Development of methods for somatic cell gene therapy directed against viral diseases, using retroviral vectors carrying the murine or human interferon-beta coding sequence: establishment of the antiviral state in human cells

Reappraisal of biosafety risks posed by PERVs in xenotransplantation

Donor materials of porcine origin could potentially provide an alternative source of cells, tissues or whole organs for transplantation to humans, but is hampered by the health risk posed by infection with porcine viruses. Although pigs can be bred in such a way that all known exogenous microorganisms are eliminated, this is not feasible for all endogenous pathogens, such as the porcine endogenous retroviruses (PERVs) which are present in the germline of pigs as proviruses. Upon transplantation, PERV proviruses would be transferred to the human recipient along with the xenograft. If xenotransplantation stimulates or facilitates replication of PERVs in the new hosts, a risk exists for adaptation of the virus to humans and subsequent spread of these viruses. In a worst-case scenario, this might result in the emergence of a new viral disease. Although the concerns for disease potential of PERVs are easing, only limited pre-clinical and clinical data are available. Small-scale, well-designed and carefully controlled clinical trials would provide more evidence on the safety of this approach and allow a better appreciation of the risks involved. It is therefore important to have a framework of protective measures and monitoring protocols in place to facilitate such initially small scale clinical trials. This framework will raise ethical and social considerations regarding acceptability.

Absence of PKR attenuates the anti-HSV-1 activity of an adenoviral vector expressing murine IFN-beta

A study was undertaken to evaluate the efficacy of an adenoviral vector containing the murine interferon-beta (IFN-beta) transgene (Ad:IFN-beta) against herpes simplex virus type 1 (HSV-1) infection in two transduced cell lines. The transduction of the adenoviral vector efficiency, ranging from 2% to 100%, was dependent on the multiplicity of infection (moi) (0.4-50 plaque-forming units [pfu]/cell). Supernatants from cells transduced with the Ad:IFN-beta but not the adenoviral null vector (Ad:Null) contained biologically active IFN-beta (6.6-106 U/ml depending on the moi). Cells transduced with the Ad:IFN-beta displayed up to 25-fold reduction in viral titers compared with cells transduced with the Ad:Null or nontransduced cell controls. The suppression in viral titer correlated with a reduction in viral gene (alpha, beta, and gamma) and protein expression. The expression of IFN beta-responsive genes, including protein kinase R (PKR) and 2',5'-oligoadenylate synthetase (OAS), were significantly elevated in the Ad:IFN-beta-transduced cells by 12-fold and 25-fold, respectively. However, after infection with HSV-1, a transient but significant drop in PKR but not OAS gene expression was observed 10 h postinfection. The absence of PKR but not RNase L significantly attenuated the antiviral efficacy of the transgene. Collectively, these results illustrate the feasibility of employing a viral vector to deliver a potent antiviral gene to targeted cells without any obvious detriment to the vector itself and support an important role for PKR as a mediator of the anti-HSV-1 activity of type I IFN.

Transfer of human CD4(+) T lymphocytes producing beta interferon in Hu-PBL-SCID mice controls human immunodeficiency virus infection

Beta interferon (IFN-beta) exerts pleiotropic antiretroviral activities and affects many different stages of the human immunodeficiency virus (HIV) infectious cycle in IFN-treated cells. To explore whether transfer of genetically engineered human CD4(+) T cells producing constitutively low amounts of IFN-beta can eradicate HIV in vivo, we developed a new Hu-PBL-SCID mouse model supporting a persistent, replicative HIV infection maintained by periodic reinoculations of activated human CD4(+) T cells. Transferring human CD4(+) T cells containing the IFN-beta retroviral vector drastically reduced the preexisting HIV infection and enhanced CD4(+) T-cell survival and Th1 cytokine expression. Furthermore, in 40% of the Hu-PBL-SCID mice engrafted with IFN-beta-transduced CD4(+) T cells, HIV-1 was undetectable in vivo as well as after cocultivation of mouse tissues with human phytohemagglutinin-stimulated lymphoblasts. These results indicate that a therapeutic strategy based upon IFN-beta transduction of CD4(+) T cells may be an approach to controlling a preexisting HIV infection and allowing immune restoration.

