Cell Cycle Dysregulation During Hiv Infection: Perspectives of a Target Based Therapy

In vivo selection of CD4(+) T cells transduced with a gamma-retroviral vector expressing a single-chain intrabody targeting HIV-1 tat

We evaluated the potential of an anti-human immunodeficiency virus (HIV) Tat intrabody (intracellular antibody) to promote the survival of CD4(+) cells after chimeric simian immunodeficiency virus (SIV)/HIV (SHIV) infection in rhesus macaques. Following optimization of stimulation and transduction conditions, purified CD4(+) T cells were transduced with GaLV-pseudotyped retroviral vectors expressing either an anti-HIV-1 Tat or a control single-chain intrabody. Ex vivo intrabody-gene marking was highly efficient, averaging four copies per CD4(+) cell. Upon reinfusion of engineered autologous CD4(+) cells into two macaques, high levels of gene marking (peak of 0.6% and 6.8% of peripheral blood mononuclear cells (PBMCs) and 0.3% or 2.2% of the lymph node cells) were detected in vivo. One week post cell infusion, animals were challenged with SHIV 89.6p and the ability of the anti-HIV Tat intrabody to promote cell survival was evaluated. The frequency of genetically modified CD4(+) T cells progressively decreased, concurrent with loss of CD4(+) cells and elevated viral loads in both animals. However, CD4(+) T cells expressing the therapeutic anti-Tat intrabody exhibited a relative survival advantage over an 8- and 21-week period compared with CD4(+) cells expressing a control intrabody. In one animal, this survival benefit of anti-Tat transduced cells was associated with a reduction in viral load. Overall, these results indicate that a retrovirus-mediated anti-Tat intrabody provided significant levels of gene marking in PBMCs and peripheral tissues and increased relative survival of transduced cells in vivo.

Dynamic Green Fluorescent Protein Sensors for High‐Content Analysis of the Cell Cycle

We have developed two dynamic sensors that report cell cycle position in living mammalian cells. The sensors use well-characterized components from proteins that are spatially and temporally regulated through the cell cycle. Coupling of these components to Enhanced Green Fluorescent Protein (EGFP) has been used to engineer fusion proteins that report G1/S and G2/M transitions during the cell cycle without perturbing cell cycle progression. Expression of these sensors in stable cell lines allows high content analysis of the effects of drugs and gene knockdown on the cell cycle using automated image analysis to determine cell cycle position and to abstract correlative data from multiplexed sensors and morphological analysis.

Cytokine and anticytokine therapy in dermatology

Cytokines play a pivotal role in the initiation, propagation and regulation of immunologic responses. They are of utmost importance in the pathogenesis of several diseases, including skin diseases. Using cytokines or cytokine antagonists as immunomodulators exhibiting either immunosuppressive or immunostimulatory effects is a rapidly emerging field and is already adding or is about to add significantly to the therapeutic arsenal for malignant and inflammatory dermatoses. Whereas some cytokine therapies, such as IFN-alpha or IL-2, are well-established in melanoma therapy, there are others in early stages of clinical development. The fascinating aspect is the ongoing transition of the work in basic immunobiology of skin diseases into clinical application. Vice versa, observations in clinical trials are also instrumental in further promoting our knowledge of the pathophysiology of skin diseases. In this review, the current status of cytokine and anticytokine therapy for skin diseases is discussed.