Haptoglobin gene expression in human glioblastoma cell lines.

Increases in cerebrospinal fluid (CSF) levels of the acute phase protein haptoglobin (Hp) occur in central nervous system (CNS) disorders such as Alzheimer's disease. To establish if Hp CSF level increases can be associated with Hp expression in brain, reverse transcription-polymerase chain reaction (RT-PCR) experiments were conducted to determine if the Hp mRNA transcript is expressed in human glioblastoma cells. Furthermore, Western blots and immunoprecipitations were performed to elucidate if Hp protein is synthesized and secreted by human glioblastoma cells. The Hp mRNA (alpha2beta) transcript (1155 bp) was detected both in U-87MG and U-138MG cells, and was positively verified by nested PCR in which a part of the beta sequence (482 bp) was targeted for amplification. Despite the presence of Hp mRNA, Hp protein was not secreted by U-87MG cells as compared to the hepatoma cell line, HepG2, where Hp protein (approximately 46 kDa) was detected in the media. The results suggest the expression of Hp protein by glioblastoma cells is possible since the Hp mRNA transcript exist, but whether or not Hp mRNA is contained in a storage pool requiring a specific signal for translation or is transiently expressed remains to be uncovered in future studies.

Iron regulation of transferrin synthesis in the human hepatoma cell line HepG2.

In human beings, serum transferrin levels increase during iron deficiency and decrease with iron overload. Yet, whether or not iron levels actually affect the synthesis of transferrin in human liver cells is not known. In previous studies, iron was shown to suppress the expression of chimeric human transferrin genes in livers of transgenic mice. The goal of this study was to determine if iron suppresses intact endogenous human transferrin synthesis by testing the effects of changes in iron levels on synthesis of transferrin in a human hepatoma cell line HepG2. In HepG2 cells, normalized(35)S-metabolically labeled transferrin synthesis was consistently less following iron treatment with hemin or ferric citrate, than following treatment with an iron-chelator deferroxamine. Thus, this study provides new evidence that iron can regulate synthesis of intact endogenous human transferrin.

A gene-specific promoter in transgenic mice directs testis-specific demethylation prior to transcriptional activation In vivo.

Transcription of the autosomal phosphoglycerate kinase gene, Pgk-2, is initiated at the onset of meiosis during spermatogenesis in mammals. However, in the mouse, the 5' portion of the endogenous Pgk-2 coding sequence undergoes a specific demethylation event that precedes transcriptional activation by 10-12 days. Here we show that transgenes consisting of the Pgk-2 core promoter ligated to the CAT reporter gene undergo a similar tissue-, stage-, and cell type-specific demethylation in the 5' portion of the CAT coding sequence, whereas transgenes consisting of the CAT reporter sequence alone, or of the CAT sequence ligated to the CpG island-containing transferrin gene promoter, demonstrate different patterns of demethylation. These results indicate that specific promoter sequences can influence the pattern of tissue-specific demethylation within different genes and that a signal for spermatogenic cell-specific demethylation resides within the core promoter of the mammalian Pgk-2 gene.

A comparison of the suppression of human transferrin synthesis by lead and lipopolysaccharide.

Transferrin, as the major iron-transport protein in serum and other body fluids, has a central role in managing iron the body receives. Liver is a major site of transferrin synthesis, and in this study we present evidence that liver synthesis of human transferrin is suppressed by both the toxic metal lead and bacterial lipopolysaccharide, an inducer of the hepatic acute phase response. The responses of intact endogenous transferrin in the human hepatoma cell line HepG2 and chimeric human transferrin-chloramphenicol acetyltransferase genes in transgenic mice were examined. In HepG2 cells, 35S-transferrin protein synthesis and mRNA levels were suppressed by 100 microM and 10 microM lead acetate as early as 24 h after the initial treatment. Yet, synthesis of two proteins known to respond in the hepatic acute phase reaction, complement C3 and albumin, was not altered by the lead treatment. In transgenic mouse liver, lead suppressed expression of chimeric human transferrin genes at both the protein and mRNA levels, but LPS only suppressed at the protein level. The study indicates that lead suppresses human transferrin synthesis by a mechanism that differs from the hepatic acute phase response and that lead may also affect iron metabolism in humans by interfering with transferrin levels.

Human APOE protein localized in brains of transgenic mice.

