Ltap, a mammalian homolog of Drosophila Strabismus/Van Gogh, is altered in the mouse neural tube mutant Loop-tail

Neural tube defects (NTDs) such as spina bifida and anencephaly are common congenital malformations in humans (1/1,000 births) that result from failure of the neural tube to close during embryogenesis. The etiology of NTDs is complex, with both genetic and environmental contributions; the genetic component has been extensively studied with mouse models. Loop-tail (Lp) is a semidominant mutation on mouse chromosome 1 (ref. 4). In the two known Lp alleles (Lp, Lpm1Jus), heterozygous mice exhibit a characteristic looped tail, and homozygous embryos show a completely open neural tube in the hindbrain and spinal region, a condition similar to the severe craniorachischisis defect in humans. Morphological and neural patterning studies indicate a role for the Lp gene product in controlling early morphogenesis and patterning of both axial midline structures and the developing neural plate. The 0.6-cM/0.7-megabase (Mb) Lp interval is delineated proximally by D1Mit113/Apoa2/Fcer1g and distally by Fcer1a/D1Mit149/Spna1 and contains a minimum of 17 transcription units. One of these genes, Ltap, encodes a homolog of Drosophila Strabismus/Van Gogh (Stbm/Vang), a component of the frizzled/dishevelled tissue polarity pathway. Ltap is expressed broadly in the neuroectoderm throughout early neurogenesis and is altered in two independent Lp alleles, identifying this gene as a strong candidate for Lp.

Genetic and biochemical diversity in the Pax gene family

The mammalian Pax gene family comprises nine members that are characterized by a conserved DNA-binding motif, the paired domain, which was originally described in the Drosophila protein paired. Both loss- and gain-of-function studies reveal that Pax genes carry out essential roles during embryogenesis, and in some instances, may function as master regulatory genes. This review focuses on both genetic and biochemical aspects of the Pax family, and emphasizes important differences in the activity of individual Pax genes and their protein products.

Identification of a new chemically induced allele (Lp(m1Jus)) at the loop-tail locus: morphology, histology, and genetic mapping

Loop-tail (Lp) is a semidominant mutation that affects neurulation in mice. Heterozygous animals are characterized by a looped-tail appearance (pig tail) and wobbly head movements while homozygous embryos exhibit a neural tube closure defect that extends from the caudal midbrain to the tip of the tail. The Lp gene has been finely mapped to the distal part of chromosome 1, and a positional cloning strategy has been initiated to isolate the defective gene. This study represents the characterization of a new Lp allele (Lp(m1Jus)) induced by N-ethyl-N-nitrosurea mutagenesis. Lp(m1Jus)/+ mice have a looped-tail appearance, and both Lp(m1Jus)/Lp(m1Jus) homozygotes and Lp/Lp(m1Jus) compound heterozygotes fail to initiate neural tube closure along most of the embryonic axis. These data indicate that the Lp(m1Jus) allele causes a neural tube defect and overall phenotype similar to that of the original Lp allele. Segregation analysis of 90 (Lp(m1Jus)/+ x C57BL/6J)F(1) x C57BL/6J looped-tail mice with seven markers that define the Lp genetic map (D1Mit455/D1Mit146/D1Mit148/D1Mit270-1 cM-D1Mit113-0.4 cM-Lp-0.2 cM-D1Mit149-0.8 cM-D1Mit115) showed significant linkage between Lp(m1Jus) and all loci analyzed (P < 0.0001). Eight crossovers were detected with the proximal cluster of D1Mit455, D1Mit146, D1Mit148, and D1Mit270, indicating a recombination rate higher than expected in this region, and a single recombinant was encountered with the distal markers D1Mit149 and D1Mit115. Based on these phenotypic and genetic data, Lp(m1Jus) is most likely allelic to Lp, thereby representing a valuable additional tool for the positional cloning of the Lp gene and its subsequent molecular characterization.

