Abstract
Background
Targeting specific tissues remains a major challenge to the promise of gene therapy. For example, several strategies have failed to target adeno-associated virus 2 (AAV2) vectors, to bone. We have evaluated in vitro and in vivo the affinity of an AAV2 vector to bone matrix, hydroxyapatite (HA) to treat Mucopolysacccharidosis IVA.
Methods
To increase vector affinity to HA, an aspartic acid octapeptide (D8) was inserted immediately after the N-terminal region of the VP2 capsid protein. The modified vector had physical titers and transduction efficiencies comparable to the unmodified vector.
Results
The bone-targeting vector had significantly higher HA affinity and vector genome copies in bone than the unmodified vector. The modified vector was also released from HA, and its enzyme activity in bone, 3 months post infusion, was 4.7-fold higher than the unmodified vector.
Conclusion
Inserting a bone-targeting peptide into the vector capsid increases gene delivery and expression in the bone without decreasing enzyme expression. This approach could be a novel strategy to treat systemic bone diseases.
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Introduction
The three major therapies for lysosomal storage disorders, all attempt to partially restore the enzyme activity: (i) hematopoietic stem cell transplantation is somewhat effective, but has a relatively high mortality rate;1 (ii) enzyme replacement therapy improves somatic manifestations and quality of life, but has limited effect on neurological and skeletal symptoms;2 and (iii) gene therapy preclinical trials show the possibility to treat patients with a single infusion of viral or non-viral vectors,3 but clinical trials are limited. In addition, targeting the vector to specific tissues such as bone or brain remains a major challenge.
Mucopolysaccharidosis IVA (MPS IVA, Morquio A disease) is an autosomal recessive disorder caused by the deficiency of lysosomal enzyme N-acetylgalatosamine-6-sulfate-sulfatase (GALNS, EC 3.1.6.4). Estimated incidence is 1 in 250,000 live births.4 GALNS deficiency leads to systemic accumulation of glycosaminoglycans (GAGs), keratan sulfate, and chondroitin-6-sulfate. Clinical features such as marked short stature and skeletal dysplasia have focused therapy on bone manifestations, though other symptoms include laxity of joints and corneal clouding without central nervous system impairment.4 For decades, only surgery (cervical fusion, spinal cord decompression, and hip replacement) and palliative treatments (non-steroidal anti-inflammatory drugs) have been used.4 Recently, the FDA-approved enzyme replacement for Morquio A.5 This treatment showed a modest improvement in the 6-min walk test and provided limited impact on bone lesions.6,7
Hydroxyapatite (HA) is a major inorganic component in bone that binds tightly to proteins via calcium sites.8 Since bone is remodeled by resorption and formation throughout life,8 a drug absorbed by HA may be released during resorption. Therefore, targeting a drug to HA could produce selective delivery to bone.9 This is feasible only if the drug exhibits a high affinity to HA and is retained there. Bisphosphonates, tetracyclines, polymers, and negatively charged peptides have been used for bone-targeted drug delivery.10 Kasugai et al. reported that conjugating fluorescein to a hexapeptide of aspartic acid increased its osteotropicity around 100 times.11 Adding this acidic oligopeptide to estradiol markedly enhanced the delivery of estrogen to the bone.12
