The Carter Lab at NIH: A Model of Inclusive Excellence in Biomedical Research.

In the 1980s and early 1990s, Dr. Barrie Carter served as the chief of the Laboratory of Molecular and Cellular Biology in the National Institute of Diabetes and Digestive and Kidney Diseases at the National Institutes of Health. During that time, his group performed seminal work in adeno-associated virus (AAV) type 2 (AAV2) biology, including creating one of the first infectious clones of AAV2 and some of the first packaged AAV2 vectors. This work contributed substantially to the development of AAVs as gene therapy vectors. Part of the success of the group was due to Dr. Carter's ability to attract and manage a diverse team of talented individuals who synergized into a collaborative group that was more than the sum of its parts. This review describes some of the promising practices employed by the Carter group, which allowed such a diverse group to function so well. These practices included promoting a culture of co-mentoring, open communication, and respectful questioning.

Substitution of adeno-associated virus Rep protein binding and nicking sites with human chromosome 19 sequences.

BACKGROUND: Adeno-associated virus type 2 (AAV2) preferentially integrates its DNA at a ~2 kb region of human chromosome 19, designated AAVS1 (also known as MBS85). Integration at AAVS1 requires the AAV2 replication (Rep) proteins and a DNA sequence within AAVS1 containing a 16 bp Rep recognition sequence (RRS) and closely spaced Rep nicking site (also referred to as a terminal resolution site, or trs). The AAV2 genome is flanked by inverted terminal repeats (ITRs). Each ITR contains an RRS and closely spaced trs, but the sequences differ from those in AAVS1. These ITR sequences are required for replication and packaging. RESULTS: In this study we demonstrate that the AAVS1 RRS and trs can function in AAV2 replication, packaging and integration by replacing a 61 bp region of the AAV2 ITR with a 49 bp segment of AAVS1 DNA. Modifying one or both ITRs did not have a large effect on the overall virus titers. These modifications did not detectably affect integration at AAVS1, as measured by semi-quantitative nested PCR assays. Sequencing of integration junctions shows the joining of the modified ITRs to AAVS1 sequences. CONCLUSIONS: The ability of these AAVS1 sequences to substitute for the AAV2 RRS and trs provides indirect evidence that the stable secondary structure encompassing the trs is part of the AAV2 packaging signal.

Transduction of rat pancreatic islets with pseudotyped adeno-associated virus vectors.

BACKGROUND: Pancreatic islet transplantation is a promising treatment for type I diabetes mellitus, but current immunosuppressive strategies do not consistently provide long-term survival of transplanted islets. We are therefore investigating the use of adeno-associated viruses (AAVs) as gene therapy vectors to transduce rat islets with immunosuppressive genes prior to transplantation into diabetic mice. RESULTS: We compared the transduction efficiency of AAV2 vectors with an AAV2 capsid (AAV2/2) to AAV2 vectors pseudotyped with AAV5 (AAV2/5), AAV8 (AAV2/8) or bovine adeno-associated virus (BAAV) capsids, or an AAV2 capsid with an insertion of the low density lipoprotein receptor ligand from apolipoprotein E (AAV2apoE), on cultured islets, in the presence of helper adenovirus infection to speed expression of a GFP transgene. Confocal microscopy and flow cytometry were used. The AAV2/5 vector was superior to AAV2/2 and AAV2/8 in rat islets. Flow cytometry indicated AAV2/5-mediated gene expression in approximately 9% of rat islet cells and almost 12% of insulin-positive cells. The AAV2/8 vector had a higher dependence on the helper virus multiplicity of infection than the AAV 2/5 vector. In addition, the BAAV and AAV2apoE vectors were superior to AAV2/2 for transducing rat islets. Rat islets (300 per mouse) transduced with an AAV2/5 vector harboring the immunosuppressive transgene, tgf beta 1, retain the ability to correct hyperglycemia when transplanted into immune-deficient diabetic mice. CONCLUSION: AAV2/5 vectors may therefore be useful for pre-treating donor islets prior to transplantation.

Preferential integration of adeno-associated virus type 2 into a polypyrimidine/polypurine-rich region within AAVS1.

