Molecular structure and sequence homology of a gene related to alpha 1-antitrypsin in the human genome

SERPINA2 is a novel gene with a divergent function from SERPINA1

Serine protease inhibitors (SERPINs) are a superfamily of highly conserved proteins that play a key role in controlling the activity of proteases in diverse biological processes. The SERPIN cluster located at the 14q32.1 region includes the gene coding for SERPINA1, and a highly homologous sequence, SERPINA2, which was originally thought to be a pseudogene. We have previously shown that SERPINA2 is expressed in different tissues, namely leukocytes and testes, suggesting that it is a functional SERPIN. To investigate the function of SERPINA2, we used HeLa cells stably transduced with the different variants of SERPINA2 and SERPINA1 (M1, S and Z) and leukocytes as the in vivo model. We identified SERPINA2 as a 52 kDa intracellular glycoprotein, which is localized at the endoplasmic reticulum (ER), independently of the variant analyzed. SERPINA2 is not significantly regulated by proteasome, proposing that ER localization is not due to misfolding. Specific features of SERPINA2 include the absence of insoluble aggregates and the insignificant response to cell stress, suggesting that it is a non-polymerogenic protein with divergent activity of SERPINA1. Using phylogenetic analysis, we propose an origin of SERPINA2 in the crown of primates, and we unveiled the overall conservation of SERPINA2 and A1. Nonetheless, few SERPINA2 residues seem to have evolved faster, contributing to the emergence of a new advantageous function, possibly as a chymotrypsin-like SERPIN. Herein, we present evidences that SERPINA2 is an active gene, coding for an ER-resident protein, which may act as substrate or adjuvant of ER-chaperones.

Deletion of Serpina1a, a murine α1-antitrypsin ortholog, results in embryonic lethality

Chronic obstructive pulmonary disease (COPD) is the fourth leading cause of death in the United States Approximately 1% to 2% of COPD patients suffer from α(1)-antitrypsin (A1AT) deficiency, the major inheritable predisposition to COPD/emphysema. To further study the role of A1AT deficiency in the pathogenesis of COPD/emphysema, the authors attempted to generate null-mutant mice for Serpina1a, 1 of 2 A1AT orthologs in mice. Here the authors show that targeted deletion of Serpina1a results in embryonic lethality prior to 8.5 days post conception (dpc). The results are surprising given that A1AT-null humans exist and therefore do not require this gene product for normal development. The Serpina1 gene cluster is substantially different between mouse and man. Through gene duplication, mice have 3 to 5 (depending on the strain) highly homologous proteinase inhibiting (Pi) genes, 2 of which inhibit neutrophil elastase. Despite the abundance of Pi genes in mice, Serpina1a serves a critical, nonredundant function during early mouse development. A1AT-deficient mice have been highly sought after to study emphysema, cancer, and liver disease, and as a model to perfect gene replacement therapy. These results highlight important differences between human and murine serpins and point to the difficulty inherent to using gene-targeted mice to study this common human genetic disease.

Polymorphisms in the SERPINA1 (Alpha-1-Antitrypsin) Gene are Associated with Severe Chronic Rhinosinusitis Unresponsive to Medical Therapy

Background

Alpha-1-antitrypsin (AAT) is a serine protease inhibitor that blocks the protease, neutrophil elastase. Previous population studies have suggested that heterozygote status for the AAT gene (SERPINA1) is a risk factor for chronic rhinosinusitis with nasal polyposis (CRSwNP). This implies a potential genetic predisposition to CRS tied to AAT deficiency. The purpose of this study was to investigate the association between single nucleotide polymorphisms (SNPs) in the SERPINA1 gene and CRS.

Methods

DNA extracted from a population of 206 patients diagnosed with CRSwNPs and 196 postal code–matched controls was used. A maximally informative set of tagging SNPs from SERPINA1 on chromosome 14q were selected from the HapMap data set (International HapMap Consortium, Nature 437:1299–1320, 2005) and genotyped on the Sequenom platform (Sequenom, San Diego, CA).