Inspired by the success of bone targeting with small molecules, we used the same strategy to a large molecule:enzyme. We showed that the tissue-non-specific alkaline phosphatase enzyme tagged with a peptide of acidic amino acid (AAA) residues had higher affinity for HA and longer retention in bone and bone marrow.13 Thereafter, Millán et al. improved bone mineralization in mice with hypophosphatasia by using bone-targeting alkaline phosphatase enzyme.14 In addition, studies with MPS VII mice showed that AAA-ß-glucuronidase enzyme was delivered to the bone and bone marrow four to five times as efficiently as the unmodified enzyme.15 We also showed that adding an N-terminal AAA peptide to a recombinant GALNS enzyme markedly prolonged its circulation in the blood after intravenous infusion into an MPS IVA murine model. It also remained longer in the bone and substantially cleared the storage materials in bone, bone marrow, and heart valves.16 A similar strategy could alter viral vectors’ tropism. Matsumoto et al. used AAV8 vectors expressing deca-aspartates linked to the C-terminus of soluble TNALP (TNALP-D10) to treat severe infantile hypophosphatasia in mice. Results showed phenotypic improvement in mice treated with the bone-targeted TNALP.17
AAV vectors are a promising tool for gene delivery. AAV vectors are non-enveloped viruses, encapsidated by 60 proteins consisting of VP1, VP2, and VP3 at a 1:1:10 ratio.18 Work on targeted delivery using AAV vectors has focused on rational insertion of defined peptide sequences into the capsid.18 Mutagenesis analysis identified the capsid positions that can hold peptide insertion with reduced impact on packaging and vector transduction.19 In AAV2 vectors, most studies have used residues 138 (VP2 N-terminal), and 587 and 588 [Heparan Sulfate Proteoglycan (HSPG) binding domain] to insert peptides ranging from 5 to 272 amino acids. Capsid proteins modifications improved gene delivery to pancreatic islets,20 lungs,21 muscle,22 myocardium,23 and cancer cells,24 among others. Thus, we hypothesize that a similar approach could alter the tropism of gene therapy vectors to the bone in combination with the addition of AAA peptides.15,16,17
Here we report adding acidic peptide to the AAV2 capsid to improve gene delivery to the bone. We have engineered an AAV2 vector by inserting an AAA peptide after the initial codon of VP2 protein. The AAV2 vectors carrying the human GALNS cDNA were tested to treat MPS IVA. The modified vector was initially tested for HA affinity and in vitro transduction of different cell types. We also systemically infused the modified vector into MPS IVA knock-out mice to evaluate bone and gene product expression at the target site.
Materials and methods
Hydroxyapatite-binding assay
Hydroxyapatite-binding assay was carried out as described previously,13 with slight modifications. Briefly, HA beads were suspended in 25 mM Tris-HCl-buffered saline, pH 7.4, at a concentration of 1000 µg/mL. Wild-type (WT) AAV2 virus, CBA-GALNS, or D8/CBA-GALNS vectors were added at a final concentration of 5 × 1011 and 1 × 1012 vector genome, respectively. Virus was quantified in the supernatant after 1 h incubation at 37 °C and 300 rpm. AAV2 vectors were quantified by spectrophotometric and ELISA methods.
Vector genome biodistribution
A number of 1.5 × 1011 vector genomes of CBA-GALNS or D8/CBA-GALNS vectors were intravenously injected into 7- to 8-week-old Galns−/− mice (n = 3 for each group unless otherwise indicated). Viral titers were measured by ELISA method for all in vivo experiments. MPS IVA control mice were injected with PBS. Mice were euthanized at 24 h, 48 h, and 2 weeks post injection; and brain, liver, and bone (leg) were dissected and immediately frozen in dry ice. N number is six for bone at 48 h for each treatment, except at 2 weeks for CBA-GALNS treatment (n = 2). Bone marrow was obtained after flushing femurs with PBS. Total DNA was extracted by using DNAzol reagent (Gibco) under manufacturer’s instructions and a PowerGen 700 homogenizer (Fisher Scientific, Pittsburgh, PA). Vector genome was quantified by qPCR using the Fast SYBR green Master Mix (Applied Biosystems, Foster City, CA), and primers pCXN-F2:5′-CCTCTAGAGCCTCTGCTAACCATGT-3′ and GALNS-R:5′-GTAGCCGTCCTGTGAGCAGT-3′, which bind to the 3′- and 5′-ends of the CBA promoter and GALNS cDNA, respectively. All mice were housed in a pathogen-free environment with normal diet. All procedures were in accordance with the Institutional Animal Care and Use Committee (IACUC) guidelines under approved protocols at Saint Louis University.
