ABCC6 Deficiency Research Articles

Abcc6 deficiency prevents rhabdomyolysis-induced acute kidney injury

Rhabdomyolysis is a risk factor for acute kidney injury, transition towards chronic kidney disease, and death. The role of calcium phosphate deposits in the mechanisms of rhabdomyolysis-induced acute kidney injury (RAKI) is still unclear. Better insight of the role calcium in RAKI could lead to new therapeutic avenues. Here, we show in a mice model of RAKI that calcium phosphate deposits were frequent in the kidney (hydroxyapatite) and partly correlated with the severity of the kidney injury. However, the intensity of deposits was highly heterogeneous between mice. Treatment with sodium chloride, sodium bicarbonate or inorganic pyrophosphate (PPi; an inhibitor of the calcium phosphate crystallization), or combinations thereof, did not improve kidney outcomes and hydroxyapatite deposition during RAKI. Unexpectedly, Abcc6 knockout mice (ko), characterized by PPi deficiency, developed less severe RAKI despite similar rhabdomyolysis severity, and had similar hydroxyapatite deposition suggesting alternative mechanisms. This improved kidney outcome at day 2 translated to a trend in improved glomerular filtration rate at month 2 in Abcc6-/-mice and to significantly less interstitial fibrosis. In addition, whereas the pattern of infiltrating cells at day 2 was similar between wt and ko mice, kidneys of Abcc6-/- mice were characterized by more CD19+ B-cells, less CD3+ T-cells and a lower R1/R2 macrophage ratio at month 2. In summary, kidney calcium phosphate deposits are frequent in RAKI but hydration with sodium bicarbonate or sodium chloride does not modify the kidney outcome. Blocking ABCC6 emerges as a new option to prevent RAKI and subsequent transition toward kidney fibrosis.

Targeting ABCC6 in Mesenchymal Stem Cells: Impairment of Mature Adipocyte Lipid Homeostasis.

Mutations in ABCC6, an ATP-binding cassette transporter with a so far unknown substrate mainly expressed in the liver and kidney, cause pseudoxanthoma elasticum (PXE). Symptoms of PXE in patients originate from the calcification of elastic fibers in the skin, eye, and vessels. Previous studies suggested an involvement of ABCC6 in cholesterol and lipid homeostasis. The intention of this study was to examine the influence of ABCC6 deficiency during adipogenic differentiation of human bone marrow-derived stem cells (hMSCs). Induction of adipogenic differentiation goes along with significantly elevated ABCC6 gene expression in mature adipocytes. We generated an ABCC6-deficient cell culture model using clustered regulatory interspaced short palindromic repeat Cas9 (CRISPR–Cas9) system to clarify the role of ABCC6 in lipid homeostasis. The lack of ABCC6 in hMSCs does not influence gene expression of differentiation markers in adipogenesis but results in a decreased triglyceride content in cell culture medium. Protein and gene expression analysis of mature ABCC6-deficient adipocytes showed diminished intra- and extra-cellular lipolysis, release of lipids, and fatty acid neogenesis. Therefore, our results demonstrate impaired lipid trafficking in adipocytes due to ABCC6 deficiency, highlighting adipose tissue and peripheral lipid metabolism as a relevant target for uncovering systemic PXE pathogenesis.

Relationships between Plasma Pyrophosphate, Vascular Calcification and Clinical Severity in Patients Affected by Pseudoxanthoma Elasticum.