Results

Successful genotyping was performed for 32 of 33 SNPs. Two SNPs (rs1243168 and rs4900229) located upstream of the SERPINA1gene, were associated with CRS. Individuals homozygous (TT)for these SNPs had an increased probability of having CRS with an odds ratio of 5.95 and 1.49, respectively. Subgroup analysis according to severity of disease identified each SNP to be increasingly common in individuals as disease severity increased (p < 0.001). These individuals were also less likely to be responsive to medical therapy (p < 0.001).

Conclusions

Polymorphisms of the SERPINA1 gene are associated with clinically severe CRS. These results, from a small subset of individuals with CRS, suggest that defects in AAT may be implicated in a subset of individuals unresponsive to conventional therapy and suggests that alternate therapies may be required for their management.

Mutation detection in the alpha-1 antitrypsin gene (PI) using denaturing gradient gel electrophoresis

A method for mutation detection in the alpha-1 antitrypsin gene (protease inhibitor 1; PI) has been developed using denaturing gradient gel electrophoresis of PCR amplified gene fragments. Using this experimental approach, all common phenotypes and mutations could be detected. Denaturing gradient gel electrophoresis (DGGE) was compared with standard isoelectric focusing (IEF) in 20 potential alpha1-antitrypsin deficient patients and their relatives. The genotype determined by DGGE was found to be more reliable in some cases than IEF, which is essential for a proper diagnosis of alpha-1 antitrypsin malfunctioning.

Stable expression and cell-specific chromatin structure of human alpha1-antitrypsin cosmid transgenes in rat hepatoma cells

The human gene encoding alpha1-antitrypsin (alpha1AT, gene symbol PI) resides in a cluster of serine protease inhibitor (serpin) genes on chromosome 14q32.1. alpha1AT is highly expressed in the liver and in cultured hepatoma cells. We recently reported the chromatin structure of a >100 kb region around the gene, as defined by DNase I-hypersensitive sites (DHSs) and matrix-attachment regions, in expressing and non-expressing cells. Transfer of human chromosome 14 by microcell fusion from non-expressing fibroblasts to rat hepatoma cells resulted in activation of alpha1AT transcription and chromatin reorganization of the entire region. In the present study, we stably introduced cosmids containing alpha1AT with various amounts of flanking sequence and a linked neo selectable marker into rat hepatoma cells. All single-copy transfectants with >14 kb of 5' flanking sequence expressed wild-type levels of alpha1AT mRNA in a position-independent manner. In contrast, expression of transgenes containing only approximately 1.5-4 kb of flanking sequence was highly variable. Long-term culture of transfectant clones in the absence of selection resulted in gradual loss of neo expression, but expression of the linked alpha1AT gene remained constant. DHS mapping of cosmid transgenes integrated at ectopic sites revealed a hepatoma-specific chromatin structure in each transfectant clone. The implications of these findings are discussed.

Differential regulation of gene activity and chromatin structure within the human serpin gene cluster at 14q32.1 in macrophage microcell hybrids

The human gene encoding alpha1-antitrypsin (alpha1AT, gene symbol PI ) is highly expressed in the liver and in cultured hepatoma cells and, to a lesser extent, in macrophages, where transcription originates from a separate upstream promoter. alpha1AT maps to a region of human chromosome 14q32.1 that includes a related serine protease inhibitor (serpin) gene that encodes corticosteroid-binding globulin (CBG). We recently reported the chromatin organization of this approximately 130 kb region, as defined by DNase I hypersensitive sites (DHSs) and matrix-attachment regions, in expressing and non-expressing cells. Furthermore, we demonstrated that transfer of human chromosome 14 from non-expressing fibroblasts to rat hepatoma cells resulted in activation of both alpha1AT and CBG transcription and gene activation was accompanied by long range chromatin reorganization of the entire region. In this study, we transferred human chromosome 14 from fibroblasts to mouse macrophages and documented activation of alpha1AT but not CBG gene expression. RT-PCR experiments indicated that transcription of the human alpha1AT gene in the microcell hybrids initiated at the macrophage promoter. Furthermore, DHS mapping experiments revealed a distinctive chromatin configuration of the locus that resembled the structure found in human macrophage-like cell lines, with many DHSs around alpha1AT but few in CBG. Thus, mouse macrophage cell lines will provide a useful cell type to study the effects of targeted modifications of the human alpha1AT-CBG locus on the regulation of cell-specific gene activity and chromatin structure.

