Altered stability of pulmonary surfactant in SP-C-deficient mice.

The surfactant protein C (SP-C) gene encodes an extremely hydrophobic, 4-kDa peptide produced by alveolar epithelial cells in the lung. To discern the role of SP-C in lung function, SP-C-deficient (-/-) mice were produced. The SP-C (-/-) mice were viable at birth and grew normally to adulthood without apparent pulmonary abnormalities. SP-C mRNA was not detected in the lungs of SP-C (-/-) mice, nor was mature SP-C protein detected by Western blot of alveolar lavage from SP-C (-/-) mice. The levels of the other surfactant proteins (A, B, D) in alveolar lavage were comparable to those in wild-type mice. Surfactant pool sizes, surfactant synthesis, and lung morphology were similar in SP-C (-/-) and SP-C (+/+) mice. Lamellar bodies were present in SP-C (-/-) type II cells, and tubular myelin was present in the alveolar lumen. Lung mechanics studies demonstrated abnormalities in lung hysteresivity (a term used to reflect the mechanical coupling between energy dissipative forces and tissue-elastic properties) at low, positive-end, expiratory pressures. The stability of captive bubbles with surfactant from the SP-C (-/-) mice was decreased significantly, indicating that SP-C plays a role in the stabilization of surfactant at low lung volumes, a condition that may accompany respiratory distress syndrome in infants and adults.

Secretion of surfactant protein C, an integral membrane protein, requires the N-terminal propeptide.

Proteolytic processing of surfactant protein C (SP-C) proprotein in multivesicular bodies of alveolar type II cells results in a 35-residue mature peptide, consisting of a transmembrane domain and a 10-residue extramembrane domain. SP-C mature peptide is stored in lamellar bodies (a lysosomal-like organelle) and secreted with surfactant phospholipids into the alveolar space. This study was designed to identify the peptide domain of SP-C required for sorting and secretion of this integral membrane peptide. Deletion analyses in transiently transfected PC12 cells and isolated mouse type II cells suggested the extramembrane domain of mature SP-C was cytosolic and sufficient for sorting to the regulated secretory pathway. Intratracheal injection of adenovirus encoding SP-C mature peptide resulted in secretion into the alveolar space of wild type mice but not SP-C (-/-) mice. SP-C secretion in null mice was restored by the addition of the N-terminal propeptide. The cytosolic domain, consisting of the N- terminal propeptide and extramembrane domain of mature SP-C peptide, supported secretion of the transmembrane domain of platelet-derived growth factor receptor. Collectively, these studies indicate that the N-terminal propeptide of SP-C is required for intracellular sorting and secretion of SP-C.

Human SP-C gene sequences that confer lung epithelium-specific expression in transgenic mice.

We used transgenic mice to identify cis-active regions of the human pulmonary surfactant protein C (SP-C) gene that impart tissue- and cell-specific expression in vivo in the lung. Approximately 3.7 kb of genomic SP-C DNA upstream of the transcription start site was sufficient to direct chloramphenicol acetyltransferase (CAT) reporter gene expression specifically in bronchiolar and alveolar epithelial cells of the lung. To further define cis-active regulatory elements that mediate cell-specific expression, we tested deletions of the parental 3.7-kb human SP-C sequence in transgenic mice. Tissue CAT assays of mice generated with truncations or overlapping internal deletions of the 3.7-kb construct functionally map alveolar cell-specific regulatory elements to within -215 bp of the SP-C promoter. Analysis of SP-C promoter deletions demonstrate that sequences between -3.7 kb and -1.9 kb contain enhancer sequences that stimulate SP-C transgene expression. In situ hybridization studies demonstrate that deletion of the -1,910- to -215-bp region abolishes the ectopic bronchiolar expression seen with the original 3.7-kb SP-C promoter construct. Comparison of sequences from -215 to +1 bp identified consensus binding sites for the homeodomain transcription factor thyroid transcription factor-1 (TTF-1). Cotransfection assays of the human 3.7-kb SP-C or -1,910- to -215-bp SP-C deletion construct with a TTF-1 expression plasmid demonstrates that TTF-1 transactivates the human SP-C gene. These results suggest that the TTF-1 cis-active sites are important in directing cell-specific expression of the SP-C gene in vivo.

Regulation of surfactant protein gene transcription.

