Expression of a human placental alkaline phosphatase gene in transfected cells: use as a reporter for studies of gene expression

Identification of LRF-1, a leucine-zipper protein that is rapidly and highly induced in regenerating liver

Liver regeneration provides one of the few systems for analysis of mitogenesis in the fully developed, intact animal. Several proteins have been identified as part of the primary growth response in regenerating liver and in mitogen-stimulated cells. Some of these proteins, such as the Jun and Fos families of transcription factors, are thought to have a role in activating transcription of genes expressed subsequently in the growth response. Through differential screening of a regenerating-liver cDNA library, we have identified a rapidly and highly induced gene encoding a 21-kDa leucine-zipper-containing protein that we have designated liver regeneration factor 1 (LRF-1). LRF-1 has no homology with other leucine-zipper proteins outside the basic and leucine-zipper domains. LRF-1 alone can bind DNA, but it preferentially forms heteromeric complexes with c-Jun and Jun-B and does not interact with c-Fos. In solution, it binds with highest affinity to cAMP response elements but also has affinity for related sites. In cotransfection studies, LRF-1 in combination with c-Jun strongly activates a c-Jun-responsive promoter. The induction of the LRF-1 gene in regenerating liver greatly increases the potential variety of heterodimeric combinations of leucine-zipper transcription factors. While LRF-1 mRNA is rapidly induced in the absence of protein synthesis, its peak induction is later than c-fos mRNA, suggesting that LRF-1 may regulate responsive genes at a later point in the cell cycle. As such, LRF-1 may have a unique and critical role in growth regulation of regenerating liver and mitogen-stimulated cells.

Alpha B-crystallin is a small heat shock protein

Sequence similarity between alpha B-crystallin and small heat shock proteins (HSPs) has prompted us to investigate whether alpha B-crystallin expression is induced by heat shock. Indeed, accumulation of alpha B-crystallin was detected immunologically in NIH 3T3 cells after incubation at elevated temperatures and after addition of Cd2+ or sodium arsenite to these cells. Two-dimensional gel electrophoresis revealed identity between alpha B-crystallin from eye lenses and from heat-treated fibroblasts. The promoter of the alpha B-crystallin gene was fused to the bacterial chloramphenicol acetyltransferase gene and was shown to confer heat inducibility on this reporter gene in transient transfection assays. A perfect heat shock element within the promoter region is likely to mediate this response. Small HSPs and alpha B-crystallin were shown to share the following two physical properties: (i) they form supramolecular structures with sedimentation values around 17 S and (ii) they are associated with the nucleus at high temperatures and are localized in the cytoplasm under normal conditions. We conclude that alpha B-crystallin has to be considered a member of the class of small HSPs.

Strict distance requirement for transcriptional activation by two regulatory elements of the glucagon gene

The glucagon gene is specifically expressed in A cells of the pancreatic islets. We have previously identified three functional DNA control elements within the 5'-flanking sequence of the glucagon gene: an upstream promoter element (G1), responsible for the A-cell-specific expression, and two enhancer-like elements (G2 and G3). Mutations within G1 completely abolished the enhancer activities of G2 and G3. We show here that the loss of transcriptional activity is not due to an absence of binding of nuclear proteins to G2 or G3, but rather to an essential role of G1 to enable G2 and G3 to exert their effects at a distance. When juxtaposed to the TATA box, both enhancers are capable of inducing transcription as efficiently as when an intact G1 is present. However, the tandem arrangement of G2 plus G3 does not result in additional transcriptional activity compared with a single element. We conclude that G2 and G3 are capable of directly activating transcription but in a highly distance-dependent fashion and without cooperatively interacting. G1 may thus serve only as a tissue-specific relay, bringing together factors that bind to enhancers and the TATA box.