Long-range chromatin reorganization of the human serpin gene cluster at 14q32.1 accompanies gene activation and extinction in microcell hybrids

The genes encoding alpha1-antitrypsin (alpha1AT, gene symbol PI) and corticosteroid-binding globulin (CBG) are part of a cluster of six serine protease inhibitor (serpin) genes located on human chromosome 14q32.1. Both genes are actively transcribed in the liver and in human hepatoma cells, but they are not expressed in most other cell types. In this study we mapped DNase I-hypersensitive sites (DHSs) in an approximately 130-kb region of 14q32.1 that includes both genes. The distributions of DHSs in expressing (HepG2) vs nonexpressing (HeLa S3) cells were very different: HepG2 cells displayed 29 DHSs in this interval, but only 7 of those sites were present in HeLa cells. To determine the chromatin organization of activated or extinguished serpin alleles, we transferred human chromosome 14 into rat hepatoma cells or fibroblasts, respectively. Human alpha1AT and CBG gene expression was activated in rat hepatoma microcell hybrids containing human chromosome 14, but extinguished in rat fibroblast hybrids with the same genotype. DHS mapping in these microcell hybrids demonstrated that the chromatin structure of the entire 130-kb region was reorganized in microcell hybrids, and the distributions of DHSs in activated and extinguished alleles recapitulated those of expressing and nonexpressing cells, respectively. Thus, microcell hybrids provide a system in which reproducible changes in gene activity and long-range chromatin organization can be induced experimentally. This provides a basis for studying the effects of targeted modifications of the alpha1AT and CBG loci on the regulation of gene activity and chromatin structure.

Human matrix attachment regions insulate transgene expression from chromosomal position effects in Drosophila melanogaster

Germ line transformation of white- Drosophila embryos with P-element vectors containing white expression cassettes results in flies with different eye color phenotypes due to position effects at the sites of transgene insertion. These position effects can be cured by specific DNA elements, such as the Drosophila scs and scs' elements, that have insulator activity in vivo. We have used this system to determine whether human matrix attachment regions (MARs) can function as insulator elements in vivo. Two different human MARs, from the apolipoprotein B and alpha1-antitrypsin loci, insulated white transgene expression from position effects in Drosophila melanogaster. Both elements reduced variability in transgene expression without enhancing levels of white gene expression. In contrast, expression of white transgenes containing human DNA segments without matrix-binding activity was highly variable in Drosophila transformants. These data indicate that human MARs can function as insulator elements in vivo.

A 370-kb cosmid contig of the serpin gene cluster on human chromosome 14q32.1: molecular linkage of the genes encoding alpha 1-antichymotrypsin, protein C inhibitor, kallistatin, alpha 1-antitrypsin, and corticosteroid-binding globulin

The human genes encoding alpha 1-antitrypsin (alpha 1AT, gene symbol PI), corticosteroid-binding globulin (CBG), alpha 1-antichymotrypsin (AACT), and protein C inhibitor (PCI) are related by descent, and they all map to human chromosome 14q32.1. This serine protease inhibitor (serpin) gene cluster also contains an antitrypsin-related sequence (ATR, gene symbol PIL), but the precise molecular organization of this region has not been defined. In this report we describe the generation and characterization of an approximately 370-kb cosmid contig that includes all five serpin genes. Moreover, a newly described serpin, kallistatin (KAL, gene symbol PI4), was also mapped within the region. Gene order within this interval is cen-CBG-ATR-alpha 1 AT-KAL-PCI-AACT-tel. The genes occupy approximately 320 kb of genomic DNA, and they are organized into two discrete subclusters of three genes each that are separated by approximately 170 kb. The distal subcluster includes KAL, PCI, and AACT; it occupies approximately 63 kb of DNA, and all three genes are transcribed in a proximal-to-distal orientation. Within the subcluster, there is approximately 12 kb of intergenic DNA between KAL and PCI and approximately 19 kb between PCI and AACT. The proximal subcluster includes alpha 1AT, ATR, and CBG; it occupies approximately 90 kb of genomic DNA, with approximately 12 kb of DNA between alpha 1AT and ATR and approximately 40 kb between ATR and CBG. These genes are all transcribed in a distal-to-proximal orientation. This represents the first detailed physical map of the serpin gene cluster on 14q32.1.

