indeed responsive to redox regulation. These observations strongly suggest an involvement for oxidative signalling in the regulation of gene expression during the G0 to G1 phase transition, in peripheral blood mononuclear cells at least.

Correlation between enhanced vascular permeability, up-regulation of cellular adhesion molecules and monocyte adhesion to the endothelium in the retina during the development of fatal murine cerebral malaria

The relationships between increased vascular permeability to protein, monocyte adherence to the endothelium, and expression of the cell adhesion molecules, intercellular adhesion molecule-1 (ICAM-1) and vascular cell adhesion molecule-1 (VCAM-1) in the central nervous system microvasculature were studied during the progression of fatal murine cerebral malaria. CBA mice were inoculated with Plasmodium berghei ANKA, and changes in the retinal microvasculature were examined on days 3, 5, and 7 postinoculation (p.i.). Evans blue dye and horseradish peroxidase (HRP) were administered intravenously to assess vascular permeability to macromolecules macroscopically and by light and electron microscopy. ICAM-1 and VCAM-1 expression were examined by immunohistochemistry. HRP leakage into the retinal parenchyma was seen macroscopically at a low level on day 3 p.i., increasing progressively at day 5 (the earliest time at which cerebral symptoms were observed) and day 7 (the day on which animals showed severe behavioral abnormalities and died). The inner retinal vascular plexus showed a slight increase in vascular permeability to intravenous Evans blue at day 3 p.i. and congestion, monocyte adherence to the endothelium, and increased vascular permeability to both Evans blue and HRP at day 7 p.i. Electron microscopic observations were consistent with these findings and also revealed disrupted light junctions and the coating of monocytes and endothelium with HRP at day 7 p.i. Immunohistochemical staining and densitometry showed a progressive increase from day 3 to day 7 p.i. in the densities of ICAM-1 and VCAM-1 on the venular endothelium of the inner retinal vascular plexus, with the appearance of adherent ICAM-1+ monocytes at the terminal stage of the disease. None of the pathological changes associated with the inner retinal plexus were seen at any stage in the outer retinal plexus. These results suggest the following sequence of events in the inner retinal vessels, particularly the venules, during the progression of fatal murine cerebral malaria: 1) a mild increase in vascular permeability at approximately day 3 p.i., 2) a progressive increase in endothelial expression of the cell adhesion molecules ICAM-1 and VCAM-1, commencing at approximately day 3 p.i., 3) monocyte adhesion to the endothelium starting at approximately day 5 p.i., and 4) frank disruption of endothelial integrity at the terminal stage (day 7 p.i.), leading to edema and hemorrhage. Similar changes in cerebral vessels may underlie the neurological complications of the disease.

Redistribution and degeneration of retinal astrocytes in experimental murine cerebral malaria: relationship to disruption of the blood-retinal barrier

To determine whether astrocytes play a critical role in the pathogenesis of experimental murine cerebral malaria (EMCM), we examined changes in astrocyte morphology and distribution, using retinal wholemounts, in three models: a fatal cerebral malaria (CM) model, in which mice die showing cerebral symptoms; a "resolving" model, in which mice exhibit mild cerebral symptoms, but then recover; and a non-CM model, in which cerebral symptoms are not seen. In the fatal model, retinal astrocytes lost their even distribution from day 3 post-inoculation (p.i.) with malaria parasites, progressing to gliosis (day 5 p.i.), well before the onset of cerebral symptoms on day 6-7 p.i. At the terminal stage of the disease there was a loss of astrocyte processes contacting retinal vessels, often along vessel segments containing adherent monocytes. These features occurred in a mild form in the resolving model and were absent in the non-CM models. To investigate the mechanisms underlying these astrocytic changes, we carried out two experimental manipulations. Firstly, since dexamethasone ameliorates cerebral complications in the fatal CM model, the astrocytic response was monitored after dexamethasone treatment on days 0 and 1 p.i., or days 3 and 4 p.i. Second, to determine whether increased blood-retinal barrier (BRB) permeability initiates the astrocyte changes, breakdown of the BRB was induced experimentally by intra-carotid injection of arabinose and astrocyte morphology and distribution were examined 12, 24, and 48 h later. Retinal astrocytes in both the dexamethasone- and the arabinose-treated groups showed loss of even astrocyte distribution but no loss of astrocyte ensheathment of vessels. It is concluded that: i) astrocytes are involved in the pathogenesis of EMCM, since these changes are only prominent in the fatal model and occur substantially before the onset of cerebral symptoms; ii) the initial changes in astrocyte distribution may be a consequence of the increase in BRB permeability; and iii) the immune response triggered by the malaria parasite may be responsible for the loss of astrocyte ensheathment of vessel segments.