Positive regulation of jun/AP-1 by E1A

Proteins encoded by the adenovirus E1A oncogene are capable of positive and negative transcriptional regulation of both viral and cellular genes. E1A regulatory function is commonly thought to involve modifications of specific cellular factors that interact with responsive promoters. In this report we present evidence that E1A induces the activity of the jun/AP-1 transcription factor in three different cell types: P19, JEG-3, and HeLa. AP-1 binds to 12-O-tetradecanoylphorbol-13-acetate (TPA)-responsive elements (TREs); therefore, E1A might modulate a specific signal transduction pathway normally induced by activation of the protein kinase C. Binding of jun/AP-1 to a TRE is induced in all cell types studied when E1A is expressed. We observe that the expression of endogenous c-jun and jun B genes is induced by E1A, which directly transactivates the promoters of c-fos, c-jun, and jun B. Similar inducibility is obtained by treatment with retinoic acid and differentiation of P19-embryonal carcinoma cells. The E1A 13S product transactivates TRE sequences and cooperates with c-jun in the transcriptional stimulation. The 12S E1A product does not activate a TRE sequence, but cotransfection with c-jun circumvents this lack of stimulation. Coexpression of c-fos and E1A 12S, however, blocks the transactivation by c-jun, suggesting an important role for fos in determining the dominance of the 12S or 13S protein.

Two different mutants blocked in synthesis of dolichol-phosphoryl-mannose do not add glycophospholipid anchors to membrane proteins: quantitative correction of the phenotype of a CHO cell mutant with tunicamycin

The addition of glycophospholipid (GPL) anchors to certain membrane proteins occurs in the rough endoplasmic reticulum and is essential for transport of the proteins to the plasma membrane. Limited circumstantial evidence suggests that dolichol-phosphoryl-mannose (DPM) is a donor of mannose residues of these anchors. We here report studies of a CHO cell mutant (B421) transfected to express the GPL-anchored protein, placental alkaline phosphatase (AP). Only a few transfectants were found to express GPL-anchored AP on their surface, and these clones synthesized DPM. Moreover, and most strikingly, when surface AP-negative transfectants were treated with tunicamycin to cause accumulation of DPM, these cells expressed lipid-anchored AP. Fusion of a cloned surface AP-negative transfectant of B421 with the Thy-1-class E mutant thymoma, which is also deficient in DPM synthesis, produced hybrids that synthesized DPM and expressed AP and Thy-1. Thus, two mutations can interrupt DPM synthesis, and three sets of observations point to an essential role of DPM for addition of GPL anchors.

Tumor-cell lysis by in-situ-activated human peripheral-blood mononuclear cells

A heteroconjugate (HC) was synthesized between OKT3 and monoclonal antibody (MAb) 7E8, which specifically reacts with the tumor marker placental alkaline phosphatase (PLAP). Similarly to OKT3, in vitro, the HC induced a dose-dependent proliferation response of human peripheral-blood mononuclear cells (PBMCs) and, in concert with rIL-2, it progressively activated T cells over a 4-day period. In co-cultures of continuously activated PBMCs and MO4 tumor cells (non-MHC-restricted mouse fibroblasts transfected with the cDNA for PLAP), the HC (25 ng/ml), again acting in concert with rIL-2, induced specific lysis of the MO4 cells. This process occurred progressively over 2 to 3 days and was monitored from the release in the supernatant fluid of cellular 3H-L-leucine, but also from analyses involving the remaining non-lysed cancer cells, i.e., by estimates of their protein content, by measurements of their viability, and most accurately by determinations of their PLAP content. Antibody 7E8 by itself induced a weak tumor-cell lysis (ADCC), potentiated by the addition of rIL-2. However, after 7 days of PBMC-preactivation with the HC and rIL-2, antibody 7E8 no longer mediated any ADCC, whereas the HC-dependent lysis was further potentiated. The observed proliferation of T cells and development of cytotoxicity at low concentrations of HC and rIL-2 support the idea that a moderate but continuous T-cell activation combined with T-cell targeting is sufficient for the induction of progressive and efficient tumor-cell lysis.

