Lung disease in mice with cystic fibrosis.

The leading cause of mortality and morbidity in humans with cystic fibrosis is lung disease. Advances in our understanding of the pathogenesis of the lung disease of cystic fibrosis, as well as development of innovative therapeutic interventions, have been compromised by the lack of a natural animal model. The utility of the CFTR-knockout mouse in studying the pathogenesis of cystic fibrosis has been limited because of their failure, despite the presence of severe intestinal disease, to develop lung disease. Herein, we describe the phenotype of an inbred congenic strain of CFTR-knockout mouse that develops spontaneous and progressive lung disease of early onset. The major features of the lung disease include failure of effective mucociliary transport, postbronchiolar over inflation of alveoli and parenchymal interstitial thickening, with evidence of fibrosis and inflammatory cell recruitment. We speculate that the basis for development of lung disease in the congenic CFTR-knockout mice is their observed lack of a non-CFTR chloride channel normally found in CFTR-knockout mice of mixed genetic background.

A serine, threonine and proline-rich region near the carboxyl-terminus of a rat intestinal mucin peptide.

Further sequencing of a cDNA encoding the C-terminal region of a rat intestinal mucin peptide reveals a region corresponding to 258 amino acids enriched in serine, threonine and proline, but no typical mucin-like tandem repeat structures. Between this region and a previously described stretch of 4.5 degenerate S,T,P-rich tandem repeats, there is a 42 amino acid cysteine-rich segment. The discontinuity of cysteine-rich and S,T,P-rich areas near the C-terminus has not been observed in other mammalian mucin structures reported to date.

Assessment of the efficacy of in vivo CFTR protein replacement therapy in CF mice.

Cystic Fibrosis (CF) is caused by mutations in the CF gene that lead, for the most part, to mislocalization of the protein product, the cystic fibrosis transmembrane conductance regulatory (CFTR). CFTR is a chloride channel normally situated in the apical membrane of epithelial cells where it contributes to transepithelial ion transport. In this study we demonstrated the feasibility of in vivo transfer of purified CFTR protein via phospholipid liposomes into the apical membrane of nasal epithelia of CFTR knockout mice. Membrane incorporation of immunogold-labeled CFTR could be visualized by electron microscopy and correction of CF-related defects in ion transport measured by nasal potential difference (PD) measurements in about one-third of the animals treated. Although these initial results are promising, effectiveness of this therapeutic approach appears to be limited by the inefficient incorporation of CFTR into the apical epithelial cell membrane.

Disruption of ClC-2 expression is associated with progressive neurodegeneration in aging mice.

Heterozygous mutations in ClC-2 have been associated in rare cases with increased susceptibility to generalized, idiopathic epilepsy. Initially, it was hypothesized that mutations in ClC-2 may be associated with epilepsy due to a direct role for ClC-2 in the modification of hippocampal neuronal excitability. However, the absence of an overt seizure-susceptibility phenotype in young ClC-2 knockout (KO) mice rendered this hypothesis- implausible. A recent study of older ClC-2 KO mice (>6 months) revealed abnormalities in the myelin of central axons and a subtle defect in the neuronal function in the central auditory pathway. These findings prompted us to re-examine hippocampal neuron morphology and excitability in older ClC-2 KO mice. Interestingly, electrocorticographic recordings obtained in older mice revealed spontaneous interictal spikes which are a marker of perturbed hippocampal neurotransmission with a resultant increase in excitation. This electrophysiological defect was associated with astrocyte activation and evidence of neuronal degeneration in the CA3 region of the hippocampus of these older mice. Together, these findings raise the possibility that ClC-2 expression plays a subtle neuroprotective role in the aging hippocampus.

Perturbation of the pore of the cystic fibrosis transmembrane conductance regulator (CFTR) inhibits its atpase activity.

Mutations in the cystic fibrosis gene coding for the cystic fibrosis transmembrane conductance regulator (CFTR) lead to altered chloride (Cl(-)) flux in affected epithelial tissues. CFTR is a Cl(-) channel that is regulated by phosphorylation, nucleotide binding, and hydrolysis. However, the molecular basis for the functional regulation of wild type and mutant CFTR remains poorly understood. CFTR possesses two nucleotide binding domains, a phosphorylation-dependent regulatory domain, and two transmembrane domains that comprise the pore through which Cl(-) permeates. Mutations of residues lining the channel pore (e.g. R347D) are typically thought to cause disease by altering the interaction of Cl(-) with the pore. However, in the present study we show that the R347D mutation and diphenylamine-2-carboxylate (an open pore inhibitor) also inhibit CFTR ATPase activity, revealing a novel mechanism for cross-talk from the pore to the catalytic domains. In both cases, the reduction in ATPase correlates with a decrease in nucleotide turnover rather than affinity. Finally, we demonstrate that glutathione (GSH) inhibits CFTR ATPase and that this inhibition is altered in the CFTR-R347D variant. These findings suggest that cross-talk between the pore and nucleotide binding domains of CFTR may be important in the in vivo regulation of CFTR in health and disease.

