Introduction

Hypophosphatasia (HPP) is a rare congenital disease caused by mutations in the gene encoding tissue-nonspecific alkaline phosphatase (TNALP) [1, 2]. HPP is characterized by defective calcification of hard tissue, pathologic fracture, dyspnea, seizures, and premature tooth loss [3, 4]. It is classified into six different types according to the age at onset and symptoms: perinatal severe HPP, perinatal benign HPP, infantile HPP, childhood HPP, adult HPP, and odonto-HPP [5, 6], with perinatal severe HPP and childhood HPP frequently being fatal [7, 8]. However, treatment for HPP has not been well established.

Whyte et al. first applied enzyme replacement therapy (ERT) by infusion of alkaline phosphatase (ALP)-rich plasma to an infantile patient with HPP [9]. In 2008, Millán et al. developed a novel ERT using bioengineered TNALP. The novel construct was formed by detaching the glycosylphosphatidylinositol (GPI) anchor from TNALP to allow secretion and adding a deca-aspartate motif to the C terminus (TNALP-D10) to increase affinity for bone [10]; the latter was possible because TNALP is an ectoenzyme whose C terminus is anchored to the cell surface by a GPI anchor glycoprotein composed of approximately 500 amino acid residues [11]. This method clearly improved the phenotype of TNALP-deficient mice [10]. Furthermore, this method was applied to patients with HPP and was effective in prolonging life span [12, 13]. In 2015, therapy with TNALP-D10 was approved for the treatment of HPP in Canada, Europe, Japan, and the USA. Although this therapy is effective in extending life and enabling patients to be weaned from artificial ventilation [14, 15], further improvements are necessary to address the following issues: (1) the HPP patient needs to receive repeated subcutaneous injections three times a week due to the short half-life of the enzyme [12], (2) the replacement enzyme dose must be increased as the patient grows, and (3) they have to continue treatment for life [16].

To resolve these problems, several approaches have been taken to establish a gene-based therapy to replace the enzyme. We have explored this approach using various viral vectors in Akp2−/− (TNALP-knockout) HPP model mice, as they exhibit dyspnea, seizures, growth failure, and bone hypoplasia, resulting in death within 3 weeks of birth [17]. Recently, Nakano et al. showed that gene correction of induced pluripotent stem cells (iPS cells) isolated from two HPP patients rescued ALP activity and mineralization in vitro [18], suggesting a possible application of gene-corrected iPS cells for patients with HPP. These in vivo and in vitro experimental systems provide opportunities to develop a new therapy that complement the disadvantages of ERT.

Our previous studies demonstrated that a single injection of adeno-associated virus (AAV) vector, which is not pathogenic to humans and is very safe, expressing TNALP-D10 in an Akp2−/− HPP model mice successfully extended survival and corrected skeletal phenotype [19, 20]. However, several insufficient therapeutic effects were observed in skeletal tissues including hypomineralization of bone and cartilage, irregularly arranged trabeculae, partial cortical bone defects, and abnormal chondrocyte layer proliferation [20]. Although these problems are not directly life-threatening, improved treatment methods are required to prevent severely diminished physical activity.

We conjectured the non-completeness of therapeutic effects observed in the previous study [20] might be caused by insufficient local replacement of ALP in the bone and cartilage. In this study, to validate our assumption, we determined the optimal AAV vector dose for increasing the local ALP concentration in bone and mitigating femoral elongation, morphological irregularity and hypomineralization. Furthermore, we investigated the efficacy of this dose in terms of mechanical properties of the femur and spontaneous locomotor activity.

Methods

Plasmid Construction and AAV Vector Production

The recombinant self-complementary AAV (scAAV) vector plasmid, pscAAV-CB-EGFP, was provided by Dr. Arun Srivastava of the University of Florida College of Medicine (Gainesville, FL, USA). The plasmid pscAAV-CB-TNALP-D10 was constructed by replacing the enhanced green fluorescence protein (EGFP) region of pscAAV-CB-EGFP with the AgeI–HindIII fragment (TNALP-D10 gene) of pAAV-CAGS-TNALP-D10 using an In-Fusion HD Cloning Kit (Clontech Laboratories, TaKaRa Bio Company, Ohtsu, Shiga, Japan). Recombinant scAAV8-CB-TNALP-D10 was generated using polyethylenimine-based adenovirus-free triple transfections of HEK293 cells in serum-free medium [21]. The AAV vector titer was determined using real-time polymerase chain reaction (PCR) using a 7500 Fast Real-Time PCR Instrument (Applied Biosystems, Carlsbad, CA) with the following primers for the TNALP-D10 gene: forward, 5′-CCGTGGCAACTCTATCTTT-3′ and reverse, 5′-GAGACATTCTCTCGTTCACC-3′.