Two different mutants blocked in synthesis of dolichol-phosphoryl-mannose do not add glycophospholipid anchors to membrane proteins: quantitative correction of the phenotype of a CHO cell mutant with tunicamycin

The addition of glycophospholipid (GPL) anchors to certain membrane proteins occurs in the rough endoplasmic reticulum and is essential for transport of the proteins to the plasma membrane. Limited circumstantial evidence suggests that dolichol-phosphoryl-mannose (DPM) is a donor of mannose residues of these anchors. We here report studies of a CHO cell mutant (B421) transfected to express the GPL-anchored protein, placental alkaline phosphatase (AP). Only a few transfectants were found to express GPL-anchored AP on their surface, and these clones synthesized DPM. Moreover, and most strikingly, when surface AP-negative transfectants were treated with tunicamycin to cause accumulation of DPM, these cells expressed lipid-anchored AP. Fusion of a cloned surface AP-negative transfectant of B421 with the Thy-1-class E mutant thymoma, which is also deficient in DPM synthesis, produced hybrids that synthesized DPM and expressed AP and Thy-1. Thus, two mutations can interrupt DPM synthesis, and three sets of observations point to an essential role of DPM for addition of GPL anchors.

Positive regulation of jun/AP-1 by E1A

Proteins encoded by the adenovirus E1A oncogene are capable of positive and negative transcriptional regulation of both viral and cellular genes. E1A regulatory function is commonly thought to involve modifications of specific cellular factors that interact with responsive promoters. In this report we present evidence that E1A induces the activity of the jun/AP-1 transcription factor in three different cell types: P19, JEG-3, and HeLa. AP-1 binds to 12-O-tetradecanoylphorbol-13-acetate (TPA)-responsive elements (TREs); therefore, E1A might modulate a specific signal transduction pathway normally induced by activation of the protein kinase C. Binding of jun/AP-1 to a TRE is induced in all cell types studied when E1A is expressed. We observe that the expression of endogenous c-jun and jun B genes is induced by E1A, which directly transactivates the promoters of c-fos, c-jun, and jun B. Similar inducibility is obtained by treatment with retinoic acid and differentiation of P19-embryonal carcinoma cells. The E1A 13S product transactivates TRE sequences and cooperates with c-jun in the transcriptional stimulation. The 12S E1A product does not activate a TRE sequence, but cotransfection with c-jun circumvents this lack of stimulation. Coexpression of c-fos and E1A 12S, however, blocks the transactivation by c-jun, suggesting an important role for fos in determining the dominance of the 12S or 13S protein.

Modulation of the IgH enhancer's cell type specificity through a genetic switch

Using defined regions of the immunoglobulin heavy-chain enhancer linked to minimal promoters and cDNAs that encode the two helix-loop-helix transcription factors ITF-1 and TFE3, we demonstrate that activity of an otherwise repressed enhancer can be stimulated in nonlymphoid cells. Repression in non-B cells is mediated by the microE5 motif. Derepression occurs at two levels. First, overexpression of ITF-1, and E12/E47-related protein that binds the microE5 motif, leads to transcriptional activation itself. Second, binding of ITF-1 physically displaces a repressor that normally blocks the stimulatory activity of TFE3, which binds the neighboring microE3 motif. TFE3 can only stimulate enhancer activity in the presence of ITF-1 or in the absence of a microE5 motif. Hence, one component of the enhancer's cell type specificity can be artificially modulated through a "genetic switch" in which activity is dictated by the relative levels of ITF-1 and a competing repressor.

