Adenovirus-mediated transfer of a recombinant alpha 1-antitrypsin gene to the lung epithelium in vivo.

The respiratory epithelium is a potential site for somatic gene therapy for the common hereditary disorders alpha 1-antitrypsin (alpha 1AT) deficiency and cystic fibrosis. A replication-deficient adenoviral vector (Ad-alpha 1AT) containing an adenovirus major late promoter and a recombinant human alpha 1AT gene was used to infect epithelial cells of the cotton rat respiratory tract in vitro and in vivo. Freshly isolated tracheobronchial epithelial cells infected with Ad-alpha 1AT contained human alpha 1AT messenger RNA transcripts and synthesized and secreted human alpha 1AT. After in vivo intratracheal administration of Ad-alpha 1AT to these rats, human alpha 1AT messenger RNA was observed in the respiratory epithelium, human alpha 1AT was synthesized and secreted by lung tissue, and human alpha 1AT was detected in the epithelial lining fluid for at least 1 week.

Molecular basis of alpha 1-antitrypsin deficiency and emphysema associated with the alpha 1-antitrypsin Mmineral springs allele.

The Mmineral springs alpha 1-antitrypsin (alpha 1AT) allele, causing alpha 1AT deficiency and emphysema, is unique among the alpha 1AT-deficiency alleles in that it was observed in a black family, whereas most mutations causing alpha 1AT deficiency are confined to Caucasian populations of European descent. Immobilized pH gradient analysis of serum demonstrated that alpha 1AT Mmineral springs migrated cathodal to the normal M2 allele. Evaluation of Mmineral springs alpha 1AT as an inhibitor of neutrophil elastase, its natural substrate, demonstrated markedly lower than normal function. Characterization of the alpha 1AT Mmineral springs gene demonstrated that it differed from the common normal M1(Ala213) allele by a single-base substitution causing the amino acid substitution Gly-67 (GGG)----Glu-67 (GAG). Capitalizing on the fact that this mutation creates a polymorphism for the restriction endonuclease AvaII, family analysis demonstrated that the Mmineral springs alpha 1AT allele was transmitted in an autosomal-codominant fashion. Evaluation of genomic DNA showed that the index case was homozygous for the alpha 1AT Mmineral springs allele. Cytoplasmic blot analysis of blood monocytes of the Mmineral springs homozygote demonstrated levels of alpha 1AT mRNA transcripts comparable to those in cells of a normal M1 (Val213) homozygote control. Evaluation of in vitro translation of Mmineral springs alpha 1AT mRNA transcripts demonstrated a normal capacity to direct the translation of alpha 1AT. Evaluation of secretion of alpha 1AT by the blood monocytes by pulse-chase labeling with [35S]methionine, however, demonstrated less secretion by the Mmineral springs cells than normal cells. To characterize the posttranslational events causing the alpha 1AT-secretory defect associated with the alpha 1AT Mmineral springs gene, retroviral gene transfer was used to establish polyclonal populations of murine fibroblasts containing either a normal human M1 alpha 1AT cDNA or an Mmineral springs alpha 1AT cDNA and expressing comparable levels of human alpha 1AT mRNA transcripts. Pulse-chase labeling of these cells with [35S]methionine demonstrated less secretion of human alpha 1AT from the Mmineral springs cells than from the M1 cells, and evaluation of cell lysates also demonstrated lower amounts of intracellular human alpha 1AT in the Mmineral springs cells than in the normal M1 control cells. Thus, the Gly-67 --> Glu mutation that characterizes Mmineral springs causes reduced alpha 1AT secretion on the basis of aberrant posttranslational alpha 1AT biosynthesis by a mechanism distinct from that associated with the alpha 1AT Z allele, whereby intracellular aggregation of the mutant protein is etiologic of the alpha 1AT-secretory defect. Furthermore, for the alpha 1AT protein that does reach the circulation, this mutation markedly affects the ability of the molecule to inhibit neutrophil elastase; i.e., the alpha 1AT Mmineral springs allele predisposes to emphysema on the basis of serum apha 1AT deficiency coupled with alpha AT dysfunction.

