Production of Retroviral and Lentiviral Gene Therapy Vectors: Challenges in the Manufacturing of Lipid Enveloped Virus

Abstract

Gamma-retroviral vectors, commonly designated retroviral vectors, were the first viral vector employed in Gene Therapy clinical trials in 1990 and are still one of the most used. More recently, the interest in lentiviral vectors, derived from complex retroviruses such as the human immunodeficiency virus (HIV), has been growing due to their ability to transduce non-dividing cells (Lewis et al. 1992; Naldini et al. 1996), an attribute that distinguishes them from other viral vectors, including their simple counterparts, gammaretroviral vectors. Retroviral and lentiviral vectors most attractive features as gene transfer tools include the capacity for large genetic payload (up to 9 kb), minimal patient immune response, high transducing efficiency in vivo and in vitro, and the ability to permanently modify the genetic content of the target cell, sustaining a long-term expression of the delivered gene (Coroadinha et al. 2010; Schweizer and Merten 2010). According to the most recent updates, retroviral and lentiviral vectors represent 23% of all the vector types and 33% of the viral vectors used in Gene Therapy clinical trials. Moreover, retroviral vectors are currently the blockbuster vectors for the treatment of monogenic and infectious diseases and gene marking clinical trials (Edelstein 2010). Retroviruses are double stranded RNA enveloped viruses mainly characterized by the ability to “reverse-transcribe” their genome from RNA to DNA. Virions measure 100-120 nm in diameter and contain a dimeric genome of identical positive RNA strands complexed with the nucleocapsid (NC) proteins. The genome is enclosed in a proteic capsid (CA) that also contains enzymatic proteins, namely the reverse transcriptase (RT), the integrase (IN) and proteases (PR), required for viral infection. The matrix proteins (MA) form a layer outside the capsid core that interacts with the envelope, a lipid bilayer derived from the host cellular membrane, which surrounds the viral core particle (Coffin et al. 1997). Anchored on this bilayer, are the viral envelope glycoproteins (Env) responsible for recognizing specific receptors on the host cell and initiating the infection process. Envelope proteins are formed by two subunits, the transmembrane (TM) that anchors the protein into the lipid membrane and the surface (SU) which binds to the cellular receptors (Fig. 1).