Human immunodeficiency virus type 1 (HIV-1) gene expression is modulated by both viral and cellular factors. A regulatory element in the HIV-1 long terminal repeat known as TAR, which extends from nucleotides ؊18 to ؉80, is critical for the activation of gene expression by the transactivator protein, Tat. RNA transcribed from TAR forms a stable stem-loop structure which serves as the binding site for both Tat and cellular factors. Although TAR RNA is critical for Tat activation, the role that TAR DNA plays in regulating HIV-1 gene expression is not clear. Several studies have demonstrated that TAR DNA can bind cellular proteins, such as UBP-1/LBP-1, which repress HIV-1 gene expression and other factors which are involved in the generation of short, nonprocessive transcripts. In an attempt to characterize additional cellular factors that bind to TAR DNA, a gt11 expression cloning strategy involving the use of a portion of TAR DNA extending from ؊18 to ؉28 to probe a HeLa cDNA library was used. We identified a cDNA, designated TAR DNA-binding protein (TDP-43), which encodes a cellular factor of 43 kDa that binds specifically to pyrimidine-rich motifs in TAR. Antibody to TDP-43 was used in gel retardation assays to demonstrate that endogenous TDP-43, present in HeLa nuclear extract, also bound to TAR DNA. Although TDP-43 bound strongly to double-stranded TAR DNA via its ribonucleoprotein protein-binding motifs, it did not bind to TAR RNA extending from ؉1 to ؉80. To determine the function of TDP-43 in regulating HIV-1 gene expression, in vitro transcription analysis was performed. TDP-43 repressed in vitro transcription from the HIV-1 long terminal repeat in both the presence and absence of Tat, but it did not repress transcription from other promoters such as the adenovirus major late promoter. In addition, transfection of a vector which expressed TDP-43 resulted in the repression of gene expression from an HIV-1 provirus. These results indicate that TDP-43 is capable of modulating both in vitro and in vivo HIV-1 gene expression by either altering or blocking the assembly of transcription complexes that are capable of responding to Tat.
The neuropeptide calcitonin gene-related peptide (CGRP) is a key player in migraine. Although migraine can be treated using CGRP antagonists that act peripherally, the relevant sites of CGRP action remain unknown. To address the role of CGRP both within and outside the CNS, we used CGRP-induced light-aversive behavior in mice as a measure of migraine-associated photophobia. Peripheral (intraperitoneal) injection of CGRP resulted in light-aversive behavior in wild-type CD1 mice similar to aversion seen previously after central (intracerebroventricular) injection. The phenotype was also observed in C57BL/6J mice, although to a lesser degree and with more variability. After intraperitoneal CGRP, motility was decreased in the dark only, similar to motility changes after intracerebroventricular CGRP. In addition, as with intracerebroventricular CGRP, there was no general increase in anxiety as measured in an open-field assay after intraperitoneal CGRP. Importantly, two clinically effective migraine drugs, the 5-HT 1B/D agonist sumatriptan and a CGRP-blocking monoclonal antibody, attenuated the peripheral CGRP-induced light aversion and motility behaviors. To begin to address the mechanism of peripheral CGRP action, we used transgenic CGRP-sensitized mice that have elevated levels of the CGRP receptor hRAMP1 subunit in nervous tissue (nestin/hRAMP1). Surprisingly, sensitivity to low light was not seen after intraperitoneal CGRP injection, but was seen after intracerebroventricular CGRP injection. These results suggest that CGRP can act in both the periphery and the brain by distinct mechanisms and that CGRP actions may be transmitted to the CNS via indirect sensitization of peripheral nerves.
The ability of human immunodeficiency virus-1 (HIV-1) to undergo efficient reverse transcription is dependent on a number of parameters. These include the binding of the tRNA(3)(Lys) to the HIV-1 primer binding site and the subsequent interaction with the heterodimeric reverse transcriptase. Recently, we demonstrated that TAR RNA was also necessary for efficient HIV-1 reverse transcription. Given the fact that the Tat protein is involved in the activation of HIV-1 gene expression in conjunction with TAR, we wished to determine whether Tat might also be involved in the control of HIV-1 reverse transcription. HIV-1 virions deleted in the tat gene were unable to initiate reverse transcription efficiently upon infection of peripheral blood mononuclear cells (PBMCs). This defect was not due to decreased amounts of genomic RNA, reverse transcriptase or other HIV-1 proteins which were incorporated into the virion. Following transfection of wild-type but not mutant tat genes into cell lines producing HIV-1 lacking tat, the virions produced could be complemented for defects in reverse transcription upon subsequent infection of PBMCs. In contrast, the defect in reverse transcription seen with HIV-1 lacking the tat gene could not be complemented when the target cells rather than the producer cells contained tat. Viruses lacking tat were also defective in endogenous assays of reverse transcription, although these viruses contained similar levels of reverse transcriptase. These results indicate that the Tat protein, in addition to regulating the level of gene expression, is also important for efficient HIV-1 reverse transcription.
Migraine is the third most common disease in the world (behind dental caries and tension-type headache) with an estimated global prevalence of 15%, yet its etiology remains poorly understood. Recent clinical trials have heralded the potential of therapeutic antibodies that block the actions of the neuropeptide calcitonin gene-related peptide (CGRP) or its receptor to prevent migraine. Calcitonin gene-related peptide is believed to contribute to trigeminal nerve hypersensitivity and photosensitivity in migraine, but a direct role in pain associated with migraine has not been established. In this study, we report that peripherally administered CGRP can act in a light-independent manner to produce spontaneous pain in mice that is manifested as a facial grimace. As an objective validation of the orbital tightening action unit of the grimace response, we developed a squint assay using a video-based measurement of the eyelid fissure, which confirmed a significant squint response after CGRP injection, both in complete darkness and very bright light. These indicators of discomfort were completely blocked by preadministration of a monoclonal anti-CGRP-blocking antibody. However, the nonsteroidal anti-inflammatory drug meloxicam failed to block the effect of CGRP. Interestingly, an apparent sex-specific response to treatment was observed with the antimigraine drug sumatriptan partially blocking the CGRP response in male, but not female mice. These results demonstrate that CGRP can induce spontaneous pain, even in the absence of light, and that the squint response provides an objective biomarker for CGRP-induced pain that is translatable to humans.
The Tat protein is a transcriptional activator which is required for efficient human immunodeficiency virus 1 (HIV-1) gene expression Tat stimulates HIV-1 transcriptional elongation by increasing the processivity of RNA polymerase II. To address whether Tat-mediated effects on HIV-1 gene expression are due to modulation in the phosphorylation of the RNA polymerase II C-terminal domain (CTD), we developed a purification protocol to identify cellular kinases that are capable of binding to Tat and hyperphosphorylating the RNA polymerase II CTD. A 600 kDa protein complex with these properties was isolated, and specific components were identified using peptide microsequence analysis. This analysis indicated that proteins comprising the multi-subunit TFIIH complex, in addition to several novel factors, were associated with Tat using both in vitro and in vivo analysis. The Tat-associated kinase bound to the activation domain of Tat, and its ability to hyperphosphorylate RNA polymerase II was markedly stimulated by Tat. Furthermore, the addition of the Tat-associated kinase to in vitro transcription assays stimulated the ability of Tat to activate HIV-1 transcription. These results define a cellular kinase complex whose activity is modulated by Tat to result in activation of HIV-1 trancription.
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