Douglas R. Martin

Isolation and characterization of multipotential mesenchymal stem cells from feline bone marrow

OBJECTIVE Although several types of stem cells have been isolated from rodent and human tissues, very few data exist on stem cell isolation from nonrodent animals, which seriously limits the advancement of stem cell biology and its ultimate translation to human clinical applications. Domestic cats are used frequently in biomedical research and are the preferred species for studies of normal physiology and disease, particularly in neuroscience. Therefore, the objective of this study was to characterize mesenchymal stem cells (MSC) from feline bone marrow for use in research on the application of stem cells to human health problems for which cats are the preferred model. METHODS Mesenchymal stem cells from feline bone marrow were isolated by standard methodology developed for other species and characterized according to morphology, growth traits, cell-surface antigen profile, and differentiation repertoire in vitro. RESULTS Feline mesenchymal stem cells exhibit a fibroblast-like morphology with bipolar or polygonal cell bodies and possess a cell-surface antigen profile similar to their rodent and human counterparts. Feline MSC exist at a frequency of 1 in 3.8 x 10(5) bone marrow mononuclear cells and are capable of differentiation to adipocytic, osteocytic, and neuronal phenotypes when exposed to appropriate induction media. CONCLUSIONS Mesenchymal stem cells isolated from feline bone marrow possess several traits typical of MSC from other species. Characterization of feline mesenchymal stem cells will facilitate future studies of stem cell biology and therapeutics for which the domestic cat is an indispensable model.

Neural stem/progenitor cells modulate immune responses by suppressing T lymphocytes with nitric oxide and prostaglandin E2

We and others have reported that neural stem/progenitor cells (NSCs) may exert direct anti-inflammatory activity. This action has been attributed, in part, to T-cell suppression. However, how T-cells become suppressed by NSCs remains unresolved. In this study, we explored one of these mechanisms and challenged some previously advanced hypotheses regarding underlying NSC-mediated T-cell suppression. We employed an easily observable and manipulatable system in which activated and non-activated T-cells were co-cultured with a stable well-characterized clone of lacZ-expressing murine NSCs. As in previous reports, NSCs were found to inhibit T-cell proliferation. However, this inhibition by NSCs was not due to suppression of T cell activation or induction of apoptosis of T cells during the early activation stage. High levels of nitric oxide (NO) and prostaglandin E2 (PGE2) were induced in the T cells when co-cultured with NSCs. In addition, inducible NOS (iNOS) and microsomal type 1 PGES (mPGES-1) were readily detected in NSCs in co-culture with T-cells, but not at all in NSCs cultured alone or in activated T cells cultured with or without NSCs. This finding suggested that activated T cells induced NO and PGE2 production in the NSCs. Furthermore, T-cell proliferation inhibited by co-culture with the NSCs was significantly restored by inhibitors of NO and PGE2 production. Therefore, NSCs appear to suppress T-cells, at least in part, by NO and PGE2 production which, in turn, would account for the well-documented reduction of central nervous system immunopathology by transplanted NSCs.

Therapeutic response in feline sandhoff disease despite immunity to intracranial gene therapy.

Salutary responses to adeno-associated viral (AAV) gene therapy have been reported in the mouse model of Sandhoff disease (SD), a neurodegenerative lysosomal storage disease caused by deficiency of β-N-acetylhexosaminidase (Hex). While untreated mice reach the humane endpoint by 4.1 months of age, mice treated by a single intracranial injection of vectors expressing human hexosaminidase may live a normal life span of 2 years. When treated with the same therapeutic vectors used in mice, two cats with SD lived to 7.0 and 8.2 months of age, compared with an untreated life span of 4.5 ± 0.5 months (n = 11). Because a pronounced humoral immune response to both the AAV1 vectors and human hexosaminidase was documented, feline cDNAs for the hexosaminidase α- and β-subunits were cloned into AAVrh8 vectors. Cats treated with vectors expressing feline hexosaminidase produced enzymatic activity >75-fold normal at the brain injection site with little evidence of an immune infiltrate. Affected cats treated with feline-specific vectors by bilateral injection of the thalamus lived to 10.4 ± 3.7 months of age (n = 3), or 2.3 times as long as untreated cats. These studies support the therapeutic potential of AAV vectors for SD and underscore the importance of species-specific cDNAs for translational research.

Widespread Central Nervous System Gene Transfer and Silencing After Systemic Delivery of Novel AAV-AS Vector.

