Expression of the pregnancy-specific beta 1-glycoprotein genes in human testis

Northern blot analysis with placental pregnancy-specific beta 1-glycoprotein (SP1) cDNA probe showed the presence of SP1 mRNAs in human testis. Presence of translational products of the mRNAs was demonstrated by Western blot analysis with anti-human SP1 antibodies albeit difference in mobilities between the testis and placental proteins was apparent. Screening of human testis cDNA library with placental SP1 probe yielded 4 groups of positive clones. Two groups were identical to human placental SP1 cDNAs previously reported. The other 2 groups consisted of cDNA of incompletely processed mRNAs. These 2 groups were present in high abundance. Sequence analysis suggested that the cDNAs were products of different genes.     

Characterization of baboon pregnancy-specific beta 1-glycoprotein

Immunostaining of baboon placental tissues with anti-human pregnancy-specific beta 1-glycoprotein (SPI) antibodies demonstrated that an SP1-like molecule was present in the syncytiotrophoblasts. Staining was observed on the membrane and in the cytoplasm, but the nucleus was devoid of any staining. Western blot analysis further demonstrated the presence of five protein species in baboon placental extract, whereas four protein bands were detected in human placental extract. Culture medium of baboon placental villi also contained five SP1-like molecules with sizes slightly different from those present in the placental extract. Amniotic fluid and culture medium of decidua basalis and chorioamniotic tissue contained lesser quantities and fewer species of SP1-like molecules. However, an 87 kDa band was present in all samples examined. Northern blot analysis of baboon placenta with a human placental SP1 cDNA probe demonstrated the presence of a 1.65 Kb band, whereas two hybridizing bands (1.65 Kb and 2.25 Kb) were present in human placenta. Southern blot analysis of baboon genomic DNA further demonstrated the presence of multiple bands hybridizing with a human placental SP1 cDNA probe. These results showed the presence in baboons of multiple genes encoding mRNAs and proteins highly similar to human placental SP1.     

Characterization of pregnancy-specific beta 1-glycoprotein synthesized by human placental fibroblasts

We have previously demonstrated that human placental fibroblasts produce a pregnancy-specific beta 1-glycoprotein (PS beta G) immunologically indistinguishable from placental PS beta G. This was confirmed by the immunocytochemical localization of PS beta G in these fibroblasts. In addition, placental fibroblasts contain all three PS beta G mRNAs of 2.3, 2.2, and 1.7 kilobases which hybridize with the three PS beta G cDNAs (PSG16, PSG93, and PSG95) identified, although at 1.4-2.5% of the levels in human term placenta. The major PS beta G species synthesized by placental fibroblasts is a 62K glycopolypeptide formed from a 58K intracellular precursor polypeptide. However, the PS beta G species found in human placenta are one major glycoprotein of 72K and two minor ones of 64K and 54K. Poly(A)+ RNA from placental fibroblasts directed the synthesis of two polypeptides of 48K and 46K (major), whereas, poly(A)+ RNA from human placenta directed the synthesis of higher levels of four polypeptides of 50 K, 48 K (major), 46 K, and 36 K. Thus, the major PS beta G species found in fibroblasts and human placenta differ. The carbohydrate side-chains are essential for the stability of fibroblast PS beta G, because PS beta G synthesis in these fibroblasts could not be detected in the presence of tunicamycin, a protein glycosylation inhibitor which did not affect PS beta G mRNA expression. Our finding that a variant PS beta G species is produced in placental fibroblasts raises the possibility that the authentic placental PS beta G species may have different functions.     