In vivo analysis of GALNS gene expression
Total RNA was extracted from liver, brain, and bone marrow by using Trizol reagent (Invitrogen) under manufacturer’s instructions. RNA from bone was extracted as described previously25 after completely flushing the bone marrow. All data are from CBA-GALNS (n = 2) and D8/CBA-GALNS (n = 3) mice with experimental replicates. First-strand cDNA was synthesized by using the SuperScript® II First-Strand Synthesis System kit (Invitrogen), according to manufacturer’s instructions. Viral cDNA was quantified by qPCR using the Fast SYBR green Master Mix (Applied Biosystems), with 20 ng of the first-strand product. Viral cDNA was amplified with the primers TOMF23:5′-ACAGGGCCATTGATGGCCTAACCTCCT-3′ and pCXN2R:5′-GATCTCAGTGGTATTTGTGAGCCA-3′. Both negative and positive controls were included in each plate. Each study sample was analyzed with two technical replicates. On average, three biological replicates were performed for each treatment. The quantitation of the vector genome was normalized by the housekee** gene, glyceraldehyde-3-phosphate dehydrogenase (GAPDH), which was amplified with primers GAPDH-S:5′-ACCACAGTCCATGCCATCAC-3′ and GAPDH-R:5′-TCCACCACCCTGTTGCTGTA-3′. Thermal cycling conditions used for the qPCR reaction were: 95 °C for 10 min, 40 cycles of 95 °C for 15 s, and 60 °C for 1 min. Fold change was determined by the ΔΔCt method.
GALNS enzyme activity
GALNS enzyme activity was evaluated in the brain, liver, heart, bone (after removal of marrow), and bone marrow. All data are from mice injected with CBA-GALNS (n = 2), D8/CBA-GALNS (n = 3), or PBS (n = 2) and compared to wild-type mice (n = 3) two weeks post injection. In addition, GALNS enzyme activity was measured in the liver and the bone 1 month and 3 months post injection with CBA-GALNS, D8/CBA-GALNS, or PBS (n = 3). Tissues were resuspended in tissue lysis buffer (1 mM phenylmethanesulfonyl-fluoride, 25 mM Tris-HCl, pH 7.2) and homogenized by using a PowerGen 700 homogenizer (Fisher). GALNS activity was assayed by using 4-MU-ß-d-galactopyranoside-6-sulfate (Toronto Chemicals Research, North York, Canada) as a substrate. Enzyme was assayed as described previously.26 One unit was defined as the enzyme catalyzing 1 nmol of substrate per hour. GALNS activity was expressed as U/mL (media) or U/mg protein (cell lysate or tissue homogenized), as determined by micro-Lowry assay.
Immunohistochemistry
Tissues were processed into paraffin, sections were cut on a Leica RM 2135 rotary microtome and dried overnight at 36 °C on Fisher Superfrost Plus slides. Sections were deparaffinized and rehydrated, and antigen retrieval was performed (120 °C, 3 min) using DIVA Decloaker (Biocare Medical). After washing in distilled water twice for 3 min, sections were blocked in PBS containing 5% normal goat serum, 1% bovine serum albumin, and 0.25% triton X-100 in a humidified chamber for 1 h at RT, then incubated in primary antibody GALNS (Epitomics) 1:50, normal rabbit IgG in block solution or Collagen X (Santa Cruz Biotechnology) 1:100 for 2 h at RT. After three washes for 5 min in the PBS, sections were incubated in goat anti-rabbit IgG Rhodamine Red-X (Invitrogen) 1:300 or Alexa Fluor 488 (Jackson Immunoresearch) in the block solution for 1 h at RT in the dark, washed three times for 5 min in PBS in the dark, rinsed in distilled water, and coverslipped in Prolong Gold with DAPI (Invitrogen).
Image analysis
Immunofluorescent imaging was conducted on an Olympus BX41 fluorescent microscope. Confocal imaging was performed on an Olympus FV1000 confocal microscope. Images were analyzed by using Image J software. Total fluorescent intensity of GALNS was quantified by using the mean gray value of the Image J software at a scale of 3.22 pixels/micron.27
Statistical analysis
Kruskal–Wallis multiple comparison test was used to assess treatment effect, time, and tissues among the three groups. Student’s t-test was used to assess pairwise comparisons. An error level of 5% (p < 0.05) was considered significant. All analyses were performed by using SPSS 23 for Windows (SPSS Inc., Chicago, IL). All results are shown as mean ± standard deviation (SD).