Pseudoxanthoma elasticum (PXE; OMIM 264800) is an autosomal recessive metabolic disorder characterized by progressive calcification in the skin, the Bruch’s membrane, and the vasculature. Calcification in PXE results from a low level of circulating pyrophosphate (PPi) caused by ABCC6 deficiency. In this study, we used a cohort of 107 PXE patients to determine the pathophysiological relationship between plasma PPi, coronary calcification (CAC), lower limbs arterial calcification (LLAC), and disease severity. Overall, our data showed a deficit in plasma PPi in PXE patients compared to controls. Remarkably, affected females showed higher PPi levels than males, but a lower LLAC. There was a strong correlation between age and PPi in PXE patients (r = 0.423, p < 0.0001) but not in controls (r = 0.059, p = 0.828). A weak correlation was found between PPi and CAC (r = 0.266, p < 0.02); however, there was no statistically significant connection with LLAC (r = 0.068, p = 0.518) or a severity score (r = 0.077, p = 0.429). Surprisingly, we found no significant correlation between plasma alkaline phosphatase activity and PPi (r = 0.113, p = 0.252) or between a 10-year cardiovascular risk score and all other variables. Multivariate analysis confirmed that LLAC and CAC were strongly dependent on age, but not on PPi. Our data showed that arterial calcification is only weakly linked to circulating PPi levels and that time (i.e., age) appears to be the major determinant of disease severity and calcification in PXE. These data are important to better understand the natural history of this disease but also for the follow-up and management of patients, and the design of future clinical trials. Our results also show that PPi is not a good biomarker for the evaluation of disease severity and progression.

ABCC6, Pyrophosphate and Ectopic Calcification: Therapeutic Solutions.

Pathological (ectopic) mineralization of soft tissues occurs during aging, in several common conditions such as diabetes, hypercholesterolemia, and renal failure and in certain genetic disorders. Pseudoxanthoma elasticum (PXE), a multi-organ disease affecting dermal, ocular, and cardiovascular tissues, is a model for ectopic mineralization disorders. ABCC6 dysfunction is the primary cause of PXE, but also some cases of generalized arterial calcification of infancy (GACI). ABCC6 deficiency in mice underlies an inducible dystrophic cardiac calcification phenotype (DCC). These calcification diseases are part of a spectrum of mineralization disorders that also includes Calcification of Joints and Arteries (CALJA). Since the identification of ABCC6 as the “PXE gene” and the development of several animal models (mice, rat, and zebrafish), there has been significant progress in our understanding of the molecular genetics, the clinical phenotypes, and pathogenesis of these diseases, which share similarities with more common conditions with abnormal calcification. ABCC6 facilitates the cellular efflux of ATP, which is rapidly converted into inorganic pyrophosphate (PPi) and adenosine by the ectonucleotidases NPP1 and CD73 (NT5E). PPi is a potent endogenous inhibitor of calcification, whereas adenosine indirectly contributes to calcification inhibition by suppressing the synthesis of tissue non-specific alkaline phosphatase (TNAP). At present, therapies only exist to alleviate symptoms for both PXE and GACI; however, extensive studies have resulted in several novel approaches to treating PXE and GACI. This review seeks to summarize the role of ABCC6 in ectopic calcification in PXE and other calcification disorders, and discuss therapeutic strategies targeting various proteins in the pathway (ABCC6, NPP1, and TNAP) and direct inhibition of calcification via supplementation by various compounds.

EP024 - From the voice of patients and caregivers: burden of illness in infantile onset ABCC6 and ENPP1 deficiency (GACI and ARHR2)

eP024 - From the voice of patients and caregivers: burden of illness in infantile onset ABCC6 and ENPP1 deficiency (GACI and ARHR2)

From the voice of patients and caregivers: Burden of illness in infantile onset ABCC6 and ENPP1 deficiency (GACI and ARHR2)

From the voice of patients and caregivers: Burden of illness in infantile onset ABCC6 and ENPP1 deficiency (GACI and ARHR2)

