Chimeric retroviral helper virus and picornavirus IRES sequence to eliminate DNA methylation for improved retroviral packaging cells

Most retroviral packaging cell lines were established by a helper virus plasmid cotransfected with a separate plasmid encoding a selection marker. Since this selection marker coexisted in trans with the helper virus sequence, helper virus gene expression could be inactivated by host DNA methylation despite selection for the cotransfected selection marker. We have reported that DNA methylation could occur in the long terminal repeat (LTR) region of helper virus in vector producer cells (VPC) in up to 2% of the population per day (W. B. Young, G. L. Lindberg, and C. J. Link, Jr., J. Virol. 74:3177-3187, 2000). To overcome host cell DNA methylation that suppresses viral gene expression, we constructed a chimeric retroviral helper virus, pAM3-IRES-Zeo, that contains Moloney murine leukemia virus as a helper virus and a picornavirus internal ribosome entry site (IRES) sequence followed by a Zeocin selection marker at the 3' end of the env sequence. This pAM3-IRES-Zeo permitted selection for intact and functional helper virus in transfected cells without subcloning. By selection with Zeocin, a mixed population of pAM3-IRES-Zeo-transfected NIH3T3 cells (AMIZ cells) was maintained with little or no DNA methylation of the helper virus 5' LTR. The high level of pAM3-IRES-Zeo gene expression resulted in no detectable vector superinfection and in high vector titers (2 x 10(6) to 1.5 x 10(7) CFU/ml) after introduction of a retroviral vector. When Zeocin selection was withdrawn from AMIZ cells, methylation of the 5' LTR increased from 17 to 36% of the population during 67 days of continuous culture and the cells became susceptible to superinfection. During this period, gene expression of pAM3-IRES-Zeo decreased and vector titer production was reduced to 2 x 10(4) CFU/ml. These data demonstrate an important role of DNA methylation in the genetic instability of VPC. The chimeric helper virus allows the establishment of a mixed population of packaging cells capable of high-level and sustained vector production without cloning procedures.     

A new retroviral vector for detecting mutations and chromosomal instability in mammalian cells

A retroviral vector carrying both forward (neo) and backward (herpes simplex virus thymidine kinase or HSV-TK gene) selection markers was constructed as a substrate for mutational assay in mammalian cells. The cells infected with this virus are first selected with G418, mutagenized and then selected with the anti-herpes drug acyclovir (ACV). Since HSV-TK, but not the host TK, is capable of converting ACV to a toxic metabolite, cells retaining the intact HSV-TK gene fail to survive, while the cells carrying a mutated HSV-TK gene or which have lost the gene can form colonies in the presence of ACV, making it possible to detect the genetic defects in a positive manner. It is also possible to discriminate between small mutations and large deletions by checking the presence of the linked marker, neo. As a model experiment, we prepared an uncloned pool of rat fibroblast cells (CREF) infected with this virus and irradiated them with increasing doses of ultraviolet light. Dose-dependent increases in the number of ACV-resistant colonies were observed. Structural analysis of the HSV-TK gene in these clones revealed point mutations or small deletions in the majority of the cases. Since it requires no pre-existing genetic markers in the host cells, this system may be used for a wide variety of mammalian cells and provides a useful tool to assess both their susceptibility to various mutagens and their genomic instability     

Small increases in pH enhance retroviral vector transduction efficiency of NIH-3T3 cells