Results
Production of modified AAV2 vector
We reported that inserting an aspartic acid octapeptide (D8) into the C-terminal of tissue-non-specific alkaline phosphatase,13 N-terminal of β-glucuronidase,15 and N-terminal of GALNS16 significantly increased the delivery of those enzymes to the bone. Therefore, we applied the same principle to engineer an AAV2 vector for bone-targeting gene delivery. A sequence encoding for D8 peptide was inserted immediately after the initial codon of VP2 protein in the packing plasmid pXX2 (Supplementary Material and Supplementary Figure S1a). Complete sequencing of the modified packing plasmid showed that the sequence was precisely located at the desired location with no fortuitous mutations (Supplementary Figure S1b).
The unmodified (CBA-GALNS) and modified (D8/CBA-GALNS) AAV2 vectors were produced in HEK293 cells, and purified by iodixanol gradient and heparin-affinity column. In previous studies, vector titers varied widely between different quantification methods.28 Thus, we have determined AAV2 titers by spectrophotometry and ELISA. Spectrophotometric titers were 6.2 × 1013 and 6.5 × 1013 vector genome/mL for the unmodified and the modified vectors, respectively, while ELISA titers were 1.3 × 109 and 4.0 × 109 capsids/mL for the unmodified and the modified vectors, respectively. Although there was variation between the spectrophotometric and the ELISA titration methods, both methods confirmed that inserting the bone-targeting sequence into the viral capsid did not affect the packing process and the physical titers. Since the peptide was not inserted into the HSPG-binding site (amino-acid residues 587 and 588), we did not expect an alteration in vector affinity to its natural receptor. In fact, during the heparin-affinity purification step, both the unmodified and the modified vectors were only detected after elution with 1 M NaCl, showing that heparin affinity was not altered.
Hydroxyapatite-binding assay
Two different amounts (5 × 1011 vector genome and 1 × 1012 vector genome) of unmodified (AAV2) and modified (CBA-GALNS and D8/CBA-GALNS) vectors were incubated with HA, and vector titers were quantified in the supernatant after 1 h of incubation at 37 °C. Regardless of the virus amount, AAV2 and CBA-GALNS were present in the supernatant, indicating no binding to HA (Fig. 1). On the other hand, the supernatant showed no vector after HA incubation with D8/CBA-GALNS, implying 100% affinity of the vector to the HA at both vector concentrations (Fig. 1).
In vitro experiments
HA toxicity was evaluated in HEK293 cells prior to transduction experiments in the presence of HA. Cells were incubated for 24 h at 37 °C with 250, 500, 750, 1000, 2500, or 5000 µg/mL of HA. As shown in Supplementary Figure S2a, HA cytotoxicity increased proportionally to HA concentration. To decrease HA cytotoxicity, HA binding was assayed with a final concentration of 100 µg/mL of HA (Supplementary Material). This revised protocol eliminated HA cytotoxicity and maintained optimal vector concentration of 1 × 105 vector genome/cell. In fact, 48 h after adding the HA vector mixture, protein values in the cell lysates were comparable to those obtained in cells transduced without HA addition (data not shown), suggesting that there was no apparent effect on cell viability.
Unmodified and modified vectors were designed to encode the human GALNS cDNA to develop a gene therapy strategy for MPS IVA disease.29,30 Vector transduction was tested in HEK293 cells, human MPS IVA fibroblasts, and murine MPS IVA chondrocytes in the presence or absence of HA. Comparable GALNS enzyme activity levels in cell lysates were observed after transduction of HEK293 cells (10.7±3.1 vs. 13.5±5.1 U/mg), human MPS IVA fibroblasts (5.9±1.1 vs. 6.0±1.2 U/mg), and murine MPS IVA chondrocytes (5.9±1.5 vs. 6.5±0.8 U/mg) with CBA-GALNS and D8/CBA-GALNS vectors, respectively (Supplementary Figures S2b-d). Enzyme activity in transduced fibroblasts and chondrocytes were 44% and 74%, respectively, of levels in WT fibroblasts and chondrocytes, regardless of presence of bone-targeting peptide. Taken together, these results show that AAA peptide in the capsid did not alter the AAV2 vector transduction efficacy.