Surfactant protein concentrations are precisely maintained during fetal development and postnatally controlled, at least in part, by the regulation of gene transcription and/or mRNA stability. Together, these mechanisms contribute to the unique temporal-spatial distribution of surfactant protein synthesis that is characteristic of the mammalian lung. Surfactant proteins A, B and C are expressed primarily in subsets of respiratory epithelial cells, wherein their expression is modified by developmental, physiological, humoral and inflammatory stimuli. Cell specific and humoral regulation of surfactant protein transcription is determined by the interactions of a number of nuclear transcription proteins that function in combination, by binding to cis-acting elements located in the 5' regulatory regions of each of the surfactant protein genes. The unique combination of distinct and shared cis-acting elements and transcriptional proteins serves to modulate surfactant protein synthesis in the lung. The present review will summarize efforts to identify the mechanisms contributing to the regulation of surfactant protein gene transcription in the lung, focusing to the nuclear transcription factor, TTF-1 (or thyroid transcription factor-1), a member of the Nkchi2 family of nuclear transcription proteins. A complete review of regulatory aspects of surfactant homeostasis is beyond the scope of the present summary.

Nuclear factor I family members regulate the transcription of surfactant protein-C.

Transcription of the surfactant protein-C (SP-C) gene is restricted to Type II epithelial cells in the adult lung. We have shown previously that the 0.32-kilobase pair (kb) mouse SP-C promoter is functional in transient transfection assays of the lung epithelial cell-derived cell line, MLE-15, and that thyroid transcription factor 1 (TTF-1) transactivates promoter activity. The 0.32-kb SP-C promoter can be separated into a proximal promoter region (-230 to +18) and an enhancer region (-318 to -230). Three DNase I footprints were mapped in the promoter region (C1 through C3) and two in the enhancer region (C4 and C5). We now show that nuclear factor I (NFI) family members bind to both individual NFI half-sites in footprints C1, C3, and C5, and to a composite site in footprint C4 by competition gel retardation and antibody supershift analyses. Mutational analysis of the 0.32-kb mouse SP-C promoter and transient transfection of MLE-15 cells demonstrated that the NFI binding sites are required for promoter activity in this cell type. Site-specific mutation of the proximal or distal NFI sites drastically reduced transactivation by a co-transfected NFI-A expression vector in HeLa cells. These data indicate that NFI family member(s), binding to sites in both the promoter and enhancer regions, regulate SP-C gene expression in a process independent of TTF-1.

Reversal of lung lesions in transgenic transforming growth factor alpha mice by expression of mutant epidermal growth factor receptor.

Transgenic mice expressing transforming growth factor alpha (TGF-alpha) in type II cells under control of the lung-specific surfactant protein-C (SP-C) promoter develop pulmonary fibrosis and marked airspace hypoplasia. To identify cellular signaling mechanisms involved in lesion formation, we generated transgenic mice expressing a mutant epidermal growth factor receptor lacking a portion of the intracytoplasmic domain (EGF-R-M) under control of the human SP-C promoter. Transcripts of the SP-C-EGF-R-M transgene were detected in distal bronchiolar and type II cells by in situ hybridization. The morphology of lungs from the SP-C-EGF-R-M transgenic mice was normal. Lung fibrosis was not detectable and airspace hypoplasia was significantly corrected in bitransgenic mice derived by breeding SP-C-TGF-alpha and SP-C-EGF-R-M mice. Correction of lung pathology in the bitransgenic mice occurred without altering the level of hTGF-alpha mRNA. To further demonstrate that reversal of TGF-alpha lesions required signaling through the EGF-R, SP-C-TGF-alpha transgenic mice were bred to mice homozygous for the wa-2 mutation which encodes a mutated EGF-R. TGF-alpha-induced lesions were reversed in homozygous wa-2 mice. Amelioration of TGF-alpha-dependent pulmonary lesions in SP-C-EGF-R-M mice or wa-2/wa-2 mice supports the concept that autocrine and paracrine signaling mediate fibrosis and airspace remodeling caused by TGF-alpha.

Altered surfactant function and structure in SP-A gene targeted mice.