Molecular linkage of the human alpha 1-antitrypsin and corticosteroid-binding globulin genes on chromosome 14q32.1

The genes encoding alpha 1-antitrypsin (alpha 1AT; gene symbol PI) and corticosteroid-binding globulin (CBG) are part of a cluster of structurally related serine protease inhibitor (serpin) genes on human Chromosome (Chr) 14q32.1. This cluster also includes the genes encoding alpha 1-antichymotrypsin (AACT) and protein C inhibitor (PCI), as well as an alpha 1-antitrypsin-related sequence (ATR; gene symbol PIL). In this report we present a detailed restriction map of a 110-kb region of genomic DNA that includes the alpha 1AT, ATR, and CBG genes. Gene order in this interval is tel-alpha 1AT-ATR-CBG-cen, and all three genes are transcribed in a distal-to-proximal orientation. Within the gene cluster, ATR is approximately 12 kb downstream of alpha 1AT, and CBG is about 57 kb downstream of alpha 1AT. Repetitive DNA sequences have been mapped throughout the interval, and several new restriction site polymorphisms in the region are described.

DNA polymorphisms associated with a new alpha 1-antitrypsin PIQ0 variant (PIQ0riedenburg)

A new PIQ0 variant (PIQ0riedenburg) is described; it is caused by a complete deletion of the alpha 1-antitrypsin (alpha 1 AT) gene. The deletion gives rise to four new restriction fragment length polymorphisms (RFLPs) detected with a genomic probe of the 5' region of the gene. Analysis of the RFLPs indicates that the deletion starts immediately upstream of exon Ic. The deletion extends into the 3' flanking region of the gene but does not include the alpha 1 AT-related gene (the PIL gene), which is located 12 kb downstream of the alpha 1 AT gene.

A null deficiency allele of alpha 1-antitrypsin, QOludwigshafen, with altered tertiary structure

The most common deficiency allele of the plasma protease inhibitor alpha 1-antitrypsin (alpha 1AT) is PI*Z. Some rare deficiency alleles of alpha 1AT produce low but detectable amounts of plasma alpha 1AT (1-20% of normal), which can be differentiated by isoelectric focusing. Others, designated null (QO) alleles, produce no alpha 1AT detectable by routine quantitative methods. We have previously described a method using DNA polymorphisms, haplotypes, and polyacrylamide isoelectric focusing gels, to differentiate various deficiency alleles. Based on haplotypes, we previously identified, in eight patients, five different null alleles, four of which had been previously sequenced. We have now analyzed all 12 null alleles in these eight patients, using allele-specific oligonucleotide probes, and have identified six different null alleles. We have cloned and sequenced one of these, PI*QOludwigshafen, which has a base substitution in exon II, replacing isoleucine 92 in the normal sequence with an asparagine. This substitution of a polar for a nonpolar amino acid occurs in one of the alpha-helices and is predicted to disrupt the tertiary structure. A total of 13 different alpha 1AT deficiency alleles, 6 of them null alleles, have been sequenced to date.

Giant G+C% mosaic structures of the human genome found by arrangement of GenBank human DNA sequences according to genetic positions

To determine the overall variation in the G+C% distribution over long ranges of the human genome, DNA sequences of human genes, which were closely linked genetically or physically, were surveyed from the GenBank Data Bank. A total of 72 sequences longer than 2 kb, which were mutually linked within 500 kb, were identified. The sequences belonged to 17 linkage groups and were ordered in each group according to their genetic positions. Analyses of the G+C% distribution along the ordered sequences showed that sequences within each group almost always had similar G+C% levels, but those belonging to different groups often had different levels. Similar analyses of more distantly linked sequences (e.g., greater than 10 Mb) showed mosaic structures of G+C% distribution. These findings are consistent with predictions made from the "isochore" structures found by CsCl equilibrium centrifugation, in that the structures having homogeneous base compositions stretched over at least several hundred kilobases. A possible boundary of the giant G+C% mosaic structures was identified between X-linked G6PD and F8C.

