Chemistry: molecular biology and microbiology – Animal cell – per se ; composition thereof; process of... – Primate cell – per se
Reexamination Certificate
2001-03-30
2003-09-16
Wortman, Donna C. (Department: 1648)
Chemistry: molecular biology and microbiology
Animal cell, per se ; composition thereof; process of...
Primate cell, per se
C435S366000, C435S069100, C435S456000, C435S457000, C435S465000
Reexamination Certificate
active
06620618
ABSTRACT:
FIELD OF THE INVENTION
The present invention relates to gene therapy, in particular to recombinant adenovirus vectors useful for gene transfer and protein production, for applications in gene therapy and functional genomics and vaccination, and to complementing cell lines for the generation and propagation of such vectors. More particularly, the invention relates to adenovirus mutants deleted at least for the gene of the adenovirus protease, to complementing cell lines expressing the protease and to corresponding gene transfer vectors.
BACKGROUND OF THE INVENTION
The term “gene therapy” is usually understood to mean the process in which a gene is introduced into the somatic cells of an individual with the aim of being expressed in the cells, to produce some therapeutic effect. Initially this principle was applied to cases where an additional normal copy of a defective gene was provided to restore the synthesis of a missing protein, such as an enzyme. The concept of gene therapy has since been broadened to include several other approaches. In particular, the transferred gene (transgene) may code for a protein that is not necessarily missing but that may be of therapeutic benefit and difficult to administer exogenously, for example IL-2 or antitumor cytokines. This form of gene therapy aims to enhance in vivo production of potentially therapeutic proteins. This approach is similar to gene vaccination, where the transferred gene is introduced into the cells to express a protein acting as an antigen inducing a protective immune response of the host's immune system. Another form of gene therapy involves transferring into cells non-physiological sequences which have antiviral activity, such as antisense oligonucleotides or sequences. Finally, so-called suicide genes can be transferred into undesirable cells (cancer cells or infected cells), to sensitize them to specific substances. When these substances are administered subsequently, they trigger selective destruction of the targeted cells.
Gene delivery systems which transfer the desired gene into the target cells are based either on physico-chemical or on biological methods. In each case the desired gene can be transferred into cells either in vitro, by extracting cells from an organ and reintroducing the cells transfected in vitro into the same organ or organism, or in vivo, i.e., directly into an appropriate tissue. Known physico-chemical methods of transfection include, for example, gene gun (biolistics), in situ naked DNA injections, complexes of DNA with DEAE-dextran or with nucleic proteins, liposomal DNA preparations, etc. Biological methods, considered to be a more reliable alternative to physico-chemical methods, rely on infectious agents as gene transfer vectors. In this group of methods, viruses have become infectious agents of choice, due to their inherent capability of infecting various cells. The transfer of a foreign gene by a viral vector is known as transduction of the gene.
Several virus classes have been tested for use as gene transfer vectors, including retroviruses (RSV, HMS, MMS, etc.), herpesviruses (e.g., HSV), poxviruses (vaccinia virus), adenoviruses (Ad, mainly derived from type 5 and 2 Ad) and adeno-associated viruses (AAV). Of those, adenovirus-based vectors are presently considered to be among the most promising viral vectors, due to their following properties, some of which are unique to this group of vectors: (i) adenovirus vectors do not require cell proliferation for expression of adenovirus proteins (i.e., are effective even in cells at the resting phase); (ii) adenovirus vectors do not integrate their DNA into the chromosomes of the cell, so their effect is impermanent and is unlikely to interfere with the cell's normal functions; (iii) adenovirus vectors can infect non-dividing or terminally differentiated cells, so they are applicable over a wide range of host cells; (iv) adenovirus vectors show a transducing efficiency of almost 100% in a variety of animal cultured cells and in several organs of various species in vivo; (v) adenovirus vectors usually possess an ability to replicate to high titer, a feature important for the preparation of vector stocks suitable for the achievement of efficient transduction in vivo; (vi) adenovirus vectors can accommodate large inserts of exogenous DNA (have a high cloning capacity); (vii) recombination events are rare for adenovirus vectors; (viii) there are no known associations of human malignancies or other serious health problems with adenovirus infections; (adenovirus type 5 is originally known to cause cold conditions in humans; live adenovirus of that type having the ability to replicate has been safely used as a human vaccine (Top et al.,
J.I.D.,
124,148-154;
J.I.D.,
124,155-160(1971)).
Structurally, adenoviruses are non-enveloped viruses, consisting of an external capsid and an internal core. Over 40 adenovirus subtypes have been isolated from humans and over 50 additional subtypes from other mammals and birds. All adenoviruses are morphologically and structurally similar, even though they differ in some properties. Subtypes of human adenoviruses are designated according to serological response to infection. Of those, serotypes Ad2 and Ad5 have been studied most intensively, and used for gene transfer purposes since the 80s. Genetically, adenovirus is a double-stranded DNA virus with a linear genome of about 36 kb. The genome is classified into early (E1-E4) and late (L1-L5) transcriptional regions (units). This classification is based on two temporal classes of viral proteins expressed during the early (E) and late (L) phases of virus replication, with viral DNA replication separating the two phases.
A viral gene transfer vector is a recombinant virus, usually a virus having a part of its genome deleted and replaced with an expression cassette to be transferred into the host cell. Additionally to a foreign (exogenous) gene, the expression cassette comprises components necessary for a proper expression of the foreign gene. It contains at least a promoter sequence and a polyadenylation signal before and after the gene to be expressed. Other sequences necessary to regulate or enhance the gene expression can be included in the cassette for specific applications.
The deletion of some parts of the viral genome may render the virus replication-incompetent, i.e., unable to multiply in the infected host cells. This highly desirable safety feature of viral vectors prevents the spread of the vector containing the recombinant material to the environment and protects the patient from an unintended viral infection and its pathological consequences. The replication-defective virus requires for its propagation either a complementing cell line (packaging cell line) or the presence of a helper virus, either of which serves to replace (restore in trans) the functions of the deleted part or parts of the viral genome. As it has been shown that the production of recombinant viral vectors free of replication-competent helper virus is difficult to achieve, the use of packaging cell lines for the propagation of replication-incompetent viral vectors is considered to be the best choice for gene therapy purposes.
Early adenovirus vectors (sometimes referred to as first generation adenovirus vectors, or singly deficient vectors) relied on deletions (and insertions) in coding regions E1 and/or E3 of the viral genome (see, for example, U.S. Pat. No. 5,670,488; U.S. Pat. No. 5,698,202; U.S. Pat. No. 5,731,172). E3 deletion was usually performed to provide the necessary space for the insertion of foreign genes of a limited size. The E3 region is non-essential for virus growth in tissue culture, so that vectors deleted only in E3 region could be propagated in non-complementing cells. As E1 region is essential for the virus growth, E1-deleted vectors could only be propagated in complementing cells, such as human 293 cells (ATCC CRL 1573), a human embryonic kidney cell line containing the E1 region of human Ad5 DNA.
One of critical issues in the development of safe viral v
Massie Bernard
Oualikene Wahiba
Anderson J. Wayne
National Research Council of Canada
Wortman Donna C.
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