The surfactant protein A (SP-A) gene was disrupted by homologous recombination in embryonic stem cells that were used to generate homozygous SP-A-deficient mice. SP-A mRNA and protein were not detectable in the lungs of SP-A(-/-) mice, and perinatal survival of SP-A(-/-) mice was not altered compared with wild-type mice. Lung morphology, surfactant proteins B-D, lung tissue, alveolar phospholipid pool sizes and composition, and lung compliance in SP-A(-/-) mice were unaltered. At the highest concentration tested, surfactant from SP-A(-/-) mice produced the same surface tension as (+/+) mice. At lower concentrations, minimum surface tensions were higher for SP-A(-/-) mice. At the ultrastructural level, type II cell morphology was the same in SP-A(+/+) and (-/-) mice. While alveolar phospholipid pool sizes were unperturbed, tubular myelin figures were decreased in the lungs of SP-A(-/-) mice. A null mutation of the murine SP-A gene interferes with the formation of tubular myelin without detectably altering postnatal survival or pulmonary function.

Transcription of the lung-specific surfactant protein C gene is mediated by thyroid transcription factor 1.

Surfactant protein C (SP-C) is expressed in alveolar Type II epithelial cells of the lung. In order to determine the mechanism(s) that regulate gene transcription, we have analyzed the activation of the murine SP-C promoter in mouse lung epithelial cells (MLE cells) and in HeLa cells after co-transfection with a vector expressing rat thyroid transcription factor-1 (TTF-1). TTF-1 transactivated SP-C-chloramphenicol acetyltransferase constructs containing -13 kilobase pairs to -320 base pairs (bp) of the 5 flanking region of the SP-C gene. Essential cis-acting elements were functionally localized to between -320 and -180 bp from the start of transcription by transfection analysis. Five DNase-protected regions, indicating multiple protein-DNA interactions within the -320 bp TTF-1-responsive region of the SP-C gene, were identified by DNase footprint analysis. A 40-bp segment of SP-C DNA from -197 to -158 linked to a heterologous promoter-chloramphenicol acetyltransferase construct activated expression after co-transfection with CMV-TTF-1 in HeLa and MLE cells. The -197 to -158 segment contained two consensus TTF-1 sites, which were specifically identified as TTF-1 binding sites by gel retardation and antibody supershift with MLE cell nuclear extracts and purified TTF-1 homeodomain protein. Site-specific mutagenesis of either of the TTF-1 binding sites completely blocked activation by TTF-1, indicating both sites are required for TTF stimulation of SP-C transcription.

Tumor necrosis factor-alpha inhibits surfactant protein C gene transcription.

Pulmonary surfactant protein C (SP-C) is a 3.7-kDa, hydrophobic peptide secreted by alveolar type II epithelial cells. SP-C enhances surface tension lowering activity of surfactant phospholipids that is critical to the maintenance of alveolar volume at end expiration. The proinflammatory cytokine, tumor necrosis factor alpha (TNF-alpha), decreased SP-C mRNA within 24 h of intratracheal administration to mice. In vitro, TNF-alpha decreased SP-C mRNA in a time-and dose-dependent manner, reducing the steady state levels of SP-C mRNA by 3-5 fold. In contrast, TNF-alpha induced intercellular adhesion molecule-1 expression in both mouse lung and murine lung epithelial cell lines. Nuclear run-on analysis demonstrated that transcription of both the endogenous SP-C gene and a human SP-C promoter-driven transgene was inhibited by TNF-alpha. TNF-alpha decreased mouse SP-C chloramphenicol acetyltransferase mRNA in stably transfected murine epithelial cells. Deletion analysis of the SP-C promoter region demonstrated that TNF-alpha inhibited gene expression in constructs containing 320 base pairs 5' from the start of transcription of the mouse SP-C gene. Inhibition of surfactant protein C gene transcription by TNF-alpha may contribute to the abnormalities of surfactant homeostasis associated with pulmonary injury and infection.

Transgenic models for study of pulmonary development and disease.

This review summarizes progress in the application of transgenic mouse technology to the study of lung development and disease. Since advances in molecular genetics have greatly facilitated the isolation of cDNA and genes, our ability to readily assess roles of both normal and mutated genes in transgenic mouse in vivo represents a major advance, bridging molecular biology and whole animal physiology. Strategies have been developed in which lung epithelial cell promoter elements are used to drive normal or mutated genes into specific subsets of respiratory epithelial cells in the lungs of developing and mature transgenic mice. These mice have been used to elucidate the cis-acting elements controlling lung epithelial cell gene expression, to discern the role of specific polypeptides in lung morphogenesis and tumorigenesis, and to create animal models of pulmonary disease. The ability to mutate genes at their precise chromosomal locations through gene targeting in embryonic stem cells has lead to the production of animal models of lung diseases such as cystic fibrosis. Both gene insertion and gene targeting create permanent mouse lines that pass the modified gene to their progeny, providing animals for the study of the pathogenesis and treatment of pulmonary disorders.