Increases in pH between 7.1 and 7.7 increase the efficiency of polybrene (Pb)- and protamine sulfate (PS)-aided retroviral transduction of NIH-3T3 cells in a serum-lot-dependent manner. The increase in Pb-aided transduction efficiency at pH 7.7, relative to the value at pH 7.33, ranged from 13% to 49% for three serum lots. For a constant Moloney murine leukemia virus (MMLV) vector dilution at pH 7.33, three different serum lots resulted in absolute transduction efficiencies ranging from 29% to 53% using Pb. At the same vector dilution, PS-aided transduction was less effective on an absolute basis than Pb-aided transduction, but the benefit of elevated pH was more pronounced with PS. There was a similar enhancement with PS at elevated pH for a murine stem cell virus (MSCV) vector as for the MMLV vector. The benefit at pH 7.7 for PS-aided transduction was partially due to greater PS stability at elevated pH. Heat inactivating the serum supplement or adding protease inhibitors helped to stabilize PS. This increased the absolute transduction efficiency but decreased the relative benefit of elevated pH to a level similar to that for Pb-aided transduction. Incubating Pb with the vector at pH 7.1 for 10 min, prior to readjusting to pH 7.7 and transducing the cells, was sufficient to abrogate the beneficial effects of transduction at pH 7.7. In contrast, prior exposure of PS with vector at pH 7.1 did not affect subsequent transduction at pH 7.7. These results indicate that pH is an important variable in retroviral transduction and that the relative benefits of Pb or PS on retroviral vector transduction will vary with the pH, polymer addition method, and serum lot.     

DNA methylation increases throughout Arabidopsis development

We used amplified fragment length polymorphisms (AFLP) to analyze the stability of DNA methylation throughout Arabidopsis development. AFLP can detect genome-wide changes in cytosine methylation produced by DNA demethylation agents, such as 5-azacytidine, or specific mutations at the DDM1 locus. In both cases, cytosine demethylation is associated with a general increase in the presence of amplified fragments. Using this approach, we followed DNA methylation at methylation sensitive restriction sites throughout Arabidopsis development. The results show a progressive DNA methylation trend from cotyledons to vegetative organs to reproductive organs.     

Non-B DNA structure-induced genetic instability

Repetitive DNA sequences are abundant in eukaryotic genomes, and many of these sequences have the potential to adopt non-B DNA conformations. Genes harboring non-B DNA structure-forming sequences increase the risk of genetic instability and thus are associated with human diseases. In this review, we discuss putative mechanisms responsible for genetic instability events occurring at these non-B DNA structures, with a focus on hairpins, left-handed Z-DNA, and intramolecular triplexes or H-DNA. Slippage and misalignment are the most common events leading to DNA structure-induced mutagenesis. However, a number of other mechanisms of genetic instability have been proposed based on the finding that these structures not only induce expansions and deletions, but can also induce DNA strand breaks and rearrangements. The available data implicate a variety of proteins, such as mismatch repair proteins, nucleotide excision repair proteins, topoisomerases, and structure specific-nucleases in the processing of these mutagenic DNA structures. The potential mechanisms of genetic instability induced by these structures and their contribution to human diseases are discussed.     

Justification of continuous packed-bed reactor for retroviral vector production from amphotropic ΨCRIP murine producer cell

To indentify a plausible large-scale production system forretroviral vector, three culture systems, i.e., batch culturewith medium exchange, microcarrier culture, and packed-bedreactor culture were compared. In batch cultures with mediumexchange, high cell concentrations were maintained for about amonth, and the harvested retroviral titer remained constant. Inmicrocarrier cultures, although cell growth was rapid, theretroviral titer was unexpectedly low, suggesting that the lowtiter was due either to serious damage to the retroviral vectoror to a reduction in the production rate of retroviral vector,caused by mechanical shear forces. Although the retroviral titer(maximum titer, 1.56 × 10⁶) in the packed-bedreactor was a little bit lower than that obtained in the batchculture with medium exchange (maximum titer, 1.91 ×10⁶), continuous production made it possible to increasethe cumulative titer up to 16-fold of that from the batchculture with medium exchange. Moreover, as the packed-bedreactor system requires less labor and shows excellentvolumetric productivity in comparison to batch cultures withmedium exchanges, it will be an appropriate production systemfor retroviral vector in large quantities.     