Transcription mapping and expression analysis of candidate genes in the vicinity of the mouse Loop-tail mutation

Loop-tail (Lp) is a semidominant mutation that maps to the distal portion of mouse Chromosome (Chr) 1 and is an established model for neural tube defects (NTDs). Homozygous embryos exhibit an open neural tube from the caudal midbrain to the tip of the tail that results from over-differentiation of the floor plate. To facilitate the positional cloning of the Lp gene, both cDNA selection and assignment of sequence-tagged-sites from the human transcript map have been used to identify genes within the Lp interval. Together with previous physical mapping, this has allowed the placement of 13 transcription units within an approximately 1-Mb region that spans the Lp genetic interval, and eight of these genes map to the nonrecombinant interval. This map includes genes that encode proteins involved in protein sorting and targeting (Tim23 and Copa), ion transport (Atp1a2, Atp1a4, and Girk3), transcription (Nhlh1), immune regulation (Cd48 and Fcer1alpha), cell adhesion (R88252), apoptosis (Pea15), and several of unknown function (H326, Kiaa0253, and Estm34). Expression analysis by Northern blotting indicated that a subset of these genes are expressed preferentially in the developing nervous system. Finally, this region of mouse Chr 1 represents a conserved linkage group with genes on human chromosome 1q21, a region that is frequently altered in human cancers and that harbors loci for several genetic conditions. Consequently, analysis of the Lp interval may provide important tools to understand how the corresponding region of human Chr 1 contributes to disease, in addition to defining a key gene product required for neurulation.

The Na,K-ATPase alpha4 gene (Atp1a4) encodes a ouabain-resistant alpha subunit and is tightly linked to the alpha2 gene (Atp1a2) on mouse chromosome 1

We have isolated and characterized cDNA clones encoding the murine homologue of a putative fourth Na,K-ATPase alpha subunit isoform (alpha4). The predicted polypeptide is 1032 amino acids in length and exhibits 75% amino acid sequence identity to the rat alpha1, alpha2, and alpha3 subunits. Within the first extracellular loop, the alpha4 subunit is highly divergent from other Na,K-ATPase alpha subunits. Because this region of Na,K-ATPase is a major determinant of ouabain sensitivity, we tested the ability of the rodent alpha4 subunit to transfer ouabain resistance in a transfection protocol. We find that a cDNA containing the complete rodent alpha4 ORF is capable of conferring low levels of ouabain resistance upon HEK 293 cells, an indication that the alpha4 subunit can substitute for the endogenous ouabain-sensitive alpha subunit of human cells. Nucleotide sequences specific for the murine alpha4 subunit were used to identify the chromosomal position of the alpha4 subunit gene. By hybridizing an alpha4 probe with a series of BACs, we localized the alpha4 subunit gene (Atp1a4) to the distal portion of mouse chromosome 1, in very close proximity to the murine Na,K-ATPase alpha2 subunit gene. In adult mouse tissues, we detected expression of the alpha4 subunit gene almost exclusively in testis, with low levels of expression in epididymis. The close similarities in the organization and expression pattern of the murine and human alpha4 subunit genes suggest that these two genes are orthologous. Together, our studies indicate that the alpha4 subunit represents a functional Na,K-ATPase alpha subunit isoform.

Physical delineation of a 700-kb region overlapping the Looptail mutation on mouse chromosome 1

The mouse looptail (Lp) mutation is an established model for neural tube defects with homozygous Lp embryos showing an open neural tube from the caudal midbrain to the tip of the tail. Heterozygous Lp mice are characterized by a "looped-tail" and wobbly head movements. The Lp gene has been mapped to a 0.6-cM interval on mouse chromosome 1 delineated by two clusters of markers, Fcer1gamma/Usf1/D1Mit113/D1Wsu1 on the proximal side and Fcer1alpha/Spna1/D1Mit149 distally. In the present study, we have created a high-resolution physical map of the Lp genetic interval that is based on long-range restriction mapping by PFGE, fluorescence in situ hybridization analysis of interphase nuclei and extended chromatid fibers, and the assembly of a cloned contig. This contig consists of 25 independent and overlapping BAC clones and 3 YAC clones. The combined analysis indicates that the 0.6-cM genetic interval for Lp corresponds to a minimal physical interval of 700 kb that is delineated by D1Mit113 proximally (two crossovers) and Fcer1alpha distally (one crossover). The overall gene order and intergene distances for the region were determined to be D1Mit113-<150 kb-Nhlh1-250 kb-Atp1alpha2-280 kb-Fcer1alpha. Partial sequencing of BAC clones from the contig yielded 42 new STS markers for this region of mouse chromosome 1. Sequence analysis of the BAC clones and assignment of ESTs from the human transcript map to the cloned contig allowed the placement of four new transcription units within this region: Pc326, Kiaa0253, and Pea15 were positioned in the Nhlh1/Atp1alpha2 nonrecombinant interval, while Girk3 was located distal to Atp1alpha2.

