Viral vectors: a look back and ahead on gene transfer technology.

No matter what their origin, strain and family, viruses have evolved exquisite strategies to reach and penetrate specific target cells where they hijack the cellular machinery to express viral genes and produce progeny particles. The ability to deliver and express genetic information to cells is the basis for exploiting viruses as "Trojan horses" to genetically modify the natural cell target or, upon manipulation of the viral receptor to retarget the virus, to genetically engineer different cell types. This process, known as transduction, is accomplished using viral vectors derived from parental wild type viruses whose viral genes, essential for replication and virulence, have been replaced with the heterologous gene(s) required for cell manipulation. Rearrangement of the viral genome to impede replication or generation of infectious virions but maintaining the ability to deliver nucleic acids has been the object of intense research since the early 1980s. Technological advances and the ever-growing knowledge of molecular virology and virus-host cell relationships have constantly improved the safety profile of viral vectors that are now used in vitro and in vivo to study cellular gene function, correct genetic defects (gene therapy), express therapeutic proteins, vaccinate against infectious agents and tumors, produce experimental animal models, and for other purposes. This review illustrates the strategies used to generate some of the most used viral vectors, and their advantages, limitations and principal applications.

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 FIV 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.

Ferritin as a reporter gene for in vivo tracking of stem cells by 1.5-T cardiac MRI in a rat model of myocardial infarction.

The methods currently utilized to track stem cells by cardiac MRI are affected by important limitations, and new solutions are needed. We tested human ferritin heavy chain (hFTH) as a reporter gene for in vivo tracking of stem cells by cardiac MRI. Swine cardiac stem/progenitor cells were transduced with a lentiviral vector to overexpress hFTH and cultured to obtain cardiospheres (Cs). Myocardial infarction was induced in rats, and, after 45 min, the animals were subjected to intramyocardial injection of ∼200 hFTH-Cs or nontransduced Cs or saline solution in the border zone. By employing clinical standard 1.5-Tesla MRI scanner and a multiecho T2* gradient echo sequence, we localized iron-accumulating tissue only in hearts treated with hFTH-Cs. This signal was detectable at 1 wk after infarction, and its size did not change significantly after 4 wk (6.33 ± 3.05 vs. 4.41 ± 4.38 mm(2)). Cs transduction did not affect their cardioreparative potential, as indicated by the significantly better preserved left ventricular global and regional function and the 36% reduction in infarct size in both groups that received Cs compared with control infarcts. Prussian blue staining confirmed the presence of differentiated, iron-accumulating cells containing mitochondria of porcine origin. Cs-derived cells displayed CD31, α-smooth muscle, and α-sarcomeric actin antigens, indicating that the differentiation into endothelial, smooth muscle and cardiac muscle lineage was not affected by ferritin overexpression. In conclusion, hFTH can be used as a MRI reporter gene to track dividing/differentiating stem cells in the beating heart, while simultaneously monitoring cardiac morpho-functional changes.

From conception to birth: ancient library sources of embryology and women anatomy kept in the Biblioteca Biomedica of the Università degli Studi di Firenze (Biomedical Library of Florence University).

The Biomedical Library of the University of Florence boasts a prestigious group of books collected at first in 1679 at the hospital "Santa Maria Nuova" and then continuously enriched in the course of time up today. The "Antique Collection" consists of 13 incunabola, hundreds of 16th-century books, more than one thousand books on medical subject from the 1600's, about six thousand 18th-century volumes and several large, valuable anatomical atlases. In this paper the most important, curious and fascinating books dealing with human ontogeny (from embryo generation to birth) and with female anatomy (mostly concerning pregnancy and childbirth) are reported in chronological order starting from the work of Hippocrates. Among the ancient sources useful for the reconstruction of the opinions about obstetrics there are also outstanding handbooks specifically edited for midwives. Many of these antique books are especially precious because they embed a great number of didactic pictures, some of which may compete against any modern book of anatomy, embryology and obstetric. Selected images from these books are shown.

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.

Novel approaches to vaccination against the feline immunodeficiency virus.

Inadequate antigen presentation and/or suboptimal immunogenicity are considered major causes in the failure of human immunodeficiency vaccine to adequately protect against wild-type virus. Several approaches have been attempted to circumvent these hurdles. Here we reviewed some recent vaccinal strategies tested against the feline immunodeficiency virus and focused on: (i) improving antigen presentation by taking advantage of the exquisite ability of dendritic cells to process and present immunogens to the immune system; (ii) boosting immune responses with vaccinal antigens presented in a truly native conformation by the natural target cells of infection. Significance of the studies, possible correlates of protection involved, and implications for developing anti-human immunodeficiency virus vaccines are discussed.

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.