Cyclosporine increases human immunodeficiency virus type 1 vector transduction of primary mouse cells

Murine primary cells are poorly permissive to human immunodeficiency virus type 1 (HIV-1) vector infection. Retroviral infectivity is influenced by dominant inhibitors such as TRIM5alpha. Sensitivity to TRIM5alpha is altered by interactions between cyclophilin A and the HIV-1 capsid. Here we demonstrate that competitive inhibitors of cyclophilins, cyclosporine or the related Debio-025, stimulate HIV-1 vector transduction of primary murine cells, including bone marrow and macrophages, up to 20-fold. Unexpectedly, the infectivity of an HIV-1 mutant or a simian lentivirus that does not recruit cyclophilin A is also stimulated by these drugs. We propose that cyclosporine and related compounds will be useful tools for experimental infection of murine primary cells. It is possible that HIV-1 infection of murine cells is inhibited by dominant factors related to immunophilins.     

A retroviral vector for siRNA expression in mammalian cells

Utilization of RNA interference (RNAi) for knockdown of gene expression has become a standard tool for the study of gene function. Short hairpin RNAs (shRNAs) expressed from RNA polymerase III promoters are widely used to achieve stable knockdown of gene expression by RNAi. We have constructed a retroviral-based shRNA expression vector, pSiRPG, as a tool for shRNA-based functional genomic studies. This vector is based on a widely used shRNA expression system and was modified to harbor an enhanced green fluorescent protein (EGFP) and a puromycin selection marker. The functionality of the elements in the pSiRPG vector was validated. The H1(TetO₂) promoter in the vector facilitates doxycycline-inducible shRNA expression, which was demonstrated in cells expressing the Tet repressor (TetR). However, we also demonstrated limited efficiency of the inhibition of shRNA expression in an uninduced TetR-expressing cell line. This observation strongly indicates that the H1(TetO₂) promoter, which is used in a wide range of vectors, is not optimal for tightly regulated shRNA expression. Stable repression of the NDRG1 protein level was observed when introducing pSiRPG constructs expressing shRNAs targeting NDRG1 into two mammary epithelial cell lines by retroviral delivery. This vector should therefore facilitate functional studies in breast cell lines that are hard to transfect with conventional plasmid-based methods.     

DNA methylation and chromosome instability in lymphoblastoid cell lines

In order to gain more insight into the relationships between DNA methylation and genome stability, chromosomal and molecular evolutions of four Epstein-Barr virus-transformed human lymphoblastoid cell lines were followed in culture for more than 2 yr. The four cell lines underwent early, strong overall demethylation of the genome. The classical satellite-rich, heterochromatic,juxtacentromeric regions of chromosomes 1, 9, and 16 and the distal part of the long arm of the Y chromosome displayed specific behavior with time in culture. In two cell lines, they underwent a strong demethylation, involving successively chromosomes Y, 9, 16, and 1, whereas in the two other cell lines, they remained heavily methylated. For classical satellite 2-rich heterochromatic regions of chromosomes 1 and 16, a direct relationship could be established between their demethylation, their undercondensation at metaphase, and their involvement in non-clonal rearrangements. Unstable sites distributed along the whole chromosomes were found only when the heterochromatic regions of chromosomes 1 and 16 were unstable. The classical satellite 3-rich heterochromatic region of chromosomes 9 and Y, despite their strong demethylation, remained condensed and stable. Genome demethylation and chromosome instability could not be related to variations in mRNA amounts of the DNA methyltransferases DNMT1, DNMT3A, and DNMT3B and DNA demethylase. These data suggest that the influence of DNA demethylation on chromosome stability is modulated by a sequence-specific chromatin structure.     