Effects of endotoxin and dexamethasone on cerebral malaria in mice

CBA/T6 and DBA/2J mice inoculated with Plasmodium berghei ANKA (PbA) develop cerebral involvement 6-8 days post-inoculation, from which the CBA mice almost invariably die and the DBA mice recover. Dexamethasone (DXM; 80 mg/kg) given to inoculated CBA mice twice, on day 3 and again within 48 h, reduced the cerebral symptoms and prevented death from cerebral malaria. Plasma tumour necrosis factor (TNF) levels, which increased at the time of the cerebral symptoms, were also reduced in these DXM-treated mice. Intravenously administered Evans Blue, a dye which binds to albumin, diffused extensively across the blood-brain barrier only during the period of cerebral symptoms, in proportion to the severity of the cerebral symptoms and the disease. In PbA-infected CBA mice, cerebral symptoms and the amounts of Evans Blue diffusing into the brain tissue were both reduced by DXM treatment, but only if the steroid was given on day 3 and again within 48 h. Endotoxin injected intravascularly into PbA-infected DBA mice after day 5 resulted in an exaggeration of cerebral symptoms and death between days 6 and 9. Plasma TNF and the amount of Evans Blue in the brain parenchyma increased above normal levels in these mice. Endotoxin injections had only minor effects on the severity of the cerebral symptoms in PbA-infected CBA mice and did not cause the animals to die sooner.

Transcription factors as targets for oxidative signalling during lymphocyte activation

We previously have demonstrated a requirement for oxidative events during cell cycle entry in T lymphocytes and have hypothesised that reactive oxygen species may act as intracellular signalling agents during lymphocyte activation. In the current study, cysteamine, an aminothiol compound with antioxidant activity, has been used to further investigate the role of oxidative signalling during lymphocyte activation. Treatment of normal human peripheral blood lymphocytes with cysteamine in vitro was found to inhibit proliferation in a dose-dependent manner, with essentially complete inhibition occurring at a dose of 400 microM. This inhibitory effect was limited to the first 2 h after mitogenic activation, localizing the time-frame of action of cysteamine to within the commitment period. It therefore was of interest to establish which, if any, commitment events were affected by oxidative signalling during cell cycle entry. Taking the IL-2 gene as a candidate, we examined the effect of cysteamine treatment on early gene expression during lymphocyte activation, and on the activity of transcription factors AP-1, NF-kappa B, NF-AT and Oct1, whose functions are required for expression of the IL-2 mRNA. Cysteamine treatment inhibited both expression of the IL-2 mRNA and secretion of IL-2 into the culture medium. The inhibitory effect of cysteamine may be mediated at least in part by an effect on transcription factor function, as the DNA binding activities of AP-1 and NF-kappa B extracted from mitogen-stimulated cells were significantly inhibited by cysteamine treatment. Interestingly, Oct1 and NF-AT DNA binding activity were not affected by cysteamine treatment, suggesting that oxidative signalling processes operate in a selective manner. The identification of regulatory proteins, such as transcription factors, as molecular targets for oxidative signalling provides further evidence to implicate oxidative signalling as being intimately involved in the G0 to G1 phase transition in T lymphocytes.

