Thymopoiesis and T cell development in common gamma chain-deficient dogs

Evolution of haematopoietic cell transplantation for canine blood disorders and a platform for solid organ transplantation

Pre-clinical haematopoietic cell transplantation (HCT) studies in canines have proven to be invaluable for establishing HCT as a highly successful clinical option for the treatment of malignant and non-malignant haematological diseases in humans. Additionally, studies in canines have shown that immune tolerance, established following HCT, enabled transplantation of solid organs without the need of lifelong immunosuppression. This progress has been possible due to multiple biological similarities between dog and mankind. In this review, the hurdles that were overcome and the methods that were developed in the dog HCT model which made HCT clinically possible are examined. The results of these studies justify the question whether HCT can be used in the veterinary clinical practice for more wide-spread successful treatment of canine haematologic and non-haematologic disorders and whether it is prudent to do so.

Gene therapy studies in a canine model of X-linked severe combined immunodeficiency

Since the occurrence of T cell leukemias in the original human γ-retroviral gene therapy trials for X-linked severe combined immunodeficiency (XSCID), considerable effort has been devoted to developing safer vectors. This review summarizes gene therapy studies performed in a canine model of XSCID to evaluate the efficacy of γ-retroviral, lentiviral, and foamy viral vectors for treating XSCID and a novel method of vector delivery. These studies demonstrate that durable T cell reconstitution and thymopoiesis with no evidence of any serious adverse events and, in contrast to the human XSCID patients, sustained marking in myeloid cells and B cells with reconstitution of normal humoral immune function can be achieved for up to 5 years without any pretreatment conditioning. The presence of sustained levels of gene-marked T cells, B cells, and more importantly myeloid cells for almost 5 years is highly suggestive of transduction of either multipotent hematopoietic stem cells or very primitive committed progenitors.

Development and use of DNA archives at veterinary teaching hospitals to investigate the genetic basis of disease in dogs

The DNA archives developed at veterinary medical teaching hospitals will be important resources for mapping disease loci and identifying underlying genes. The most important feature of a DNA archive is accurate identification or exclusion of diseases in each animal. Such archives will be complimentary resources to tissue banks that are currently available.

Correction of canine X-linked severe combined immunodeficiency by in vivo retroviral gene therapy

X-linked severe combined immunodeficiency (XSCID) is characterized by profound immunodeficiency and early mortality, the only potential cure being hematopoietic stem cell (HSC) transplantation or gene therapy. Current clinical gene therapy protocols targeting HSCs are based upon ex vivo gene transfer, potentially limited by the adequacy of HSC harvest, transduction efficiencies of repopulating HSCs, and the potential loss of their engraftment potential during ex vivo culture. We demonstrate an important proof of principle by showing achievement of durable immune reconstitution in XSCID dogs following intravenous injection of concentrated RD114-pseudotyped retrovirus vector encoding the corrective gene, the interleukin-2 receptor gamma chain (gamma c). In 3 of 4 dogs treated, normalization of numbers and function of T cells were observed. Two long-term-surviving animals (16 and 18 months) showed significant marking of B lymphocytes and myeloid cells, normalization of IgG levels, and protective humoral immune response to immunization. There were no adverse effects from in vivo gene therapy, and in one dog that reached sexual maturity, sparing of gonadal tissue from gene transfer was demonstrated. This is the first demonstration that in vivo gene therapy targeting HSCs can restore both cellular and humoral immunity in a large-animal model of a fatal immunodeficiency.

Gnotobiotics and immunopathology: The use of the gnotobiotic environment to study acquired and inherited immunodeficiency diseases

Gnotobiotic animals are highly valued for the study of infectious diseases wherein the clinical signs and lesions of disease can be directly related to host-pathogen interactions and not to the additive effects of environmental influences and other confounding factors. Gnotobiotic dogs have been used to study the pathogenesis of acquired immunodeficiencies associated with canine distemper virus (CDV). In recent years, the laboratory at OSU, in conjunction with University of Pennsylvania personnel have begun a series of long-term studies of dogs affected with the canine X chromosome-linked severe combined immunodeficiency (XSCID) syndrome. This fatal inherited defect is caused by mutation in the common gamma chain (IL2RG) gene and renders affected animals profoundly immunodeficient. XSCIDs dogs, raised within a gnotobiotic environment for up to 3 years remain clinically healthy and are, in every respect normal except for the persistent T-cell defect and the failure to develop lymph nodes. Bone marrow transplantation (unfractionated or enriched for CD34+ stem cells) is the treatment of choice for both the XSCID dogs and male human infants affected with this syndrome. In preliminary studies, we have shown that human CD34+ stem cells colonized XSCIDs-affected gnotobiotic dogs, migrated to the thymus and demonstrated post-thymic activation (CD45RA+ phenotype) in peripheral blood. While many issues are unresolved, these data suggest that, through the use of the gnotobiotic environment, xenotransplantation (human-to-dog) may yield a stable and immunologically functional human-dog chimera.