Regulation of gene expression in the lung.

Lung gene expression is regulated by a complex interaction of autocrine, paracrine, and endocrine factors. With cloning of lung-specific genes, the mechanisms of transcriptional control of lung gene expression are beginning to be deciphered. This review focuses on expression are beginning to be deciphered. This review focuses on recent research that identifies cis-active sequences and trans-active proteins interacting to control expression of lung-specific genes. Delineating the mode of gene regulation is important in beginning to understand the mechanisms underlying the cellular differentiation required for fetal development of lung cells and recovery of lung cells from acute and chronic injury.

Respiratory epithelial cell expression of human transforming growth factor-alpha induces lung fibrosis in transgenic mice.

Increased production of EGF or TGF-alpha by the respiratory epithelial cells has been associated with the pathogenesis of various forms of lung injury. Growth factors and cytokines are thought to act locally, via paracrine and autocrine mechanisms, to stimulate cell proliferation and matrix deposition by interstitial lung cells resulting in pulmonary fibrosis. To test whether TGF-alpha mediates pulmonary fibrotic responses, we have generated transgenic mice expressing human TGF-alpha under control of regulatory regions of the human surfactant protein C (SP-C) gene. Human TGF-alpha mRNA was expressed in pulmonary epithelial cells in the lungs of the transgenic mice. Adult mice bearing the SP-C-TGF-alpha transgene developed severe pulmonary fibrosis. Fibrotic lesions were observed in peribronchial, peribronchiolar, and perivascular regions, as well as subjacent to pleural surfaces. Lesions consisted of fibrous tissue that included groups of epithelial cells expressing endogenous SP-C mRNA, consistent with their identification as distal respiratory epithelial cells. Peripheral fibrotic regions consisted of thickened pleura associated with extensive collagen deposition. Alveolar architecture was disrupted in the transgenic mice with loss of alveoli in the lung parenchyma. Pulmonary epithelial cell expression of TGF-alpha in transgenic mice disrupts alveolar morphogenesis and produces fibrotic lesions mediated by paracrine signaling between respiratory epithelial and interstitial cells of the lung.

Utilization of modified surfactant-associated protein B for delivery of DNA to airway cells in culture.

Pulmonary surfactant lines the airway epithelium and creates a potential barrier to successful transfection of the epithelium in vivo. Based on the functional properties of pulmonary surfactant protein B (SP-B) and the fact that this protein is neither toxic nor immunogenic in the airway, we hypothesized that SP-B could be modified to deliver DNA to airway cells. We have modified native bovine SP-B by the covalent linkage of poly(lysine) (average molecular mass of 3.3 or 10 kDa) to the N terminus of SP-B and formed complexes between a test plasmid and the modified SP-B. Transfection efficiency was determined by transfection of pulmonary adenocarcinoma cells (H441) in culture with the test plasmid pCPA-RSV followed by measurement of activity of the reporter gene encoding chloramphenicol acetyltransferase (CAT). Transfections were performed with DNA.protein complexes using poly(lysine)10kDa-SP-B ([Lys]10kDa-SP-B) or poly(lysine)3.3kDa-SP-B ([Lys]3.3kDa-SP-B), and results were compared with transfections using unmodified poly(lysine).DNA, unmodified SP-B.DNA, or DNA only. For [Lys]10kDa-SP-B.pCPA-RSV preparations, CAT activity was readily detectable above the background of [Lys]3.3kDa-SP-B or unmodified SP-B. The SP-B-poly(lysine) conjugates were effective over a broad range of protein-to-DNA molar ratios, although they were optimal at approximately 500:1-1000:1. Transfection efficiency varied with the tested cell line but was not specific to airway cells. Addition of replication-defective adenovirus to the [Lys]10kDa-SP-B.pCPA-RSV complex enhanced CAT activity about 30-fold with respect to that produced by the [Lys]10kDa-SP-B.pCPA-RSV complex alone. This increase suggests routing of the adenoviral.[Lys]10kDa-SP-B.pCPA-RSV complex through an endosomal pathway. Effects of covalent modification on the secondary structure of SP-B were examined by Fourier transform infrared spectrometry (FTIR). Results of FTIR indicated that the conformation of [Lys]10kDa-SP-B was comprised primarily of alpha-helical structure compared with a predominantly aggregated structure of unmodified poly(lysine). We conclude that poly(lysine) conjugates of SP-B effectively deliver DNA in vitro and may have utility as DNA delivery vehicles to the airway in vivo.