Intracellular degradation of newly synthesized collagen.

The intracellular degradation of newly synthesized collagen is a cellular pathway that accounts for the destruction of 10-60% of collagen synthesized by a variety of cell types prior to secretion. This pathway can serve in a regulatory role to limit the secretion of defective molecules, and, in response to some extracellular mediators, regulates the amount and type of collagens secreted. In addition, this pathway may contribute to the pathogenesis of a variety of conditions affecting the extracellular matrix including fibrosis, diabetes mellitus, and scurvy.

In vivo transfer of the human cystic fibrosis transmembrane conductance regulator gene to the airway epithelium.

Direct transfer of the normal cystic fibrosis (CF) transmembrane conductance regulator (CFTR) gene to airway epithelium was evaluated using a replication-deficient recombinant adenovirus (Ad) vector containing normal human CFTR cDNA (Ad-CFTR). In vitro Ad-CFTR-infected CFPAC-1 CF epithelial cells expressed human CFTR mRNA and protein and demonstrated correction of defective cAMP-mediated Cl- permeability. Two days after in vivo intratracheal introduction of Ad-CFTR in cotton rats, in situ analysis demonstrated human CFTR gene expression in lung epithelium. PCR amplification of reverse transcribed lung RNA demonstrated human CFTR transcripts derived from Ad-CFTR, and Northern analysis of lung RNA revealed human CFTR transcripts for up to 6 weeks. Human CFTR protein was detected in epithelial cells using anti-human CFTR antibody 11-14 days after infection. While the safety and effectiveness remain to be demonstrated, these observations suggest the feasibility of in vivo CFTR gene transfer as therapy for the pulmonary manifestations of CF.

Molecular basis of the liver and lung disease associated with the alpha 1-antitrypsin deficiency allele Mmalton.

Alpha 1-Antitrypsin (alpha 1AT) deficiency is characterized by reduced serum levels of alpha 1AT and a risk for the development of emphysema and liver disease. However, whereas there is an increased risk for emphysema associated with at least 10 alpha 1AT deficiency and null alleles, the hepatic disease is observed only in a subset of these alleles, suggesting that it is not the reduced serum levels of alpha 1AT per se which cause the liver disease. The present study characterizes the alpha 1AT deficiency allele Mmalton, an allele that like the common Z deficiency mutation (Glu342----Lys) is associated with both alpha 1AT deficiency and hepatic disease. Capitalizing on the identification of the homozygous inheritance of the rare Mmalton alpha 1AT deficiency allele, it was demonstrated that although caused by a very different mutation, the Mmalton allele shares with the Z allele the association of liver disease with the same type of abnormalities of alpha 1AT biosynthesis. Cloning of the Mmalton gene and sequence analysis demonstrated that it differs from the normal alpha 1AT M2 allele by deletion of the entire codon (TTC) for residue Phe52. Liver biopsy of the Mmalton homozygote revealed inflammation, mild fibrosis, and intrahepatocyte accumulation of alpha 1AT. Evaluation of de novo alpha 1AT biosynthesis in alpha 1AT-synthesizing cells of this individual demonstrated normal levels of alpha 1AT mRNA transcripts but abnormal intracellular accumulation of newly synthesized alpha 1AT at the level of the rough endoplasmic reticulum with consequent reduced alpha 1AT secretion. Finally, retroviral gene transfer of a normal alpha 1AT cDNA and an alpha 1AT cDNA with the Mmalton Phe52 deletion into murine cells demonstrated that the Mmalton cells reproduced the abnormal accumulation of newly synthesized alpha 1AT, thus directly demonstrating that the deletion mutation is responsible for the intracellular accumulation of the newly synthesized alpha 1AT. Thus, not only is the liver disease associated with alpha 1AT deficiency restricted to a subset of alpha 1AT deficiency alleles, it appears to be restricted to those alleles associated with intracellular accumulation of newly synthesized alpha 1AT, suggesting that it is the abnormal intrahepatocyte alpha 1AT accumulation which incites the liver injury.