Isolation and characterization of complementary DNAs encoding human pregnancy-specific beta 1-glycoprotein

Pregnancy-specific beta 1-glycoprotein (PS beta G) isolated from human placenta consists of a set of at least three glycoproteins with apparent molecular masses of 72, 64, and 54 kDa, respectively. This heterogeneity is confirmed by the detection of three nonglycosylated polypeptides of 50, 48, and 36 kDa, which can be immunoprecipitated by antiserum to placental PS beta G obtained by in vitro translation of placental poly(A)+ RNA. To examine the structural relationships between these proteins, two cDNA clones of 1912 base pairs (PSG16) and 2131 base pairs (PSG93) encoding human PS beta Gs were isolated from a human placental lambda gt11 cDNA library. The sequenced portions of these two cDNAs are identical with the exception that clone PSG93 contains an additional 86 base pairs at the end of the common 3'-coding region. This insertion could result in the generation of a PS beta G species of 419 amino acid residues instead of the 417 amino acid residues predicted by the sequence of clone PSG16. The calculated molecular masses of the two polypeptides encoded by PSG16 and PSG93 are 46.9 and 47.2 kDa, close to the size of the major nonglycosylated PS beta G of 48 kDa. The identity of proteins coded for by these cDNA clones was confirmed by comparing the predicted amino acid sequences to sequences determined from endoproteinase Lys-C peptides obtained from human placental PS beta G. Two placental PS beta G mRNAs of 2200 bases (major) and 1700 bases (minor) have been detected by Northern hybridization analysis. Primer extension and S1 nuclease mapping experiments demonstrated that PS beta G mRNAs have heterogeneous 5' termini.     

Effects of sodium butyrate on the synthesis of human pregnancy-specific beta 1-glycoprotein

Human pregnancy-specific beta 1-glycoprotein (PS beta G) is a polymorphic placental protein which shows strong sequence similarity with the oncofetal protein, carcinoembryonic antigen. To better understand the role of PS beta G in pregnancy, we examined its synthesis and regulation in placental fibroblasts, which had been shown to express the PS beta G gene. The major placental PS beta G is a 72-kDa glycoprotein, while the major fibroblast PS beta G is a 62-kDa species. Administration of sodium butyrate to these fibroblasts slightly stimulated the synthesis of the 62-kDa species but markedly increased the production of two additional PS beta Gs of 72 and 48 kDa. The similarity between the PS beta Gs synthesized by butyrate-treated fibroblasts and human placenta was confirmed by cell-free protein synthesis. Poly(A)+ RNA from butyrate-treated fibroblasts and placenta directed the synthesis of two polypeptides of 48 and 36 kDa, which form the polypeptide backbone of the 72- and 48-kDa glycoproteins. Moreover, the predicted molecular weights of PS beta Gs encoded by the two types of PS beta G cDNA clones were 48,000 and 36,000. Most PS beta G cDNAs identified to date, including the three cDNAs (PSG16, PSG93, and PSG95) isolated in this laboratory, share strong sequence similarity at the 5' region (designated PSG-5') but differ in sequences at their 3' regions. The PSG-5', PSG93-specific, PSG16/PSG93-3', and PSG95-3' probes, which identify the majority of PS beta G mRNAs, hybridized with three PS beta G mRNAs of 2.3, 2.2, and 1.7 kilobases from placental fibroblasts. Butyrate increased the steady-state levels of all three mRNAs. Ribonuclease protection analysis showed that butyrate increased the PS beta G mRNAs containing the PSG-5' or PSG93-specific sequence to approximately 20% of human placental levels. However, unlike human term placenta, which predominantly expressed PS beta G mRNAs with 3'-sequences similar to PSG16/PSG93, the butyrate-treated fibroblasts expressed roughly equal levels of PS beta G mRNAs with the PSG16/PSG93-3' and PSG95-3' ends. All PS beta G cDNAs identified encode proteins with distinct carboxyl termini, suggesting that the composition of the 72-kDa species in placenta and butyrate-treated fibroblasts is likely to be different. Placental fibroblasts provide a unique model for the study of the mechanisms responsible for the differential expression of the PS beta G gene.     