Helix 2 of the paired domain plays a key role in the regulation of DNA-binding by the Pax-3 homeodomain

Pax3 contains two structurally independent DNA-binding domains, a paired domain (PD) and a homeodomain (HD). Biochemical and mutagenesis studies have shown that both domains are functionally interdependent. In particular, it has been shown that the PD can regulate the DNA-binding specificity and dimerization potential of the HD. To delineate Pax3 protein segments that are involved in the regulation of HD DNA-binding, a series of chimeric proteins were created in which the HD and linker region were gradually replaced with corresponding sequences from a heterologous HD protein, Phox. Characterization of chimeric proteins by electrophoretic mobility shift analysis (EMSA) suggests that a portion of the linker region contributes to the functional interaction between the PD and HD. In addition, stepwise removal of sequences from the Pax3 PD was used to define regions within this domain that are involved in the regulation of HD DNA-binding. EMSA of these proteins in the context of the chimeric Pax3/Phox backbone provided two key findings: (i) the C-terminal subdomain of the PD does not play a major role in the regulation of HD DNA-binding and (ii) the N-terminal subdomain and, in particular, the second alpha-helix are essential for modulation of HD DNA-binding. Significantly, deletion of helix 2 was found to be sufficient to uncouple regulation of HD DNA-binding by the PD.

Reciprocal effect of Waardenburg syndrome mutations on DNA binding by the Pax-3 paired domain and homeodomain

The Pax-3 protein contains two DNA-binding domains, a paired domain and a homeodomain. Mutations in Pax-3 cause Waardenburg syndrome (WS) in humans and the mouse Splotch (Sp) phenotype. In the Sp-delayed mouse, a mutation in the Pax-3 paired domain (G9R) abrogates the DNA-binding activity of both the paired domain and the homeodomain, suggesting that they may functionally interact. To investigate this possibility further, we have analyzed the DNA-binding properties of additional point mutants in the Pax-3 paired domain and homeodomain that occur in WS patients (F12L, N14H, G15S, P17L, R23L, G48A, S51F and G66D in the paired domain, V47F and R53G in the homeodomain), the Pax-1 un mutation (G15A) and a substitution associated with Peters' anomaly in the PAX-6 gene (R23G). Within the paired domain, seven of 10 mutations were found to abrogate DNA-binding by the paired domain. Remarkably, these seven mutations also affected DNA binding by the homeodomain, causing either a complete loss (P17L and G66D), a reduction (R23G, R23L, G15S and G15A) or an increase in DNA-binding activity (N14H). In addition, the effect of paired domain mutations occurred at the level of monomer formation by the homeodomain, while the dimerization potential of this domain seemed unaffected in mutants where it could be analyzed. Furthermore, while both homeodomain mutations were found to abolish DNA binding by this domain, the R53G mutation also abrogated DNA binding by the paired domain. The important observation that independent mutations in either domain can affect DNA binding by the other in the intact Pax-3 protein strongly suggests that the two domains are not functionally independent but bind DNA through cooperative interactions. Modeling the deleterlous mutations on the three-dimensional structure of the paired domain of Drosophila Prd shows that these mutations cluster at the DNA interface, thus suggesting that a series of DNA contacts are essential for DNA binding by both the paired domain and the homeodomain of Pax-3.

The paired-domain regulates DNA binding by the homeodomain within the intact Pax-3 protein