Animal Procedures and Vector Injection

TNALP-knockout Akp2−/− mice and Akp2+/+ mice were obtained by mating Akp2+/− mice with mice with a mixed genetic background of 129/J and C57BL/6 J, which were generated in the Millán laboratory (La Jolla, CA) [17]. All mice were fed ad libitum a rodent diet supplemented with 325 ppm pyridoxine (vitamin B6)/10 kg of feed (Oriental Yeast Co., Ltd., Tokyo, Japan) to suppress seizures [22]. Genotyping was performed using PCR with the following primers immediately after birth: forward, 5′-AGTCCGTGGGCATTGTGACTA-3′; and reverse, 5′-TGCTGCTCCACTCACGTCGAT-3′. To characterize the expression of TNALP-D10, scAAV8-CB-TNALP-D10 was injected into both quadriceps femoris muscles of neonatal Akp2−/− mice on day 1 after birth. The amount of vector injected was 1.5 × 1011 (n = 8), 7.5 × 1011 (n = 7), 1.5 × 1012 (n = 7), or 4.5 × 1012 (n = 7) vector genomes (v.g.)/body diluted with phosphate-buffered salts (PBS) to a total volume of 20 µL. The physical appearance of the mice was observed regularly, and body weight was measured every 10 days for 90 days. To examine the therapeutic effects of scAAV8-CB-TNALP-D10, the treated Akp2−/− mice were sacrificed at 90 days of age and perfused with 15 mL of PBS. Tissue samples were taken from the heart, liver, lung, spleen, kidney, quadriceps femoris muscle, genitalia, bone (both hind limbs), and brain. Akp2+/+ mice of the same age were used as controls (n = 7).

ALP Activity in Serum

Blood samples were collected from the tail vein or inferior vena cava using a 29-gauge insulin syringe on days 30, 60, and 90 after birth (n = 7). ALP activity in the serum was measured using a colorimetric assay, as described previously [23], with 1 U being the amount of enzyme needed to catalyze the generation of 1 µmol p-nitrophenol per min.

X-ray Analysis

All the radiographic images were recorded on µFX-1000 film (Fujifilm, Tokyo, Japan). Imaging conditions were as follows: tube voltage, 25 kV; tube current, 100 µA; exposure time, 30 s [20]. At 90 days after birth, hind limbs were X-ray irradiated and imaged with a Typhoon FLA-7000 scanner (Fujifilm) (n = 7).

Micro-computed Tomography Imaging

Micro-computed tomography (micro-CT) analysis was performed using an TDM-1000 scanner (Yamato Scientific, Tokyo, Japan). Imaging conditions were as follows: matrix size, 1024 × 1024; tube voltage, 60 kV; tube current, 60 µA; magnification, × 3.5; filter, 0.1 mm brass; slice pitch, 17 µm; voxel size, 17 × 17 × 17 (µm). The growth plate and midshaft were selected as the scan site (midshaft = half of the entire length) [24] (n = 5).

Morphometric Evaluation of Trabecular Bone

To analyze femur morphometry, we employed the 3D analytical software TRI/3D-BON (Ratoc System Engineering, Tokyo, Japan). The region of interest (ROI) was 1-mm-thick and positioned 0.5 mm above the growth plate. Bone mineral density, bone volume/tissue volume, trabecular number, trabecular thickness, trabecular separation, and marrow space star volume were semi-automatically determined in accordance with the guidelines for evaluation of bone microstructure using 3D images [24, 25].