Structure, sequence, chromosomal location, and evolution of the human ferredoxin gene family

Ferredoxin is an iron-sulfur protein that serves as an electron transport intermediate for mitochondrial cytochromes P450 involved in steroid, vitamin D, and bile acid metabolism. We cloned and characterized the human ferredoxin gene family, which includes two expressed genes and two pseudogenes. Sequence analysis of this gene family revealed that it encodes only one protein product. The expressed genes were assigned to chromosome 11 and pseudogenes to chromosomes 20 and 21 by identifying single-copy probes from each gene segment and hybridizing them to DNA from rodent-human hybrid cells. The pseudogenes lacked introns and contained numerous mutations, including insertion, deletion, and substitution which rendered them inactive. They were 96% and 85% homologous to the expressed gene, yet they were only 78% homologous with each other. The intronless nature, higher diversity among themselves, and distinct chromosomal location of the pseudogenes suggests that they arose by independent, retroposon-mediated events.     

A pregnancy-specific beta 1-glycoprotein, a CEA gene family member, expressed in a human promyelocytic leukemia cell line, HL-60: structures of protein, mRNA and gene

Both genomic and cDNA clones encoding a precursor for a pregnancy-specific beta 1-glycoprotein (PS beta G) belonging to the CEA family, expressed in a human promyelocytic leukemia cell line, HL-60, have been isolated and the entire primary structure of the precursor is deduced. The 335-AA precursor has a 34-AA signal peptide followed by domains of N, IIA, IIB and C, which are encoded by separate exons. The genomic sequence contains extra exons IA and IB between exons N and IIA. Apparently, exon IA is excluded from the mRNA by alternative splicing while IB is a pseudo-exon having a stop codon formed by a deletion of dinucleotide in the middle of the sequence. This provides another mechanism to render exon IB abortive and is different from that we reported for another PS beta G (Biochem. Biophys. Res. Comm. (1988) 156, 68-77).     

Structure and chromosomal localization of the human thrombospondin gene

Thrombospondin (THBS1) is a large modular glycoprotein component of the extracellular matrix and contains a variety of distinct domains, including three repeating subunits (types I, II, and III) that share homology to an assortment of other proteins. Determination of THBS1 gene structure has revealed that the type I repeat modules are encoded by symmetrical exons and that the heparin-binding domain is encoded by a single exon. To further elucidate the higher level organization of THBS1, the gene was localized to the q11-qter region of chromosome 15.     

Effect of pregnancy-specific beta 1-glycoprotein on the development of preimplantation embryo

The objective of this study is to test the hypothesis that members of the pregnancy-specific beta 1-glycoprotein (PSG) family enhance the growth and maturation of embryos. cDNA encoding two members of the PSG family, namely PSG1 and PSG3, were expressed in Chinese Hamster Ovary (CHO) cells with the expression vector pH beta APr-1-neo. Two-cell stage mouse embryos were co-cultured in a two-chamber system with CHO cells expressing either recombinant PSG1 (rPSG1) or PSG3 (rPSG3) in the presence and absence of neutralizing PSG antibodies. The cleavage and maturation stage of the embryos was assessed at 12-hr intervals. Mouse embryos co-cultured with transfectants expressing rPSG1 showed a significant enhancement of cleavage and maturation rate compared to controls with P < 0.005-0.004. In co-cultures with CHO cells expressing rPSG3, no significant difference from the controls was observed in the early stage of development until late blastocyst formation. At that stage, there was a statistically significant enhancement of development by rPSG3 when compared to controls with P < 0.001. These results suggest that PSG1 and PSG3 exhibit embryotropic activity at different stages of development in the mouse model.     