Pax-3 contains two structurally independent DNA-binding domains, a paired-domain and a homeodomain. Their functional interdependence has been suggested by the analysis of the Sp-delayed (Spd) mouse mutant, in which a glycine to arginine substitution at position 9 of the paired-domain abrogates DNA binding by both domains. This glycine is located in the beta-turn portion of a beta-hairpin motif, and the requirement for this structure was investigated by mutagenesis at this and neighboring positions. At position 9, only substitution with proline increased DNA binding by the paired-domain and homeodomain above the level observed with the Spd arginine mutation, suggesting that the beta-turn is necessary for the function of both DNA-binding domains. Alanine scanning mutagenesis also identified a number of flanking residues important for DNA binding by both domains, emphasizing the requirement of the beta-hairpin for the interaction of Pax-3 with DNA. Furthermore, we show that these mutations reduce binding by the homeodomain at the monomeric level and do not impair dimerization on a TAAT(N)2ATTA consensus motif. In contrast, the wild-type paired-domain was found to prevent dimerization on consensus motifs with 3-base pair spacing of the type TAAT(N)3ATTA. Importantly, both the deleterious effect of the Spd mutation on homeodomain DNA binding and the loss of dimerization on TAAT(N)3ATTA motifs can be transferred to a heterologous homeodomain from the human phox protein. Moreover, the presence of the paired-domain affects sequence discrimination within the 3-base pair spacer in this context. These analyses establish that the beta-hairpin motif is essential for paired-domain and homeodomain DNA binding, and suggest a novel mechanism by which the paired-domain can influence sequence specificity of the homeodomain within the Pax-3 polypeptide.

Hepatic nuclear proteins that bind cis-regulatory elements in the proximal promoter of the rat corticosteroid-binding globulin gene

The plasma transport protein for glucocorticoids, corticosteroid-binding globulin (CBG), is produced by hepatocytes, and expression of the CBG gene (Cbg) in the liver is controlled by a variety of hormones, environmental stimuli, and developmental cues. The rat Cbg proximal promoter, including 145 base pairs (bp) from the transcription start site, contains two cis-regulatory elements (designated P1 and P2), and is as transcriptionally active as a much more extended region (approximately 1.2 kbp) of the promoter. We have now characterized the rat liver nuclear proteins that interact with P1 and P2. Several proteins interacted specifically with P1 during an electrophoretic mobility shift assay (EMSA), and based on ultraviolet (UV) cross-linking and Southwestern blot analyses, as well as an antibody-supershifting EMSA, one of these has been identified as hepatic nuclear factor (HNF)1 beta. The major band shift formed with P2 in an EMSA appears to comprise a protein that migrates as a doublet of 58 and 62 KDa on sodium dodecylsulfate-polyacrylamide gel ectrophoresis (SDS-PAGE) after UV cross-linking with an oligonucleotide containing P2, as well as during Southwestern blot analyses. Mutations of the CCAAT sequence within P2 also prevent binding to this protein, the physicochemical properties of which resemble the CCAAT-binding protein CP2. Functional analyses of this region of the rat Cbg proximal promoter fused to a luciferase reporter gene demonstrated that mutations within P1, which prevent its interaction with NHF1, do not influence adversely its transcriptional activity. Thus, although members of the HNF1 family of nuclear proteins play an essential role in the transcriptional activation of several other related genes (e.g., thyroxin-binding globulin and alphal-antitrypsin) in hepatocytes, HNF1 beta does not appear to be required for the basal activity of the rat Cbg promoter. In addition, deletion of P2 from the proximal promoter abolishes transcriptional activity and the CCAAT-binding protein that interacts with P2 probably represents an important determinant of Cbg expression under different physiological conditions.

An alternative splicing event in the Pax-3 paired domain identifies the linker region as a key determinant of paired domain DNA-binding activity

We have identified alternatively spliced isoforms of murine Pax-3 and Pax-7 which differ by the presence or absence of a single glutamine residue in a linker region which separates two distinct DNA-binding subdomains within the paired domain. By reverse transcription-PCR, these isoforms of Pax-3 and Pax-7 (Q+ and Q-) were detected at similar levels through multiple developmental stages in the early mouse embryo. DNA-binding studies using the Q+ and Q- isoforms of Pax-3 revealed that this alternative splicing event had no major effect on the ability of these isoforms to bind to an oligonucleotide specific for the Pax-3 homeodomain (P2) or to a paired domain recognition sequence (e5) that interacts primarily with the N-terminal subdomain of the paired domain. However, DNA-binding studies with sequences (P6CON and CD19-2/A) containing consensus elements for both the N-terminal and C-terminal subdomains revealed that the Q- isoform binds to these sequences with a two- to fivefold-higher affinity; further mutation of the GTCAC core N-terminal subdomain recognition motif of CD19-2/A generated binding sites with a high degree of specificity for the Q- isoform. These differences in DNA binding in vitro were also reflected in the enhanced ability of the Q- isoform to stimulate transcription of a reporter containing multiple copies of CD19-2/A upstream of the thymidine kinase basal promoter. In support of the observations made with these naturally occurring Pax-3 isoforms, introducing a glutamine residue at the analogous position in PAX6 caused a fivefold reduction in binding to P6CON and a complete loss of binding to CD19-2/A and to the C-terminal subdomain-specific probe 5aCON. These studies therefore provide direct evidence for a role for the paired-domain linker region in DNA target site selection, and they identify novel isoforms of Pax-3 and Pax-7 that have the potential to mediate distinct functions in the developing embryo.

