Co-expression of alpha(1,3)galactosyltransferase and Bacillus thuringiensis PIPLC enhances hyperacute rejection of tumor cells.

The use of alpha(1,3)galactosyltransferase (alphaGT) as a method of inducing hyperacute rejection of tumors has been gaining interest recently. However, the approach is based in part on the sensitivity of each tumor line to the effects of complement lysis. Tumors expressing complement resistance factors such as membrane cofactor (CD46), decay accelerating factor (CD55) and protectin (CD59) have been shown to be more resistant to complement mediated lysis. Anchored to the membrane by a glycosylphosphoinositol moiety (GPI-anchored), CD55 and CD59 can be cleaved by Bacillus thuringiensis phosphatidylinositol-specific phospholipase C (PIPLC). Complement resistant A549 human lung carcinoma cells were engineered to express both the murine alphaGT gene and the B. thuringiensis PIPLC gene to alleviate complement resistance and enhance alphagal-mediated cancer killing. The PIPLC native signal sequence was replaced with the human epidermal growth factor signal sequence, EGFssPIPLC, to induce secretion from A549. Expression of EGFssPIPLC resulted in complete removal of CD55 and CD59 while sparing the non-GPI-anchored CD46. Results demonstrated that A549 cells transduced with two recombinant retroviral vectors carrying the alphaGT and EGFssPIPLC genes expressed high levels of alphagal epitope and exhibited a 5-fold increase in sensitivity to anti-alphagal mediated complement lysis.

High-throughput fluorescent screening of transgenic animals: phenotyping and haplotyping.

BACKGROUND: Methods for genotyping transgenic animals currently consist of extracting genomic DNA from blood or tissue followed by PCR or Southern blot analysis. These methods when used to screen large numbers of animals can be time consuming and expensive. Therefore, we developed a novel method that allows high-throughput screening of phenotypic changes on leukocytes, resulting from the transgenic genotype. This technique allows investigators to quickly screen a large number of animals without the need to extract DNA from each one. Moreover, since blood is collected for the initial screening, putative homozygotes can be confirmed by conventional methods using the same blood samples. METHODS: We collected blood from wild-type alphagal positive and alphagal knockout mice and probed for the presence of Galalpha(1-->3)Gal (alphagal) epitopes. Also, alloantigen specific antibodies were used to determine the haplotype of our outbred mouse colony in order to develop an inbred line. RESULTS: alphagal epitopes were detected in wild-type but not alphagal knock-out samples. To validate these results, PCR was used to demonstrate the native alphagal gene in wild-type and the pGKneo construct in alphagal knock-out mice. Furthermore, haplotypes were determined and mice divided for backcrosses. CONCLUSIONS: This screening method is useful for both preliminary screening of transgenic mice and the development of an inbred mouse colony by rapid determination of MHC I haplotype. Here, we demonstrate the use of this technique and show how it can be a valuable tool, saving time and resources in both investigator effort and animal husbandry.

Iron chelators increase the resistance of Ataxia telangeictasia cells to oxidative stress.

Ataxia telangeictasia (A-T) is an autosomal recessive disorder characterized by immune dysfunction, genomic instability, chronic oxidative damage, and increased cancer incidence. Previously, desferal was found to increase the resistance of A-T, but not normal cells to exogenous oxidative stress in the colony forming-efficiency assay, suggesting that iron metabolism is dysregulated in A-T. Since desferal both chelates iron and modulates gene expression, we tested the effects of apoferritin and the iron chelating flavonoid quercetin on A-T cell colony-forming ability. We demonstrate that apoferritin and quercetin increase the ability of A-T cells to form colonies. We also show that labile iron levels are significantly elevated in Atm-deficient mouse sera compared to syngeniec wild type mice. Our findings support a role for labile iron acting as a Fenton catalyst in A-T, contributing to the chronic oxidative stress seen in this disease. Our findings further suggest that iron chelators might promote the survival of A-T cells and hence, individuals with A-T.

Desferrioxamine treatment increases the genomic stability of Ataxia-telangiectasia cells.

Ataxia-telangiectasia (AT) is an autosomal recessive disorder characterized by genomic instability, chronic oxidative damage, and increased cancer incidence. Compared to normal cells, AT cells exhibit unusual sensitivity to exogenous oxidants, including t-butyl hydroperoxide (t-BOOH). Since ferritin releases labile iron under oxidative stress (which is chronic in AT) and labile iron mediates the toxic effects of t-butyl hydroperoxide, we hypothesized that chelation of intracellular labile iron would increase the genomic stability of AT cells, with and without exogenous oxidative stress. Here we report that desferrioxamine treatment increases the plating efficiency of AT, but not normal cells, in the colony forming-efficiency assay (a method often used to measure genomic stability). Additionally, desferrioxamine increases AT, but not normal cell resistance, to t-butyl hydroperoxide in this assay. Last, AT cells exhibit increased sensitivity to the toxic effects of FeCl(2) in the colony forming-efficiency assay and fail to demonstrate a FeCl(2)-induced G(2) checkpoint response when compared to normal cells. Our data indicates that: (1) chelation of labile iron increases genomic stability in AT cells, but not normal cells; and (2) AT cells exhibit deficits in their responses to iron toxicity. While preliminary, our findings suggest that AT might be, in part, a disorder of iron metabolism and treatment of individuals with AT with desferrioxamine might have clinical efficacy.

Immunity to the alpha(1,3)galactosyl epitope provides protection in mice challenged with colon cancer cells expressing alpha(1,3)galactosyl-transferase: a novel suicide gene for cancer gene therapy.

Human immunity to alpha(1,3)Galactosyl epitopes (alpha Gal) may provide the means for a successful cancer gene therapy that uses the immune system to identify and to destroy tumor cells expressing the suicide gene alpha(1,3)Galactosyltransferase (alpha GT). Innate antibody specific for cell surface alpha Gal constitutes a high percentage of circulating IgG and IgM immunoglobulins in humans and is the basis for complement-mediated hyperacute xenograft rejection and antibody-dependent cell-mediated cytotoxicity. In humans, the gene for alpha GT is mutated, and cells do not express the alpha Gal moiety. We hypothesized that human tumor cells induced to express the alpha Gal epitope would be killed by the hosts' innate immunity. Previous in vitro work by our group has demonstrated complement-mediated lysis of alpha Gal-transduced human tumor cells in culture by human serum. To induce antibodies to alpha Gal in this in vivo study, alpha GT knockout mice were used to determine whether immunization with alpha Gal could provide protection from challenge with alpha Gal-expressing murine MC38 colon cancer cells. Knockout mice were immunized either a single time, or twice, with rabbit RBC. Antibody titers to alpha Gal measured by indirect ELISA were significantly higher in mice immunized twice and approached the titers observed in human serum. Anti-alpha Gal antibodies were predominantly of the IgG1 and IgG3 subtype. Immunized knockout mice were challenged i.p. with varying doses of alpha Gal(+) MC38 colon carcinoma cells. Nonimmunized control groups consisting of alpha GT knockout mice, and wild-type C57BL/6 mice were challenged as well with MC38 cells. Immunized mice survived and exhibited slower tumor development in comparison to nonimmunized knockout and control mice. This study demonstrates, in vivo, the protective benefit of an immune response to the alpha Gal epitope. Our results provide a basis to pursue additional development of this cancer gene therapy strategy.