118 DNA structure-induced genetic instability in mammals

Naturally occurring repetitive DNA sequences can adopt alternative (i.e. non-B) DNA secondary structures, and often co-localize with chromosomal breakpoint “hotspots,” implicating non-B DNA in translocation-related cancer etiology. We have found that sequences capable of adopting H-DNA and Z-DNA structures are intrinsically mutagenic in mammals. For example, an endogenous H-DNA-forming sequence from the human c-MYC promoter and a model Z-DNA-forming CpG repeat induced genetic instability in mammalian cells, largely in the form of deletions resulting from DNA double-strand breaks (Wang & Vasquez, 2004; Wang et al., 2006). Characterization of the mutants revealed microhomologies at the breakpoints, consistent with a microhomology-mediated end-joining repair of the double-strand breaks (Kha et al., 2010). We have constructed transgenic mutation-reporter mice containing these human H-DNA- and Z-DNA-forming sequences to determine their effects on genomic instability in a chromosomal context in a living organism (Wang et al., 2008). Initial results suggest that both H-DNA- and Z-DNA-forming sequences induced genetic instability in mice, suggesting that these non-B DNA structures represent endogenous sources of genetic instability and may contribute to disease etiology and evolution. Our current studies are designed to determine the mechanisms of DNA structure-induced genetic instability in mammals; the roles of helicases, polymerases, and repair enzymes in H-DNA and Z-DNA-induced genetic instability will be discussed.     

Synthesis of plus strands of retroviral DNA in cells infected with avian sarcoma virus and mouse mammary tumor virus

The vast majority of plus strands synthesized in quail cells acutely infected with avian sarcoma virus were subgenomic in size, generally less than 3 kilobases (kb). A series of discrete species could be identified after agarose gel electrophoresis by annealing with various complementary DNAs, indicating specificity in the initiation and termination of plus strands. The first plus strand to appear (within 2 h postinfection) was similar in length to the long redundancy at the ends of linear DNA (0.35 kb), and it annealed with complementary DNAs specific for the 3' and 5' termini of viral RNA (Varmus et al., J. Mol. Biol. 120:50-82, 1978). Several subgenomic plus-strand fragments (0.94, 1.38, 2.3, and 3.4 kb) annealed with these reagents. At least the 0.94- and 1.38-kb strands were located at the same end of linear DNA as the 0.35-kb strand, indicating that multiple specific sites for initiation were employed to generate strands which overlapped on the structural map. We were unable to detect RNA liked to plus strands isolated as early as 2.5 h postinfection; thus, the primers must be short (fewer than 50 to 100 nucleotides), rapidly removed, or not composed of RNA. To determine whether multiple priming events are a general property of retroviral DNA synthesis in vivo, we also examined plus strands of mouse mammary tumor virus DNA in chronically infected rat cells after induction of RNA and subsequent DNA synthesis with dexamethasone. In this case, multiple, discrete subgenomic DNA plus strands were not found when the same methods applied to avian sarcoma virus DNA were used; instead, the plus strands present in the linear DNA of mouse mammary tumor virus fell mainly into two classes: (i) strands of ca. 1.3 kb which appeared early in synthesis and were similar in size and genetic content to the terminally repeated sequence in linear DNA; and (ii) plus strands of the same length as linear DNA. A heterogeneous population of other strands diminished with time, was not found in completed molecules, and was probably composed of strands undergoing elongation. These two retroviruses thus appear to differ with respect to both the number of priming sites used for the synthesis of plus strands and the abundance of full-length plus strands. On the other hand the major subgenomic plus strand of mouse mammary tumor virus DNA (1.3 kb) is probably the functional homolog of a major subgenomic plus strand of avian sarcoma virus DNA (0.35 kb). The significance of this plus strand species is discussed in the context of current models which hold that it is used as a template for the completion of the minus strand, thereby generating the long terminal redundancy.     