Transgenic mice carrying the three common human apolipoprotein E (APOE) alleles have been developed. In this study, brains of the transgenic mice have been analyzed by in situ histohybridization, immunohistochemistry, and immunoblots to determine sites of gene expression, to identify specific brain cells associated with human apoE protein, and to determine the relative concentrations of the human apoE. Results indicate that (1) human APOE mRNA and apoE protein occur in the gray and white matter of transgenic mouse brains; (2) in the hippocampus of transgenic brains, human apoE protein reacts immunologically within the same cells as the glial fibrillary acidic protein (GFAP), a specific marker for astrocytes; and (3) concentrations of the apoE isoforms determined in three heterozygous transgenic brains range from 22 to 250 pmol/g wet weight of brain.

YY1 and Sp1 transcription factors bind the human transferrin gene in an age-related manner.

The iron-binding protein transferrin has major roles in transporting, delivering, and sequestering ferric ions acquired by body tissues. Yet, during aging, serum transferrin levels decrease in humans. Likewise, in transgenic mice carrying chimeric human transferrin transgenes, liver expression of transferrin transgenes decreases with age. The aging regulation is due to decreased gene transcription. Electrophoretic mobility shift assays and antibody-recognition have revealed the binding of 5' regulatory elements of the human transferrin gene by three YY1 proteins, called YY1, YY1-a, and YY1-b, and an Sp1-a transcription factor. An age-related increase in YY1-a and YY1-b binding activities and a decrease in Sp1-like binding activity were shown. Since Sp1 is a positive transcription factor and YY1 can be a negative transcription factor, the alterations in their binding with age could cause the decreased transcription of the human transferrin transgene, and also the age-related decreased serum transferrin levels in humans.

Discovery of a brain promoter from the human transferrin gene and its utilization for development of transgenic mice that express human apolipoprotein E alleles.

Transgenic mice carrying heterologous genes directed by a 670-bp segment of the regulatory sequence from the human transferrin (TF) gene demonstrated high expression in brain. Mice carrying the chimeric 0.67kbTF-CAT gene expressed TF-CAT in neurons and glial cells of the nucleus basalis, the cerebrum, corpus callosum, cerebellum, and hippocampus. In brains from two independent TF-CAT transgenic founder lines, copy number of TF-CAT mRNA exceeded the number of mRNA transcripts encoding either mouse endogenous transferrin or mouse endogenous amyloid precursor protein. In two transgenic founder lines, the chloramphenicol acetyltransferase (CAT) protein synthesized from the TF-CAT mRNA was estimated to be 0.10-0.15% of the total soluble proteins of the brain. High expression observed in brain indicates that the 0.67kbTF promoter is a promising director of brain expression of heterologous genes. Therefore, the promoter has been used to express the three common human apolipoprotein E (apoE) alleles in transgenic mouse brains. The apoE alleles have been implicated in the expression of Alzheimer disease, and the human apoE isoforms are reported to interact with different affinities to the brain beta-amyloid and tau protein in vitro. Results of this study demonstrate high expression and production of human apoE proteins in transgenic mouse brains. The model may be used to characterize the interaction of human apoE isoforms with other brain proteins and provide information helpful in designing therapeutic strategies for Alzheimer disease.

The 5'-untranslated region of human transferrin mRNA, which contains a putative iron-regulatory element, is bound by purified iron-regulatory protein in a sequence-specific manner.

Human transferrin mRNA contains a 5'-untranslated region that (1) has homology to an iron responsive element and (2) is implicated in translational iron regulation of human transferrin transgenes in transgenic mice. Ferritin mRNA contains a 5'-untranslated region iron-responsive element, but iron regulation of ferritin differs from that of human transferrin transgenes in both magnitude and direction. Structural differences between the ferritin iron-responsive element and the human transferrin putative iron-responsive element may influence their iron-regulatory protein interactions and direct the differing translational responses. This study examines human transferrin RNA nucleotide sequence requirements for binding of cytoplasmic proteins and purified iron-regulatory protein. Mutations of the putative transferrin iron-responsive element similarly affected binding of purified iron-regulatory protein and liver cytoplasmic proteins, providing evidence that the IRP is one of the liver cytoplasmic proteins that binds the human transferrin iron-regulatory element and suggesting that it may be involved in iron-regulation of transferrin.