ABCC6 deficiency promotes dyslipidemia and atherosclerosis

ABCC6 deficiency promotes ectopic calcification; however, circumstantial evidence suggested that ABCC6 may also influence atherosclerosis. The present study addressed the role of ABCC6 in atherosclerosis using Ldlr−/− mice and pseudoxanthoma elasticum (PXE) patients. Mice lacking the Abcc6 and Ldlr genes were fed an atherogenic diet for 16 weeks before intimal calcification, aortic plaque formation and lipoprotein profile were evaluated. Cholesterol efflux and the expression of several inflammation, atherosclerosis and cholesterol homeostasis-related genes were also determined in murine liver and bone marrow-derived macrophages. Furthermore, we examined plasma lipoproteins, vascular calcification, carotid intima-media thickness and atherosclerosis in a cohort of PXE patients with ABCC6 mutations and compared results to dysmetabolic subjects with increased cardiovascular risk. We found that ABCC6 deficiency causes changes in lipoproteins, with decreased HDL cholesterol in both mice and humans, and induces atherosclerosis. However, we found that the absence of ABCC6 does not influence overall vascular mineralization induced with atherosclerosis. Decreased cholesterol efflux from macrophage cells and other molecular changes such as increased pro-inflammation seen in both humans and mice are likely contributors for the phenotype. However, it is likely that other cellular and/or molecular mechanisms are involved. Our study showed a novel physiological role for ABCC6, influencing plasma lipoproteins and atherosclerosis in a haploinsufficient manner, with significant penetrance.

From membrane to mineralization: the curious case of the ABCC6 transporter.

ATP-binding cassette subfamily C member 6 gene/protein (ABCC6) is an ATP-dependent transmembrane transporter predominantly expressed in the liver and the kidney. ABCC6 first came to attention in human medicine when it was discovered in 2000 that mutations in its encoding gene, ABCC6, caused the autosomal recessive multisystemic mineralization disease pseudoxanthoma elasticum (PXE). Since then, the physiological and pathological roles of ABCC6 have been the subject of intense research. In the last 20years, significant findings have clarified ABCC6 structure as well as its physiological role in mineralization homeostasis in humans and animal models. Yet, several facets of ABCC6 biology remain currently incompletely understood, ranging from the precise nature of its substrate(s) to the increasingly complex molecular genetics. Nonetheless, advances in our understanding of pathophysiological mechanisms causing mineralization lead to several treatment options being suggested or already tested in pilot clinical trials for ABCC6 deficiency. This review highlights current knowledge of ABCC6 and the challenges ahead, particularly the attempts to translate basic science into clinical practice.

A natural history study of generalized arterial calcification of infancy (GACI) and autosomal recessive hypophosphatemic rickets (ARHR2) due to ENPP1 or ABCC6 deficiency: interim analysis

A natural history study of generalized arterial calcification of infancy (GACI) and autosomal recessive hypophosphatemic rickets (ARHR2) due to ENPP1 or ABCC6 deficiency: interim analysis

405 Adenovirus-mediated ABCC6 gene therapy prevents ectopic mineralization in an Abcc6-/- mouse model of pseudoxanthoma elasticum

Biallelic loss-of-function mutations in the ABCC6 gene cause pseudoxanthoma elasticum (PXE) and type 2 generalized arterial calcification of infancy (GACI), heritable ectopic mineralization disorders without effective treatment. ABCC6 encodes the putative efflux transporter ABCC6 which is predominantly expressed in the liver. While the substrate of ABCC6 protein remains unknown, recent studies demonstrated that PXE is a metabolic disorder caused by reduced circulating levels of inorganic pyrophosphate (PPi), a potent inhibitor of mineralization. Here, we hypothesized that reconstitution of ABCC6 might counteract ectopic mineralization in an Abcc6-/- mouse model of PXE. Intravenous administration of a recombinant adenovirus expressing wild type human ABCC6 in Abcc6-/- mice showed sustained high-level expression of human ABCC6 in the liver for up to 4 weeks, increasing PPi levels in plasma. In addition, adenovirus injection every 4 weeks restored plasma PPi levels, and consequently, significantly reduced ectopic mineralization in the skin of young mice. By contrast, the same treatment in old mice, 43 weeks of age, with already established mineral deposits failed to reduce mineralization. These results suggest that adenovirus-mediated ABCC6 gene delivery, when initiated early, is a promising prevention therapy for PXE and GACI, diseases that currently lack preventive or therapeutic options to counteract ABCC6 deficiency.