Adeno-associated virus helper activity of adenovirus DNA binding protein

The requirement for the adenovirus (Ad) single-stranded DNA binding protein (DBP) in the expression of adeno-associated virus (AAV) proteins was studied by specific immunofluorescent staining of infected cells and in vitro translation of RNA from infected cells. The Ad5 mutant ts125, which carries a mutation in the DBP gene, helped AAV as efficiently as the Ad5 wild type (WT) did at both the permissive (32 degrees C) and nonpermissive (40.5 degrees C) temperatures in HeLa and KB cells. Furthermore, at 40.5 degrees C ts125 was as efficient as Ad5WT was in inducing the expression of AAV proteins in a line of Detroit 6 cells which is latently infected with AAV. However, little if any AAV protein was synthesized when coinfections were carried out with Ad5WT in CV-C cells, a monkey cell line that is highly restrictive for human Ad replication unless the cells are also infected with simian virus 40. On the other hand, AAV protein was efficiently produced in CV-C cells in coinfections with the Ad5 mutant hr404, whose growth is unrestricted in CV-C cells and whose mutation also maps in the DBP gene. Finally, preparations of cytoplasmic RNA extracted from CV-C cells infected with AAV and Ad5WT or from CV-C cells infected with AAV, Ad5WT, and simian virus 40 were each capable of directing the in vitro synthesis of abundant amounts of AAV proteins in a rabbit reticulocyte lysate system. These results indicate that the abnormal DBP of ts125 still retains its helper function for AAV replication, but that the molecular feature of the DBP which relates to the monkey cell host range restriction of Ad's may also account for the observed block to AAV protein translation in CV-C cells.     

Ri-plasmid as a helper for introducing vector DNA into alfalfa plants

Genetic engineering of legumes and other important dicotyledonous plants is limited because of the difficulty of regenerating plants via cell culture. Since a considerable number of crop plants can be regenerated only from root culture, the introduction of foreign genes into Agrobacterium rhizogenes-induced hairy roots may expand the list of crop plants that could be genetically engineered. Here we report genetic transformation of alfalfa (Medicago sativa L.), a valuable forage legume, using a virulent strain of Agrobacterium rhizogenes containing, in addition to its Ri-plasmid, a binary vector containing a nopaline synthase gene. Plant cells transformed by this vector can be easily identified by their ability to produce nopaline. Transformed alfalfa plants were recovered from A. rhizogenes-induced hairy roots. These transgenic plants were characterized by normal leaf morphology and stem growth but a root system that was shallow and more extensive than normal. These plants were also fertile, set seeds upon self-pollination and outcrossing. Nopaline was detected in R1 progeny. Southern blot analysis confirmed the presence of multiple copies of T-DNAs from the Riplasmid in the plant genome in addition to the vector T-DNA.     

Patterns of frog virus 3 DNA methylation and DNA methyltransferase activity in nuclei of infected cells.

The iridovirus frog virus 3 (FV3) can replicate in culture in fat head minnow (FHM) fish cells or in BHK-21 hamster cells. Viral DNA replication commences about 3 h after infection of FHM cells with FV3. Between 3 and 6 h postinfection (p.i.), a portion of the intranuclear FV3 DNA is partly unmethylated. At later times, p.i., all of the viral DNA in the nuclear and cytoplasmic compartments is methylated at the 5'-CCGG-3' sequences. Cytoplasmic FV3 DNA has not been found unmethylated. We have cloned viral DNA fragments from methylated virion DNA. By using the genomic sequencing technique, it has been demonstrated for segments of the FV3 DNA replicated both in FHM fish and BHK21 hamster cells that in a stretch encompassing a total of 350 bp, all of the analyzed 5'-CG-3' dinucleotides are methylated. The modified nucleotide 5-methyldeoxycytidine is present exclusively in the 5'-CG-3' dinucleotide combination. In the cloned FV3 DNA fragment p21A, an open reading frame has been located. The 5' region of this presumptive viral gene is also methylated in all 5'-CG-3' positions. DNA methyltransferase activity has been detected in the nuclei of FV3-infected FHM cells at 4, 11, and 20 h p.i. In the cytoplasmic fraction, comparable activity has not been observed. These data are consistent with the interpretation that FV3 DNA is newly synthesized and de novo methylated in the nuclei of infected FHM cells and subsequently exported into the cytoplasm for viral assembly.