Correction of the biochemical and functional deficits in fabry mice following AAV8-mediated hepatic expression of alpha-galactosidase A.

The advent of novel adeno-associated virus (AAV) serotype vectors with higher transduction activity has encouraged a re-evaluation of the merits of this delivery platform for a variety of diseases. We report here that administration of a recombinant AAV8-based serotype vector encoding human alpha-galactosidase A into Fabry mice facilitated more rapid and significantly higher levels of production of the enzyme than an AAV2 vector. This translated into improved clearance of globotriaosylceramide, the glycosphingolipid that accumulates in the lysosomes of affected Fabry cells, and to correction of the peripheral neuropathy shown associated with this disease. The higher levels of alpha-galactosidase A expression also allowed for a more rapid induction of immunotolerance to the enzyme. Recombinant AAV8 vectors that facilitated hepatic-restricted expression of high levels of alpha-galactosidase A conferred immunotolerance to the expressed enzyme as early as 30 days post-treatment. Animals expressing lower levels of the hydrolase, such as those treated with an AAV2-based vector or with lower doses of the AAV8-based vector, were also able to develop immunotolerance, but only after a more extended time period. Adoptive transfer of T cells isolated from the spleens of immunotolerized mice suppressed the formation of antibodies in naïve recipient animals, suggesting the possible role of regulatory T cells in effecting this state.

Correction of the Biochemical and Functional Deficits in Fabry Mice Following AAV8-mediated Hepatic Expression of α-galactosidase A.

The advent of novel adeno-associated virus (AAV) serotype vectors with higher transduction activity has encouraged a re-evaluation of the merits of this delivery platform for a variety of diseases. We report here that administration of a recombinant AAV8-based serotype vector encoding human α-galactosidase A into Fabry mice facilitated more rapid and significantly higher levels of production of the enzyme than an AAV2 vector. This translated into improved clearance of globotriaosylceramide, the glycosphingolipid that accumulates in the lysosomes of affected Fabry cells, and to correction of the peripheral neuropathy shown associated with this disease. The higher levels of α-galactosidase A expression also allowed for a more rapid induction of immunotolerance to the enzyme. Recombinant AAV8 vectors that facilitated hepatic-restricted expression of high levels of α-galactosidase A conferred immunotolerance to the expressed enzyme as early as 30 days post-treatment. Animals expressing lower levels of the hydrolase, such as those treated with an AAV2-based vector or with lower doses of the AAV8-based vector, were also able to develop immunotolerance, but only after a more extended time period. Adoptive transfer of T cells isolated from the spleens of immunotolerized mice suppressed the formation of antibodies in naïve recipient animals, suggesting the possible role of regulatory T cells in effecting this state.

Structure of human ferritin L chain.

Ferritin is the major iron-storage protein present in all cells. It generally contains 24 subunits, with different ratios of heavy chain (H) to light chain (L), in the shape of a hollow sphere hosting up to 4500 ferric Fe atoms inside. H-rich ferritins catalyse the oxidation of iron(II), while L-rich ferritins promote the nucleation and storage of iron(III). Several X-ray structures have been determined, including those of L-chain ferritins from horse spleen (HoSF), recombinant L-chain ferritins from horse (HoLF), mouse (MoLF) and bullfrog (BfLF) as well as recombinant human H-chain ferritin (HuHF). Here, structures have been determined of two crystal forms of recombinant human L-chain ferritin (HuLF) obtained from native and perdeuterated proteins. The structures show a cluster of acidic residues at the ferrihydrite nucleation site and at the iron channel along the threefold axis. An ordered Cd2+ structure is observed within the iron channel, offering further insight into the route and mechanism of iron transport into the capsid. The loop between helices D and E, which is disordered in many other L-chain structures, is clearly visible in these two structures. The crystals generated from perdeuterated HuLF will be used for neutron diffraction studies.

AAV8-mediated hepatic expression of acid sphingomyelinase corrects the metabolic defect in the visceral organs of a mouse model of Niemann-Pick disease.

Acid sphingomyelinase deficiency is a lysosomal storage disorder in which the defective lysosomal hydrolase fails to degrade sphingomyelin. The resulting accumulation of substrate in the lysosomes of histiocytic cells leads to hepatosplenomegaly and severe pulmonary inflammation. Administration of a recombinant AAV1 vector encoding human acid sphingomyelinase to acid sphingomyelinase knockout (ASMKO) mice effectively reduced the accumulated substrate in all of the affected visceral organs. However, more complete and rapid clearance of sphingomyelin was observed when an AAV8-based serotype vector was used in lieu of AAV1. Importantly, AAV8-mediated hepatic expression of higher and sustained levels of the enzyme also corrected the abnormal cellularity, cell differentials, and levels of the chemokine MIP-1alpha in the bronchoalveolar lavage fluids of the ASMKO mice. Treatment also reversed the morphological aberrations associated with the alveolar macrophages of ASMKO mice and restored their phagocytic activity. No antibodies to the expressed enzyme were detected when the viral vectors were used in conjunction with a transcription cassette harboring a liver-restricted enhancer/promoter. Together, these data support the continued development of AAV8-mediated hepatic gene transfer as an approach to treat the visceral manifestations observed in individuals with acid sphingomyelinase deficiency.

