Shift of adenosine kinase expression from neurons to astrocytes during postnatal development suggests dual functionality of the enzyme.

Adenosine is a potent modulator of excitatory neurotransmission, especially in seizure-prone regions such as the hippocampal formation. In adult brain ambient levels of adenosine are controlled by adenosine kinase (ADK), the major adenosine-metabolizing enzyme, expressed most strongly in astrocytes. Since ontogeny of the adenosine system is largely unknown, we investigated ADK expression and cellular localization during postnatal development of the mouse brain, using immunofluorescence staining with cell-type specific markers. At early postnatal stages ADK immunoreactivity was prominent in neurons, notably in cerebral cortex and hippocampus. Thereafter, as seen best in hippocampus, ADK gradually disappeared from neurons and appeared in newly developed nestin- and glial fibrillary acidic protein (GFAP)-positive astrocytes. Furthermore, the region-specific downregulation of neuronal ADK coincided with the onset of myelination, as visualized by myelin basic protein staining. After postnatal day 14 (P14), the transition from neuronal to astrocytic ADK expression was complete, except in a subset of neurons that retained ADK until adulthood in specific regions, such as striatum. Moreover, neuronal progenitors in the adult dentate gyrus lacked ADK. Finally, recordings of excitatory field potentials in acute slice preparations revealed a reduced adenosinergic inhibition in P14 hippocampus compared with adult. These findings suggest distinct roles for adenosine in the developing and adult brain. First, ADK expression in young neurons may provide a salvage pathway to utilize adenosine in nucleic acid synthesis, thus supporting differentiation and plasticity and influencing myelination; and second, adult ADK expression in astrocytes may offer a mechanism to regulate adenosine levels as a function of metabolic needs and synaptic activity, thus contributing to the differential resistance of young and adult animals to seizures.

Protective T-cell-based immunity induced in neonatal mice by a single replicative cycle of herpes simplex virus.

Newborns are very susceptible to infections because their immune systems are not fully developed and react to antigen exposure preferentially with unresponsiveness. UV-inactivated herpes simplex virus type 1 (HSV-1) represents such an antigen and does not induce an immune response in neonates. In contrast, protective T cells were primed in newborn mice by a single replicative cycle of DISC HSV-1 given once within 24 h of birth. Each of the HSV-1-primed CD4(+) or CD8(+) T cells induced in wild-type or interferon-deficient mice conferred resistance to naive animals exposed to a lethal virus challenge. Inactivated HSV-1, injected at variable doses up to 10(4) times that of DISC HSV-1, was ineffective in inducing any detectable immune responses in neonates. Thus, the capacity of HSV-1 to replicate once, but not the number of virus particles per se, was decisive in inducing protective T-cell-associated immunity in newborn mice.

Acetate-specific stress response in acetate-resistant bacteria: an analysis of protein patterns.

Many metabolic byproducts have toxic effects on bacteria, and acetic acid is an excellent model for such molecules. The negative effects of acetate, which include decreased growth rates and specific productivities, appear for Escherichia coli at acetate concentrations lower than 5 g/L. Acetic acid bacteria, however, are naturally resistant to the detrimental effects of acetate in their surroundings; they remain active at acetate levels well over 40 g/L. This study investigated the response to acetate challenges by the naturally acetate-resistant bacteria Acetobacter aceti and Gluconobacter suboxydans to learn more about possible mechanisms of tolerance to otherwise toxic low molecular weight metabolites. Growth studies showed that the resistant bacteria grow more slowly in the presence of acetate but are not slowed nearly so much as is E. coli. In addition, two-dimensional gel electrophoresis (2DE) was applied to study the relative protein patterns of acetate-resistant bacteria during growth in the presence and absence of acetate. In each organism, growth in acetate-containing medium led to elevated levels of many stress response proteins. 2DE analysis of heat-shocked cultures was used to determine which were nonspecific. Elimination of those proteins that were also amplified following heat shock left only eight proteins, here designated acetate-specific stress proteins (Asps), which are overexpressed specifically in response to acetate. Three of these, AspA, AspB, and AspC, appear to be analogous in the two bacterial strains studied, based on their apparent pIs and molecular weights.

Analysis of host-induced response in the rice blast fungus Magnaporthe grisea using two-dimensional polyacrylamide gel electrophoresis.