Vitamin C redox reactions in blood of normal and malaria-infected mice studied with isoascorbate as a nonisotopic marker

It has been suggested that the host antimalarial response depends in part on phagocyte-derived oxidants and that the parasite itself exerts an oxidative stress on its erythrocytic environment. Intraerythrocytic malaria parasites are particularly susceptible to being damaged by oxidative drugs, several of which are under development as chemotherapeutic agents. Thus the antioxidant status and associated regulatory mechanisms of the blood during malaria infection are of great interest. The important antioxidant ascorbate (AH-) and isoascorbate (IAH-), an isomer that does not occur naturally in animals, were found to have similar redox properties. We therefore assessed the usefulness of IAH- as a marker for studies of AH- handling in vivo and in vitro under normal conditions and in murine malaria infection. DHIA added to whole blood from normal or Plasmodium vinckei-infected mice in vitro was rapidly taken up into blood cells and reduced to IAH-. Intracellular IAH- derived from the exogenous DHIA was released into the plasma by blood cells from malaria-infected mice but not those from normal mice. Uptake and reduction of DHIA had no effect on plasma or cellular levels of AH- under these conditions. IAH- injected i.v. into either normal or P. vinckei-infected mice was rapidly cleared in both cases and led to an increase in plasma levels of AH-; this suggested displacement of the latter from some intracellular site, presumably not associated with blood cells. DHIA administered as an intravascular bolus into either normal or malaria-infected mice was rapidly reduced. However, in contrast to the in vitro situation, the concentration of plasma IAH- derived from the injected DHIA was approximately the same in both the infected and control animals. The IAH- so formed disappeared quickly from the plasma. Intravenous injection of DHIA into malaria-infected mice caused a rapid, prolonged increase in the proportion of plasma vitamin C in the form of DHA, whereas in uninfected mice there was a transient decrease in plasma DHA followed by normalisation. The changes in plasma AH- and DHA following IV injection of a single dose of DHA closely paralleled those seen after DHIA administration. These observations indicate that: (i) blood cells from normal and malaria-infected mice take up and reduce DHIA in a similar fashion, but they have different ways of handling the resulting IAH-; (ii) cells other than blood cells are important in the reduction of plasma DHIA and DHA in vivo; (iii) malaria-infected mice are less capable of handling oxidative challenge than normal ones; (iv) in some circumstances IAH- and DHIA may be useful nonisotopic markers for studies of vitamin C handling in vitro and in vivo.

Thiol-bearing compounds selectively inhibit protein kinase C-dependent oxidative events and proliferation in human T cells

The aminothiol cysteamine at 10(-5) to 10(-4) M concentrations inhibited both the proliferation of mitogenically stimulated human peripheral mononuclear cells and the phorbol myristate acetate-mediated oxidation of 2',7'-dichlorofluorescein within these cells. Both 2',7'-dichlorofluorescein oxidation and the proliferative response were maximally sensitive to cysteamine-induced inhibition during the first 2 h of mitogenic stimulation. This period of sensitivity indicates that cysteamine preferentially arrests cells transiting from G0 to G1 and is the first such demonstration, of an early cell cycle site of arrest for this compound. 2,3-Dimercapto-1-propane-sulfonic acid and WR 1065 were found to be more effective than cysteamine in attenuating T cell replication but not N-acetylcysteine. Aminothiols preferentially inhibited the intracellular oxidation of 2',7'-dichlorofluorescein, rather than the activity of protein kinase C, which initiates the oxidation, indicating that oxidative events are one of a number of crucial and independent events required for the successful transition through G0-G1. Since aminothiols affect both lectin and PMA/ionomycin-directed proliferation, these aminothiol-sensitive events may serve to integrate and regulate common pathways in T cell activation.

