GALNS gene expression profiling in Morquio A patients' fibroblasts.

BACKGROUND: Quantification studies of mutated mRNAs have not been carried out on Morquio A patients. Such studies are very important for the determination of stability of premature termination codons (PTC) bearing transcripts in order to assess the appropriateness of introducing the newly developed therapeutic strategies such as "stop codon read-through therapy". METHODS: This paper focuses on the study of the GALNS gene and mRNAs in two severe forms of Morquio A patients' fibroblasts with development of a new and rapid real-time RT-PCR for detection and quantification of absolute mRNA copy number. RESULTS: We identified two new mutations c.385A>T (p.K129X) and c.899-1G>C) in Pt1 and a known splicing defect c.120+1G>A in Pt2. Using RT-PCR and real-time RT-PCR in Pt2 we detected low levels of mRNAs, suggesting its instability; in Pt1, we detected three aberrant mRNAs introducing premature stop codons, suggesting that both the c.385A>T and c.899-1G>C mutations produce mRNAs capable of escaping the nonsense-mediated decay (NMD) pathway. CONCLUSIONS: The development of a real-time RT-PCR assay allows to absolutely quantify the GALNS mRNAs carrying mutations that lead to PTCs bearing transcripts, which escape the NMD process and are potentially suitable for the new therapeutic approach.

Bilateral nuclear cataracts as the first neonatal sign of Fanconi-Bickel syndrome.

A patient with early bilateral nuclear cataracts and subsequent diagnosis of Fanconi-Bickel syndrome is described. Despite impaired galactose and glucose metabolism, cataracts have been reported in only few cases with this disorder. We conclude that Fanconi-Bickel syndrome should be considered in the differential diagnosis of neonatal cataracts. The pathogenesis of this complication has not been fully elucidated.

Human respiratory cells from nasal polyps as a model for gene transfer by non-viral cationic vectors.

The influence of cell differentiation and proliferation on cationic vector mediated gene transfer into the explant-outgrowth cell culture from nasal polyps was investigated. Respiratory cells were categorized into two groups based on the expression of cytokeratin filaments (CKs), which were used as differentiation markers. Outgrowths grown for 2 weeks expressed similar levels of CKs 14, 13 and 18 showing a de-differentiated phenotype, while outgrowths cultured for 4 weeks presented very high levels of CK 13, high CK 14 and low CK 18 expression and were squamous differentiated. De-differentiated cells presented higher proliferation indexes than squamous cells. Gene transfer levels, as evaluated using a quantitative reporter gene (firefly luciferase), were significantly higher in the 2- than in the 4-week-old outgrowths. Cationic vector transfected respiratory cells were located both proximally and distally to the explant, as shown by enzymatic staining of beta-galactosidase-positive cells. Respiratory cell outgrowths from nasal polyps can be considered a suitable model to study gene transfer protocols in vitro.

Restoration of bacterial killing activity of human respiratory cystic fibrosis cells through cationic vector-mediated cystic fibrosis transmembrane conductance regulator gene transfer.

In vitro and in vivo studies have demonstrated that gene transfer of the CFTR (cystic fibrosis transmembrane conductance regulator) cDNA into human respiratory cells through nonviral vectors can occur safely and can be done repeatedly. Although functional evaluation of CFTR in cystic fibrosis (CF) patients enrolled in phase I clinical trials using cationic liposomes has shown a partial correction of nasal potential difference, a biological assay indicating a therapeutic relevance of CFTR gene transfer is still missing. Our aims were to study the induction of killing activity toward Pseudomonas aeruginosa (PA) in CF cells by cationic vector-mediated CFTR gene transfer and to use this assay as a therapeutic end point. Luciferase expression and GFP FACS analysis were used to evaluate the optimal vector and the efficiency of gene transfer into non-CF human respiratory cells growing from nasal polyp explants at the air-liquid interface. To prove that transgenic CFTR was expressed in CF cell cultures under the same experimental conditions, a specific RT-PCR was performed. Challenge of the outgrowths with a known amount of PA showed a bacterial clearance activity by non-CF respiratory cells, while in the case of CF cells it even resulted in bacterial growth. Cationic vector-mediated CFTR cDNA determined the recovery of bacterial clearance activity only under those conditions yielding 5% or more of GFP-positive cells. The results shown in this study might be helpful in considering cationic vectors as therapeutic nonviral vectors for transferring CFTR into human CF respiratory cells, as well as for restoring the bacterial killing activity defective in cystic fibrosis.