Two-dimensional (2-D) polyacrylamide gel electrophoresis of proteins was used to study the response of the rice blast fungus to extracts prepared from resistant and susceptible rice cultivars. A protein of molecular mass 31 kDa was induced by a susceptible host extract, while the fungus exposed to extract from the resistant cultivar and the untreated samples did not show the presence of this protein. Levels of this 31 kDa protein increased 30-fold, 72 h after treatment with plant extracts, with the concomitant appearance of at least sixteen other novel proteins. Fungus treated with extracts of resistant host or the untreated samples did not show any of these proteins while the proteins specific to different growth stages appeared as expected. Analysis of the extracellular samples showed induction of a 17 kDa protein after 72 h in the culture treated with susceptible host extract. Since the resistant host extract does not cause induction of any protein it is likely that the proteins induced in response to the susceptible host are expressed during the disease process and/or its establishment. Our study demonstrates usefulness of 2-D analysis in understanding host-pathogen interactions.

Identification of heterotrimeric G proteins in human sperm tail membranes.

Heterotrimeric G proteins play important roles as signal transducing components in various mammalian sperm functions. We were interested in the distribution of G proteins in human sperm tails. Prior to membrane preparation, spermatozoa were separated from contaminating cells which are frequently present in human ejaculates. Enriched human sperm tail membranes were generated by using hypoosmotic swelling and homogenization procedures. Antisera against synthetic peptides were used to identify G proteins in immunoblots. AS 8, an antiserum directed against an amino acid sequence that is found in most G protein alpha-subunits, and A 86, which detects all known pertussis toxin-sensitive alpha-subunits, reacted specifically with a 40-kDa protein. Antisera against individual G protein alpha-subunits failed to detect any specific antigens in enriched tail membranes. AS 36, recognizing the beta 2-subunit of G proteins, identified a 35-kDa protein in sperm tail membranes. Antisera against the 36-kDa beta 1-subunit did not detect any relevant proteins in the membrane fraction. Neither G protein alpha-subunits nor G protein beta-subunits were found in the cytosol. ADP ribosylation of spermatozoal membrane or cytosolic proteins revealed no pertussis toxin-sensitive alpha-subunits. However, membrane preparations of nonpurified human spermatozoa contained alpha i2 subunits, as shown immunologically and by ADP ribosylation; they most probably derived from somatic cells which are frequently present in human ejaculates. Our results stress the fact that spermatozoa need to be purified before sperm membrane preparation to avoid misinterpretations caused by contaminating cells. Furthermore, we suggest that G proteins in membranes of human sperm tails belong to a novel subtype of G protein alpha-subunits; the putative beta-subunit was identified as a beta 2-subunit.

Antigen presentation in the central nervous system. The inhibitory effect of IL-10 on MHC class II expression and production of cytokines depends on the inducing signals and the type of cell analyzed.

Cells of the macrophage lineage are required to cope with bacterial infection and to serve as APC for T lymphocytes. Among the regulatory factors limiting the macrophage response to infection and the expansion of Ag-specific T cells, IL-10 has received recent attention. On monocytes/macrophages, IL-10 has been shown to inhibit the intracellular killing of bacteria, the secretion of cytokines, and the expression of MHC molecules. In the present study we have examined the effect of IL-10 on different APC obtained from the central nervous system. Both, astrocytes and microglial cells are in a resting state and require activation signals to express MHC class II and cytokine genes. Whereas IL-10 profoundly inhibits the IFN-gamma-induced expression of MHC class II Ag on microglial cells, it had no such effects on astrocytes. Nevertheless, IL-10 suppressed the MHC class II- and Ag-dependent proliferative response of T cells in the presence of both types of APC. As shown by the use of anti-IL-10 Abs, endogenously produced IL-10 influenced the function of microglia but not of astrocytes to serve as APC. IL-10 significantly inhibited the LPS-induced production of granulocyte-macrophage-CSF, macrophage-CSF, and IL-6 by both astrocytes and microglial cells. In contrast, the secretion of these cytokines by the two glial cell population was not altered by IL-10 when IL-1 beta, TNF-alpha, or viruses were used as stimuli.

Production of macrophage colony-stimulating factor by astrocytes and brain macrophages.