Genomic organization and chromosomal localization of the human casein gene family

Five yeast artificial chromosome (YAC) clones containing the human casein gene family were isolated and characterized to study the control mechanisms for the expression of these genes. Partial restriction analysis in conjunction with the chromosomal fragmentation method and fluorescence in situ hybridization (FISH) analysis were performed to construct a detailed physical map of the casein gene family and to determine the chromosomal localization of these genes. The isolated YAC clones 748F3, 750D11, 882G11, 886B3 and 960D2 were 1.2 Mb, 860 kb, 800 kb 1.5 Mb and 1.5 Mb in size, respectively. The clones 748F3, 882G11, 886B3 and 960D2 contained the entire casein gene family, while the κ-casein gene was absent in 750D11. The human αS1-, β- and κ-casein genes were found to be closely linked and arranged in the order αS1-β-κ. The distance between αS1 and β, and between αS1 and κ was approximately 10 and 300 kb, respectively. The β-casein gene was oriented in the opposite direction to the αS1- and κ-casein genes. The casein gene family was localized to chromosome 4q21.1 by FISH analysis. Received: 7 July 1996 / Revised: 29 October 1996     

Structure and evolution of the human prosaposin chromosomal gene.

The gene for prosaposin was characterized by sequence analysis of chromosomal DNA to gain insight into the evolution of this locus that encodes four highly conserved sphingolipid activator proteins or saposins. The 13 exons ranged in size from 57 to 1200 bp, while the introns were from 91 to 3812 bp in length. The regions encoding saposins A, B, and D each had three exons, while that for saposin C had only two. This sequence included the regions that encode the carboxy terminus of the signal peptide, the four mature prosaposin proteins, and the 3' untranslated region. Primer extension studies indicated that over 99% of the coding sequence was contained in these 19,985 bp. Use of PCR and reverse PCR techniques indicated that the most 5' coding approximately 140 bp contained large introns and at least two small exons. Analyses of the intronic positions in the saposin regions indicated that this gene evolved from an ancestral gene by two duplication events and at least one gene rearrangement involving a double crossover after introns had been inserted into the gene.     

Molecular cloning of a cDNA for human pregnancy-specific beta 1-glycoprotein:homology with human carcinoembryonic antigen and related proteins

Human pregnancy-specific beta 1-glycoprotein (SP1) plays an essential role in normal pregnancy. It is also a well-characterized oncodevelopmental antigen, expressed aberrantly by all trophoblastic tumors and some other malignant cell types. Here we report the identification of a human placental cDNA encoding the SP1 polypeptide sequence. The coding sequence shows 95% identity at the nucleotide level with a distinct, recently published SP1 cDNA sequence (PSG16). Unexpectedly, the sequence is also highly homologous to the published sequence of human carcinoembryonic antigen (CEA). SP1, CEA and CEA-related nonspecific cross-reacting species thus belong to a group of closely related though antigenically diverse tumor-associated glycoproteins. Comparison of the deduced amino acid sequence of the SP1 cDNA with that of CEA provides insight into the modular nature of these related proteins. This may have implications for the genomic organization and evolution of the CEA gene family.     

Exon-intron organization of a gene for pregnancy-specific beta 1-glycoprotein, a subfamily member of CEA family: implications for its characteristic repetitive domains and C-terminal sequences

A fragment of human gene for pregnancy-specific beta 1-glycoprotein(s), recently identified CEA family member(s), has been cloned. Analyses of nucleotide and deduced amino acid sequences revealed that it carried, from 5' to 3' direction, exons IA, IB, IIA, IIB, C3, C1 and C2, the first four encoding peptides distinct from but highly similar to domains of PS beta Gs. The lack of consensus 3' splice site sequence ahead of IB indicated that it was an abortive exon, which would explain the peculiar domain construction of PS beta Gs, i.e. N-IA-IIA-IIB-C1, 2 or 3. Apparently, the multiple C-terminal sequences for a PS beta G were generated by alternative splicing among C1, C2 and C3 exons. Furthermore, sequences which overlapped partly with Cexons, were found to be similar to parts of 3'-UTR of CEA and NCA, indicating further the close relationship of CEA/NCA and PS beta G subfamily genes.     

Structure, expression and chromosomal localization of human p80-coilin gene.