The type I interferon receptor: structure, function, and evolution of a family business

Recent results indicate that coherent models of how multiple interferons (IFN) are recognized and signal selectively through a common receptor are now feasible. A proposal is made that the IFN receptor, with its subunits IFNAR-1 and IFNAR-2, presents two separate ligand binding sites, and this double structure is both necessary and sufficient to ensure that the different IFN are recognized and can act selectively. The key feature is the duplication of the extracellular domain of the IFNAR-1 subunit and the configurational geometry that this imposes on the intracellular domains of the receptor subunits and their associated tyrosine kinases.

Macaque lymphocytes transduced by a constitutively expressed interferon beta gene display an enhanced resistance to SIVmac251 infection

We are developing a method of gene therapy of HIV infection based on the low constitutive expression of an interferon beta (IFN-beta) gene in HIV target cells. Herein we report the first step in the development of a relevant animal model, provided by the macaque (Macaca fascicularis) infected with a pathogenic SIVmac251 isolate. To avoid the possibility of in vivo rejection of macaque lymphocytes expressing Hu IFN-beta, we have PCR-amplified and sequenced the Ma IFN-beta-coding sequence, and placed it under the control of a PstI-NruI 0.6-kb fragment of the murine H-2Kb gene promoter in the MFG-K(b)MaIFNbeta retroviral vector. Lymphocytic CEMX174 cells, transduced by coculture on packaging cells with this construct, harbored a mean of 0.07 to 1.2 copies of the IFN-beta transgene per cell, and were characterized by an IFN production ranging from 75 to 750 units per 5 x 10(5) cells per 3 days. The IFN-beta-transduced populations displayed an enhanced resistance against the pathogenic SIVmac251 isolate. Control experiments showed that the enhanced resistance could not be ascribed to the Ma IFN-beta released during the 3 days of coculture by the packaging cells, or to the mere transduction with a retroviral vector. Macaque lymphocytes transduced by the MFG-K(b)MaIFNbeta retroviral vector by coculture on packaging cells, acquired a mean number of IFN-beta transgene copies per cell ranging from 0.03 to 0.1. Such transduction led to the release of IFN-beta into the culture medium, ranging from 10 to 20 units per 5 x 10(5) cells per 3 days. This increased the anti-SIV resistance of the lymphocytes, as demonstrated by a decreased p27 antigen release into the culture medium, without affecting lymphocyte proliferation.

[Development of an anti-HIV gene therapy based on the antiviral properties of beta interferon]

The aim of our work is to explore the use of IFN-beta for gene therapy in the HIV-infection. Transduction of various HIV target cells with a retroviral vector that carries the Hu-IFN-beta coding sequence under constitutive low expression control, confers resistance to HIV without affecting cell replication or function. After transduction, lymphocytes from HIV-infected patients develop resistance to the endogenous virus, provided the cells are derived from individuals with a CD4 cell count higher than 200 per mm3.

Antiviral activity of autocrine interferon-beta requires the presence of a functional interferon type I receptor

We and others have previously observed that the antiviral effects of autocrine interferon (IFN)-alpha/beta activity cannot be abolished by neutralizing antibodies, even when present to a large excess. This raises the possibility that the major part of autocrine activity is triggered intracellularly, possibly bypassing the transmembrane IFN-alpha/beta receptor. To examine this possibility, cells derived from IFN-alpha/beta Ro/o knockout mice lacking a functional IFN-alpha/beta receptor were stably transformed with pHMB-KbMuIFN beta or pMFG-MuIFN beta plasmids encoding a constitutively expressed murine IFN-beta gene. Four different clones were isolated and examined for resistance to a retrovirus, MFG-LacZ, and to Semliki Forest virus. Despite the production of autocrine IFN-beta at levels inducing high antiviral resistance in control cells, none of the clones displayed antiviral resistance. Thus, despite its failure to be neutralized by potent antiserum, the antiviral activity of autocrine IFN-beta takes place via the transmembrane IFN-alpha/beta receptor, and no additional pathway is involved.