Transcriptional elements from the human SP-C gene direct expression in the primordial respiratory epithelium of transgenic mice.

Transgenic animals bearing a chimeric gene containing 5'-flanking regions of the human surfactant protein C (SP-C) gene ligated to the bacterial chloramphenicol acetyltransferase (CAT) gene were analyzed by in situ hybridization histochemistry to determine the temporal and spatial distribution of transgene expression during organogenesis of the murine lung. Ontogenic expression of the SP-C-CAT gene was compared to that of the endogenous SP-C gene and to the Clara cell CC10 gene. High levels of SP-C-CAT expression were observed as early as Day 10 of gestation in epithelial cells of the primordial lung buds. Low levels of endogenous SP-C mRNA were detected a day later, but only in the more distal epithelial cells of the newly formed, primitive, lobar bronchi. On Gestational Days 13 through 16, transcripts for both the endogenous and chimeric gene were restricted to distal epithelial elements of the branching bronchial tubules and were no longer detected in the more proximal regions of the bronchial tree. Although high levels of SP-C-CAT expression were maintained throughout organogenesis, endogenous SP-C expression increased dramatically on Gestational Day 15, coincident with acinar tubule differentiation at the lung periphery. Low levels of endogenous CC10 expression were detected by Gestational Day 16 in both lobar and segmental bronchi. By the time of birth, CC10 transcripts were expressed at high levels in the trachea and at all levels of the bronchial tree; endogenous SP-C mRNA was restricted to epithelial cells of the terminal alveolar saccules; and SP-C-CAT expression was now detected in both alveolar and bronchiolar epithelial cells. These results indicate that (1) cis-acting regulatory elements of the human SP-C gene can direct high levels of foreign gene expression to epithelial cells of the embryonic mouse lung; (2) expression of the human SP-C-CAT chimeric gene is developmentally regulated, exhibiting a morphogenic expression pattern similar, but not identical, to that of the endogenous murine SP-C gene; (3) the embryonic expression of endogenous SP-C and chimeric SP-C-CAT transcripts identifies progenitor cells of the distal respiratory epithelium; and (4) differentiation of bronchial epithelium is coincident with loss of SP-C expression and subsequent acquisition of CC10 expression in proximal regions of the developing bronchial tubules.

Murine pulmonary surfactant SP-A gene: cloning, sequence, and transcriptional activity.

SP-A is an abundant pulmonary surfactant-associated protein whose expression is controlled in a cell- and developmental-specific manner. To analyze regulation of SP-A gene expression, the murine SP-A gene was cloned and sequenced. The murine DBA/2J gene was approximately 4.6 kb in length comprised of six exons and five introns. Three mRNAs of 3.0, 1.7, and 0.9 kb were detected by Northern blot analysis of murine lung mRNA. Expression of the SP-A mRNAs was first detected at day 15 of gestation and increased dramatically before birth. A single SP-A gene was detected in the DBA/2J mouse genome. SP-A mRNA was detected in lung but not in the gastrointestinal tract, kidney, brain, liver, or heart and was detected by in situ hybridization in bronchial and alveolar cells of the murine lung. Primer extension analysis with a primer to exon three revealed two extension products differing by 9 bp in length, suggesting two closely juxtaposed transcription initiation sites. Chimeric gene(s) containing 1.8 kb of 5' SP-A sequences and the bacterial chloramphenicol acetyltransferase gene were expressed in pulmonary adenocarcinoma cells and in HeLa cells. Expression of the murine SP-A gene is partially controlled by non-cell-selective transcriptionally active sequences.

Human Mn-superoxide dismutase in pulmonary epithelial cells of transgenic mice confers protection from oxygen injury.

To test directly whether mitochondrial Mn-superoxide dismutase (Mn-SOD) protects the lung epithelium from oxygen-induced injury, transgenic mice were produced in which the expression of human Mn-SOD mRNA was directly by transcriptional elements from the human pulmonary surfactant protein C gene. Human Mn-SOD mRNA was expressed in a lung-specific manner, and increased Mn-SOD protein was detected within mitochondria of alveolar Type II and nonciliated bronchiolar cells of the distal respiratory epithelium of the transgenic mice. The activity of Mn-SOD, but not catalase, CuZn-SOD, or glutathione peroxidase, was increased in lungs of transgenic mice. Transgenic mice were highly protected from lung injury during exposure to 95% oxygen, surviving significantly longer than nontransgenic littermates. Pulmonary pathology demonstrated decreased hemorrhage, hyaline membrane formation, and alveolar and interstitial edema in transgenic animals. The finding that increased Mn-SOD in distal respiratory epithelial cells confers protection from oxygen injury provides a basis for novel therapies to protect lung from injury during oxygen therapy of acute and chronic lung diseases.