Comparison between cationic polymers and lipids in mediating systemic gene delivery to the lungs.

Airway inflammation frequently found in congenital and acquired lung diseases may interfere with gene delivery by direct administration through either instillation or aerosol. Systemic delivery by the intravenous administration represents an alternative route of delivery that might bypass this barrier. A nonviral approach for transfecting various airway-derived cell lines in vitro showed that cationic polymers (PEI 22K and 25K) and lipids (DOTAP, GL-67/DOPE) are able to transfect with high efficiency the reporter genes firefly luciferase and E. coli lacZ. Notably, two properties predicted that cationic vectors would be useful for a systemic gene delivery approach to the lung: (1) transfection was not inhibited or increased when cells were incubated with cationic lipids or polymers in the presence of serum; and (2) cationic vectors protected plasmid DNA from DNase degradation. A single injection of DNA complexed to the cationic polymer PEI 22K into the tail vein of adult mice efficiently transfected primarily the lungs and to a lesser extent, heart, spleen, kidney and liver. The other vectors mediated lower to undetectable levels of luciferase expression in the lungs, with DOTAP > GL67/DOPE > PEI 25K > DOTMA/DOPE. A double injection protocol with a 15-min interval between the two doses of DOTAP/DNA complexes was investigated and showed a relevant role of the first injection in transfecting the lungs. A two log increase in luciferase expression was obtained either when the two doses were comprised of luciferase plasmid or when an irrelevant plasmid was used in the first injection. The double injection of luciferase/PEI 22K complexes determined higher transgene levels than a single dose, but a clear difference using an irrelevant plasmid as first dose was not observed. Using lacZ as a reporter gene, it was shown that only cells in the alveolar region, including type II penumocytes, stained positively for the transgene product.

Acute pyelonephritis as a cause of hyponatremia/hyperkalemia in young infants with urinary tract malformations.

Obstructive uropathy causes tubular resistance to aldosterone and severe metabolic imbalance may be precipitated by an episode of pyelonephritis. In the last 3 years we investigated 52 episodes of pyelonephritis (positive urine culture, elevated C reactive protein, fever, elevated neutrophil count) in 50 children between 15 days and 15 months of age. Ultrasonography voiding cystography and renal scintiscan were performed in all cases and i.v. urography in some. A salt-losing syndrome with hyponatremia and hyperkalemia (Na < 125 meq/liter; K > 6.3 meq/liter) was observed in 17 infants < 3 months, accompanied by plasma aldosterone concentration of 5000 to 23,000 pg/ml (normal value, < 1000 pg/ml). All these children had a severe urinary tract (UT) malformation (ureteropelvic junction stenosis in 7 cases, vesicoureteral reflux in 7, posterior urethral valves in 2, double system in 1). Thirteen infants < 3 months, 7 with no urinary tract malformations, did not have electrolyte imbalance. Pyelonephritis was diagnosed in 20 other patients ages 4 to 15 months, including 16 with severe UT malformations; 4 had normal UTs. We conclude that a salt-losing syndrome with tubular resistance to aldosterone can occur during pyelonephritis in young infants with congenital UT malformation, that the risk diminishes considerably or disappears after 3 months of age and that in the absence of UT malformation pyelonephritis does not cause acute sodium loss of clinical relevance.