A human (3.3 kb) haptoglobin-CAT transgene is modulated in lungs of transgenic mice by inflammation.

Four independent lines of transgenic mice were produced carrying integrated copies of a chimeric gene composed of 3.3 kb of the human haptoglobin 5' regulatory region fused to the CAT (chloramphenicol acetyl transferase) reporter gene. Although the endogenous mouse haptoglobin (Hp) and human haptoglobin (HP) genes express mainly in liver and lung, expression of the human 3.3-kb HP-CAT transgene was not detected until after induction of inflammation and then only in lungs. The results indicated that the transgene maintained the regulatory DNA elements required for lung specific responsiveness to inflammation in vivo but lacked the DNA sequence required for robust expression in liver. The DNA sequence(s) responsible for the normally high level of HP expression in liver either reside outside the 3.3-kb regulatory region of the HP chimeric gene or this region contains a suppressor sequence affecting tissue specific expression in the liver.

Brain and liver targeted overexpression of O6-methylguanine DNA methyltransferase in transgenic mice.

O6-Methylguanine DNA methyltransferase (MGMT; EC 2.1.1.63) is an unusual DNA repair protein in that it directly and specifically repairs a premutagenic DNA lesion without involving other proteins. MGMT removes the alkyl group from O6-alkylguanine in DNA in a unique stoichiometric reaction by accepting the alkyl group on a cysteine residue. The intracellular level of MGMT varies among tissues and appears to be inversely correlated to tissue-specific tumorigenesis induced by monofunctional alkylating agents. Because MGMT acts in solo, genetic manipulation of its expression may provide valuable insight into its contribution to cellular resistance to alkylation toxicity and to tumor induction. The human MGMT full length cDNA has been fused with a portion of the human transferrin (TF) 5'-flanking region (TF/MGMT). Transgenic founder mice were produced carrying the TF/MGMT transgene and then bred to establish stable transgenic lines. Human MGMT transcripts were specifically expressed in abundance in transgenic brain and liver tissues. In vitro MGMT assays revealed approximately 150-fold and approximately 25-fold increases in MGMT activity in transgenic brain and liver extracts respectively. Western blot analysis confirmed that human MGMT protein is specifically synthesized in transgenic brain and liver tissues.

Posttranscriptional regulation of chimeric human transferrin genes by iron.

Transferrin, the transferrin receptor, and ferritin are integral to the body's management of iron, an element required for life but highly toxic when present in excess. The transferrin receptor and ferritin are regulated posttranscriptionally by iron: the transferrin receptor by mRNA stability and ferritin by mRNA translation. Results described here indicate that transferrin, like ferritin, is regulated by iron at the level of translation. Chimeric genes introduced into the mouse genome were composed of the human transferrin 5' regulatory region fused to the chloramphenicol acetyl transferase (CAT) reporter gene. Iron administration to transgenic mice resulted in a significant decrease of transferrin-directed CAT enzyme activity and CAT protein in liver, but no significant decrease in human transferrin-CAT mRNA levels. Binding of specific RNA iron regulatory elements by proteins in cytoplasmic extracts have been shown to regulate ferritin and transferrin receptor synthesis. Similar results have been obtained with transferrin mRNA. A decreased binding of human transferrin 5'-untranslated region RNA by factors in cytoplasmic extracts of livers from mice receiving iron was found when compared to extracts from control mice. A human transferrin RNA-protein complex migrated electrophoretically with the same mobility as a ferritin iron responsive element RNA-iron responsive element binding protein complex. The ferritin iron responsive element RNA also competed with the human transferrin 5'-untranslated region RNA-protein complexes formed and vice versa. Therefore, iron modulation of human transferrin may share a factor common or similar to that observed in ferritin and transferrin receptor iron modulation.

Expression of chimeric human transferrin-chloramphenicol acetyltransferase genes in liver and brain of transgenic mice during development.