Histological Analysis

Prepared knee joints were fixed in 4% paraformaldehyde in PBS and embedded in Super Cryoembedding Medium compound (Leica Microsystems, Wetzlar, Germany). Then, they were frozen without decalcification. Sections 10-µm-thick were prepared by the Kawamoto method [26] using Cryofilm Type IIC (9) (Leica Microsystems, Wetzlar, Germany), air-dried for 10 min, washed with PBS, and further washed with distilled water. To examine cartilage structure, sections were stained with Alcian blue solution pH 2.5 (Muto Pure Chemicals, Tokyo, Japan) for 30 min, washed with distilled water for 2 min, and counterstained with Kernechtrot (nuclear fast red) stain solution (Muto Pure Chemicals) for 1 min. Standard hematoxylin and eosin (H&E) staining was performed for histological observation. To analyze ALP replenishment areas, sections were stained using an ALP-staining kit (Muto Pure Chemicals) for 120 min at 37 °C. Sections were mounted on MAS-coated glass slides (Matsunami Glass, Tokyo, Japan) and examined under a light microscope (n = 5).

Finite Element Analysis

The reconstructed 3D-images obtained using micro-CT were exploited for finite element analysis (FEA). The ROI was set with the anterior–posterior axis as the X-axis, the internal–external axis as the Y-axis, and the major axis as the Z-axis. It was defined as a 2-mm-thick region spanning from 1.8 mm proximal to 0.2 mm distal to the growth plate. Using Carter’s equation [27], the Young’s modulus was set at 22 GPa for cortical bone and 6 GPa for trabecular bone, and the Poisson ratio was set at 0.30 for both bone types. A strain was applied to the entire proximal side of the cortical bone and trabecular bone. The element on this surface was restrained to 1 voxel. Bone fracture was defined as a minimal principal strain of 10% or more, and forced displacement was stopped when bone fracture reached 2% or more of bone volume [28]. Simultaneously, the total reaction force on the bottom surface (= fixed area) was analyzed as a fracture load using the TRI/3D-FEM64 FEA software (Ratoc System Engineering, Tokyo, Japan) [29] (n = 5).

Spontaneous Locomotor Activity

The spontaneous locomotor activity of mice was measured using a dual activity monitor system (Shinfactory, Fukuoka, Japan). This system comprised a rectangular enclosure (30 × 20 cm2) containing a wheel; the side wall of the enclosure had infrared sensors at 2-cm intervals [30]. The system was placed in a softly illuminated sound-proof room. At 85 days after birth, Akp2+/+ mice, and Akp2−/− mice injected with AAV vector at 1.5 × 1011 or 4.5 × 1012 v.g./body, were put in the system. After 1 day of training, spontaneous movement was recorded for 5 days to determine planar movement (floor movement) count number, wheel movement rotational number, wheel movement total distance, wheel movement average speed (average running speed other than 0), wheel movement activity time, and wheel movement acceleration (maximum running speed); each parameter was calculated per day. The spontaneous locomotor activity analyses were carried out using a ACTIMO-DATAII software (Bio Research Center, Aichi, Japan) (n = 5).

Statistical Analysis

All data are presented as the mean ± SD. Bartlett’s test was used to confirm that the data showed a normal distribution and similar variance among groups. Differences between multiple groups were examined using one-way analysis of variance (single-factor ANOVA) and Tukey–Kramer post hoc tests. P values less than 0.05 were considered statistically significant. Survival rates were estimated using the Kaplan–Meier method, and the differences in survival rates were examined using the log-rank test. Statistical analyses were conducted in Statcel 4 for Windows (OMS, Saitama, Japan).

Results

Elevated Serum ALP Activity and Prolonged Survival in Akp2−/− Mice Following Intramuscular Injection of scAAV8-CB-TNALP-D10

The vector scAAV8-CB-TNALP-D10 was administered intramuscularly to Akp2−/− mice at 1.5 × 1011, 7.5 × 1011, 1.5 × 1012, or 4.5 × 1012 v.g./body on day 1 after birth. To determine ALP levels in the serum, ALP activity was measured via a colorimetric assay every 30 days after AAV vector injection. The serum ALP activity rapidly increased in all groups. The effect of the AAV vector was dose dependent: Akp2−/− mice treated at 1.5 × 1011, 7.5 × 1011, 1.5 × 1012, or 4.5 × 1012 v.g./body showed on average 1.69, 1.94, 8.45, and 24.97 U/mL serum ALP activity, respectively, at day 90 after birth (Fig. 1a). High vector copy numbers were observed in the liver and in quadriceps femoris muscles (the injection sites) (Fig. S1A). Moreover, ALP activity was very high in the quadriceps femoris muscle but low in the liver (Fig. S1B). Untreated Akp2−/− mice had a normal appearance but experienced epileptic seizures and hypomineralization by day 10 after birth and died within 3 weeks of birth. In contrast, treated mice displayed significantly prolonged survival rates at all vector doses (P < 0.001, log-rank test) (Fig. 1b).