Effective gene delivery to the central nervous system (CNS) is vital for development of novel gene therapies for neurological diseases. Adeno-associated virus (AAV) vectors have emerged as an effective platform for in vivo gene transfer, but overall neuronal transduction efficiency of vectors derived from naturally occurring AAV capsids after systemic administration is relatively low. Here, we investigated the possibility of improving CNS transduction of existing AAV capsids by genetically fusing peptides to the N-terminus of VP2 capsid protein. A novel vector AAV-AS, generated by the insertion of a poly-alanine peptide, is capable of extensive gene transfer throughout the CNS after systemic administration in adult mice. AAV-AS is 6- and 15-fold more efficient than AAV9 in spinal cord and cerebrum, respectively. The neuronal transduction profile varies across brain regions but is particularly high in the striatum where AAV-AS transduces 36% of striatal neurons. Widespread neuronal gene transfer was also documented in cat brain and spinal cord. A single intravenous injection of an AAV-AS vector encoding an artificial microRNA targeting huntingtin (Htt) resulted in 33-50% knockdown of Htt across multiple CNS structures in adult mice. This novel AAV-AS vector is a promising platform to develop new gene therapies for neurodegenerative disorders.

Comparative Analysis of Brain Lipids in Mice, Cats, and Humans with Sandhoff Disease

Sandhoff disease (SD) is a glycosphingolipid (GSL) storage disease that arises from an autosomal recessive mutation in the gene for the β-subunit of β-Hexosaminidase A (Hexb gene), which catabolizes ganglioside GM2 within lysosomes. Accumulation of GM2 and asialo-GM2 (GA2) occurs primarily in the CNS, leading to neurodegeneration and brain dysfunction. We analyzed the total lipids in the brains of SD mice, cats, and humans. GM2 and GA2 were mostly undetectable in the normal mouse, cat, and human brain. The lipid abnormalities in the SD cat brain were generally intermediate to those observed in the SD mouse and the SD human brains. GM2 comprised 38, 67, and 87% of the total brain ganglioside distribution in the SD mice, cats, and humans, respectively. The ratio of GA2–GM2 was 0.93, 0.13, and 0.27 in the SD mice, cats, and humans, respectively, suggesting that the relative storage of GA2 is greater in the SD mouse than in the SD cat or human. Finally, the myelin-enriched lipids, cerebrosides and sulfatides, were significantly lower in the SD brains than in the control brains. This study is the first comparative analysis of brain lipids in mice, cats, and humans with SD and will be important for designing therapies for Sandhoff disease patients.

Recent Advances in Delivery Through the Blood-Brain Barrier

Current routes of delivering therapeutics to the brain to treat a variety of neurologic conditions include intracerebral, intrathecal, and intranasal delivery. Though successes have been achieved through the use of these methods, each has limitations that warrant a more universal delivery system involving the intravenous pathway. Two main barriers to intravenous delivery are the blood-brain barrier (BBB) and the blood-cerebrospinal fluid barrier. This review discusses potential methods for overcoming barriers of intravenous-mediated brain targeting as well as highlights aspects of the highly restrictive BBB anatomy that are important to consider in the design of successful drug delivery systems. Recent advances in intravenous delivery to the brain have exploited receptor-mediated transcytosis and BBB disruption, as well as control of carrier properties. Currently, three predominant synthetic carriers are being studied to transport therapeutics across the BBB: liposomes, metallic nanoparticles, and polymersomes. This article also focuses on receptors that may be upregulated by brain endothelial cells and their ability to significantly increase brain tissue drug distribution when specific targeting moieties to these receptors are attached to synthetic nanocarriers.

Molecular consequences of the pathogenic mutation in feline GM1 gangliosidosis

G(M1) gangliosidosis is an inherited, fatal neurodegenerative disease caused by deficiency of lysosomal beta-d-galactosidase (EC 3.2.1.23) and consequent storage of undegraded G(M1) ganglioside. To characterize the genetic mutation responsible for feline G(M1) gangliosidosis, the normal sequence of feline beta-galactosidase cDNA first was defined. The feline beta-galactosidase open reading frame is 2010 base pairs, producing a protein of 669 amino acids. The putative signal sequence consists of amino acids 1-24 of the beta-galactosidase precursor protein, which contains seven potential N-linked glycosylation sites, as in the human protein. Overall sequence homology between feline and human beta-galactosidase is 74% for the open reading frame and 82% for the amino acid sequence. After normal beta-galactosidase was sequenced, the mutation responsible for feline G(M1) gangliosidosis was defined as a G to C substitution at position 1448 of the open reading frame, resulting in an amino acid substitution at arginine 483, known to cause G(M1) gangliosidosis in humans. Feline beta-galactosidase messenger RNA levels were normal in cerebral cortex, as determined by quantitative RT-PCR assays. Although enzymatic activity is severely reduced by the mutation, a full-length feline beta-galactosidase cDNA restored activity in transfected G(M1) fibroblasts to 18-times normal. beta-Galactosidase protein levels in G(M1) tissues were normal on Western blots, but immunofluorescence analysis demonstrated that the majority of mutant beta-galactosidase protein did not reach the lysosome. Additionally, G(M1) cat fibroblasts demonstrated increased expression of glucose-related protein 78/BiP and protein disulfide isomerase, suggesting that the unfolded protein response plays a role in pathogenesis of feline G(M1) gangliosidosis.