Transferrin (TF) gene expression is tissue specific and is regulated during development. Transgenic mice have been developed which carry 1.2 or 0.67 kb of the TF 5' flanking region of the human TF gene fused to the bacterial chloramphenicol acetyltransferase (CAT) gene. The onset of expression of the chimeric human TF-CAT transgenes in liver and brain during development has been studied in these transgenic mice. In brain, the TF(0.67)CAT transgene began to express between 5 and 10 days after birth; in liver, the TF(0.67)CAT transgene was turned on between 10 and 20 days after birth. Endogenous mouse TF mRNA levels in liver and brain have also been measured during development by Northern analysis. In brain, the developmental expression pattern of the TF(0.67)CAT transgene is the same as the mouse endogenous TF gene; in liver, the transgene is turned on later than the endogenous mouse TF gene. DNA-protein mobility shift assays and DNase I footprinting analyses were conducted in the region of -621 to -409 bp of the human TF gene by using TF-CAT expressing liver nuclear extract from 27-day-old mice and nonexpressing liver nuclear extract from 7-day-old mice. The level of protein-DNA complex formation is several times higher in the expressing extracts, and the region from -481 to -463 bp of human TF gene is protected by the expressing extract but not the nonexpressing extracts. As demonstrated by this and other studies, the transgenic mouse model furnishes a unique opportunity to analyze developmental regulation of human transgenes.

Lead suppresses chimeric human transferrin gene expression in transgenic mouse liver.

The major iron-transport protein in serum is transferrin (TF) which also has the capacity to transport other metals. This report presents evidence that synthesis of human TF can be regulated by the metal lead. Transgenic mice carrying chimeric human TF-chloramphenicol acetyl transferase (CAT) genes received lead or sodium salts by intraperitoneal injections or in drinking water. Transgene expression in liver was suppressed 31 to 50% by the lead treatment. Lead regulates human TF transgenes at the mRNA level since liver CAT enzyme activity, CAT protein, and TF-CAT mRNA levels were all suppressed. The dosages of lead did not alter synthesis of the other liver proteins, mouse TF and albumin, as measured by Northern blot analysis of total liver RNA and rocket immunoelectrophoresis of mouse sera. Moderate levels of lead exposure were sufficient to evoke the human TF transgene response; blood lead levels in mice that received lead acetate in drinking water ranged from 30 micrograms/dl to 56 micrograms/dl. In addition to suppressing expression of TF-CAT genes in transgenic mice, lead also suppressed synthesis of TF protein in cultured human hepatoma HepG2 cells. The regulation of human TF apparently differs from the regulation of mouse TF which is unresponsive to lead exposure.

The expression of transferrin mRNA in the salivary glands and other tissues of baboons.

In order to determine whether all the extrinsic salivary glands synthesize transferrin mRNA, the polyadenylated ribonucleic acids [poly(A)+ RNAs] from parotid, submandibular, and sublingual glands, liver, midbrain, testis, spleen, heart, kidney, and the mucosae of oesophagus and stomach from adult male baboons were analysed, using oligo(dT)-cellulose chromatography, agarose gel electrophoresis, followed by transfer of the mRNAs to nitrocellulose filters and identification with transferrin and tubulin cDNA probes. Transferrin and tubulin mRNAs were visualized by autoradiography and analysed by measuring specific activity from beta emitting nuclides following transfer to nitrocellulose filters and hybridizing with [alpha-32P]-labelled human transferrin and tubulin cDNA probes. The results indicate that transferrin mRNA is present in all the extrinsic salivary glands (submandibular, sublingual, parotid) of baboons.

Expression of a human chimeric transferrin gene in senescent transgenic mice reflects the decrease of transferrin levels in aging humans.

Transgenic mice provide a means to study human gene expression in vivo throughout the aging process. A DNA sequence containing 668 bp of the 5' regulatory region of the human transferrin gene was fused to the bacterial reporter gene chloramphenicol acetyl transferase (TF-CAT) and introduced into the mouse genome. Expression of the human chimeric transferrin gene was similar to the tissue patterns of mouse and human transferrin. In aging transgenic mice, expression of the human chimeric transferrin gene was found to diminish 40% in livers between 18 and 26 months of age. Transferrin levels and serum iron levels in aging humans also diminish, as observed from measurements of total iron binding capacity and percent iron saturation in sera from 701 individuals ranging from 0 to 99 years of age. In contrast, in transgenic mice and nontransgenic mice, the mouse endogenous plasma transferrin and endogenous Tf mRNA increase significantly during aging. Neither the decrease of human TF-CAT nor the increase of mouse transferrin during aging appears to be part of a typical inflammatory reaction. Although the 5' regions of the human transferrin and mouse transferrin genes are homologous, sequence diversities exist which could account for the different responses to inflammation and aging observed.