Fig. 1
figure 1

Effect of TNALP-D10 dose on serum ALP activity and survival rate. Akp2−/− mice were untreated or injected with the indicated doses of AAV vector (scAAV8-CB-TNALP-D10) at day 1 after birth. Untreated Akp2+/+ mice were used as a control. a Serum ALP activity measured at the indicated days after birth. Error bars, SD (n = 7). b Kaplan–Meier survival analysis of AAV vector-treated Akp2−/− mice. Treatment with AAV vector at all test doses improved the survival rate significantly compared with that of untreated mice. ***P < 0.001

Promotion of Weight Gain and Femur Elongation by a High Dose of TNALP-D10

Body weight and femur length were used to assess the growth of AAV vector-transduced mice. Akp2−/− mice treated with a high dose (4.5 × 1012 v.g./body) of AAV vector achieved normal weight gain at day 90 after birth: that is, the body weight of the treated mice (24.58 ± 1.89 g) was similar to that of the control mice (24.78 ± 2.49 g). However, Akp2−/− mice treated with lower doses showed stagnated weight gain after day 20 (Fig. 2a); the differences in body weight between these groups and the control mice were significant at day 90 (> 5 g difference; Fig. 2b). In X-ray images taken at day 90, irregular shapes of the knee joint were seen in the hind limbs of mice treated with the lowest dose (1.5 × 1011 v.g./body) and two middle doses (7.5 × 1011 v.g./body and 1.5 × 1012 v.g./body) of AAV vector; conversely, control mice and mice treated with the highest does (4.5 × 1012 v.g./body) exhibited normal knee joint formation (Fig. 2c). Femur lengths did not differ significantly between mice treated with 4.5 × 1012 v.g./body (14.02 ± 0.43 mm) and control mice (14.66 ± 0.38 mm); however, mice treated with lower doses had significantly shorter femurs than control mice (> 2 mm difference; all P < 0.01; Fig. 2d).

Fig. 2
figure 2

Effect of TNALP-D10 high-dose on growth. Akp2−/− mice were untreated or injected with the indicated doses of AAV vector (scAAV8-CB-TNALP-D10) at day 1 after birth. Untreated Akp2+/+ mice were used as a control. a All mice were weighed after birth and then every 10 days until day 90. The growth curve of Akp2−/− mice treated with 4.5 × 1012 v.g./body vector was similar to that of the control mice. Error bars, SD (male, n = 4; female, n = 3). b Weight comparison of each group at 90 days after birth. Mice treated with 4.5 × 1012 v.g./body showed a similar weight gain to that of the control mice. Error bars, SD (male, n = 4; female, n = 3). *P < 0.05; **P < 0.01: NS, not significant. c Representative X-ray images of the hind limbs of mice treated with 4.5 × 1012 v.g./body, taken at 90 days after birth; the bone structure at the joint showed normal morphology. Whereas irregular shapes of the knee joint is seen in the hind limbs of mice treated with the lower doses (1.5 × 1011 v.g./body, 7.5 × 1011 v.g./body and 1.5 × 1012 v.g./body) of AAV vector. White arrows are irregular knee shape. Scale bars, 4 mm. d Femur lengths of mice treated with 4.5 × 1012 v.g./body AAV vector were similar to those of control mice. Error bars, SD (n = 7). **P < 0.01: NS, not significant

Restoration of Normal Bone Structure and Bone Quality Upon Administration of High Dose of TNALP-D10

We conducted a micro-CT analysis of the femoral structure in Akp2−/− mice treated with AAV vector at 1.5 × 1011 v.g./body or 4.5 × 1012 v.g./body. The images showed irregular shape of growth plate, decrease in trabecular bones and defect and thinning of cortical bone in the mice treated with 1.5 × 1011 v.g./body. In contrast, these morphological abnormalities were not observed in mice treated with 4.5 × 1012 v.g./body; these mice exhibited the same bone structure as the control mice (Fig. 3a). In trabecular bone analysis of the ROI, images indicated that mice exhibited numerous cavities as a result of the low number of trabeculae and the bone width unusually wide in mice treated with 1.5 × 1011 v.g./body. In marked contrast, the bone structure was normal in mice treated with 4.5 × 1012 v.g./body (Fig. 3b). Indeed, for all parameters measured in the trabecular bone analysis (bone mineral density, bone volume/tissue volume, trabecular number, trabecular thickness, trabecular separation, and marrow space star volume), the values in mice treated with 1.5 × 1011 v.g./body were significantly lower than those in control mice and there was no significant difference between mice treated with 4.5 × 1012 v.g./body and control mice (Fig. 3c).