Amelioration of murine cerebral malaria by dietary restriction

CBA/T6 strain mice infected with Plasmodium berghei ANKA develop cerebral symptoms and die, with mononuclear cell attachment to the cerebral microvascular endothelium, petechial haemorrhages and breakdown of the blood-brain barrier, some 6-7 days post-inoculation. The effects of dietary restriction on this process were examined. Mice were fed ab libitum (Group 1) or their food was restricted to produce body weight loss of 1.0-2.0% (Group 2), 2.5-3.5% (Group 3), 4.0-6.5% (Group 4) or 7.0-9.5% (Group 5) relative to Group 1. Dietary restriction reduced deaths caused by cerebral malaria from 100% in Group 1 to 47% (Group 2), 43% (Group 3), 10% (Group 4) and 53% (Group 5). Restriction of food intake had no effect on (1) the progression of parasitaemia in infected mice (2) changes in haematocrit, spleen weight, total lymph node cell number or (3) peritoneal exudate cell number in either malaria-infected or uninfected mice. P. berghei ANKA infection did not significantly affect the proportion of lymph node leucocytes that were Thy-1+ T cells or CD8+ T cells, but did lead to significant increases in the CD4+ and B cell populations. Dietary restriction alone increased the lymph node CD4+ cell population but did not affect the increase in B cells in malaria-infected mice. P. berghei ANKA infection and dietary restriction together did not lead to increased CD4+ cell numbers in lymph node leucocytes. The in vitro proliferative response to isolated lymph node cells to concanavalin A or phorbol myristate acetate plus ionomycin was measured and found to be identical in all treatment groups.(ABSTRACT TRUNCATED AT 250 WORDS)

Comparisons between microvascular changes in cerebral and non-cerebral malaria in mice, using the retinal whole-mount technique

CBA/T6 mice inoculated with Plasmodium berghei ANKA strain (PbA) exhibited cerebral symptoms and died from cerebral malaria 6-8 days p.i. whereas DBA/2J mice developed (around days 6-9) a non-fatal cerebral malaria, with milder cerebral symptoms, and died between days 15 and 22 from other malaria-related complications. When inoculated with P. berghei K173 (Pb) these mouse strains did not develop cerebral malaria. These mouse/parasite strain combinations were used, in conjunction with the retinal whole-mount technique, to elucidate factors critical in the pathology of murine cerebral malaria. CBA/T6 mice infected with PbA (PbA-CBA mice) demonstrated mild changes in vascular permeability as early as days 2-3, prior to the appearance on day 5 of cerebral symptoms, whereas mice with non-cerebral malaria did not show any vascular permeability changes until the very late stage of the disease (days 14-22). In the PbA infections, progressive deterioration of endothelial barrier properties, demonstrated by Evans' Blue leakage both generally and from specific focal areas, as well as a developing monocytosis and adherence of mononuclear cells to the endothelium of the retinal vessels continued until death (in CBA/T6 mice) or resolution (in DBA/2J mice). Adherent monocytes, particularly in PbA-CBA mice, were associated with reduced Hoechst staining of individual endothelial cells and a banking up proximally of both parasitized and non-parasitized blood cells in the small blood vessels, often with accompanying focal leakage of Evans' Blue from the retinal vessels. The occurrence and severity of these early changes in the microcirculation correlated with the subsequent development of cerebral symptoms. Monocyte margination appeared to be the most significant factor associated with the development of cerebral symptoms.

Redox metabolism of vitamin C in blood of normal and malaria-infected mice

As oxidative mechanisms have been suggested to be part of the host immune reaction against malarial parasites, we investigated the redox metabolism of the antioxidant vitamin C in the blood of control and malaria-infected mice. At the peak of infection (day 6) with the malaria parasite P. vinckei, plasma levels of ascorbate (AH-) were 10.8 +/- 0.9 micrograms/ml compared to 5.7 +/- 0.7 micrograms/ml in control mice, though no significant change was observed in the plasma concentration of dehydroascorbate (DHA). The plasma redox ratio of vitamin C, [AH-]:[DHA], was 7.4 in control mice and 18.5 in infected mice on day 6 post-inoculation. The increased AH- level in plasma of P. vinckei-infected mice was not due to differences in stabilities of either AH- or DHA in plasmas from control or P. vinckei-infected mice. DHA added to plasma was lost rapidly. In contrast, when added to whole blood. DHA was rapidly taken up and reduced to AH by blood cells from both normal mice and P. vinckei-infected mice. Most of the intracellular AH- derived from the exogenously added DHA was released into the plasma by blood cells from the infected but not normal mice. The observed release of AH- into the plasma by blood cells from infected mice was not caused by a plasma factor. Depletion of leukocytes from erythrocytes had no effect on the uptake and reduction of DHA by red blood cells, but the subsequent release of intracellular AH- occurred more rapidly.(ABSTRACT TRUNCATED AT 250 WORDS)