Chromosomal localization of three pulmonary surfactant protein genes in the mouse.

Pulmonary surfactant, a protein-phospholipid mixture, maintains surface tension at the lung epithelium/air interface preventing alveolar collapse during respiration. For mammals appropriate developmental production of surfactant is necessary for adaptation to the air breathing environment. Deficiency of pulmonary surfactant results in respiratory distress syndrome (RDS), a leading cause of death in premature infants. Recently, three lung-specific pulmonary surfactant proteins designated SP-A, SP-B, and SP-C have been described. Cloned sequences for the genes that encode each of these proteins have been partially characterized in humans and other species. Analysis of interspecific backcross mice has allowed us to map the chromosomal locations of these three genes in the mouse. The gene encoding SP-A (Sftp-1) and the gene encoding SP-C (Sftp-2) both map to mouse chromosome 14, although at separate locations, while the gene encoding SP-B (Sftp-3) maps to chromosome 6. The mouse map locations determined in this study for the Sftp genes are consistent with the locations of these genes on the human genetic map and the syntenic relationships between the human and the mouse genomes.

Genetic element from human surfactant protein SP-C gene confers bronchiolar-alveolar cell specificity in transgenic mice.

Transgenic mice bearing chimeric genes consisting of 5'-sequences derived from the human surfactant protein C (SP-C) gene and the bacterial chloramphenicol acetyltransferase (CAT) gene were generated. Analysis of CAT activity was utilized to demonstrate tissue-specific and developmental expression of chimeric genes containing 3.7 kb of sequences from the human SP-C gene. Lung-specific expression of the 3.7 SP-C-CAT transgene was observed in eight distinct transgenic mouse lines. Expression of the 3.7 SP-C-CAT transgene was first detected in fetal lung on day 11 of gestation and increased dramatically with advancing gestational age, reaching adult levels of activity before birth. In situ hybridization demonstrated that expression of 3.7 SP-C-CAT mRNA was confined to the distal respiratory epithelium. Antisense CAT hybridization was detected in bronchiolar and type II epithelial cells in the adult lung of the 3.7 SP-C-CAT transgenic mice. In situ hybridization of four distinct 3.7 SP-C-CAT transgenic mouse lines demonstrated bronchiolar-alveolar expression of the chimeric CAT gene, although the relative intensity of expression at each site varied within the lines studied. Glucocorticoids increased murine SP-C mRNA in fetal lung organ culture. Likewise, expression of 3.7 SP-C-CAT transgene increased during fetal lung organ or explant culture and was further enhanced by glucocorticoid in vitro. The 5'-regions of human SP-C conferred developmental, lung epithelial, and glucocorticoid-enhanced expression of bacterial CAT in transgenic mice. The increased expression of SP-C accompanying prenatal lung development and exposure to glucocorticoid is mediated, at least in part, at the transcriptional level, being influenced by cis-active elements contained within the 5'-flanking region of the human SP-C gene.

A portion of the human surfactant protein A (SP-A) gene locus consists of a pseudogene.

SP-A is the most abundant, surfactant-associated protein isolated from lung lavage. Genomic blot analysis of total human cellular DNA with SP-A cDNA demonstrated the presence of multiple hybridizing fragments that are not accounted for by available SP-A gene sequences. In this report, we have cloned and characterized human genomic DNA fragments that account for some of the other hybridizing fragments. These clones contain nucleotide sequences that are highly homologous to the fourth intron and fifth exon of the human SP-A gene. Sequences upstream from these SP-A-like sequences are not detectable by Northern blot hybridization of SP-A-expressing cells and the SP-A-like sequences contain premature stop codons, consistent with the interpretation that these clones represent an SP-A pseudogene. Restriction fragments consistent with this pseudogene and the functional SP-A gene are present in a human chromosome 10 genomic library made from a single chromosome, showing that the functional SP-A gene and the pseudogene are syntenic.