Engineered protein cages for nanomaterial synthesis.

Self-assembled particles of genetically engineered human L subunit ferritin expressing a silver-binding peptide were used as nanocontainers for the synthesis of silver nanoparticles. The inner cavity of the self-assembled protein cage displays a dodecapeptide that is capable of reducing silver ions to metallic silver. This chimeric protein cage when incubated in the presence of silver nitrate exhibits the growth of a silver nanocrystal within its cavity. Our studies indicate that it is possible to design chimeric cages, using specific peptide templates, for the growth of other inorganic nanoparticles.

Shear stress-induced binding of large and unusually large von Willebrand factor to human platelet glycoprotein Ibalpha.

Platelet membrane glycoprotein (GP) Ib(alpha), a component of the GP Ib-IX-V complex, is a receptor for von Willebrand factor (VWF). A small quantity of large VWF multimers binds to platelets under high shear stress, and induces aggregation. We studied the shear-induced attachment of large and unusually large VWF multimers to the GPIb(alpha) extracellular domain (glycocalicin), human platelets, and GPIb(alpha) gxpressing Chinese hamster ovary (CHO) cells. Compared to binding in the presence of botrocetin and ristocetin, shear stress only induced low-level NVWF (normal plasma VWF multimers) binding. This shear stress induced interaction is also dependent on VWF multimeric size. Elevated binding levels of endothelial cell VWF (enriched in unusually large VWF multimers) to glycocalicin-coated beads were observed under low shear conditions, which did not result in the attachment of normal plasma VWF.

AAV2 vector harboring a liver-restricted promoter facilitates sustained expression of therapeutic levels of alpha-galactosidase A and the induction of immune tolerance in Fabry mice.

The successful application of gene therapy for the treatment of genetic diseases such as Fabry is reliant on the development of vectors that are safe and that facilitate sustained expression of therapeutic levels of the transgene product. Here, we report that intravenous administration of a recombinant AAV2 vector encoding human alpha-galactosidase A under the transcriptional control of a liver-restricted enhancer/promoter (AAV2/DC190-alphagal) generated significantly higher levels of expression in BALB/c and Fabry mice than could be realized using the ubiquitous CMV promoter (AAV2/CMVHI-alphagal). Moreover, AAV2/DC190-alphagal-mediated hepatic expression of alpha-galactosidase A was sustained for 12 months in BALB/c mice and was associated with a significantly reduced immune response to the expressed enzyme. Subsequent challenge of the AAV2/DC190-alphagal-treated animals with recombinant human alpha-galactosidase A at 6 months failed to elicit the production of anti-alpha-galactosidase A antibodies, suggesting the induction of immune tolerance in these animals. The levels of expression attained with AAV2/DC190-alphagal in the Fabry mice were sufficient to reduce the abnormal accumulation of globotriaosylceramide in the liver, spleen, and heart to basal levels and in the kidney by approximately 40% at 8 weeks. Together, these results demonstrate that AAV2-mediated gene transfer that limits the expression of alpha-galactosidase A to the liver may be a viable strategy for treating Fabry disease.

The mucin-like macroglycopeptide region of glycoprotein Ibalpha is required for cell adhesion to immobilized von Willebrand factor (VWF) under flow but not for static VWF binding.

A dominant feature of the structure of platelet glycoprotein (GP) Ibalpha, the von Willebrand factor (VWF)-binding subunit to the GP Ib-IX-V complex, is the presence of an elongated, heavily glycosylated mucin-like stalk between the plasma membrane and the N-terminal 45-kDa ligand-binding domain. Here, we investigated the function of that region by expressing a mutant lacking residues 318-452 as part of a recombinant GP Ib-IX complex. We studied the VWF-binding function of this mutant under both static conditions and flow. The mutant GP Ibalpha was expressed normally on the surface of CHO bIX cells (stably expressing GP Ibbeta and GP IX) and the proper conformation of the ligand-binding region was verified by the normal binding of 5 conformation-sensitive monoclonal antibodies. Under static conditions, cells expressing mutant GP Ibalpha bound VWF (binding induced by either botrocetin or ristocetin) in a manner indistinguishable from cells expressing wild-type GP Ibalpha. We also evaluated the ability of the mutant to mediate cell adhesion to immobilized VWF in the presence of fluid shear stress (at 2 and 10 dyn/cm(2)). When the mutant-expressing cells were incubated with immobilized VWF for 1 min before being exposed to shear, they rolled on the VWF surface in a manner similar to wild-type cells. However, if the cells were not first allowed to settle on the surface before the application of shear stress, the mutant GP Ibalpha was unable to capture the cells onto the VWF surface from the fluid stream, an indication that steric hindrance from other cell surface molecules may prevent access of the GP Ibalpha ligand-binding site to the surface-immobilized VWF.

