To examine a possible association between plasma viremia and interferon-alpha (IFN-alpha) in patients with the acquired immunodeficiency syndrome (AIDS), we performed IFN plasma immunoadsorption by apheresis (IFN-alpha apheresis) in four volunteers with AIDS who had sustained levels of endogenous plasma IFN-alpha. IFN-alpha apheresis with two plasma volume exchanges was performed daily for 5 days. Clinical signs and symptoms and hematologic, virologic, and immunologic parameters were monitored. Two subjects developed anemia from phlebotomy, and one had a catheter++-associated bacteremia. The IFN-alpha apheresis was effective only in transiently removing IFN-alpha: depletion of IFN-alpha led only to its rapid reconstitution. Cell-associated HIV-1 was unchanged, but three of four subjects had a modest decrease in culturable plasma virus burden following the procedures. The recovery of in vivo HIV-1-related IFN-alpha by apheresis allowed its biologic and biochemical characterization. The HIV-1 IFN-alpha showed characteristics on ELISA, western blot, and biologic assays similar to two subspecies of the natural protein. The natural, recombinant, and HIV-1-induced IFN-alpha s demonstrated nearly identical antiviral activities. The HIV-1 IFN-alpha eluted from the column was not acid labile. The inability of large amounts of plasma IFN-alpha found in some patients with AIDS to affect viral burden likely reflects properties of the virus or of host factors independent of IFN-alpha.
We have examined the effects of the antiestrogen tamoxifen (TAM) and the estrogen 17 beta-estradiol (E2) on several estrogen-regulated responses in GH4C1 pituitary tumor cells. After 5 days of treatment with either TAM (1.0 microM) or E2 (1.0 nM), the level of PRL mRNA was markedly increased when measured by the cytosolic dot blot procedure. In contrast, only E2 was able to increase the levels of beta-actin mRNA and cytosolic protein, suggesting that this estrogen may stimulate cell proliferation over the course of treatment. This apparent difference in the abilities of TAM and E2 to stimulate GH4C1 cell proliferation was examined directly. TAM had no effect on cell proliferation as evidenced by its inability to increase cellular DNA or deoxythymidine triphosphate incorporation by nuclei isolated from treated cells. In contrast, E2 stimulated cell proliferation as evidenced by increases in cellular DNA and deoxythymidine triphosphate incorporation by isolated nuclei. The abilities of TAM and E2 to induce progesterone receptor (PR) and PR mRNA were also examined. TAM was unable to increase the levels of PR or PR mRNA, whereas E2 was effective in both of these regards. When added in combination with E2, TAM acted as a classical antiestrogen, partially blocking the induction of PR by E2. To determine whether the inabilities of TAM to stimulate cell proliferation and induce PR were a function of TAM concentration, dose-response experiments were performed. TAM at concentrations ranging from 10(-8)-10(-6) M was effective in inducing PRL mRNA, but at none of the tested concentrations was TAM effective in stimulating cell proliferation or inducing PR.(ABSTRACT TRUNCATED AT 250 WORDS)
Based on radio-ligand binding assays, most of the aZB-adrenoceptors in rat kidney are found in the proximal tubules and are of the aZB-adrenoceptors subtype. To determine more accurately the distribution of the aZB-adrenoceptors in the rat kidney, we studied the expression of a2B-adrenoceptors mRNA in rat kidney slices and microdissected nephron fragments using reverse transcription-polymerase chain reaction (RT-PCR) technique. Sprague-Dawley rat kidney was dissected into cortex, outer medulla and inner medulla. Total RNA was prepared from the kidney slices. Microdissected single nephron segments about 1 mm in length were transferred to tubes containing lysis buffer. RT-PCR was performed using a GeneAmp RNA PCR kit from Perkin-Elmer Corporation. The PCR primers were designed based on the sequences of the third cytoplasmic loop of the rat aZB-gene. After the PCR, the products were analyzed by agarose gel electrophoresis.The specificity of PCR amplified products was examined by restriction endonuclease digestion and internal oligonucleotide hybridization.Our results indicate that aZB-adrenoceptors mRNA is expressed in rat kidney cortex, outer medulla and inner medulla. Microdissection and RT-PCR showed that aZB-adrenoceptor mRNA was expressed in the proximal straight tubules (S3), cortical and medullary thick ascending limbs of Henle (CTALH, MTALH) and cortical and outer medullary collecting tubules (CCT, OMCT). (Hypertens Res 1993; 16: 259-263)
HIV-1-infected brain macrophages participate in neurologic dysfunction through their continual secretion of neurotoxins. We previously demonstrated that astroglial cells activate HIV-1-infected monocytes to produce such neurotoxic activities. In this study, the mechanism underlying these monocyte secretory activities was unraveled and found dependent on HIV-1's ability to prime monocytes for activation. LPS stimulation of HIV-1-infected monocytes resulted in an overexpression of eicosanoids, platelet-activating factor (PAF), and TNF-alpha. This was dependent on the level of HIV-1 infection and monocyte stimulation. Cell to cell interactions between activated virus-infected monocytes and primary human astrocytes reduced monocyte secretions. The capacity of astrocytes to deactivate monocytes was, notably, TGF-beta independent. Although astrocytes constitutively produced latent TGF-beta 2, HIV-1-infected monocytes neither affected TGF-beta 2 production nor converted it into a bioactive molecule. Furthermore, addition of rTGF-beta 1 or rTGF-beta 2 or its Abs to LPS-stimulated monocyte-astrocyte mixtures had no effect on monokine production. In contrast, addition of rIL-10 to LPS-stimulated monocytes produced a dose-dependent decrease in TNF-alpha. IL-10 mRNAs were detected in monocytes, but not astrocytes, following LPS treatment. These results suggest that macrophage activation, a major component of HIV-1 infection in the brain, precipitates neuronal injury by causing virus-infected cells to synthesize neurotoxins. The neurotoxins produced by monocytes are then regulated by astrocytes. Astrocytes therefore, can play either positive or negative roles for disease depending on prior macrophage activation. These findings begin to unravel the cellular control mechanisms that influence cognitive and motor dysfunctions in HIV-1-infected individuals.
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