T Lymphocytes Transduced with a Lentiviral Vector Expressing F12-vif Are Protected from HIV-1 Infection in an APOBEC3G-Independent Manner

The viral infectivity factor (Vif) is an essential component of the HIV-1 infectious cycle. Vif counteracts the action of the cytidine deaminase APOBEC3G (AP3G), which confers nonimmune antiviral defense against HIV-1 to T lymphocytes. Disabling or interfering with the function of Vif could represent an alternative therapeutic approach to AIDS. We have expressed a natural mutant of Vif, F12-Vif, in a VSV-G-pseudotyped lentiviral vector under the Tat-inducible control of the HIV-1 LTR. Conditional expression of F12-Vif prevents replication and spreading of both CXCR4 and CCR5 strains of HIV-1 in human primary T lymphocyte and T cell lines. T cells transduced with F12-Vif release few HIV-1 virions and with reduced infectivity. Several lines of evidence indicate that HIV-1 interference requires the presence of both wild-type and F12-Vif proteins, suggesting a dominant-negative feature of the F12-Vif mutant. Surprisingly, however, the F12-Vif-mediated inhibition does not depend on the reestablishment of the AP3G function

606. Identification of a 45-aa Domain of the F12-Vif Mutant Possessing Anti-HIV Activity

Our previous results have demonstrated that T-cell lines and primary T lymphocytes transduced with a Tat-dependent HIV-based lentiviral vectors expressing the mutant isoform of the vif gene, F12-vif, are protected from HIV-1 infection. F12-Vif is a 192-aa natural variant polypeptide owing 14 unique amino acid substitutions. The substitutions are randomly scattered along the entire sequence with the exception of a 5-aa cluster located at positions 127, 128, and 130|[ndash]|132. None of the 14 aa substitutions is present in the SOCS box that recruits the E3 ubiquitin ligase responsible of APOBEC3G (AP3G) degradation during HIV infection. In line with this notion, we have shown that the antiviral function of F12-Vif is not due to a dominant negative feature of the mutant in regards to the Vif-mediated degradation of AP3G rather to some other unknown means. Therefore, in the effort to elucidate the F12-Vif mechanism of action, we started to identify the protein domain of F12-Vif responsible of HIV-1 inhibition. To this end, we have constructed three chimeric genes (Chim1, Chim2 and Chim3) composed by wild-type and F12-vif regions. T cell lines and cord blood derived CD4+T lymphocytes were transduced with the lentiviral vectors expressing the chimeric genes and then challenged with both X4 and R5 HIV-1 strains. We show that 45 amino acids in the C-terminal domain of the F12-Vif mutant are sufficient to exert anti-viral effect in transduced cells. In contrast to F12-Vif, Chim3 does not allow the rescue of the replication of a vif-deficient HIV-1 in the context of either X4 or R5 tropism in non permissive cells. This specific feature renders Chim3 a truly dominant negative protein more suitable than F12-Vif for an anti-HIV gene therapy approach

Lentiviral Hematopoietic Stem Cell Gene Therapy Benefits Metachromatic Leukodystrophy

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Determination of interference during in vitro pyrogen detection: development and characterization of a cell-based assay

Contamination of pharmaceutical products and medical devices with pyrogens such as endotoxins is the most common cause of systemic inflammation and, in worst cases, of septic shock. Thus, quantification of pyrogens is crucial. The limulus amebocyte lysate (LAL)-based assays are the reference tests for in vitro endotoxin detection, in association with the in vivo rabbit pyrogen test (RPT), according to European Pharmacopoeia (EP 2.6.14), and U.S. Pharmacopoeia (USP ). However, several substances interfere with LAL assay, while RPT is not accurate, not quantitative, and raises ethical limits. Biological assays, as monocyte activation tests, have been developed and included in European Pharmacopoeia (EP 7.0; 04/2010:20630) guidelines as an alternative to RPT and proved relevant to the febrile reaction in vivo. Because this reaction is carried out by endogenous mediators under the transcriptional control of nuclear factor-kappaB (NF-kappaB), we sought to determine whether a NF-kappaB reporter-gene assay, based on MonoMac-6 (MM6) cells, could reconcile the basic mechanism of innate immune response with the relevance of monocytoid cell lines to the organism reaction to endotoxins. This article describes both optimization and characterization of the reporter cells-based assay, which overall proved the linearity, accuracy, and precision of the test, and demonstrated the sensitivity of the assay to 0.24 EU/mL endotoxin, close to the pyrogenic threshold in humans. Moreover, the assay was experimentally compared to the LAL test in the evaluation of selected interfering samples. The good performance of the MM6 reporter test demonstrates the suitability of this assay to evaluate interfering or false-positive samples

Tumor necrosis factor-alpha drives HIV-1 replication in U937 cell clones and upregulates CXCR4

U937 cell clones in which efficient (plus) vs poor (minus) replication of HIV-1 occurs have been described. We evaluated the role of host factors in their differential ability to support HIV-1 replication. Plus clones constitutively produced TNF-alpha and viral replication was inhibited by neutralization of endogenous TNF-alpha. However, HIV-1 replication was strongly upregulated in minus clones by exogenous TNF-alpha, which also further accelerated the kinetics of infection in plus clones. We observed an increased accumulation of proviral DNA within one round of HIV-1 replication following TNF-a treatment of plus cells. This effect was associated with increased surface density of CXCR4 in both plus and minus clones. Our results identify TNF-alpha as one correlate that contributes to the higher ability of U937-plus clones to sustain HIV-1 replication. Furthermore, we suggest that TNF-alpha may affect steps of the viral life cycle that occur earlier than transcription and also enhance HIV-1 replication by increasing the surface density of CXCR