Abcc6 deficiency in mice leads to altered ABC transporter gene expression in metabolic active tissues

BackgroundATP-binding cassette (ABC) transporters are involved in a huge range of physiological processes. Mutations in the ABCC6 gene cause pseudoxanthoma elasticum, a metabolic disease with progressive soft tissue calcification.MethodsThe aim of the present study was to analyze gene expression levels of selected ABC transporters associated with cholesterol homeostasis in metabolic active tissues, such as the liver, kidney and white adipose tissue (WAT) of Abcc6−/− mice from an early and late disease stage (six-month-old and 12-month-old mice).ResultsThe strongest regulation of ABC transporter genes was observed in the liver tissue of six-month-old Abcc6−/− mice. Here, we found a significant increase of mRNA expression levels of phospholipid, bile salt and cholesterol/sterol transporters Abcb1b, Abcb11, Abcg1, Abcg5 and Abcg8. Abcd2 mRNA expression was increased by 3.2-fold in the liver tissue. We observed strong upregulation of Abca3 and Abca1 mRNA expression up to 3.3-fold in kidney and WAT, and a 2-fold increase of Abca9 mRNA in the WAT of six-month-old Abcc6 knockout mice. Gene expression levels of Abcb1b and Abcg1 remained increased in the liver tissue after an age-related disease progression, while we observed lower mRNA expression of Abca3 and Abca9 in the kidney and WAT of 12-month-old Abcc6−/− mice.ConclusionsThese data support previous findings that Abcc6 deficiency leads to an altered gene expression of other ABC transporters depending on the status of disease progression. The increased expression of fatty acid, bile salt and cholesterol/sterol transporters may be linked to an altered cholesterol and lipoprotein metabolism due to a loss of Abcc6 function.

Cellular signaling in pseudoxanthoma elasticum: an update

Pseudoxanthoma elasticum is an autosomal recessive genodermatosis with variable expression, due to mutations in the ABCC6 or ENPP1 gene. It is characterized by elastic fiber mineralization and fragmentation, resulting in skin, eye and cardiovascular symptoms. Significant advances have been made in the last 20 years with respect to the phenotypic characterization and pathophysiological mechanisms leading to elastic fiber mineralization. Nonetheless, the substrates of the ABCC6 transporter - the main cause of PXE - remain currently unknown. Though the precise mechanisms linking the ABCC6 transporter to mineralization of the extracellular matrix are unclear, several studies have looked into the cellular consequences of ABCC6 deficiency in PXE patients and/or animal models. In this paper, we compile the evidence on cellular signaling in PXE, which seems to revolve mainly around TGF-βs, BMPs and inorganic pyrophosphate signaling cascades. Where conflicting results or fragmented data are present, we address these with novel signaling data. This way, we aim to better understand the up- and down-stream signaling of TGF-βs and BMPs in PXE and we demonstrate that ANKH deficiency can be an additional mechanism contributing to decreased serum PPi levels in PXE patients.

Dietary Pyrophosphate Modulates Calcification in a Mouse Model of Pseudoxanthoma Elasticum: Implication for Treatment of Patients