Use of sodium butyrate to enhance production of retroviral vectors expressing CFTR cDNA

Previously, we constructed a retrovirus vector (LCFSN) for transduction and expression of the cDNA encoding the normal human cystic fibrosis transmembrane conductance regulator (CFTR). The titer of virus from amphotropic packaging cells producing the LCFSN vector was low (10(3)-10(4) infectious units/ml). In an attempt to increase virus production, we used sodium butyrate (NaB) to treat murine retrovirus packaging cells producing this vector. NaB treatment increased the production of LCFSN from between 20-fold to greater than 1,000-fold, depending upon the producer clone, thereby resulting in virus titers up to about 1 x 10(7) infectious units/ml. This induction of virus titer could be accounted for, at least in part, by an increase in steady-state levels of full-length vector RNA within the producer cells. With some clonal producer cell lines, lowering the temperature of the virus harvest in combination with NaB treatment resulted in an apparent synergistic increase in virus production. The production of retrovirus vectors containing genes other than CFTR could also be increased by NaB treatment, although the enhancement in titer was modest (2-fold to 10-fold). The increase in virus production was not accompanied by an induction of replication-competent helper virus. NaB treatment also increased the transient production of retroviral vectors following DNA-mediated transfection into packaging cells such that virus titers of greater than 10(6) infectious units/ml could be readily attained.

IFN-alpha 1 gene transfection completely abolishes the tumorigenicity of murine B16 melanoma cells in allogeneic DBA/2 mice and decreases their tumorigenicity in syngeneic C57BL/6 mice

The murine B16 melanoma (H-2b) was transfected with a retroviral vector containing the mouse IFN-alpha 1 gene. IFN-alpha 1-transfected cells produced IFN-alpha in vitro and exhibited an altered phenotype characterized by a decreased rate of multiplication, enhanced expression of H-2 antigens, an antiviral state to VSV, and decreased pigmentation. Control and IFN-alpha 1-transfected cells were tested for their ability to grow in syngeneic (H-2b) C57Bl/6 and allogeneic (H-2d) DBA/2 mice. IFN-alpha 1-producing B16 clones were less tumorigenic after s.c., i.p., and i.v. routes of injection than IFN-non-producer B16 clones in syngeneic C57Bl/6 mice. IFN-alpha 1-producing B16 cells were, however, totally rejected by allogeneic DBA/2 mice regardless of the routes and inocula tested, while control B16 cells grew in and killed DBA/2 mice. The total rejection of IFN-alpha 1-transfected B16 cells in allogeneic mice appeared to be dependent on T cells as these cells grew in DBA/2 nude mice. Incubation of IFN-alpha-producing clones with anti-mouse IFN-alpha/beta prior to injection into C57Bl/6 mice did not enhance their tumorigenicity. Likewise, injection of C57Bl/6 and DBA/2 mice with antibody to IFN-alpha/beta did not enhance the tumorigenicity of IFN-alpha 1-transfected cells. C57Bl/6 mice immunized with irradiated IFN-alpha 1 cells were only slightly protected against a subsequent challenge with parental B16 cells. In contrast, DBA/2 mice immunized with irradiated IFN-alpha 1 cells exhibited tumor-specific, long-lasting immunity to subsequent challenge with parental B16 cells.