cis-regulatory elements within the proximal promoter of the rat gene encoding corticosteroid-binding globulin

Corticosteroid-binding globulin (CBG) transports and modulates the bioavailability of glucocorticoids in blood plasma. It is produced predominantly by the liver, but is also produced in a complex spatial and temporal pattern during development and is regulated hormonally. The rat Cbg promoter (pCbg) has therefore been cloned to allow identification of cis-acting sequence elements that could contribute to its regulation. Five protein-binding sites (P1 to P5) were identified within 236 bp immediately 5' of the transcription start point by DNase I footprinting with rat liver nuclear extracts. These P1-P5 sites are highly conserved in the human pCbg, and resemble recognition sequences for HNF-1, CP-2, DBP, HNF-3 and C/EBP or NF-1L6, respectively. Electrophoretic mobility-shift assays indicted that the P1 element most likely binds HNF-1, and transient transfection assays with luciferase reporter plasmids demonstrated that P1-P5 represent a positive component of rat pCbg activity, whereas additional 5' sequences repressed promoter activity 2-4-fold in H4IIEC3 rat hepatoblastoma cells.

Activation of a MMTV/mdr3 fusion transcript from a cryptic viral promoter is stimulated by mdr-derived sequences located in intron I

In P388/VCR-10 cells, resistance to cytotoxic drugs is caused by the overexpression of the mdr3 gene, in absence of gene amplification. The gene is transcriptionally activated following integration of a full-length mouse mammary tumor virus (MMTV) within intron I, upstream of the coding region of the gene. This integration results in the production of MMTV/mdr3 fusion transcripts that originate from the antisense 5'LTR of the provirus. The mechanism of mdr3 activation in these cells remains unclear since it cannot be accounted for either by activation from the normal MMTV promoter or by activation of the mdr3 promoter by MMTV enhancer sequences. Subcloning and sequence analysis of the genomic region encompassing the 5' LTR of the provirus with adjacent mdr3 sequences up to exon 2 showed that the LTR had not undergone small rearrangements or deletions. Transfections of fusion plasmids containing this genomic fragment and the reporter gene luciferase showed the presence of transcriptionally active sequences in that region. Deletions of 5' and 3' sequences from this fragment have shown that the antisense LTR itself has little contribution to the activation of the luciferase gene, whereas the mdr3 derived sequences that include part of intron I and the beginning of exon 2 strongly activated luciferase expression when inserted in either orientations upstream of the reporter gene. These results suggest the presence of an activator element within intron I of mdr3 capable of activating transcription from a cryptic start site present in the antisense MMTV LTR. Derepression of this activator sequence within intron I by a mechanism involving integration of a transposable element may be a prerequisite to transcriptional activation of the gene which is silent in the parental P388 cells. Further support for a derepression mechanism of activation in P388 cells is provided by the identification of independent genomic rearrangements in the 5' region of mdr3 in additional MDR P388 derivatives analyzed in this study.

Analysis of the mouse Splotch-delayed mutation indicates that the Pax-3 paired domain can influence homeodomain DNA-binding activity