Pseudoxanthoma elasticum is a heritable disease caused by ABCC6 deficiency. Patients develop ectopic calcification in skin, eyes, and vascular tissues. ABCC6, primarily found in liver and kidneys, mediates the cellular efflux of ATP, which is rapidly converted into inorganic pyrophosphate (PPi), a potent inhibitor of calcification. Pseudoxanthoma elasticum patients and Abcc6-/- mice display reduced PPi levels in plasma and peripheral tissues. Pseudoxanthoma elasticum is currently incurable, although some palliative treatments exist. In recent years, we have successfully developed therapeutic methodologies to compensate the PPi deficit in animal models and humans. Here, we inadvertently discovered that modulating dietary PPi can also be an effective approach to reducing calcification in Abcc6-/- mice. Our findings were prompted by a change in institutional rodent diet. The new chow was enriched in PPi, which increased plasma PPi, and significantly reduced mineralization in Abcc6-/- mice. We also found that dietary PPi is readily absorbed in humans. Our results suggest that the consumption of food naturally or artificially enriched in PPi represents a possible intervention to mitigate calcification progression in pseudoxanthoma elasticum, that dietary preferences of patients may explain pseudoxanthoma elasticum heterogeneous manifestations, and that animal chow has the potential to influence data reproducibility.

Pathogenic variants in the ABCC6 gene are associated with an increased risk for ischemic stroke.

Ischemic stroke causes a high mortality and morbidity worldwide. It results from a complex interplay of incompletely known environmental and genetic risk factors. We investigated the ABCC6 gene as a candidate risk factor for ischemic stroke because of the increased ischemic stroke incidence in the autosomal recessive disorder pseudoxanthoma elasticum, caused by biallelic pathogenic ABCC6 variants, the higher cardiovascular risk in heterozygous carriers and the established role of ABCC6 dysfunction in myocardial ischemia. We established segregation of a known pathogenic ABCC6 variant (p.[Arg1314Gln]) in 11/19 family members of an ischemic stroke patient in a large multigenerational family suffering from ischemic stroke and/or cardiovascular disease at a relatively young age. In an independent case-control study in 424 ischemic stroke patients and 250 healthy controls, pathogenic ABCC6 variants were 4.9 times more frequent (P = 0.036; 95% CI 1.11-21.33) in the ischemic stroke patient cohort. To study cellular consequences of ABCC6 deficiency in the brain, immunostaining of brain sections in Abcc6-deficient mice and wild-type controls were performed. An upregulation of Bmp4 and Eng and a downregulation of Alk2 was identified in Abcc6-/- mice, suggesting an increase in apoptosis and angiogenesis. As both of these processes are induced in ischemia, we propose that a pro-ischemic state may explain the higher risk to suffer from ischemic stroke in patients carrying a pathogenic ABCC6 variant, as this may lower the threshold to develop acute ischemic events in these patients. In conclusion, this study identified heterozygous ABCC6 variants as a risk factor for ischemic stroke. Further, dysregulation of Bmp (Bmp4, Alk2) and Tgfβ (Eng) signaling in the brain of Abcc6-/- mice could lead to a pro-ischemic state, lowering the threshold to develop acute ischemic events. These data demonstrate the importance of a molecular analysis of the ABCC6 gene in patients diagnosed with cryptogenic ischemic stroke.

Generation and Validation of a Complete Knockout Model of abcc6a in Zebrafish.

Pseudoxanthoma elasticum is an ectopic mineralization disease due to biallelic ABCC6 mutations. As no treatment options are currently available, a reliable zebrafish model is invaluable for high throughput compound screening. However, data from previously reported knockdown and mutant zebrafish models for abcc6a, the functional orthologue of ABCC6, showed phenotypic discrepancies. To address this, we developed a complete abcc6a knockout model using Clustered Regularly Interspaced Short Palindromic Repeats/Cas9 and compared its phenotype to that of a mutant model (Sa963) and a splice junction morpholino model. Our data showed that abcc6a is not required for embryonic survival, but rather that it has an essential role in controlling mineralization. The three models developed very similar hypermineralization of spine and ribs starting embryonically and progressing in adulthood with development of scoliosis. Our results indicate a direct relation between loss of abcc6a expression and dysregulated osteogenesis. As such, our models recapitulate part of the human phenotype in which ectopic mineralization and pro-osteogenic signaling have been reported. Because of its reproducibility in three models and its ease of quantification, we consider this phenotype to be unequivocally the result of abcc6 deficiency and, as such, an excellent readout for drug screening purposes and multiplex mutagene analysis.