Fig. 3
figure 3

Micro-CT analysis of the effect of TNALP-D10 high-dose on bone structure. Akp2−/− mice were injected with the indicated dose of AAV vector (scAAV8-CB-TNALP-D10) at day 1 after birth. Untreated Akp2+/+ mice were used as a control. a Representative micro-CT images of femur taken on day 90 after birth. Femurs of mice treated with 4.5 × 1012 v.g./body displayed uniform cortical bone, and there were no differences in epiphyseal cupping compared with control mice. However, femur of mice treated with 1.5 × 1012 v.g./body showed defects (white arrows) and thinning (yellow arrow) of cortical bone. White box indicates irregular shape of growth plate. Scale bars, 1 mm. b Images of regions of interest (ROIs) in cancellous bone analysis. Trabecular arrangement in the ROI of the mice treated with 4.5 × 1012 v.g./body was similar to that in the control mice. Scale bars, 1 mm. c Morphometric evaluation of trabecular bone. In the mice treated with 4.5 × 1012 v.g./body, all parameters examined were recovered to the same values as those in control mice. BMD, bone mineral density; BV/TV, bone volume/tissue volume; Tb.N, trabecular number; Tb.Th, trabecular thickness; Tb.Sp, trabecular separation; V*m. Space, marrow space star volume. Error bars, SD (n = 5). *P < 0.05; **P < 0.01: NS not significant

Normal Skeletal Structure in Histological Analysis Following a High Dose of TNALP-D10

To observe the condition of cartilaginous tissue, the growth plate and epiphysis of the femurs of treated mice were subjected to Alcian blue staining and Kernechtrot counterstaining. In Akp2−/− mice treated with 1.5 × 1011 v.g./body, the growth plate cartilage was structurally disrupted and abnormally arranged, and the articular cartilage in the epiphysis was abnormally thick. In contrast, the arrangement of the growth plate cartilage and the thickness of articular cartilage in the epiphysis in Akp2−/− mice treated with 4.5 × 1012 v.g./body was similar to that in control mice (Fig. 4a). Ectopic fibrous tissue was observed in H&E staining images of the epiphysis and cortical bone in mice treated with 1.5 × 1011 v.g./body, but not in those treated with 4.5 × 1012 v.g./body or in control mice (Fig. 4b).

Fig. 4
figure 4

Histological examination of the effect of TNALP-D10 high-dose on bone structure. Akp2−/− mice were injected with the indicated doses of AAV8 vector (scAAV8-CB-TNALP-D10) at day 1 after birth. Untreated Akp2+/+ mice were used as a control (n = 5). a Alcian blue and Kernechtrot (nuclear fast red) staining of femur, growth plate, and epiphysis at 90 days after birth. The growth plate chondrocyte layer of mice treated with 4.5 × 1012 v.g./body was regularly arranged, whereas mice treated with 1.5 × 1011 v.g./body was irregular arranged. Scale bars: femur, 500 µm; growth plate, 200 µm; glenoid fossa, 200 µm. b Hematoxylin and eosin staining. Black arrows indicate ectopic fibrous tissue. Abnormal fibrous tissue was not observed in mice treated with AAV vector at 4.5 × 1012 v.g./body. Scale bars: femur, 500 µm; glenoid fossa, 200 µm; and cortical bone, 200 µm. c ALP staining. Black arrows indicate weak positive spots for ALP. In mice treated at 4.5 × 1012 v.g./body, the levels of serum ALP were sufficient for ALP to be distributed locally in the bone. Scale bars: femur, 500 µm; growth plate, 200 µm; glenoid fossa, 200 µm; cortical bone, 200 µm. d Ectopic structure images. Ectopic structures were detected in both mice treated with 1.5 × 1011 v.g./body and those treated with 4.5 × 1012 v.g./body. Black arrows indicate ectopic structure. Scale bars, 200 µm