Biotechnology domain

Biotechnology and the use of biologically based agents for the betterment of mankind is an active field which is founded on the interaction between many basic sciences. This is achieved in coordination with engineering and technology for scaling up purposes. The application of modern recombinant DNA technology gave momentum and new horizons to the field of biotechnology both in the academic setting and in industry. The applications of biotechnology are being used in many fields including agriculture, medicine, industry, marine science and the environment. The final products of biotechnological applications are diverse. In the medical applications of biotechnology, for example, the field has been evolving in such a way that the final product could be a small molecule (e.g. drug/antibiotic) that can be developed based on genetic information by drug design or drug screening using a cloned and expressed target protein.

Consequences of stable transduction and antigen-inducible expression of the human interleukin-7 gene on tetanus-toxoid-specific T cells

Interleukin-7 (IL-7) has previously been shown to increase antigen-specific immune responses; the effect of IL-7 on human antigen-specific T cell lines has not directly been addressed. A tetanus-toxoid (TT)-specific T cell line exhibited increased proliferation in the presence of exogenous IL-7, suggesting that IL-7 may be useful in the potentiation of immune responses to defined microbial antigens. Murine retroviral vectors encoding the human IL-7 gene and the neomycin phosphotransferase gene (neoR) were packaged into murine retroviral particles, and supernatants containing these retroviral vectors were used to infect a CD4+ lymphoblastoid cell line. Stable integration of the retroviral vector and constitutive expression of the IL-7 gene were observed. Successful IL-7 gene transduction into TT-specific T cells was also accomplished. Detection of neoR DNA sequences and expression of IL-7-specific mRNA increased with selection in geneticin. Production of IL-7 in these cells was induced by exposure to TT. Production of IL-4, IL-6, and interferon-gamma (IFN-gamma) was detected after antigenic stimulation; there was, however, no effect of IL-7 on the pattern or kinetics of cytokine production by these cells. Human IL-7 transduced cells showed greater proliferation to TT than control T cells, particularly at subthreshold TT concentrations. These dta imply that genetic modification of antigen-specific T cells may be a plausible strategy for the study and manipulation of the immune responses to microbial pathogens.

Blocking of retroviral infection at a step prior to reverse transcription in cells transformed to constitutively express interferon beta

We are developing methods for somatic-cell gene therapy directed against infection with human immunodeficiency virus, by enhancing antiviral resistance of target cells through the constitutive production of autocrine interferon (IFN). Using the human IFN-beta coding sequence under the constitutive low-expression control of a 0.6-kb murine H-2Kb promoter-fragment, we have constructed a retroviral vector, HMB-KbHuIFN beta, and have transformed cells of the T98G human neuroblastoma line, the U-937 human promonocytic line, and the CEM human lymphocytic line. These human IFN-beta-transformed cell populations have acquired a low, constitutive production of human IFN, while replicating at a rate similar to that of untransformed cells and of cells transformed with the control vector carrying a human IFN-beta sequence encoding an inactive, mutated protein. In the three different cell populations tested, transformation with the HMB-KbHuIFN beta vector resulted in a 1.3-2.3 log10 reduction in the number of cells infected with a defective amphotropic MFG-LaZ retrovirus. A kinetic study of the fate of the MFG-LacZ retrovirus in the culture medium and intracellularly immediately after exposure of the cells to virus revealed a significant reduction of the appearance of intracellular virus in human IFN-beta-transformed cells. A similar effect was obtained by treating untransformed T98G, U-937, and CEM cells with exogenous human IFN-beta. The blocking effect of autocrine or exogenous human IFN-beta on viral entry was not limited to virus specific for the amphotropic receptor but was also obtained in murine IFN-beta-treated NIH 3T3 mouse fibroblasts infected with an ecotropic MFG-LacZ retrovirus. Infection of human IFN-beta-transformed CEM cells with human immunodeficiency virus type 1 gave comparable results. Immediately following exposure of the cells to human immunodeficiency virus, a kinetic study of the fate of the virus failed to reveal the appearance of intracellular virus and showed that the majority of the input virus remained in the extracellular medium. We conclude that low autocrine IFN-beta synthesis, or exposure of cells to exogenous IFN-beta, prevents virus from getting inside the cells, regardless of the virus receptor involved.