Expression of chimeric human transferrin genes in vitro.

Transferrin (TF), a major plasma protein, binds and transports ferric iron. Evidence exists for unique roles for TF in brain in oligodendrocyte differentiation, myelination and neuronal development. In this study, 5' flanking regions of the TF gene important in regulating gene expression were identified by transfected cell studies and a comparison of 5' flanking sequences of the human TF and TF receptor genes. Human glioma cell lines HTB-16 and HTB-17 were shown to synthesize TF identical in size and immunological reaction to TF synthesized by liver. The expression of a series of human chimeric TF genes in glioma cells was compared with hepatoma and HeLa cells. A difference in transient expression was observed in hepatoma and glioma cells transfected with TF chimeric genes containing 3.9 kb of the 5' region; hepatoma cells demonstrated significantly more expression than did glioma cells, suggesting that a DNA region present in the 3.9-kb construct is important either in liver-specific expression or in repression of brain expression, or in both. Smaller constructs containing less than or equal to 0.622 kb of the 5' regulatory region of the TF gene failed to demonstrate cell-specific expression; they were expressed in HeLa cells, a line that does not synthesize TF. High levels of expression of 0.15-kb TF constructs were also observed in hepatoma and glioma cell lines, but not in transgenic mice. Possible explanations of differences observed in expression of shorter TF constructs in vitro and in vivo are discussed.

Human transferrin. Expression and iron modulation of chimeric genes in transgenic mice.

Transferrin (TF) is a plasma protein that transports and is regulated by iron. The aim of this study was to characterize human TF gene sequences that respond in vivo to cellular signals affecting expression in various tissues and to iron administration. Chimeric genes were constructed containing 152, 622, and 1152 base pairs (bp) of the human TF5'-flanking region with the coding region of a reporter gene, CAT (chloramphenicol acetyltransferase), and introduced into the germ line of mice. Transgenes containing TF 5'-flanking sequences to -152 bp were expressed poorly in all tissues examined. In contrast, transgenes containing TF sequences to -622 or -1152 bp were expressed at high levels in brain and liver, greater than or equal to 1000-fold higher than tissues such as heart and testes. Liver and brain are major sites of endogenous TF mRNA synthesis, but liver mRNA levels are 10-fold higher than brain. A significant diminution of CAT enzymatic activity in liver accompanied iron administration in both TF(0.67) and TF(1.2)CAT transgenic mice, mimicking the decrease of transferrin in humans following iron overload. Levels of endogenous plasma transferrin also decreased in iron-treated transgenic mice. Transgenic mouse lines carrying human TF chimeric genes will be useful models for analyzing the regulation of human transferrin by iron and for determining the molecular basis of transferrin regulation throughout mammalian development into the aging process.

Expression of human plasma protein genes in ageing transgenic mice.

Introduction of human plasma protein genes into the mouse genome to produce transgenic mice furnishes an in vivo model for correlating chromosomal DNA sequences with developmental and tissue-specific expression. The liver produces an array of plasma proteins that circulate throughout the body contributing to homeostasis. Non-hepatic tissue sites of synthesis have been identified where a local provision of plasma proteins is needed. Analysis of expression of human plasma protein genes in ageing transgenic mice appears especially promising in identifying DNA sequences that respond to environmental adversities such as inflammatory factors, hormonal changes and metal toxicity. The results indicate that human genes encoding and controlling liver plasma proteins serve as useful models for studying genetic regulation in the background of development and ageing.

Expression of transferrin and vitamin D-binding protein genes in an osteogenic sarcoma cell line.

Expression of genes encoding transferrin and the vitamin D-binding protein is described in a cell line, U-2 OS, derived from a human osteogenic sarcoma. The mRNA transcripts of transferrin and vitamin D-binding protein were shown to be the lengths of those found in normal human liver. The cells synthesize and secrete the transferrin and vitamin D-binding proteins, in addition to human albumin and ceruloplasmin. The U-2 OS cells were successfully transfected with chimeric genes carrying 670 bp of the 5' regulatory sequence of the human transferrin gene fused to a reporter chloramphenicol acetyltransferase gene. These data indicate that the appropriate transcriptional factors required for expression of four plasma proteins are produced by U-2 OS nuclei and that the U-2 OS cell line will be useful for studies analyzing regulation of these genes.