We performed ALP staining of the growth plate, epiphysis, and cortical bone in the femurs of Akp2−/− mice treated with 1.5 × 1011 or 4.5 × 1012 v.g./body. The ALP distribution in mice treated with 4.5 × 1012 v.g./body was similar to that in control mice: i.e., ALP was distributed in the hypertrophic chondrocyte layer of the growth plate, the surface of glenoid trabecular bone, and the periosteum. However, only a few weak spots of ALP were observed in mice treated with 1.5 × 1011 v.g./body (Fig. 4c). Ectopic structures were not observed in control mice but were observed in the knee joint or cortical bone near the knee joint in mice treated with 1.5 × 1011 or 4.5 × 1012 v.g./body. The properties of ectopic structures differed between mice treated with 1.5 × 1011 and those treated with 4.5 × 1012 v.g./body, as outlined below. The ectopic structures in mice treated with 1.5 × 1011 were restricted to irregular chondrocytes; ALP staining was negative and mineralization was not observed. In contrast, the ectopic structures in mice treated with 4.5 × 1012 were ectopic bones, in which the trabecular bone construction and detected surface of trabecular bone were ALP positive (Fig. 4d).

Ability of Femoral Strength to Withstand Normal Mechanical Stress Following High Doses of TNALP-D10

We performed FEA of the femur epiphysis in Akp2−/− mice treated with 1.5 × 1011 or 4.5 × 1012 v.g./body; the ROI and analytical conditions are shown in Fig. 5a. The bone strength (fracture load) of mice treated with 1.5 × 1011 v.g./body was significantly lower than that of control mice. In contrast, the bone strength of mice treated with 4.5 × 1012 v.g./body mice did not differ significantly from that of control mice (Fig. 5b).

Fig. 5
figure 5

FEA assessment of the effect of TNALP-D10 high-dose on femoral strength. Akp2−/− mice were injected with the indicated doses of AAV vector (scAAV8-CB-TNALP-D10) at day 1 after birth. Untreated Akp2+/+ mice were used as a control (n = 5). a Schematic of a region of interest (ROI) and analytical conditions. X-axis, anterior–posterior axis; Y-axis, internal–external axis; Z-axis, major axis. b Fracture load was determined by FEA at 90 days after birth. The femurs of mice treated with 4.5 × 1012 v.g./body could tolerate mechanical stress to a similar level as those of control mice. Error bars, SD. *P < 0.05; **P < 0.01: NS not significant

Failure to Restore Normal Spontaneous Locomotor Activity with a High Dose of TNALP-D10

Using a wheel cage, we investigated the spontaneous locomotor activity of Akp2−/− mice treated with AAV vector at 1.5 × 1011 or 4.5 × 1012 v.g./body (Fig. 6). The present study is the first to include a long-term analysis of spontaneous activity. There was no significant difference in the planar movement count number between the AAV-treated mice and the control mice. However, wheel movement was significantly lower in terms of rotation number, total distance, and activity time in both mice treated with 1.5 × 1011 v.g./body and those treated with 4.5 × 1012 v.g./body than in control mice.

Fig. 6
figure 6

Effect of TNALP-D10 dose on spontaneous movement. Akp2−/− mice were injected with the indicated doses of AAV8 vector (scAAV8-CB-TNALP-D10) at day 1 after birth. Untreated Akp2+/+ mice were used as a control. In terms of wheel movement rotation number (/day) and wheel movement total distance (m/day), spontaneous movement was significantly lower in mice treated with both 1.5 × 1011 v.g./body and 4.5 × 1012 v.g./body than in the control mice. Error bars, SD (n = 5). *P < 0.05; **P < 0.01: NS not significant