Alteration of Extracellular Nucleotide Metabolism in Pseudoxanthoma Elasticum

Pseudoxanthoma elasticum (PXE) is a rare genetic condition primarily caused by hepatic ABCC6 transporter dysfunction. Most clinical manifestations of PXE are due to premature calcification of elastic fibers. However, the vascular impact of PXE is pleiotropic and remains ill defined. ABCC6 expression has recently been associated with cellular nucleotide export. We studied the impact of ABCC6 deficiency on blood levels of adenosine triphosphate and related metabolites and on soluble nucleotidase activities in PXE patients and Abcc6-/- mice. In addition, we investigated the expression of genes encoding ectocellular purinergic signaling proteins in mouse liver and aorta. Plasma adenosine triphosphate and pyrophosphate levels were significantly reduced in PXE patients and in Abcc6-/- mice, whereas adenosine concentration was not modified. Moreover, 5'-nucleotidase/CD73 activity was increased in the serum of PXE patients and Abcc6-/- mice. Consistent with alterations of purinergic signaling, the expression of genes involved in purine and phosphate transport/metabolism was dramatically modified in Abcc6-/- mouse aorta, with much less impact on the liver. ABCC6 deficiency causes impaired vascular homeostasis and tissue perfusion. Our findings suggest that these alterations are linked to changes in extracellular nucleotide metabolism that are remote from the liver. This opens new perspectives for the understanding of PXE pathophysiology.

Early arterial calcification does not correlate with bone loss in pseudoxanthoma elasticum

Background and aimsPseudoxanthoma elasticum (PXE; OMIM 264800, prevalence 1/25,000 to 1/50,000) is an autosomal recessive multisystem disease due to deficiency in ABCC6, an ATP-binding cassette, sub-family C transporter. The PXE phenotype is mainly characterized by progressive ectopic calcification of connective tissues (namely skin, retinal Bruch's membrane and peripheral arteries) but the impact of PXE on bone structure is currently unknown. The present study sought to investigate bone mineralization and its potential link with vascular calcification in a large cohort of PXE patients with inherited mutations of the ABCC6 gene. Methods and results96 patients (61 women) matching the PXE criteria participated in this study. Their clinical history and status and bone biological markers were collected. Bone mineral density (BMD) was measured by dual energy X-ray absorptiometry and expressed as T- and Z-scores. Osteoporotic fractures were identified by X-ray, and coronary (CAC) and lower limb arterial calcification (LLAC) scores were determined by CT scan. Results44% of the women were menopausal. Osteopenia was disclosed in 46% (17 women) while 23% (9 women) exhibited osteoporosis, 3 with severe osteoporosis. Fractures of an osteoporotic nature were authenticated in 3 patients (1 woman). Markers of bone remodelling processes (CTX, BSAP and osteocalcin) were within the normal range for our laboratory standards. Severe vitamin D deficiency (<25nmol/L) was found in 15%, while 51% exhibited no vitamin D deficiency (vitamin D≥50nmol/L). LLAC and CAC scores were significantly higher in the patients with a low T- and/or Z-score, although this difference disappeared in multivariate analysis with age as a confounding factor. There was no significant difference in LLAC and CAC between PXE patients with and without osteoporotic fractures. There was no statistically significant association between BMD, LLAC and CAC and any of the bone remodelling factors. ConclusionsThis is the first report on the bone mineralization process in PXE patients. Our data shows that PXE patients are not markedly prone to exaggerated bone demineralization and fracture risk, and prevalence of osteoporosis remains within the normal range for the general population. Furthermore, the relationships between LLAC, but not CAC, and BMD with age are similar to those observed in the general population. Therefore, despite its pivotal role in ectopic calcification, ABCC6 deficiency does not interfere with the bone-vascular axis. The lack of PXE-related disturbances between BMD and arterial calcification also supports vitamin D supplementation in PXE patients with vitamin D deficiency.ClinicalTrials.gov Identifier: NCT01446393.