Mouse and human retinoic acid receptor beta 2 promoters: sequence comparison and localization of retinoic acid responsiveness

The retinoic acid receptor beta (RAR beta) gene is a member of the family of retinoic acid/thyroid hormone receptor genes, encoding retinoic acid-inducible transcription factors. To study regulation of the RAR beta gene, genomic clones containing the mouse and human retinoic acid receptor beta 2 (RAR beta 2) promoters were isolated and approximately 1.5 kb of upstream and downstream sequences relative to the transcriptional start site were completely sequenced. Both the mouse and human RAR beta 2 promoters are highly homologous around the transcription initiation site, with perfect conservation of the TATA box and retinoic acid responsive element (RARE). Promoter activation studies in P19 EC cells show, that the RARE in both the human and mouse promoters confers RA-responsiveness to the RAR beta 2 promoter. However, sequences located immediately upstream of the RARE also confer RA-inducibility to both the mouse and human RAR beta 2 gene promoters. This region contains conserved consensus sequences for a TPA-responsive element (TRE) and cAMP-responsive element (CRE), suggesting that in addition to regulation by RA receptors other transcription factors regulate RAR beta 2 expression in EC cells. Furthermore, the availability of the mouse RAR beta 2 promoter should facilitate studies for transgene expression and gene targeting experiments in embryonic stem cells.

Molecular analysis of human argininosuccinate lyase: mutant characterization and alternative splicing of the coding region

Argininosuccinic acid lyase (ASAL) deficiency is a clinically heterogeneous autosomal recessive urea cycle disorder. We previously established by complementation analysis that 28 ASAL-deficient patients have heterogeneous mutations in a single gene. To prove that the ASAL structural gene is the affected locus, we sequenced polymerase chain reaction-amplified ASAL cDNA of a representative mutant from the single complementation group. Fibroblast strain 944 (approximately 1% of residual ASAL activity), from a late-onset patient who was the product of a consanguineous mating, had only a single base-pair change in the coding region, a C-283----T transition at a CpG dinucleotide in exon 3. This substitution converts Arg-95 to Cys (R95C), occurs in a stretch of 13 residues that is identical in yeast and human ASAL, and was present in both of the patient's alleles but not in 14 other mutant or 10 normal alleles. Expression in COS cells demonstrated that the R95C mutation produces normal amounts of ASAL mRNA but little protein and less than 1% ASAL activity. We observed that amplified cDNA from mutant 944 and normal cells (liver, keratinocytes, lymphoblasts, and fibroblasts) contained, in addition to the expected 5' 513-base-pair band, a prominent 318-base-pair ASAL band formed by the splicing of exon 2 from the transcript. The short transcript maintains the ASAL reading frame but removes Lys-51, a residue that may be essential for catalysis, since it binds the argininosuccinate substrate. We conclude (i) that the identification of the R95C mutation in strain 944 demonstrates that virtually all ASAL deficiency results from defects in the ASAL structural gene and (ii) that minor alternative splicing of the coding region occurs at the ASAL locus.

A family of constitutive C/EBP-like DNA binding proteins attenuate the IL-1 alpha induced, NF kappa B mediated trans-activation of the angiotensinogen gene acute-phase response element

The gene encoding angiotensinogen, the glycoprotein precursor of the potent vasopressor peptide angiotensin II, is transcriptionally activated in hepatocytes during the acute-phase response through interactions of mutually cooperative glucocorticoid receptors and proteins that bind to an acute-phase response element (APRE) 5'-AGTTGGGATTTCCCAACC-3'. The APRE binds a family of constitutive proteins (BPcs) and a cytokine inducible protein (BPi) that is indistinguishable from nuclear factor kappa B (NF kappa B). The interactions of purified proteins with the APRE were studied by in vitro binding and in vivo transcriptional trans-activation assays. BPc is a family of heat-stable DNA binding proteins, the different sized members of which are capable of forming heterodimers. BPcs are recognized by anti-C/EBP antiserum and produce a footprint similar to bacterially expressed C/EBP on the APRE. BPi has a 4- to 5-fold greater affinity for the APRE than the BPcs, and contacts guanosine residues distinct from those contacted by the BPcs, demonstrating that these two classes of proteins contain functionally distinct DNA binding domains. Assays of APRE-luciferase reporter plasmids transfected into HepG2 cells show that a mutated APRE that binds only BPi functions as an IL-1 alpha inducible enhancer, whereas a mutated APRE that binds only BPc does not. The APRE mutant that binds the C/EBP-like BPcs to the exclusion of BPi functions as an uninducible basal enhancer both in the native context of the angiotensinogen gene and when multimerized and placed upstream of a minimal angiotensinogen promoter. The wild-type APRE that binds both BPi and BPc is less inducible by IL-1 alpha than the mutated APRE that binds only BPi. Gel shift competition assays demonstrate in vitro that the mechanism of transcriptional regulation by the APRE involves a competition between BPc and the inducible BPi for binding to the APRE. IL-1 alpha stimulation of hepatocytes leads to nuclear translocation of the NF kappa B-like BPi which competes with the constitutive C/EBP-like BPcs for overlapping binding sites on the APRE and thereby replaces weak transcriptional activators with a stronger one.

