Tissue-specific expression of the ABCC6 gene.

The ABCC6 gene encodes MRP6, a member of the multidrug resistance-associated protein (MRP) family. Interest in ABCC6/MRP6 derives, in part, from the fact that mutations in this gene/protein system have been identified in families with pseudoxanthoma elasticum (PXE). Early studies indicated that ABCC6 is expressed primarily in the liver and to a lesser extent in the kidney, but more recently a widespread distribution has been suggested. To explore the tissue-specific expression of ABCC6, we first examined various mouse tissues by RT-PCR. The results indicated high levels of mRNA in the liver, whereas low level of expression was noted in the kidney and small intestine. To explore other tissues in which initial RT-PCR was essentially negative, a second-round nested PCR was performed, which revealed expression also in the brain, tongue, stomach, and eye. Unexpectedly, however, distinct PCR products of smaller molecular weight were noted in these tissues. Subcloning and sequencing of these PCR products indicated that they reflected aberrant splicing in the 3' end of the ABCC6 mRNA, resulting in each case in a premature termination codon. Similar results were noted with RT-PCR analysis using RNA isolated from cultured human epidermal keratinocytes and dermal fibroblasts. Collectively, our results confirm high level of expression of ABCC6 in the liver and the kidney, whereas very low level of expression in a variety of other tissues was noted. The results have implications for mutation detection strategies in PXE by RT-PCR, and they further support the notion that PXE is a primary metabolic disorder.

Targeted ablation of the abcc6 gene results in ectopic mineralization of connective tissues.

Pseudoxanthoma elasticum (PXE), characterized by connective tissue mineralization of the skin, eyes, and cardiovascular system, is caused by mutations in the ABCC6 gene. ABCC6 encodes multidrug resistance-associated protein 6 (MRP6), which is expressed primarily in the liver and kidneys. Mechanisms producing ectopic mineralization as a result of these mutations remain unclear. To elucidate this complex disease, a transgenic mouse was generated by targeted ablation of the mouse Abcc6 gene. Abcc6 null mice were negative for Mrp6 expression in the liver, and complete necropsies revealed profound mineralization of several tissues, including skin, arterial blood vessels, and retina, while heterozygous animals were indistinguishable from the wild-type mice. Particularly striking was the mineralization of vibrissae, as confirmed by von Kossa and alizarin red stains. Electron microscopy revealed mineralization affecting both elastic structures and collagen fibers. Mineralization of vibrissae was noted as early as 5 weeks of age and was progressive with age in Abcc6(-/-) mice but was not observed in Abcc6(+/-) or Abcc6(+/+) mice up to 2 years of age. A total body computerized tomography scan of Abcc6(-/-) mice revealed mineralization in skin and subcutaneous tissue as well as in the kidneys. These data demonstrate aberrant mineralization of soft tissues in PXE-affected organs, and, consequently, these mice recapitulate features of this complex disease.

Novel and recurrent mutations in the laminin-5 genes causing lethal junctional epidermolysis bullosa: molecular basis and clinical course of Herlitz disease.

Herlitz disease (H-JEB), the lethal form of junctional epidermolysis bullosa, is a rare genodermatosis presenting from birth with widespread erosions and blistering of skin and mucosae because of tissue cleavage within the epidermal basement membrane. Mutations in any of the three genes encoding the alpha3, beta3 and gamma2 chains of laminin-5 underlie this recessively inherited disorder. Here, we report the molecular basis and clinical course of H-JEB in 12 patients. Two novel nonsense mutations in the gene LAMA3 (E281X and K1299X) and a novel frame-shift mutation in the gene LAMB3 (1628insG) leading to a premature termination codon were identified by DNA sequencing and confirmed by restriction fragment length polymorphism analysis. In the four patients affected, neither the resulting truncated polypeptide chains nor assembled laminin-5 protein were detectable by immunofluorescence. Three patients were found to be heterozygous for the known hotspot mutation R635X and the recurrent mutations Q373X or 29insC in the gene LAMB3, whereas five others were homozygous for R635X. Significant variations in the disease progression and survival times between 1 and 30 months in this group of H-JEB patients emphasised the impact of modifying factors and the importance of immunostaining or mRNA assessment as parallel diagnostic methods. Interestingly, the only patients who survived for longer than 6 months were four females carrying the mutation R635X homozygously. In one of them, the clinical course may have been improved by treatment with artificial skin equivalents. These data may stimulate further investigation of genotype-phenotype correlations and facilitate mutation analysis and genetic counselling of affected families.