Pyrophosphate Supplementation Prevents Chronic and Acute Calcification in ABCC6-Deficient Mice

Soft tissue calcification occurs in several common acquired pathologies, such as diabetes and hypercholesterolemia, or can result from genetic disorders. ABCC6, a transmembrane transporter primarily expressed in liver and kidneys, initiates a molecular pathway inhibiting ectopic calcification. ABCC6 facilitates the cellular efflux of ATP, which is rapidly converted into pyrophosphate (PPi), a major calcification inhibitor. Heritable mutations in ABCC6 underlie the incurable calcification disorder pseudoxanthoma elasticum and some cases of generalized arterial calcification of infancy. Herein, we determined that the administration of PPi and the bisphosphonate etidronate to Abcc6-/- mice fully inhibited the acute dystrophic cardiac calcification phenotype, whereas alendronate had no significant effect. We also found that daily injection of PPi to Abcc6-/- mice over several months prevented the development of pseudoxanthoma elasticum-like spontaneous calcification, but failed to reverse already established lesions. Furthermore, we found that the expression of low amounts of the human ABCC6 in liver of transgenic Abcc6-/- mice, resulting in only a 27% increase in plasma PPi levels, led to a major reduction in acute and chronic calcification phenotypes. This proof-of-concept study shows that the development of both acute and chronic calcification associated with ABCC6 deficiency can be prevented by compensating PPi deficits, even partially. Our work indicates that PPi substitution represents a promising strategy to treat ABCC6-dependent calcification disorders.

Functional Rescue of ABCC6 Deficiency by 4-Phenylbutyrate Therapy Reduces Dystrophic Calcification in Abcc6–/– Mice

Soft-tissue calcification is associated with aging, common conditions such as diabetes or hypercholesterolemia, and with certain genetic disorders. ABCC6 is an efflux transporter primarily expressed in liver facilitating the release of adenosine triphosphate from hepatocytes. Within the liver vasculature, adenosine triphosphate is converted into pyrophosphate, a major inhibitor of ectopic calcification. ABCC6 mutations thus lead to reduced plasma pyrophosphate levels, resulting in the calcification disorder pseudoxanthoma elasticum and some cases of generalized arterial calcification of infancy. Most mutations in ABCC6 are missense, and many preservetransport activity but are retained intracellularly. We have previously shown that the chemical chaperone 4-phenylbutyrate (4-PBA) promotes the maturation of ABCC6 mutants to the plasma membrane. In a humanized mouse model of pseudoxanthoma elasticum, we investigated whether 4-PBA treatments could rescue the calcification inhibition potential of selected ABCC6 mutants. We used the dystrophic cardiac calcification phenotype of Abcc6-/- mice as an indicator of ABCC6 function to quantify the effect of 4-PBA on human ABCC6 mutants transiently expressed in the liver. We showed that 4-PBA administrations restored the physiological function of ABCC6 mutants, resulting in enhanced calcification inhibition. This study identifies 4-PBA treatment as a promising strategy for allele-specific therapy of ABCC6-associated calcification disorders.

388 A novel Abcc6 knockout rat model highlights the role of PPi in the pathogenesis of ectopic mineralization process in PXE