A monomer is the minimum functional unit required for channel and ATPase activity of the cystic fibrosis transmembrane conductance regulator.

The cystic fibrosis transmembrane conductance regulator (CFTR) normally functions as a phosphorylation-regulated chloride channel on the apical surface of epithelial cells, and lack of this function is the primary cause for the fatal disease cystic fibrosis (CF). Previous studies showed that purified, reconstituted CFTR can function as a chloride channel and, further, that its intrinsic ATPase activity is required to regulate opening and closing of the channel gate. However, these previous studies did not identify the quaternary structure required to mediate conduction and catalysis. Our present studies show that CFTR molecules may self-associate in CHO and Sf9 membranes, as complexes close to the predicted size of CFTR dimers can be captured by chemical cross-linking reagents and detected using nondissociative PAGE. However, CFTR function does not require a multimeric complex for function as we determined that purified, reconstituted CFTR monomers are sufficient to mediate regulated chloride conduction and ATPase activity.

Quaternary structure of the chloride channel ClC-2.

The chloride channel ClC-2 is thought to be essential for chloride homeostasis in neurons and critical for chloride secretion by the developing respiratory tract. In the present work, we investigated the quaternary structure of ClC-2 required to mediate chloride conduction. We found using chemical cross-linking and a novel PAGE system that tagged ClC-2 expressed in Sf9 cells exists as oligomers. Fusion of membranes from Sf9 cells expressing this protein confers double-barreled channel activity, with each pore exhibiting a unitary conductance of 32 pS. Polyhistidine-tagged ClC-2 from Sf9 cells can be purified as monomers, dimers, and tetramers. Purified, reconstituted ClC-2 monomers do not possess channel function whereas both purified ClC-2 dimers and tetramers do mediate chloride flux. In planar bilayers, reconstitution of dimeric ClC-2 leads to the appearance of a single, anion selective 32 pS pore, and tetrameric ClC-2 confers double-barreled channel activity similar to that observed in Sf9 membranes. These reconstitution studies suggest that a ClC-2 dimer is the minimum functional structure and that ClC-2 tetramers likely mediate double-barreled channel function.

Novel method for evaluation of the oligomeric structure of membrane proteins.

Assessment of the quaternary structure of membrane proteins by PAGE has been problematic owing to their relatively poor solubility in non-dissociative detergents. Here we report that several membrane proteins can be readily solubilized in their native quaternary structure with the use of the detergent perfluoro-octanoic acid (PFO). Further, PFO can be used with PAGE, thereby providing a novel, accessible tool with which to assess the molecular mass of homo-multimeric protein complexes.

Tissue-specific expression of a rat intestinal mucin-like peptide.

Expression of the gene for a rat intestinal mucin-like peptide (MLP) was studied by Northern-blot analyses of RNA prepared from a panel of rat tissues. Four probes (A-D) were constructed so as to span a 3.5 kb-long cDNA for rat MLP, and used for hybridization. Positive signals were obtained in intestine and colon, whereas lung, liver, stomach, submandibular gland and spleen were negative. The only transcript detected was approx. 9.5 kb in size. No mRNA splice variants were found. Hybridization in situ using probe B1, which corresponds to a cysteine-rich region near the C-terminus of MLP, confirmed that the gene for MLP is expressed by goblet cells of rat intestine and colon.

A novel procedure for the efficient purification of the cystic fibrosis transmembrane conductance regulator (CFTR).

This report describes a novel, single-step strategy for the purification of the cystic fibrosis transmembrane conductance regulator from Sf9 cells, which will facilitate studies of the structure-function relationships of this clinically important molecule. The new method combines the use of the novel detergent sodium pentadecafluoro-octanoate with metal-affinity chromatography to produce a high yield of purified protein which can be functionally reconstituted as a chloride channel and an ATPase.

Walker mutations reveal loose relationship between catalytic and channel-gating activities of purified CFTR (cystic fibrosis transmembrane conductance regulator).