GALNS enzyme activity levels were not affected in cells transduced with CBA-GALNS vector in the presence of HA (Supplementary Figures S2b-d). GALNS tended to be more active in HEK293 cells transduced with D8/CBA-GALNS in the presence of HA, but this increment was not statistically significant (p = 0.14), and the activity was comparable to that observed in cells transduced with the unmodified vector (Supplementary Figure S2b). Similarly, 10% less GALNS activity in human MPS IVA fibroblasts transduced with D8/CBA-GALNS vector in the presence of HA was not statistically significant compared with those results obtained without HA (Supplementary Figure S2c). These results show that the bone-targeting vector can be released from HA under normal conditions and can transduce different cell types, suggesting that the aspartic octapeptide in the vector capsid does not alter the vector transduction efficiency. PBS was used as negative control of transduction in MPS IVA human and murine-deficient cells.
Vector genome biodistribution
Distribution of unmodified and modified vectors was evaluated in Galns−/− mice. Vector genome (vg) was amplified by using specific primers for the human GALNS cDNA, which do not amplify any other sequence derived from the mouse genome. Only brain, liver, bone and bone marrow are shown here, since other tissues exhibited negligible amounts of vector.
Total vector genome distribution compared to unmodified capsid (CBA-GALNS)
At 48 h post infusion, modified vector had decreased by a factor of 10 in the bone marrow, which contrasted the 10 times increase in the bone. At 48 h, there were more vector genome copies in the bone of mice treated with D8/CBA-GALNS than at 24 h with an unmodified capsid (Fig. 2). Vector genome levels in the bone of mice treated with D8/CBA-GALNS differed significantly (p = 0.034) with time from mice treated with CBA-GALNS. However, bone was the only tissue where vector genome copies differed significantly (p = 0.004) between two treatments. Vector genome distribution was also compared to liver and to 24 h post infusion (Supplementary Figures S3a and b).
These results suggest that D8/CBA-GALNS vector allows retaining vector genome copies at the target site (bone), potentially prolonging the expression of its gene product.
These results were confirmed by immunofluorescence staining (DAPI, GALNS, and/or Collagen X) in the liver and the bone. The intensity of GALNS staining derived from hepatocytes transduced with CBA-GALNS and D8/CBA-GALNS vectors showed less signal at 48 h than at 12 h after infusion. (CBA p = 0.022; D8/CBA p = 0.06) (Fig. 3a).
Those liver findings contrasted with findings in the trabecular bone. In the trabecular bone, mice transduced with D8/CBA-GALNS showed higher signal at 48 h than modified and unmodified vector at 12 h post infusion (p < 0.001) (Fig. 3b).
In summary, these results indicate that AAA peptide in the capsid vector facilitates a significant increase in gene delivery to the bone.
GALNS gene expression
GALNS gene expression was analyzed in the brain, liver, bone, and bone marrow 2 weeks after infusion. These tissues were selected based on the vector genome distribution profile. The greatest change in GALNS gene expression of mice treated with D8/CBA-GALNS relative to CBA-GALNS was observed in the bone, average fold change was 1559 (1187–1932). In the brain and liver, fold change in gene expression to CBA-GALNS were 0.66 (0.53–0.79) and 0.77 (0.65–0.89), levels not considered significant for both vectors. On the other hand, the GALNS gene expression in bone marrow was reduced about one-tenth, average fold change: 0.09 (0.07–0.11) (Fig. 4a). GALNS gene expression was not detected in any tissue of Galns−/− mice infused with PBS.
GALNS enzyme activity
Two weeks post injection
The GALNS enzyme activity in tissues 2 weeks after injection is shown in Fig. 4b. Injections with CBA-GALNS or D8/CBA-GALNS led to activity increases in liver, brain, heart, and bone marrow (19% vs. 24%, 45% vs. 35%, 28% vs. 62%, and 12.4% vs. 13.8% of WT enzyme activity levels, respectively). Enzyme activity in the bone was 4.8% (1.3±1.9 U/mg) and 42% (11.8±5.6 U/mg) in CBA-GALNS and D8/CBA-GALNS mice, respectively. Comparison of CBA-GALNS and D8/CBA-GALNS showed increased levels of enzyme activity in D8/CBA-GALNS when compared to CBA-GALNS in liver (p = 0.82), heart (p = 0.37), bone (p = 0.07), and bone marrow (p = 0.61), although not significant.