The murine Pax-3 protein contains two DNA-binding domains, a paired domain and a homeodomain, and alterations in the Pax-3 gene are responsible for the neural tube defects observed in the Splotch (Sp) mouse mutant. Of five Sp alleles, Splotch-delayed (Spd) is the only one that encodes a full-length Pax-3 protein, containing a single glycine-to-arginine substitution within the paired domain. To better understand the consequence of this mutation on Pax-3 function, we have analyzed the DNA-binding properties of wild-type and Spd Pax-3, using oligonucleotides that bind primarily to the paired domain (e5) or exclusively to the homeodomain (P2). Wild-type Pax-3 was found to bind e5 in a specific manner. In contrast, the Spd mutation reduced binding of Pax-3 to e5 17-fold, revealing a defect in DNA binding by the paired domain. Surprisingly, the Spd mutation also drastically reduced the homeodomain-specific binding to P2 by 21-fold when compared with the wild-type protein. Interestingly, a deletion which removes the Spd mutation was found to restore P2-binding activity, suggesting that within the full-length Pax-3 protein, the paired domain and homeodomain may interact. We conclude, therefore, that the Spd mutation is phenotyically expressed in vitro by a defect in the DNA-binding properties of Pax-3. Furthermore, it is apparent that the paired domain and homeodomain of Pax-3 do not function as independent domains, since a mutation in the former impairs the DNA-binding activity of the latter.

Molecular studies of corticosteroid binding globulin structure, biosynthesis and function

Phylogenetic comparisons of the primary structure of corticosteroid binding globulin (CBG) have revealed several conserved domains that include sites for N-glycosylation and a region which probably represents a portion of the steroid binding site. The major site of CBG biosynthesis in adults is clearly the liver, and the human CBG gene promoter contains sequence elements that interact with liver-specific transcription factors. Low levels of CBG gene expression have been detected in other tissues, and these may be important for fetal development during late gestation when hepatic CBG mRNA levels are low. Studies of the ontogeny of CBG biosynthesis in the rat have also indicated that plasma CBG levels may be influenced by a more rapid clearance of the protein during pubertal development. Analyses of the structural organization and chromosomal location of the human CBG gene have further confirmed its close relationship with the serine proteinase inhibitors, and suggests that CBG, alpha 1-proteinase inhibitor and alpha 1-antichymotrypsin evolved relatively recently by gene duplication. The functional significance of this relationship has been examined and our studies suggest that a specific interaction between CBG and elastase on the surface of neutrophils may represent a physiologically important event that promotes the delivery of glucocorticoids to these cells at sites of inflammation.

The human sex hormone-binding globulin gene contains exons for androgen-binding protein and two other testicular messenger RNAs

When a sex hormone-binding globulin (SHBG) cDNA was used to screen a human testicular cDNA library, three distinct cDNAs were isolated, one of which corresponds to the human SHBG cDNA sequence and probably represents testicular androgen-binding protein. The other two SHBG-related cDNAs each contain unique 5' regions that diverge from the SHBG cDNA sequence at the same position, and one of them (SHBGr-2) lacks a 208-base pair region within the SHBG cDNA. As a result, this cDNA could potentially encode for a truncated form of SHBG which lacks N-linked carbohydrates and part of the steroid-binding domain. Southern blots of human placental DNA and cloned genomic DNA fragments also indicate that SHBG and its related testicular cDNAs are the products of a single gene. Sequence analysis of the gene indicates that the complete coding region for the SHBG precursor is comprised of 8 exons, which are distributed over 3.2 kilobase (kb) of genomic DNA, and the unique 5' regions associated with the two SHBG-related testicular cDNAs were identified 1.9 kb upstream from the initiating codon for SHBG. In addition, the deletion within SHBGr-2 is due to the removal of exon 7, and an interesting feature of the gene is that differentially used exons are preceded by Alu repetitive DNA sequences. Although the relative abundance of the various SHBG-related mRNAs in the testis has not been established, Northern blot analysis indicates that they are similar in size (1.6 kb) to that of hepatic SHBG mRNA.

Organization of the human corticosteroid binding globulin gene and analysis of its 5'-flanking region

The structure of the human corticosteroid binding globulin (CBG) gene has been determined, and restriction endonuclease maps of human placental DNA and cloned genomic DNA indicate that CBG is encoded by a single gene. The transcription unit for hepatic CBG mRNA comprises five exons distributed over approximately 19 kilobases (kb), and nuclease protection and primer extension studies using human liver RNA demonstrate that the first exon spans 70 base pairs (bp). Typical of many eukaryotic promoters, sequences that resemble TATA and CAAT-box motifs are centered 28 bp and 73 bp upstream from the origin of transcription, respectively. In addition, six highly conserved sequence elements, responsible for efficient, liver-specific expression of the mouse albumin gene, are located within the first 200 bp of the 5'-flanking region. Further analysis of a region (500 bp) immediately 5' of the transcription start site, however, failed to reveal sequences that might correspond to known steroid hormone response elements. When compared to other serine protease inhibitor genes, the organization of the human CBG gene is most closely related to the human alpha 1-proteinase inhibitor and alpha 1-antichymotrypsin genes. It would therefore appear that these proteins are derived from a common ancestral gene, and this supports the concept that they may be functionally related.