Correction of the nonlinear dose response improves the viability of adenoviral vectors for gene therapy of Fabry disease.

Systemic administration of recombinant adenoviral vectors for gene therapy of chronic diseases such as Fabry disease can be limited by dose-dependent toxicity. Because administration of a high dose of Ad2/CMVHI-alpha gal encoding human alpha-galactosidase A results in expression of supraphysiological levels of the enzyme, we sought to determine whether lower doses would suffice to correct the enzyme deficiency and lysosomal storage abnormality observed in Fabry mice. Reducing the dose of Ad2/CMVHI-alpha gal by 10-fold (from 10(11) to 10(10) particles/mouse) resulted in a greater than 200-fold loss in transgene expression. In Fabry mice, the reduced expression of alpha-galactosidase A, using the lower dose of Ad2/CMVHI-alpha gal, was associated with less than optimal clearance of the accumulated glycosphingolipid (GL-3) from the affected lysosomes. It was determined that this lack of linearity in dose response was not due to an inability to deliver the recombinant viral vectors to the liver but rather to sequestration, at least in part, of the viral vectors by the Kupffer cells. This lack of correlation between dose and expression levels could be obviated by supplementing the low dose of Ad2/CMVHI-alpha gal with an unrelated adenoviral vector or by depleting the Kupffer cells before administration of Ad2/CMVHI-alpha gal. Prior removal of the Kupffer cells, using clodronate liposomes, facilitated the use of a 100-fold lower dose of Ad2/CMVHI-alpha gal (10(9) particles/mouse) to effect the nearly complete clearance of GL-3 from the affected organs of Fabry mice. These results suggest that practical strategies that minimize the interaction between the recombinant adenoviral vectors and the reticuloendothelial system (RES) may improve the therapeutic window of this vector system. In this regard, we showed that pretreatment of mice with gamma globulins also resulted in significantly enhanced adenovirus-mediated transduction and expression of alpha-galactosidase A in the liver.

Adenovirus-transduced lung as a portal for delivering alpha-galactosidase A into systemic circulation for Fabry disease.

Gene therapy efforts have focused primarily on the use of either the liver or skeletal muscle as depot organs for the production of a variety of therapeutic proteins that act systemically. Here we examined the lung to determine whether it could function as yet another portal for the secretion of proteins into the circulation. Fabry disease is caused by a deficiency of the lysosomal hydrolase alpha-galactosidase A, resulting in the abnormal deposition of the glycosphingolipid globotriaosylceramide (GL-3) in vascular lysosomes. Pulmonary instillation of a recombinant adenoviral vector (Ad2/CMVHI-alpha(gal)) encoding human alpha-galactosidase A into Fabry mice resulted in high-level transduction and expression of the enzyme in the lung. Importantly, enzymatic activity was also detected in the plasma, liver, spleen, heart, and kidneys of the Fabry mice. The detection of enzymatic activity outside of the lung, along with the finding that viral DNA was limited to the lung, indicates that the enzyme crossed the air/blood barrier, entered the systemic circulation, and was internalized by the distal visceral organs. The levels of alpha-galactosidase A attained in these tissues were sufficient to reduce GL-3 to basal levels in the lung, liver, and spleen and to approximately 50% of untreated levels in the heart. Together, these results suggest that the lung may be a viable alternate depot organ for the production and systemic secretion of alpha-galactosidase A for Fabry disease.

RETRACTED: Factor XI binding to the platelet glycoprotein Ib-IX-V complex promotes factor XI activation by thrombin.

Factor XI binds to high affinity sites on the surface of stimulated platelets where it is efficiently activated by thrombin. Here, we provide evidence that the factor XI binding site on platelets is in the glycoprotein (GP) Ibalpha subunit of the GP Ib-IX-V complex as follows. 1) Bernard-Soulier platelets, lacking the complex, are deficient in factor XI binding; 2) two GP Ibalpha ligands, SZ-2 (a monoclonal antibody) and bovine von Willebrand factor, inhibit factor XI binding to platelets; 3) by surface plasmon resonance, factor XI bound specifically to glycocalicin (the extracellular domain of GP Ibalpha) in Zn(2+)-dependent fashion (K(d)( app) approximately 52 nm). We then investigated whether glycocalicin could promote factor XI activation by thrombin, another GP Ibalpha ligand. In the presence of high molecular weight kininogen (45 nm), Zn(2+) and Ca(2+) ions, thrombin activated factor XI in the presence of glycocalicin at rates comparable with those seen in the presence of dextran sulfate (1 microg/ml). With higher high molecular weight kininogen concentrations (360 nm), the rate of thrombin-catalyzed factor XI activation in the presence of glycocalicin was comparable with that on activated platelets. Thus, factor XI binds to the GP Ib-IX-V complex, promoting its activation by thrombin.