One month and three months post injection
Specific GALNS activity was measured in liver and bone of mice injected with CBA-GALNS or D8/CBA-GALNS, showing that the activity in bone 3 months after injection grew to therapeutic levels (Fig. 4c). Since the CBA promoter yields ubiquitous transgene expression, high activity was expected in the liver (CBA-GALNS 1mo vs. D8/CBA-GALNS 1mo, p < 0.05).
Thus, all parameters studied in the bone (vector genome, GALNS gene expression, and GALNS enzyme activity) demonstrate that AAA peptide in the vector capsid not only increases gene tropism to the bone, but also elevates gene expression and enzyme activity in the bone.
Discussion
Develo** systemically injectable gene delivery vectors is critical for bone disease gene therapies. This study aimed to target an AAV2 vector to the bone and evaluate the efficiency of gene delivery and expression levels in a Galns−/− mouse model. We demonstrated that including AAA peptide into the vector capsid: (1) does not affect packing and transduction, (2) enhances in vivo gene delivery, and (3) increases the expression of its gene product in bone.
Here for the first time, we have demonstrated successful delivery of a gene therapy vector to bone by inserting a bone-targeting peptide into the vector capsid.
During the last decade, special attention has been paid to altering viral vectors’ natural tropism.18 AAV2 vectors have been extensively studied for peptide insertion sites, kind of peptides, and the effect on vector genome packing, transduction efficiency, and tissue targeting.18 N-terminal region of the VP2 protein represents one of the most studied capsid positions that allows peptide insertion with minimum effect on DNA packaging and virus trafficking.18 Serpin receptor ligand (KFNKPFVFLI) inserted after position 138 increased viral transduction 15-fold in IB3 cells.19 An ApoE-derived ligand inserted after position 138 led to a 90-fold increase in in vitro transduction of pancreatic islet cells and a fourfold increase of expression of human antitrypsin.20 Such studies show progress in AAV retargeting to desired tissues, but the biodistribution and targeting of AAV vectors to bone remained unsolved.31
Our present study inserting AAA peptide into the viral capsid shows successful vector targeting to the bone. We also show that a highly negatively charged peptide in the N-terminal of VP2 protein was well tolerated, without reducing physical titers and transduction efficiency. These results agree with the fact that inserting peptides after the N-terminal region of the VP2 protein does not affect the physical and infectious titers.19,20,32 In addition, inserting AAA peptide did not affect heparin affinity of the vector, since the HSPG-binding site is distant from the VP2 N-terminal, and they do not come close together in final capsid assembly.33 This result agrees with previous findings that inserting a peptide after the N-terminal of VP2 does not affect the vector binding to the natural receptor (HSPG) or heparin column used in purification steps.19,20,32 Lee et al., inserted the same acidic oligopeptide in the AAV2 capsid for muscle targeting.23 They observed no effect on vector titers, which agrees with our results. However, since the oligopeptide was inserted after amino acid 587 (the HSPG-binding site), the vector lost the ability to transduce HEK293 cells or human chondrocytes, and showed different transduction and tropism profiles to those of D8/CBA-GALNS vector.23
Zincarelli and colleagues34 found AAV2 vector genome in all mouse tissues investigated (heart, lung, liver, kidney, testes, brain, and muscle) at comparable levels, while gene expression was only detected in heart, liver, and muscle. However, vector distribution in the bone was not assessed. Herein, we show that an AAV2 vector itself has very low affinity for HA both in vitro and in vivo, which could be associated with positively charged residues at the receptor-binding site.35 More notably, although the bone-targeting vector has a marked affinity for HA both in vitro and in vivo, the vector can be released from the HA and can transduce cells without the loss of infectious efficiency. How the vector is released in vitro remains unknown, but in vivo, it has been proposed that a molecule tagged to the bone by using the AAA peptide could be released during bone matrix resorption.11,12
A single copy of AAA peptide was initially used for bone targeting of small molecules (estradiol) and then large molecules (recombinant enzymes: 50–100 kDa).11,12,13,14,15,16 We have demonstrated herein that this strategy can modify the tropism of even a macromolecule, a viral vector of ~5000 kDa. Higher affinity to HA (100%) and better bone targeting were achieved by using multiple copies of AAA peptide, in comparison with the reports for recombinant enzymes.13,14,15,16 This efficient retargeting can be explained by a higher copy number of an AAA peptide, since AAV2 capsid is composed of 60 subunits of VP1, VP2, and VP3 at a molar ratio of approximately 1:1:10, leading to five VP1 and five VP2 proteins containing the bone-targeting sequence.18,33
Previously, we showed the ability to treat MPS IVA by gene therapy in vitro.29,30,36 We evaluate here in vivo with a new targeting strategy. Although the enzyme was less active than in WT mice, the activity was sufficient to improve lesions. Noteworthy, the activity in bone from D8/CBA-GALNS-treated mice was 42% of WT levels, whereas in the mice treated with the unmodified vector these levels were only 4.8% of WT levels, indicating the marked advantage of using AAA peptide into the vector capsid. Previous studies showed that recombinant GALNS enzyme was poorly distributed to the bone,26 and that including a bone-targeting peptide to the recombinant enzyme allowed increased distribution more specific to the bone, improving the therapeutic effect.16 Hence, we may expect substantially improved pathology after a long-term treatment of MPS IVA mouse model with this bone-targeting approach.