The cystic fibrosis transmembrane conductance regulator (CFTR) functions as an ATPase and as a chloride channel. It has been hypothesized, on the basis of electrophysiological findings, that the catalytic activity of CFTR is tightly coupled to the opening and closing of the channel gate. In the present study, to determine the structural basis for the ATPase activity of CFTR, we assessed the effect of mutations within the "Walker A" consensus motifs on ATP hydrolysis by the purified, intact protein. Mutation of the lysine residue in the "Walker A" motif of either the first nucleotide binding fold (CFTRK464A) or the second nucleotide binding fold (CFTRK1250A) inhibited the ATPase activity of the purified intact CFTR protein significantly, by greater than 50%. This finding suggests that the two nucleotide binding folds of CFTR are functioning cooperatively in catalysis. However, the rate of channel gating was only significantly inhibited in one of these purified mutants, CFTRK1250A, suggesting that ATPase activity may not be tightly coupled to channel gating as previously hypothesized.

cDNA for the carboxyl-terminal region of a rat intestinal mucin-like peptide.

When subjected to thiol reduction, purified intestinal mucins have been shown to undergo a decrease in molecular mass and to liberate a 118-kDa glycopeptide (Roberton, A. M., Mantle, M., Fahim, R. E. F., Specian, R., Bennick, A., Kawagishi, S., Sherman, P., and Forstner, J. F. (1989) Biochem. J. 261, 637-647). The latter has been called a putative "link" component because it is assumed to be important for disulfide bond-mediated mucin polymerization. Controversy exists as to whether the putative link is an integral mucin component or a separate mucin-associated glycopeptide. In the present study both NH2-terminal and internal amino acid sequences of the 118-kDa glycopeptide of rat intestinal mucin were used to generate opposing oligonucleotide primers for polymerase chain reaction. A specific 1.2-kilobase (kb) product was obtained, from which a 0.5-kb HindIII fragment was used as a probe to screen a lambda ZAP II cDNA library of rat intestine. A 2.6-kb cDNA (designated MLP 2677) was sequenced and revealed an open reading frame of 2.5 kb encoding 837 amino acids. The deduced amino acid sequence showed that the putative link peptide is equivalent to the carboxyl-terminal 689 amino acids of a larger peptide. Northern blots revealed a mRNA size of approximately 9 kb. Computer searches revealed no sequence homology with other proteins, but similarities were seen in the alignment of cysteine residues in the link and in several domains of human von Willebrand factor, as well as cysteine-rich areas of bovine and porcine submaxillary mucins and a frog skin mucin designated FIM-B.1. In keeping with earlier demonstrations of the presence of mannose in the 118-kDa glycopeptide, there were several (13) consensus sequences for attachment of N-linked oligosaccharides within the link domain. Further sequencing of MLP 2677 in a direction 5' to the codon specifying the NH2-terminal proline of the link has revealed a coding region for 148 amino acids, including a unique 75-amino acid domain rich in cysteine and proline, and a region containing 4.5-variable tandem repeats (each 11-12 amino acids) rich in serine, threonine, and proline. The presence of mucin-like tandem repeats suggests that the entire cysteine-rich link peptide represents the carboxyl-terminal region (75.5 kDa) of a mucin-like peptide (MLP). The latter is estimated to have a molecular mass of approximately 300 kDa.

A conserved region of the R domain of cystic fibrosis transmembrane conductance regulator is important in processing and function.

The R domain of cystic fibrosis transmembrane conductance regulator (CFTR) connects the two halves of the protein, each of which possess a transmembrane-spanning domain and a nucleotide binding domain. Phosphorylation of serine residues, which reside mostly within the C-terminal two-thirds of the R domain, is required for nucleotide-dependent activation of CFTR chloride channel activity. The N terminus of the R domain is also likely to be important in CFTR function, since this region is highly conserved among CFTRs of different species and exhibits sequence similarity with the "linker region" of the related protein, P-glycoprotein. To date, however, the role of this region in CFTR channel function remains unknown. In this paper, we report the effects of five disease-causing mutations within the N terminus of the CFTR-R domain. All five mutants exhibit defective protein processing in mammalian HEK-293 cells, suggesting that they are mislocalized and fail to reach the cell surface. However, in the Xenopus oocyte, three mutants reached the plasma membrane. One of these mutants, L619S, exhibits no detectable function, whereas the other two, D614G and I618T, exhibit partial activity as chloride channels. Single channel analysis of these latter two mutants revealed that they possess defective rates of channel opening, consistent with the hypothesis that the N terminus of the R domain participates in ATP-dependent channel gating. These findings support recent structural models that include this region within extended boundaries of the first nucleotide binding domain.