Molecular biology and respiratory disease. 7. The alpha 1 antitrypsin gene and chronic lung disease

Images

A physical map of the human PI and AACT genes

We have used probes from the human genes PI, PIL, and AACT (alpha 1-antitrypsin, alpha 1-antitrypsin-related sequence, and alpha 1-antichymotrypsin) to make a pulsed-field map of the surrounding region of 14q31-32. We have discovered that the PI-PIL gene cluster is only 220 kb away from the AACT gene and that it is orientated in the opposite direction. The comparatively short distance between the genes comes as a surprise given previous estimates of the level of genetic recombination between them.

Complete cDNA sequence and chromosomal localization of mouse alpha 1-antitrypsin

A cDNA encoding the complete open reading frame of murine alpha 1-antitrypsin has been cloned and sequenced. The nucleic acid and predicted amino acid sequences show homology to human alpha 1-antitrypsin and demonstrate the preservation of critical structural determinants for intracellular targeting, carbohydrate attachment, and catalytic function. The alpha 1-antitrypsin gene locus (Aat) has been localized on murine chromosome 12E----F by in situ hybridization.

Serine proteinase inhibitors on chromosome 14 and the genetics of familial chronic obstructive airways disease

Environmental and genetic factors contribute to familial chronic obstructive airways disease. The genetic component could be polygenic or in some families be associated with one or two major genes. It is assumed that most cases of familial chronic obstructive airways disease are polygenic, but this conclusion is based on insufficient data. The use of linkage analysis using DNA probes for specific genes that may have a direct role in the disease process should facilitate our understanding of the genetics. Genetic deficiency of alpha1-antitrypsin is associated with predisposition to pulmonary emphysema. In the absence of alpha 1-antitrypsin deficiency I suggest that a study of serine-proteinase inhibitors on chromosome 14 may identify a significant proportion of families where only one major gene is important.

Deletion/frameshift mutation in the alpha 1-antitrypsin null allele, PI*QObolton

The most common deficiency allele of the protease inhibitor (PI) alpha 1-antitrypsin (alpha 1AT) is PI*Z. Other rare deficiency alleles of alpha 1AT are of two types: those producing low but detectable amounts of alpha 1AT (less than 20% of normal serum concentrations), and null alleles producing less than 1% of normal alpha 1AT and therefore not detectable by routine quantitative methods. We have previously used DNA polymorphisms and family data to determine heterozygosity in an individual producing low levels of serum alpha 1AT (12% of normal) of PI type Mmalton. By DNA analysis we observed the typical haplotype associated with PI*Mmalton and a unique null haplotype associated with the allele PI*QObolton. The QObolton allele produces no detectable serum alpha 1AT. We have cloned and sequenced the QObolton allele from a phage genomic library. Deletion of a single cytosine residue near the active site of alpha 1 AT in exon V results in a frameshift causing an in-frame stop codon downstream of the deletion. This stop codon leads to premature termination of protein translation at amino acid 373, resulting in a truncated protein. The truncated protein is predicted to have an altered carboxy terminus (amino acids 363-372) and will lack structurally important amino acids.

Widespread expression of human alpha 1-antitrypsin in transgenic mice revealed by in situ hybridization

In situ hybridization is a powerful means of identifying sites of gene expression. We used this technique to examine the spatial and developmental control of transcription of the human alpha 1-antitrypsin (alpha 1 AT) gene in transgenic mice carrying this gene and extensive 5'- and 3'-flanking sequences. In addition to expression in yolk sac and liver, human alpha 1AT RNA was detected in gut, stomach, pancreas, nasal epithelium, pharynx, bronchi, spinal ganglia, and ossifying cartilage of transgenic fetuses at 14.5 days post coitum (dpc). In transgenic adults, expression was no longer found in the pancreas but was found in the kidney and salivary gland. In each tissue, expression was confined to a specific cell population. This pattern of alpha 1AT expression was found to correlate with that seen in several fetal and adult human tissues. These results suggest a wider role of alpha 1AT in human physiology and development than previously suspected, and they demonstrated the potential value of this approach in delineating the physiological role of human proteins. Expression of the endogenous alpha 1AT gene in mice was confined to a limited, but overlapping, set of tissues, suggesting that the cis-acting DNA sequences that regulate the expression of the human and mouse genes interact differently with transcription factors present in mouse cells.