Evaluation of N-nonyl-deoxygalactonojirimycin as a pharmacological chaperone for human GM1 gangliosidosis leads to identification of a feline model suitable for testing enzyme enhancement therapy

Deficiencies of lysosomal β-D-galactosidase can result in GM1 gangliosidosis, a severe neurodegenerative disease characterized by massive neuronal storage of GM1 ganglioside in the brain. Currently there are no available therapies that can even slow the progression of this disease. Enzyme enhancement therapy utilizes small molecules that can often cross the blood brain barrier, but are also often competitive inhibitors of their target enzyme. It is a promising new approach for treating diseases, often caused by missense mutations, associated with dramatically reduced levels of functionally folded enzyme. Despite a number of positive reports based on assays performed with patient cells, skepticism persists that an inhibitor-based treatment can increase mutant enzyme activity in vivo. To date no appropriate animal model, i.e., one that recapitulates a responsive human genotype and clinical phenotype, has been reported that could be used to validate enzyme enhancement therapy. In this report, we identify a novel enzyme enhancement-agent, N-nonyl-deoxygalactonojirimycin, that enhances the mutant β-galactosidase activity in the lysosomes of a number of patient cell lines containing a variety of missense mutations. We then demonstrate that treatment of cells from a previously described, naturally occurring feline model (that biochemically, clinically and molecularly closely mimics GM1 gangliosidosis in humans) with this molecule, results in a robust enhancement of their mutant lysosomal β-galactosidase activity. These data indicate that the feline model could be used to validate this therapeutic approach and determine the relationship between the disease stage at which this therapy is initiated and the maximum clinical benefits obtainable.

Sustained Normalization of Neurological Disease after Intracranial Gene Therapy in a Feline Model

In a feline model of lysosomal storage disease, intracranial gene therapy achieved therapeutic efficacy in the CNS and increased long-term survival. Gene Therapy for a Lysosomal Storage Disease GM1 gangliosidosis results from defects in the lysosomal enzyme β-galactosidase (β-gal) and subsequent accumulation of GM1 ganglioside, which causes neurodegeneration and premature death. Although no effective treatment exists, encouraging gene therapy data from the GM1 mouse model warranted an evaluation of the feasibility for human clinical application in a large animal model. In a new study, McCurdy et al. injected an adeno-associated viral vector encoding feline β-gal bilaterally into two brain targets (thalamus and deep cerebellar nuclei) of cats with GM1 gangliosidosis. Sixteen weeks after injection, β-gal activity and GM1 storage were normalized throughout the central nervous system of the animals, with accompanying increases in enzyme activity in cerebrospinal fluid and liver. In long-term studies, the mean survival of 12 treated cats with GM1 gangliosidosis was >38 months, compared to 8 months for untreated cats. A minority of cats that progressed to the humane endpoint had low β-gal activity in the spinal cord, yet still lived >2.5 times longer than untreated animals. Most of the treated GM1 cats demonstrated subtle or no gait abnormalities, and magnetic resonance imaging showed normalization of brain architecture up to at least 32 months of age. Long-term correction of the disease phenotype in cats with GM1 gangliosidosis suggests that gene therapy may be useful for treating the human disorder. Progressive debilitating neurological defects characterize feline GM1 gangliosidosis, a lysosomal storage disease caused by deficiency of lysosomal β-galactosidase. No effective therapy exists for affected children, who often die before age 5 years. An adeno-associated viral vector carrying the therapeutic gene was injected bilaterally into two brain targets (thalamus and deep cerebellar nuclei) of a feline model of GM1 gangliosidosis. Gene therapy normalized β-galactosidase activity and storage throughout the brain and spinal cord. The mean survival of 12 treated GM1 animals was >38 months, compared to 8 months for untreated animals. Seven of the eight treated animals remaining alive demonstrated normalization of disease, with abrogation of many symptoms including gait deficits and postural imbalance. Sustained correction of the GM1 gangliosidosis disease phenotype after limited intracranial targeting by gene therapy in a large animal model suggests that this approach may be useful for treating the human version of this lysosomal storage disorder.

In Vivo Selection Yields AAV-B1 Capsid for Central Nervous System and Muscle Gene Therapy

Adeno-associated viral (AAV) vectors have shown promise as a platform for gene therapy of neurological disorders. Achieving global gene delivery to the central nervous system (CNS) is key for development of effective therapies for many of these diseases. Here we report the isolation of a novel CNS tropic AAV capsid, AAV-B1, after a single round of in vivo selection from an AAV capsid library. Systemic injection of AAV-B1 vector in adult mice and cat resulted in widespread gene transfer throughout the CNS with transduction of multiple neuronal subpopulations. In addition, AAV-B1 transduces muscle, β-cells, pulmonary alveoli, and retinal vasculature at high efficiency. This vector is more efficient than AAV9 for gene delivery to mouse brain, spinal cord, muscle, pancreas, and lung. Together with reduced sensitivity to neutralization by antibodies in pooled human sera, the broad transduction profile of AAV-B1 represents an important improvement over AAV9 for CNS gene therapy.