Streamlined design of a self-inactivating feline immunodeficiency virus vector for transducing ex vivo dendritic cells and T lymphocytes.

BACKGROUND: Safe and efficient vector systems for delivering antigens or immunomodulatory molecules to dendritic cells (DCs), T lymphocytes or both are considered effective means of eliciting adaptive immune responses and modulating their type, extent, and duration. As a possible tool toward this end, we have developed a self-inactivating vector derived from feline immunodeficiency virus (FIV) showing performance characteristics similar to human immunodeficiency virus-derived vectors but devoid of the safety concerns these vectors have raised. METHODS: The pseudotyped FIV particles were generated with a three-plasmid system consisting of: the packaging construct, providing Gag, Pol and the accessory proteins; the vector(s), basically containing FIV packaging signal (psi), Rev responsive element, R-U5 region at both ends, and the green fluorescent protein as reporter gene; and the Env plasmid, encoding the G protein of vesicular stomatitis virus (VSV-G) or the chimeric RD114 protein. Both packaging and vector constructs were derived from p34TF10, a replication competent molecular clone of FIV. The pseudotyped particles were produced by transient transfection in the Crandell feline fibroblast kidney (CrFK) or the human epithelial (293T) cell line. RESULTS: To broaden its species tropism, the final vector construct was achieved through a series of intermediate constructs bearing a longer psi, the FIV central polypurin tract sequence (cPPT), or the woodchuck hepatitis post-regulatory element (WPRE). These constructs were compared for efficiency and duration of transduction in CrFK or 293T cells and in the murine fibroblast cell line NIH-3T3. Whereas psi elongation and cPPT addition did not bring any obvious benefit, insertion of WPRE downstream GFP greatly improved vector performances. To maximize the efficiency of transduction for ex-vivo murine DCs and T-lymphocytes, this construct was tested with VSV-G or RD114 and using different transduction protocols. The results indicated that the FIV construct derived herein stably transduced both cell types, provided that appropriate vector makeup and transduction protocol were used. Further, transduced DCs underwent changes suggestive of an induced maturation. CONCLUSION: In contrast to previously described FIV vectors that were poorly efficient in delivering genetic material to DCs and T lymphocytes, the vector developed herein has potential for use in experimental immunization strategies

A Lentiviral Vector-Based, Herpes Simplex Virus 1 (HSV-1) Glycoprotein B Vaccine Affords Cross-Protection against HSV-1 and HSV-2 Genital Infections

Genital herpes is caused by herpes simplex virus 1 (HSV-1) and HSV-2, and its incidence is constantly increasing in the human population. Regardless of the clinical manifestation, HSV-1 and HSV-2 infections are highly transmissible to sexual partners and enhance susceptibility to other sexually transmitted infections. An effective vaccine is not yet available. Here, HSV-1 glycoprotein B (gB1) was delivered by a feline immunodeficiency virus (FIV) vector and tested against HSV-1 and HSV-2 vaginal challenges in C57BL/6 mice. The gB1 vaccine elicited cross-neutralizing antibodies and cell-mediated responses that protected 100 and 75% animals from HSV-1- and HSV-2-associated severe disease, respectively. Two of the eight fully protected vaccinees underwent subclinical HSV-2 infection, as demonstrated by deep immunosuppression and other analyses. Finally, vaccination prevented death in 83% of the animals challenged with a HSV-2 dose that killed 78 and 100% naive and mock-vaccinated controls, respectively. Since this FLY vector can accommodate two or more HSV immunogens, this vaccine has ample potential for improvement and may become a candidate for the development of a truly effective vaccine against genital herpes

In vivo Delivery of Herpes Simplex Type 1 Glycoprotein B Confers Substantial Protection against Genital Herpes

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Feline immunodeficiency virus vector as a tool for preventative strategies against human breast cancer

Breast cancer is the most common type of neoplasia in women. Currently 90% cases are sporadic whereas up to 10% are hereditary and likely due to germ-line mutations in specific genes. Eighty percent hereditary breast cancers are associated with inactivation of breast cancer-associated genes (BRCA) type 1 and 2 by sequential mutations. Loss of functionality of one or both genes greatly increases the risk to develop breast cancer and set the basis for the design of strategies to restore BRCA functions or replace the inactive gene(s) before the emergence of the neoplasia. We have produced a lentiviral vector from the feline immunodeficiency virus (FIV) to transduce wild type BRCA1 into primary mammary cells with a non-functional gene. The system was set up and optimized in tumor cells expressing a truncated gene. Transduced BRCA1 was expressed efficiently and fully functional as demonstrated by the restored ability to repair DNA damages upon exposure of transduced cells to ionizing radiations. This work sets the basis for innovative gene therapy strategies against human breast cancer

W-Band Combined Liquid Crystal and MEMS Reflection Phase Shifter

This paper presents a reflection phase shifter, realized in a combined Liquid Crystal and MEMS switch technology. The phase shifter offers a continuously tunable phase range of 360°, measurements have shown 7 dB losses at 69 GHz

Combined Liquid Crystal and MEMS Phase Shifter: Preliminary Measurement Results

This paper presents preliminary measurement results of a reflection phase shifter realized in a hybrid MEMS and Liquid Crystal technology. The MEMS switch part of the phase shifter is undesirably affected by Liquid Crystal, leading to a higher actuation voltage and the absence of a sudden switching operation. Nevertheless, measurements of the LC filled MEMS switch could achieve the desired 180° phase shift