Coiled bodies (CBs) are non-capsular nuclear bodies with a diameter of 0.3-1 micron and appear to be composed of coiled fibrils. Human autoantibodies to CBs recognize an 80-kD nuclear protein highly enriched in CBs, and this protein has been named p80-coilin. CBs are known to assemble and disassemble during the cell cycle, with the highest number of CBs occurring at mid to late G1 where p80-coilin is assembled into several small nuclear body-like structures. In S and G2 phases, CBs become larger and their number decreases and often they are undetectable during mitosis. Using a human autoantibody as a probe for expression cloning, we initially isolated a partial cDNA encoding p80-coilin. In this report, the 5' end of the complete cDNA for p80-coilin was obtained using the 5'-RACE (rapid amplification of cDNA ends) methodology. The size of the reconstructed full-length cDNA corresponds to the 2.7-kb mRNA detected in Northern blot analysis. The complete p80-coilin protein consists of 576 amino acids with a predicted molecular mass of 62,608. A putative p80-coilin pseudogene was also detected during the rescreening of p80-coilin cDNA. To confirm the validity of the cDNA sequence, three overlapping genomic DNA clones representing the human p80-coilin gene were selected for further analysis. The complete gene for p80-coilin contains 7 exons spanning approximately 25kb. Sequence analysis of exons 1 and 2 in genomic DNA clones confirmed the accuracy of the 5' cDNA sequence derived from the 5'-RACE procedure. Furthermore, the human p80-coilin gene was localized to chromosome 17q22-23 by fluorescence in situ hybridization.     

Structure and chromosomal localization of the human glycogenin-2 gene GYG2

Glycogenin-2 is one of two self-glucosylating proteins involved in the initiation phase of the synthesis of the storage polysaccharide glycogen. Cloning of the human glycogenin-2 gene, GYG2, has revealed the presence of 11 exons and a gene of more than 46 kb in size. The structure of the gene explains much of the observed diversity in glycogenin-2 cDNA sequences as being due to alternate exon usage. In some cases, there is variation in the splice junctions used. Over regions of protein sequence similarity, the GYG2 gene structure is similar to that of the other glycogenin gene, GYG. A genomic GYG2 clone was used to localize the gene to Xp22.3 by fluorescence in-situ hybridization. Localization close to the telomere of the short arm of the X chromosome is consistent with mapping information obtained from glycogenin-2 STS sequences. Glycogenin-2 maps between the microsatellite anchor markers AFM319te9 (DXS7100) and AFM205tf2 (DXS1060), and its 3' end is 34.5 kb from the 3' end of the arylsulphatase gene ARSD. GYG2 is outside the pseudoautosomal region PAR1 but still in a region of X-Y shared genes. As is true for several other genes in this location, an inactive remnant of GYG2, consisting of exons 1-3, may be present on the Y chromosome.     

Structure, chromosomal localization and evolutionary conservation of the gene encoding human U1 snRNP-specific A protein.

Three specific proteins, called A, 70K and C, are present in the U1 small nuclear ribonucleoprotein (snRNP) particle, in addition to the common proteins. The human U1 snRNP-specific A protein is, apart from a proline-rich region, highly similar to the U2 snRNP-specific protein B". To examine the homologous regions at the genomic level, we isolated and characterized the human U1-A gene. The human U1-A protein appears to be encoded by a single-copy gene and its locus has been mapped to the q arm of chromosome 19. The gene, about 14-16 kb in length, consists of six exons. The regions homologous to the U2-B" gene are not limited to single exons and are mostly not confined by exon-exon junctions in the corresponding U1-A mRNA. However, the proline-rich region of U1-A, absent in U2-B", is encoded by a single exon, suggesting a specific function for this domain of U1-A. The region of the cap site and upstream sequences contain interesting similarities to the promoter region of other snRNP protein-encoding genes and several housekeeping genes, in particular the vertebrate ribosomal protein-encoding genes. Hybridization experiments with various vertebrate genomic DNAs revealed that U1-A sequences are evolutionarily conserved in all tested vertebrate genomes, except for chicken, duck and pigeon. The divergence of these avian genomes is probably typical for the class of birds.