Discussion

In previous studies, we successfully prolonged the survival of HPP mice by TNALP-D10 replacement via the single administration of lentivirus vector [31] or an AAV vector [19, 20]. However, detailed analysis of the femurs of these mice revealed issues, including morphological irregularity, insufficient extension, and hypomineralization, suggesting that the condition was not fully resolved and that the AAV vector dosage may have been suboptimal [20]. Considering the application to patients with HPP, these results suggested that suboptimal dose would not prevent patients from suffering from growth impairment leading to short stature and persistent susceptibility to fractures. Because the most severe type of HPP affects infants and young children at an age when they are growing rapidly, growth impairment causing short stature is psychologically distressing for both patients and their families, and persistent susceptibility to fractures leads to skeletal deformity and ultimately contributes to impaired physical function. Accordingly, although these problems are not life-threatening, they severely diminish the QOL of patients and their families [32,33,34]. Such impaired growth has already been observed in patients with HPP receiving the current enzyme replacement therapy, with data showing that their height and weight are greater than two standard deviations below the mean [14]. There is, therefore, a need to develop new treatment regimens capable of ameliorating the insufficient elongation, morphological irregularity, and hypomineralization of the femur by comparing the effects of ERT.

In this study, to investigate the optimum AAV vector dose needed to ameliorate femoral morphological irregularity and hypomineralization, we administered four different doses of scAAV8-CB-TNALP-D10 (1.5 × 1011, 7.5 × 1011, 1.5 × 1012, or 4.5 × 1012 v.g./body) by intramuscular injection into both quadriceps femoris muscles of HPP mice. All these doses increased serum ALP activity to over 1 U/mL, thereby prolonging survival of the mice. This result is consistent with previous reports [19, 20]. We observed high vector copy numbers in liver and injected muscle, and high-ALP activity in muscle. It is known from clinical trials in hemophilia B patients that transduction does not result in long-term sustained gene expression in the liver because of the immune reaction to the viral capsid [35]. On the basis of this observation, we assume that, although transduction of AAV vector is easily achieved in muscle and liver [21], it does not persist in the liver.

Normal body weight and femoral length were achieved only in HPP mice that received a dose of 4.5 × 1012 v.g./body; those that received lower doses exhibited plateaus in weight gain and impaired femoral elongation. In previous discussions on enzyme replacement therapy in HPP mice, it has been argued that the lack of adipose tissue in treated mice results in a plateauing of weight gain that must be due to a mechanism other than morphological irregularities of bone [36]. However, data from this study showed that, like the control mice, HPP mice treated with 4.5 × 1012 v.g./body had normal-length femurs, and their weight gain did not plateau but continued to increase until they ultimately reached normal weight. These results suggest that persistent insufficient bone elongation is likely a direct cause of the plateau in weight gain. We performed a micro-CT analysis to observe the femoral morphology in greater detail. HPP mice treated with 1.5 × 1011 v.g./body, which resulted in a serum ALP activity of 1 U/mL and was found to extend survival, exhibited morphological irregularities, including persistent epiphyseal cupping, irregularly arranged trabeculae, cortical bone defects, and non-uniform cortical bone thickness in previous studies [20]. Cancellous bone analysis confirmed that the disease also remained unresolved in quantitative terms. In contrast, HPP mice treated with 4.5 × 1012 v.g./body exhibited bone morphology that was almost identical to that of the control mice, and the values measured in the cancellous bone analysis and FEA also improved. These findings support the hypothesis that the level of serum ALP activity required to prolong survival (1 U/mL) is insufficient in terms of local ALP replacement in femoral bone. At this serum ALP level, the disease remains unresolved in a number of aspects, including insufficient elongation of the femur, epiphyseal cupping, irregularly arranged trabeculae, hypomineralization, and cortical bone defects. It also suggests that administering TNALP-D10 at a sufficiently high dose for local femoral bone may ameliorate these unresolved problems.

To evaluate the histological condition of bone, we conducted Alcian blue staining, H&E staining, and ALP staining. In HPP mice treated with 1.5 × 1011 v.g./body, histological staining revealed morphological irregularities in the growth plate cartilage and articular cartilage as well as ectopic fibrous tissue in the epiphysis and cortical bone, and there were only a few weak positive spots in the ALP staining. In contrast, mice treated with 4.5 × 1012 v.g./body exhibited the same morphology and ALP distribution as those seen in the control group. This result lends further support to the hypothesis that TNALP-D10 replacement at a dose sufficient to achieve normal levels of ALP in local bone brings about normal calcareous degeneration of the hypertrophic chondrocyte layer, leading to normal endochondral ossification [37], and ameliorates insufficient elongation, morphological irregularity, and hypomineralization of the femur. In the present study, we applied the frozen sections (10 µm thick) obtained from unfixed and undecalcified bone tissues to detect more accurate ALP activity. This technique provided successful detection of ALP activity, but it failed to observe details of chondrocyte columnar arrangement due to the reduced resolution of histology. Application of more advanced technique to detect accurate ALP activity retaining detailed morphology will be necessary to compare accurate therapeutic effects between ERT and gene therapy at histological level.

