Different combinations of regulatory elements may explain why placenta-specific expression of the glycoprotein hormone alpha-subunit gene occurs only in primates and horses.

Expression of the glycoprotein hormone alpha-subunit gene occurs in the pituitary of all mammals but in placenta of only primates and horses. In humans, two different elements, termed upstream regulatory element (URE) and cAMP response element (CRE), are required for placenta-specific expression of the alpha-subunit gene. The URE binds a protein unique to placenta whereas the CRE binds a ubiquitous protein. Comparative analysis of the promoter-regulatory region of the alpha-subunit gene from a number of mammals indicates that a functional URE has been retained and suggests the potential for placenta-specific expression. Indirect evidence also indicates that the URE-binding protein has been conserved, even in placenta from mammals that fail to express the alpha-subunit gene. Lack of expression of the alpha-subunit gene in placenta of rodents and cattle can be traced to a single nucleotide change that renders the CRE-like sequence of these genes incapable of binding the protein that confers responsiveness to cAMP. In contrast, although expression of the alpha-subunit gene occurs in horse placenta, the promoter-regulatory region lacks a functional CRE but appears to retain a functional URE. This suggests that either a different accessory element and cognate protein interacts with the horse URE to provide placenta-specific expression or that a completely different set of regulatory elements is required for placenta-specific expression in horses.     

Different combinations of regulatory elements may account for expression of the glycoprotein hormone alpha-subunit gene in primate and horse placenta.

Expression of the glycoprotein hormone alpha-subunit gene occurs in the pituitaries of all mammals and in the placentas of primates and horses. In humans, tandem cAMP response elements (CREs), located in the proximal promoter-regulatory region of the alpha-subunit gene, act together with an adjacent upstream regulatory element to confer placenta-specific expression. Here, we report that the alpha-subunit genes of Old World Monkeys contain a single functional CRE. This suggests that tandem CREs are unique to higher primates and humans and are not absolutely required for placenta-specific expression. In contrast, the comparable promoter-regulatory region of the horse alpha-subunit gene lacks a functional CRE but appears to retain a functional upstream regulatory element. This suggests that acquisition of placenta-specific expression of the alpha-subunit gene occurred independently in these distantly related mammals. As a result, different combinations of cis-acting elements may explain why expression of the alpha-subunit gene only occurs in placenta of primates and horses.     

Expression and regulation of the pituitary- and placenta-specific human glycoprotein hormone alpha-subunit gene is restricted to the pituitary in transgenic mice.

Expression of the glycoprotein hormone alpha subunit occurs in both the pituitary and placenta in humans. However, this study found that expression of this subunit is restricted to the pituitary in mice. An interspecies analysis of human alpha-subunit gene regulation was undertaken, using the transgenic-mouse approach. In mice transgenic for a genomic clone containing the complete human alpha-subunit gene and several kilobases of 5'- and 3'-flanking sequences, cell-type-specific expression and hormonal regulation of the human alpha-subunit transgene occurred in the mouse pituitary, whereas no expression of the transgene was detectable in the mouse placenta. These findings provide strong evidence that a common trans-acting factor(s) regulates glycoprotein hormone alpha-subunit gene expression in the human and mouse pituitaries; however, this factor(s) or a unique factor(s), though functional in the human placenta, is either nonfunctional or absent in the mouse placenta.     

Complementation of placental defects and embryonic lethality by trophoblast-specific lentiviral gene transfer

Placental dysfunction underlies many complications during pregnancy, and better understanding of gene function during placentation could have considerable clinical relevance. However, the lack of a facile method for placenta-specific gene manipulation has hampered investigation of placental organogenesis and the treatment of placental dysfunction. We showed previously that transduction of fertilized mouse eggs with lentiviral vectors leads to transgene expression in both the fetus and the placenta. Here we report placenta-specific gene incorporation by lentiviral transduction of mouse blastocysts after removal of the zona pellucida. All of the placentas analyzed, but none of the fetuses, were transgenic. Application of this method substantially rescued mice deficient in Ets2, Mapk14 (also known as p38alpha) and Mapk1 (also known as Erk2) from embryonic lethality caused by placental defects. Ectopic expression of Mapk11 also complemented Mapk14 deficiency during placentation.     

Expression of Cre recombinase in early diploid trophoblast cells of the mouse placenta

An increasing number of genes known to be critical for cell cycle control, differentiation, and tumor suppression have been found to impact development of the placenta. To elucidate how these genes contribute to development of embryonic and extra-embryonic lineages, we generated a transgenic mouse in which the Cre transgene is driven by placenta-specific regulatory sequences from the human CYP19 gene. Using ROSA26 conditional reporter mice, we could detect expression of the CYP19-Cre transgene throughout the extra-embryonic ectoderm and in the ectoplacental cone at embryonic day 6.5 (E6.5). By E11.5, recombination of LoxP reporter sites was detected in all derivatives of trophoblast stem cells, including spongiotrophoblast, giant cells, and labyrinth trophoblasts. We conclude that the CYP19-Cre transgenic mouse developed here can be used in combination with conditional alleles to distinguish between embryonic and extra-embryonic gene function, and to begin to map the period of time when gene function is critical during development.     