Morphological hallmarks of inflammatory and degenerative diseases of the brain are hypertrophy of astrocytes and accumulation of macrophages recruited from circulating blood monocytes and/or from resident macrophages, the so-called microglial cells. Recently, production of granulocyte-macrophage colony-stimulating factor (GM-CSF) by astrocytes has been suggested to contribute to the macrophage response. Here we report that in addition to GM-CSF, murine astrocytes also produce macrophage (M)-CSF upon stimulation with tumor necrosis factor alpha, interleukin-1 and lipopolysaccharides. The bioactivity detected in supernatant of astrocytes was characterized using the M-CSF-dependent cell line M-NFS-60 and neutralizing anti-M-CSF antibodies. RNase protection analysis showed M-CSF mRNA already in unstimulated astrocytes without striking up-regulation by the stimuli. Thus, in astrocytes the expression of the M-CSF gene is predominantly regulated at the posttranscriptional level.

Antigen presentation and tumor cytotoxicity by interferon-gamma-treated microglial cells.

In this study microglial cells isolated from brain cell cultures of newborn mice were characterized and investigated for morphology, their responses to growth factors and their functional properties. The microglial cells were phagocytic, contained nonspecific esterase activity and expressed Fc (IgG1/2b) and type-3 complement receptors. Scanning electron microscopy revealed that in analogy to brain tissue two types of microglial cells are present in the cultures: the ameboid and the ramified type which both display similar appearance by transmission electron microscopy. Interleukin 3 and the granulocyte-macrophage colony-stimulating factor were potent growth factors for the cultured microglial cells. The cells were negative for class II antigens (Ia) of the major histocompatibility antigen complex. However, upon treatment with interferon-gamma (IFN-gamma) microglial cells became Ia+ and functioned as antigen-presenting cells when tested on ovalbumin-specific Ia-restricted helper T cells. Furthermore, microglial cells exposed to IFN-gamma and endotoxin developed tumor cell cytotoxicity and produced tumor necrosis factor alpha. Taken together, microglial cells share the characteristics of cells of the macrophage lineage.

Astrocyte-derived interleukin 3 as a growth factor for microglia cells and peritoneal macrophages.

Astrocytes have been shown to release an interleukin 3 (IL 3)-like factor that induces the expression of 20-alpha-hydroxysteroid-dehydrogenase (20-alpha SDH) in nu/nu spleen cells, and the proliferation of the IL 3-dependent cell line 32DCL. We have investigated whether astrocyte-derived IL 3 supports growth of macrophages and their representatives in the brain, the microglia cells. Evidence for intercellular communication between murine astrocytes and macrophages became already detectable in co-culture experiments: astrocytes activated with endotoxin resulted in an increased growth of peritoneal macrophages on the astrocyte monolayer. Biochemical analysis of supernatants of activated astrocytes revealed that the IL 3-like factor that stimulated 32DCL cells and the expression of 20 alpha SDH also served as a growth factor for cultured peritoneal macrophages. The same results were obtained by using microglia cells isolated from primary brain cell cultures of newborn mice, which are characterized by their positive reaction for macrophage markers such as Mac-1 and nonspecific esterase. If secreted by reactive astrocytes in vivo, the IL 3-like factor may contribute to the accumulation of macrophages and microglia cells detected in brain lesions of patients with multiple sclerosis.

Astrocytes of the brain synthesize interleukin 3-like factors.

Interleukin 3 (IL 3) is produced by T lymphocytes and T cell lines, as well as by a myelomonocytic cell line (WEHI-3), and it activates lymphocytes and mast cells, as well as macrophages. Recently we have demonstrated that astrocytes act as immune accessory cells through the secretion of interleukin 1 and the presentation of antigens to T lymphocytes. Here we show that cultured astrocytes from newborn mice release a 30,000 m.w. factor that induces the expression of 20-alpha-hydroxysteroid dehydrogenase in nu/nu spleen cells and the proliferation of the IL 3-dependent cell line 32DCL. An analogous biological activity was detected in supernatant of cultured rat C6 glioma cells. Production of IL 3-like factors by astrocytes of the central nervous system may be essential for development and maintenance of hemo and lymphopoietic cells within inflammatory brain lesions.