Treatment of two patients with Herlitz junctional epidermolysis bullosa with artificial skin bioequivalents.

OBJECTIVE: To evaluate the effects of a treatment with artificial skin bioequivalents in Herlitz junctional epidermolysis bullosa (H-JEB). METHODS: Two infants, both homozygous for the Herlitz mutation R635X in the LAMB3 gene, who had refractory anemia and hypoproteinemia as a result of a continuous loss of body fluids through multiple large erosions, were treated with artificial skin bioequivalents. RESULTS: In the first patient, 10 of 13 acute or chronic wounds were found healed 3 to 6 weeks after the treatment, and the protein, iron, and hemoglobin levels normalized. Normal weight gain and marked improvement of the quality of life for this patient's family have been evident since. Nine treated wounds remained healed for at least 18 weeks and appeared to be more resistant to trauma. In a skin biopsy from a treated site obtained after 9 weeks, DNA of the graft was still detectable by polymerase chain reaction. In the second patient, who was treated at a late stage of the disease, only 2 of 18 chronic wounds were found healed at 3 weeks after the treatment. One site remained healed completely, and some additional islets of the grafts persisted for longer. There were no adverse events. CONCLUSION: Early treatment with artificial skin substitutes may improve the clinical course of H-JEB. However, a true cure of the cutaneous manifestations of H-JEB would require gene therapy of autologous epidermal stem cells, which could then be transplanted by using this or a similar cultured skin bioequivalent.

Sustained delivery of therapeutic concentrations of human clotting factor IX--a comparison of adenoviral and AAV vectors administered in utero.

BACKGROUND: Prenatal somatic gene therapy has been considered for genetic disorders presenting with morbidity at birth. Haemophilia is associated with an increased risk of catastrophic perinatal bleeding complications such as intracranial haemorrhage, which could be prevented by gene transfer in utero. Prenatal gene therapy may be more promising than postnatal treatment, as the fetus may be more amenable to uptake and integration of therapeutic DNA and the immaturity of its immune system may permit life-long immune tolerance of the transgenic protein, thus avoiding the dominant problem in haemophilia treatment, the formation of inhibitory antibodies. METHODS: Adenovirus serotype 5-derived or AAV serotype 2-derived vectors carrying human clotting factor IX (hfIX) cDNA or a reporter gene were administered intramuscularly, intraperitoneally or intravascularly to late-gestation mouse fetuses. Both vector types were evaluated with respect to the kinetics of hfIX delivery to the systemic circulation and possible immune responses against the vector or the transgene product. RESULTS: Mice treated in utero by intramuscular injection of an adenoviral vector carrying hfIX cDNA exhibited high-level gene expression at birth and therapeutic--albeit continuously decreasing--plasma concentrations of hfIX over the entire 6 months of the study. Adenoviral vector spread to multiple organs was detected by polymerase chain reaction (PCR). Intramuscular, intraperitoneal or intravascular application of AAV vectors carrying hfIX cDNA led to much lower plasma concentrations of hfIX shortly after birth, which appeared to decline during the first month of life but stabilized in some of the mice at detectable levels. No signs of immune responses were found, either against the different viral vectors or against hfIX. CONCLUSION: This study demonstrates for the first time that sustained systemic delivery of a therapeutic protein can be achieved by prenatal gene transfer. It thus shows the feasibility of gene therapy in utero and provides a basis for considering this concept as a preventive therapeutic strategy for haemophilia and perhaps also for other plasma protein deficiencies.