The human growth hormone gene cluster locus control region supports position-independent pituitary- and placenta-specific expression in the transgenic mouse

The human growth hormone (hGH) cluster contains five genes. The hGH-N gene is predominantly expressed in pituitary somatotropes, whereas the remaining four genes, the chorionic somatomammotropin genes (hCS-L, hCS-A, and hCS-B) and hGH-V, are expressed selectively in the placenta. In contrast, the mouse genome contains a single pituitary-specific GH gene and lacks any GH-related CS genes. Activation of the hGH transgene in the mouse is dependent on its linkage to a previously described locus control region (LCR) located -15 to -32 kilobases upstream of the hGH cluster. The sporadic, nonreproducible expression of hCS transgenes lacking the LCR suggests that they may be dependent on hGH LCR activity as well. To determine whether the hCS genes could be expressed with appropriate placental specificity, a series of five transgenic mouse lines carrying an 87-kilobase human genomic insert encompassing the majority of the hGH gene cluster and the entire contiguous LCR was established. All of the hGH cluster genes were appropriately expressed in each of these lines. High level expression of hGH was restricted to the pituitary and hCS to the labyrinthine layer of the placenta. The expression of the GH cluster genes in their respective tissues paralleled transgene copy numbers irrespective of the transgene insertion site in the host mouse genome. These studies have extended the utility of the transgenic mouse model for the analysis of the full spectrum of hGH gene cluster activation. Further, they support a role for the hGH LCR in placental hCS, as well as pituitary hGH gene activation, and expression.     

Evolution of placenta-specific gene expression: comparison of the equine and human gonadotropin alpha-subunit genes.

Primate and equine species are thought to be unique among mammals in synthesizing placental gonadotropin glycoprotein hormones. Human chorionic gonadotropin (CG) and equine pregnant mare's serum gonadotropin (PMSG) are produced in placenta by the specific activation of a glycoprotein hormone alpha-subunit gene and a corresponding beta-subunit gene. The evolutionary mechanisms for the apparently independent acquisition of tissue specificity were investigated by cloning the 5' flanking region of the equine alpha-subunit gene and comparing the DNA elements and trans-acting factors involved in placental expression. We find that though the equine gene is expressed and induced by cAMP, it does not contain the elements known to confer tissue-specific expression to the human gene, the cAMP response element (CRE) and the trophoblast-specific element (TSE), nor does it bind to the trans-acting factors CREB and TSEB. Instead, an additional factor (alpha-ACT) is found which binds to the equine and human, but not the murine, alpha-subunit genes in a region between the positions of the CRE and TSE and confers cAMP responsiveness.     

Expression and cAMP-mediated regulation of the human gonadotropin alpha subunit gene in transfected mouse L-cells

Expression of the dimeric glycoprotein hormone, human chorionic gonadotropin (HCG), occurs either eutopically in placental trophoblast cells and trophoblastic tumor cells (choriocarcinoma) or ectopically in nontrophoblastic tumor cells. However, regulation of constitutive HCG-subunit mRNA production appears to differ in trophoblastic and nontrophoblastic cells, as evidenced by the fact that cAMP analogs and agonists enhance eutopic but not ectopic HCG-subunit mRNA synthesis. In the present study, we compared the effects of cAMP on HCG alpha-subunit expression in human choriocarcinoma cells and in nontrophoblastic mouse L-cells stably transfected with the HCG alpha-subunit gene. Constitutive levels of alpha-subunit expression in transfected mouse L-cells were equivalent to or exceeded those found in choriocarcinoma cells as determined by Northern blot analysis and indirect immunofluorescence for alpha-subunit protein. However, cAMP-mediated induction of alpha-subunit gene expression was retained in nontrophoblastic L-cells and closely paralleled that observed in human choriocarcinoma cells. These findings indicate that cells distinctly nontrophoblastic in origin may share the necessary cellular factors for cAMP-mediated induction of alpha-subunit gene expression. Failure of ectopic HCG-producing tumor cells to be stimulated by cAMP may thus be the result of deletion or mutation of such factors.     

Cytological distribution of chorionic gonadotropin subunit and placental lactogen messenger RNA in neoplasms derived from human placenta

Normal trophoblast of the human placenta elaborates at least two major protein hormones, chorionic gonadotropin (hCG), and placental lactogen (hPL). There are several gestational trophoblastic diseases of the placenta called hydatidiform mole, invasive mole, and choriocarcinoma. Molar and choriocarcinoma tissues characteristically synthesize large amounts of hCG and small quantities of hPL. To examine the role of trophoblast differentiation in the expression of the hCG and hPL genes, we studied the cytological distribution of their messenger RNA (mRNA) in tissue sections of human hydatidiform mole and choriocarcinoma by in situ hybridization. Histologically, these tissues are in different stages of cellular differentiation. In normal placenta, hCG alpha and - beta mRNA can be localized to some cytotrophoblasts and primarily to the syncytium, whereas hPL mRNA appears only in the syncytial layer. In hydatidiform mole, which still retains placental villous morphology, the hPL gene and hCG alpha and -beta genes are expressed but are poorly localized because of the admixture of cyto- and syncytiotrophoblasts. By contrast, choriocarcinoma, which is devoid of placental villous pattern but in which the cyto- and syncytiotrophoblast-like components are distinguishable, expresses hCG alpha and -beta in the syncytial- like areas but little, if any, hPL. These results suggest that a certain level of trophoblast differentiation, such as villous formation, is associated with hPL expression, while the hCG alpha gene and the hCG beta gene can be expressed in more disorganized tissues that contain cytotrophoblastic elements.