Corticosteroid binding globulin, testosterone-estradiol binding globulin, and androgen binding protein belong to protein families distinct from steroid receptors

The cDNA nucleotide sequences and the deduced amino acid sequences of human corticosteroid binding globulin (hCBG), human testosterone-estradiol binding globulin (hTeBG), and rat androgen binding protein (rABP) were determined. Studies of the steroid binding sites suggest they are toward the carboxy-terminus in hTeBG and rABP and more central in hCBG. hCBG has remarkable sequence homology with members of a superfamily whose functions have diverged; these include thyroxine-binding protein, serine protease inhibitors, egg white proteins, and angiotensinogen. hTeBG and rABP have a 68% amino acid sequence identity. Hybridization studies suggest that hTeBG is probably even more closely related, if not identical, to hABP. The carboxy-terminal sequences of hTeBG and rABP are also similar to that of protein S, a vitamin-K-dependent clotting factor. There were no nucleotide or amino acid sequence homologies between hCBG, hTeBG, or rABP and other steroid binding proteins such as steroid receptors, albumin, alpha-fetoprotein, and vitamin D binding protein. We conclude that the "extracellular steroid binding proteins" and steroid receptors do not appear to have descended from a common ancestor.

Primary structure of human corticosteroid binding globulin, deduced from hepatic and pulmonary cDNAs, exhibits homology with serine protease inhibitors

We have isolated and sequenced cDNAs for corticosteroid binding globulin (CBG) prepared from human liver and lung mRNAs. Our results indicate that CBG mRNA is relatively abundant in the liver but is also present in the lung, testis, and kidney. The liver CBG cDNA contains an open reading frame for a 405-amino acid (Mr 45,149) polypeptide. This includes a predominantly hydrophobic, leader sequence of 22 residues that precedes the known NH2-terminal sequence of human CBG. We, therefore, predict that the mature protein is composed of 383 amino acids and is a polypeptide of Mr 42,646. A second, in-frame, 72-base-pair cistron of unknown significance exists between the TAA termination codon for CBG and a possible polyadenylylation signal (AATAAA) located 16 nucleotides before the polyadenylylation site. The deduced amino acid sequence of mature CBG contains two cysteine residues and consensus sequences for the attachment of six possible N-linked oligosaccharide chains. The sequences of the human lung and liver CBG cDNAs differ by only one nucleotide within the proposed leader sequence, and we attribute this to a point mutation. No sequence homology was found between CBG and other steroid binding proteins, but there is a remarkable similarity between the amino acid sequences of CBG and of alpha 1-antitrypsin, and this extends to other members of the serpin (serine protease inhibitor) superfamily.

The cDNA-deduced primary structure of human sex hormone-binding globulin and location of its steroid-binding domain

We have sequenced a cDNA for sex hormone-binding globulin (SHBG) isolated from a phage lambda gt11 human liver cDNA library. The library was screened with a radiolabeled rat androgen-binding protein (ABP) cDNA, and the abundance of SHBG cDNAs was 1 in 750,000 plaques examined. The largest human SHBG cDNA (1194 base-pairs) contained a reading frame for 381 amino acids. This comprised 8 amino acids of a signal peptide followed by 373 residues starting with the known NH2-terminal sequence of human SHBG, and ending with a termination codon. The predicted polypeptide Mr of SHBG is 40,509, and sites of attachment of one O-linked (residue 7) and two N-linked oligosaccharide (residues 351 and 367) chains were identified. Purified SHBG was photoaffinity-labeled with delta 6-[3H]testosterone and cleaved with trypsin. The labeled tryptic fragment was isolated by reverse-phase HPLC, and its NH2-terminal sequence was determined. The results suggest that a portion of the steroid-binding domain of SHBG is located between residue 296 and the 35 predominantly hydrophilic residues at the C-terminus of the protein.