In the bone strength analysis of the epiphyseal ROI in HPP mice treated with 1.5 × 1011 v.g./body, we found that the growth plate and trabeculae were unable to absorb the mechanical stress generated by forced displacement and exhibited extremely fragile structural characteristics compared with those of control mice. In contrast, in HPP mice treated with 4.5 × 1012 v.g./body, which had bone morphology almost identical to that of the control group, these areas were able to withstand displacement to a level comparable to that of the control group. This finding suggests that the persistence of cortical bone defects, reduced trabecular numbers, and irregularly arranged trabeculae observed in HPP mice treated with suboptimal doses of vector may interfere with one of the most important functions of bone—its role as a supporting tissue maintaining the body’s structure against its own weight.

Although femoral morphology was improved in HPP mice treated with 4.5 × 1012 v.g./body, histological analysis unexpectedly revealed the presence of ectopic bone structures in these mice, which will be an adverse effect of the treatment. We speculate that these structures relate to the timing of the start of treatment. Because treatment began neonatally, endochondral ossification in utero went untreated, and hypertrophic chondrocytes did not undergo calcareous degeneration, and overproliferated. As a result, overproliferated cartilages of the epiphysis may have separated when force was applied. The ectopic calcification seen in the HPP mice treated with 4.5 × 1012 v.g./body may have been formed by TNALP-D10 replacement in this detached cartilage. This issue might be resolved by starting the treatment in utero, and we are now planning to conduct fetal gene therapy experiments. Here, we found that a high dose of 4.5 × 1012 v.g./body was required to provide sufficient ALP replacement in local bone to ameliorate the signs of HPP. In gene therapy using large animals, intravenous administration of high doses of AAV vectors reportedly causes liver toxicity [38, 39]. This toxicity is likely caused not only by the presence of contaminating proteins or the method of viral vector preparation [40, 41] but also by the viral load or promotor sequence [39]. Previous studies have found that the treatment vector is more easily introduced into bone when gene therapy is conducted in utero rather than neonatally [42]. Investigating in utero gene therapy could enable a lower dose of the vector to be administered, which is desirable from a safety perspective.

The symptoms of HPP patients include muscle weakness and muscle pain, and many patients exhibit delayed or impaired motor development [43, 44]. Here, although there was no significant difference in activity levels on the floor between the control mice and HPP mice treated with AAV vector at 1.5 × 1011 or 4.5 × 1012 v.g./body, we found that the activity in the wheel cage was lower in HPP mice at all treatment doses examined than in control mice. We previously reported that activity was restored in the treated HPP mice [20]; however, in that study, we performed only a short-term analysis of activity levels on the floor. Our investigation of daily spontaneous activity in a wheel cage provided the important knowledge that the activity level does not, in fact, recover, even in mice treated with 4.5 × 1012 v.g./body. Given our finding that the structure and strength of bone did recover in these mice, we considered that joint or muscle abnormalities may be present. Attempts have recently been made to create large-animal models of HPP, and the successful establishment of an ovine HPP model using CRISPR/Cas9 has been reported [45]. At 2 months of age, the HPP model sheep showed signs of muscle weakness, with a qualitatively altered gait, and skeletal muscle biopsy revealed abnormalities in muscle fiber size and incorrectly folded mitochondrial cristae [45]. Myopathy has also been reported in HPP patients, with muscle biopsy revealing no abnormalities in some cases [46] but abnormalities in muscle fiber size in others [43]. This mechanism is currently under investigation.

Conclusion

In this study, injection of model HPP mice with scAAV8-CB-TNALP-D10 at an optimal high dose resulted in high levels of bone ALP activity and induced normal growth and improved bone formation. Therefore, optimized AAV vector-mediated TNALP-D10 replacement therapy is a promising option for improvement of the QOL of patients with the infantile form of HPP. Further studies concerning the comparison of the therapeutic effect between our gene therapy and ERT are necessary using Akp2−/− mice before clinical application.