Reperfusion injury following tissue ischemia occurs as a consequence of vaso-occlusion that is initiated by activation of invariant natural killer T (iNKT) cells. Sickle cell disease (SDC) results in widely disseminated microvascular ischemia and reperfusion injury as a result of vaso-occlusion by rigid and adhesive sickle red blood cells. In mice, iNKT cell activation requires NF-κB signaling and can be inhibited by the activation of anti-inflammatory adenosine A2A receptors (A2ARs). Human iNKT cells are divided into subsets of CD4+ and CD4- cells. In this study we found that human CD4+ iNKT cells, but not CD4- cells undergo rapid NF-κB activation (phosphorylation of NF-κB on p65) and induction of A2ARs (detected with a monoclonal antibody 7F6-G5-A2) during SCD painful vaso-occlusive crises. These findings indicate that SCD primarily activates the CD4+ subset of iNKT cells. Activation of NF-κB and induction of A2ARs is concordant, i.e. only CD4+ iNKT cells with activated NF-κB expressed high levels of A2ARs. iNKT cells that are not activated during pVOC express low levels of A2AR immunoreactivity. These finding suggest that A2AR transcription may be induced in CD4+ iNKT cells as a result of NF-κB activation in SCD. In order to test this hypothesis further we examined cultured human iNKT cells. In cultured cells, blockade of NF-κB with Bay 11–7082 or IKK inhibitor VII prevented rapid induction of A2AR mRNA and protein upon iNKT activation. In conclusion, NF-κB-mediated induction of A2ARs in iNKT cells may serve as a counter-regulatory mechanism to limit the extent and duration of inflammatory immune responses. As activated iNKT cells express high levels of A2ARs following their activation, they may become highly sensitive to inhibition by A2AR agonists.
DNA-binding proteins such as bacteriophage repressors belong to the helix-turn-helix family. Ionic interactions drive DNA binding, which means that repressors bind DNA most tightly at low salt concentrations. This raises the question of how gene expression might be regulated in obligate halophiles, which maintain internal salt concentrations of about 5 M. As a model system we have investigated the phage OH, which infects the archaebacterium Halobacterium halobium. Previous genetic data and transcriptional mapping had suggested a region of the phage genome where a repressor might bind. A modified electrophoretic mobility shift assay was used to identify an activity, present only in lysogens, that specifically binds this region. Methylation interference and DNA sequencing were used to identify four similar binding sites, which are arranged so that two copies of a dimer might bind on one face of the DNA helix. Binding of a protein at these sites could block RNA polymerase from initiating a transcript found only during lytic growth. A nearby divergent promoter produces a lysogen-specific transcript, T6, which encodes a member of the helix-turn-helix family of DNA-binding proteins. By expressing the gene in Escherichia coli, we confirmed that T6 specifies the DNA binding activity detected biochemically. The data show that the basic DNA-binding motif of repressors can be adapted even for the unfavorable conditions of high salt concentration.Selective gene expression is primarily dependent on the activity of sequence-specific DNA-binding proteins. The identification, purification, and characterization of such proteins are a major focus of contemporary research in molecular biology. DNA-binding proteins are typically prepared by extracting cells or nuclei by buffers of high salt concentration. This procedure is effective because high salt concentrations dissociate protein-DNA complexes. The thermodynamic origin of this dissociation is in the large electrostatic component of the binding energy (16, 19). Protein-DNA interaction can be considered to be an ion-exchange reaction in which protein binding accompanies counterion displacement. In this situation, increasing the free cation concentration shifts the equilibrium in favor of dissociation. This raises the question of how protein-DNA interaction is driven in organisms with high internal salt concentrations. We have chosen to study the halophilic archaebacterium Halobacterium halobium, which maintains an internal salt concentration matching that of the external environment, typically about 5 M (5).Many DNA-binding proteins, such as bacteriophage repressors, belong to the helix-turn-helix family (14). Extensive genetic (17), biochemical (19), and structural (1, 30) data exist on their interaction with DNA. To take advantage of the previous work on phage repressors
We have examined the expression and structure of several genes belonging to two classes of vegetative specific genes of the simple eukaryote, Dictyostelium discoideum. In amebae grown on bacteria, deactivation of all vegetative specific genes occurred at the onset of development and very little mRNA exists by 8 to 10 hours. In contrast, when cells were grown in axenic broth, the mRNA levels remained constant until a dramatic drop occurred around 10 to 12 hours. Thus, regulation of both classes of genes during the first several hours of development is dependent upon the prior growth conditions. Analysis of genomic clones has resulted in the identification of two V genes, V1 and V18, as ribosomal protein genes. Several other V genes were not found to be ribosomal protein genes, suggesting that in Dictyostelium non-ribosomal protein genes may be coordinately regulated with the ribosomal protein genes. Finally, using deletion analysis we show that the promoters of two of the V genes are composed of a constitutive positive element(s) located upstream of sequences involved in the regulated expression of these genes and within the first 545 upstream bp for V18 and 850 bp for V14. The regions involved in regulated expression were localized between -7 and -222 for V18 and -70 and -368 for V14. The sequences conferring protein synthesis sensitivity were shown to reside between -502 and -61 of the H4 promoter.
We have examined the expression and structure of vegetative specific genes belonging to the V and H gene classes. Both classes of genes are deactivated at the onset of development by a reduction in the rate of transcription. Thus, the genes must be reactivated when the terminally differentiated spores germinate and the resulting amebae return to the vegetative state. During germination, activation of expression of most members of the V gene class was found to parallel the emergence of amoebae from the spore coats. The activation of the V genes did not occur when protein synthesis was inhibited. The timing of activation of the H genes was more heterogeneous and did not parallel emergence. H gene activation occurred even when protein synthesis was inhibited. V4 was found to be the only vegetative specific gene that was responsive to the presence of bacteria. V4 expression was induced by 25-100 fold via transcriptional activation when bacteria were added to amebae growing axenically. Isolation and sequence analysis of the corresponding genomic clones revealed that two V genes, V18 and V1, encode ribosomal proteins. Promoter analysis has delineated the sequences necessary for expression and regulation for several of the V and H genes. In all cases, expression was determined by sequences within the first several hundred base pairs of the transcription start site. For V18 and V14, a positive constitutive element was identified in addition to the sequences involved in regulation. Finally, all of the characterizations and findings are discussed in terms of postulated models for V and H gene expression and regulation.
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