388 A novel Abcc6 knockout rat model highlights the role of PPi in the pathogenesis of ectopic mineralization process in PXE Q Li, K van de Wetering, J Kingman, JP Sundberg and J Uitto 1 Thomas Jefferson University, Philadelphia, PA, 2 Netherlands Cancer Institute, Amsterdam, Netherlands and 3 The Jackson Laboratory, Bar Harbor, ME Pseudoxanthoma elasticum (PXE) is characterized by systemic connective tissue mineralization caused by loss-of-function mutations in the ABCC6 gene. The currently available Abcc6 mice represent a useful model system to study PXE pathophysiology and to explore potential treatment modalities. Abcc6 rats would, however, provide a more suitable model for metabolic studies and specifically unravel the role of PPi and Pi homeostasis in PXE. We have therefore generated Abcc6 rats using zinc finger nuclease (ZFN), targeting the first coding exon of Abcc6. Five germline transmission competent rats were identified that harbored deletions ranging from 10 to 23 bp surrounding the ZFN target site. These mutations were predicted to cause out-of-frame translation and induce a premature stop codon. Immunostaining of liver sections using a rat ABCC6 specific antibody showed plasma membrane expression in basolateral surface of hepatocytes in wild type rats and complete absence in the homozygous mutant rats. As a consequence of ABCC6 deficiency, complete necropsy of three mutant lines demonstrated ectopic mineralization in the muzzle skin, eyes, and arterial blood vessels in the knockout rats, features mimicking human PXE. Mineralization in the dermal sheath of vibrissae was also monitored by small animal CT scanning, which allows noninvasive evaluation of the mineralization process. Similar to human PXE patients, clinical chemistry did not reveal differences in serum calcium and phosphorus levels between wild type and Abcc6 rats. However, plasma PPi level was significantly reduced (<60%) in the Abcc6 rats as compared to wild type rats, leading to a significantly lower PPi/Pi ratio. Since PPi is physiologically a potent antimineralization factor, the results highlight the role of PPi in the context of the PPi/Pi ratio in the novel Abcc6 rat model due to loss-of-function of ABCC6, leading to ectopic mineralization in PXE. 389 Pirfenidone inhibits RDEB fibrosis and scarring J Cogan, K Yim, Y Hou, L Chao, V Gor, D Woodley and M Chen Dermatology, University of Southern California, Los Angeles, CA Patients with recessive dystrophic epidermolysis bullosa (RDEB) develop multiple skin wounds that heal with extensive scarring, contractures and mitten deformities. RDEB patients display increased pro-fibrotic TGF-b signaling, a distinct pro-fibrotic gene expression profile and elevated inflammation genes. So far, no specific pharmacological treatment is available for RDEB fibrosis. Among promising anti-fibrotic molecules, pirfenidone (PFD) has shown anti-fibrotic and anti-inflammatory activity in animal and cell models, and it is already being used clinically for the treatment of idiopathic pulmonary fibrosis. In this study, we evaluated the feasibility of using PFD to inhibit RDEB fibrosis using fibroblasts from RDEB patients and a RDEB mouse model. RDEB fibroblasts treated with PFD demonstrated reduced expression of multiple fibrosis markers [collagen I, connective tissue growth factor (CTGF), alpha smooth muscle actin (a-SMA), periostin, and tenascin C] by immunoblot analysis. By RT-PCR, PFD also reduced mRNA levels for fibrosis genes [tenascin-C, CTGF, periostin, TGF-b2, and aSMA] as well as IL-6, an inflammation gene known to stimulate fibrosis. In addition, PFD reduced the levels of pro-fibrogenic TGF-b in the media of RDEB fibroblasts as assessed by ELISA. Furthermore, PFD also reversed the characteristic RDEB cellular phenotype of collagen lattice hypercontractability. Lastly, using a RDEB mouse model featuring nail dystrophy and mitten deformities, PFD administered once daily subcutaneously for 4 weeks attenuated the onset of RDEB-associated fibrosis including mitten deformities and nail loss. It reduced in the skin of RDEB mice, their intrinsically elevated fibrosis markers [periostin, aSMA, fibronectin, collagen 1 and tenascin C] and pro-fibrogenic TGF-b and its downstream signaling [phospho-Smad2/3]. PFD also significantly reduced the number of cd11b-positive inflammatory cells in RDEB mice. These data demonstrate that PFD may be a non-invasive, safe and novel therapy for reducing RDEB fibrosis and scarring and improving the quality of life of RDEB patients.