Adeno-associated virus type 2 (AAV2) preferentially integrates its genome into the AAVS1 locus on human chromosome 19. Preferential integration requires the AAV2 Rep68 or Rep78 protein (Rep68/78), a Rep68/78 binding site (RBS), and a nicking site within AAVS1 and may also require an RBS within the virus genome. To obtain further information that might help to elucidate the mechanism and preferred substrate configurations of preferential integration, we amplified junctions between AAV2 DNA and AAVS1 from AAV2-infected HeLaJW cells and cells with defective Artemis or xeroderma pigmentosum group A genes. We sequenced 61 distinct junctions. The integration junction sequences show the three classical types of nonhomologous-end-joining joints: microhomology at junctions (57%), insertion of sequences that are not normally contiguous with either the AAV2 or the AAVS1 sequences at the junction (31%), and direct joining (11%). These junctions were spread over 750 bases and were all downstream of the Rep68/78 nicking site within AAVS1. Two-thirds of the junctions map to 350 bases of AAVS1 that are rich in polypyrimidine tracts on the nicked strand. The majority of AAV2 breakpoints were within the inverted terminal repeat (ITR) sequences, which contain RBSs. We never detected a complete ITR at a junction. Residual ITRs at junctions never contained more than one RBS, suggesting that the hairpin form, rather than the linear ITR, is the more frequent integration substrate. Our data are consistent with a model in which a cellular protein other than Artemis cleaves AAV2 hairpins to produce free ends for integration.

Stable secondary structure near the nicking site for adeno-associated virus type 2 Rep proteins on human chromosome 19.

Adeno-associated virus serotype 2 (AAV-2) can preferentially integrate its DNA into a 4-kb region of human chromosome 19, designated AAVS1. The nicking activity of AAV-2's Rep68 or Rep78 proteins is essential for preferential integration. These proteins nick at the viral origin of DNA replication and at a similar site within AAVS1. The current nicking model suggests that the strand containing the nicking site is separated from its complementary strand prior to nicking. In AAV serotypes 1 through 6, the nicking site is flanked by a sequence that is predicted to form a stem-loop with standard Watson-Crick base pairing. The region flanking the nicking site in AAVS1 (5'-GGCGGCGGT/TGGGGCTCG-3' [the slash indicates the nicking site]) lacks extensive potential for Watson-Crick base pairing. We therefore performed an empirical search for a stable secondary structure. By comparing the migration of radiolabeled oligonucleotides containing wild-type or mutated sequences from the AAVS1 nicking site to appropriate standards, on native and denaturing polyacrylamide gels, we have found evidence that this region forms a stable secondary structure. Further confirmation was provided by circular dichroism analyses. We identified six bases that appear to be important in forming this putative secondary structure. Mutation of five of these bases, within the context of a double-stranded nicking substrate, reduces the ability of the substrate to be nicked by Rep78 in vitro. Four of these five bases are outside the previously recognized GTTGG nicking site motif and include parts of the CTC motif that has been demonstrated to be important for integration targeting.

Selective protection of restriction endonuclease sites.

A difficulty that is encountered when attempting to insert a PCR-amplified product or DNA fragment of interest into a particular vector is the presence within the insert of one or more internal restriction endonuclease (RE) sites identical to those selected for the flanks of the insert. Our method circumvents this problem by partially protecting internal RE sites while flanking sites for the same RE are cleaved. The amplified product is first heat denatured in the presence of excess amounts of perfectly complementary oligonucleotides that can anneal to the flanks of the insert. The mixture is allowed to anneal and is subsequently digested with the appropriate endonucleases. This results in the cleavage of the flanking RE sites while digestion at the internal RE site is not efficient. The mixture is subsequently heat denatured and column purified to remove the oligonucleotides. The product is then allowed to anneal and can be used directly in a ligation reaction with the plasmid vector. This method facilitates the construction of recombinant molecules by creating desired flanks while preserving internal RE sites.

Second generation adeno-associated virus type 2-based gene therapy systems with the potential for preferential integration into AAVS1.

Adeno-associated virus type 2 (AAV-2) is a non-pathogenic human parvovirus that is being developed as a gene therapy vector for the treatment of numerous diseases. One property of wild-type AAV-2, that is highly desirable in a gene therapy vector, is its ability to preferentially integrate its DNA into a 4 kilobase region of human chromosome 19, designated AAVS1. One disadvantage of AAV-2 is its relatively small packaging capacity, approximately 4.7 kilobases. Because of this size limitation, the AAV-2 rep and cap genes were removed from first-generation AAV-2-based gene therapy vectors to make room for the therapeutic or marker gene. It was later discovered that the rep gene, or at least one of its products, the Rep68 or Rep78 protein, is required for preferential integration of AAV-2. Recent developments in AAV-2 gene therapy vector construction allow the inclusion of the rep gene into a second generation of AAV-2-based gene therapy systems. These new systems fall into four major categories: plasmid-based systems, co-transduction with multiple AAV-2 vectors, incorporation of the AAV-2 vector into a larger virus, and in vitro packaging. These systems not only allow the inclusion of the rep gene, they also allow the delivery of larger therapeutic genes.