Elevated enzyme activity observed in treated mice agrees with previous reports of gene therapy in adult MPS mouse models treated with AAV2 vectors.37 Although in adult mice extensive bone disease cannot be reversed, its progression can be ameliorated. Several studies show that: (i) enzyme activity in the plasma and tissues should be supraphysiological to correct bone pathology in adult mice38 or that (ii) treatment should begin at the neonatal stage.39 In this regard, further studies should focus on long-term evaluation of the therapy (specially the effect in growth plate), neonatal treatment of mice, evaluating other AAV serotypes (AAV8), and other bone-targeting peptides with different amino acids (such as glutamic acid) or size.
Conclusion
We have demonstrated that targeting an AAV2 vector to bone can be markedly improved by inserting eight aspartic amino acids into the N-terminal of the VP2 protein. This modification not only increases copies of viral genomes in the bone, but also yields substantial enzyme activity in the bone. This novel capsid thus allows AAV vectors to treat a variety of other lysosomal storage disorders with bone dysplasia, as well as other bone diseases. Further long-term studies in vivo are required to validate this strategy by assessing the pathological and clinical improvement in the bone, starting age for treatment, and correlation between enzyme activity in blood and efficacy of treatment.
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Acknowledgements
We are grateful to Dr. Guang** Gao for his critical comments to our work, Dr. Paula Buchanan for statistical assistance; and Eric Shelley, Dr. Qi Gan, and Dr. Michael Flanagan for their technical assistance. We also thank Mike Marcinkowski for editorial assistance. This project was supported in part by the International Morquio Organization (Carol Ann Foundation) and Austrian MPS Society. C.J.A.-D. was supported by Departamento Administrativo de Ciencia, Tecnología e Innovación—Colciencias (Colombia, ID PRY 5174, Grant 120356933205). C.J.A.-D. and L.A.B. were supported by Pontificia Universidad Javeriana (ID PRY 3763 and 3916). S.T. and A.M.M. were supported by the National Institutes of Health grant R01HD065767.
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C.J.A.-D., A.M.M., L.A.B., and S.T. designed the research. C.J.A.-D. and A.M.M. performed the research. C.J.A.-D., A.M.M., L.A.B., and S.T. analyzed the data. C.J.A.-D., A.M.M., and S.T. contributed to report the work described. The manuscript was written through contributions of all authors. All authors have given approval to the final version of the manuscript.
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The authors have US patent 7,972,593 issued on 5 July 2011. The patent covers the underlying concept of AAV vector with bone targeting described in the manuscript. S.T. was a former employee at Saint Louis University, where the experiments were conducted and completed.
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Alméciga-Díaz, C.J., Montaño, A.M., Barrera, L.A. et al. Tailoring the AAV2 capsid vector for bone-targeting. Pediatr Res 84, 545–551 (2018). https://doi.org/10.1038/s41390-018-0095-8
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DOI: https://doi.org/10.1038/s41390-018-0095-8
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