The permissive role of glucocorticoids on interleukin-1 stimulation of angiotensinogen gene transcription is mediated by an interaction between inducible enhancers

The acute-phase activation of the rat angiotensinogen (rAT) gene in liver cells is a transcriptional event mediated through an interleukin-1-inducible, NF kappa B-binding, cis-acting element (the acute-phase response element [APRE]). Using a cell culture model for the acute-phase response, we showed that the increase in angiotensionogen mRNA in H35 rat hepatoma cells requires costimulation with glucocorticoids and cytokines. Stably transfected rAT promoter-luciferase reporter genes were also activated by cytokines only in the presence of glucocorticoids. This permissive role of glucocorticoids is dependent on the expression of functional glucocorticoid receptors, because in HepG2 cells naturally deficient in such receptors, rAT gene-luciferase reporter constructs responded to interleukin-1 only when cotransfected with an expression vector for the glucocorticoid receptor. Point mutations in the two rAT gene glucocorticoid response elements located adjacent to the APRE led to loss of interleukin-1 inducibility. Induction of luciferase activity in transfected cells occurred even in the presence of cycloheximide, demonstrating that this synergistic response did not depend on new protein synthesis. Thus, a direct interaction between the interleukin-1-inducible NF kappa B-binding APRE and glucocorticoid response elements, located in cis, underlies the acute-phase activation of the rAT gene.

The permissive role of glucocorticoids on interleukin-1 stimulation of angiotensinogen gene transcription is mediated by an interaction between inducible enhancers

The acute-phase activation of the rat angiotensinogen (rAT) gene in liver cells is a transcriptional event mediated through an interleukin-1-inducible, NF kappa B-binding, cis-acting element (the acute-phase response element [APRE]). Using a cell culture model for the acute-phase response, we showed that the increase in angiotensionogen mRNA in H35 rat hepatoma cells requires costimulation with glucocorticoids and cytokines. Stably transfected rAT promoter-luciferase reporter genes were also activated by cytokines only in the presence of glucocorticoids. This permissive role of glucocorticoids is dependent on the expression of functional glucocorticoid receptors, because in HepG2 cells naturally deficient in such receptors, rAT gene-luciferase reporter constructs responded to interleukin-1 only when cotransfected with an expression vector for the glucocorticoid receptor. Point mutations in the two rAT gene glucocorticoid response elements located adjacent to the APRE led to loss of interleukin-1 inducibility. Induction of luciferase activity in transfected cells occurred even in the presence of cycloheximide, demonstrating that this synergistic response did not depend on new protein synthesis. Thus, a direct interaction between the interleukin-1-inducible NF kappa B-binding APRE and glucocorticoid response elements, located in cis, underlies the acute-phase activation of the rAT gene.

Differential expression of jun and fos genes during differentiation of mouse P19 embryonal carcinoma cells

The jun and fos gene families encode DNA binding proteins involved in transcriptional regulation of genes containing a TPA responsive element (TRE). To study their role in gene regulation during early mammalian development, expression and transcription regulatory properties of their gene products were investigated during retinoic acid (RA) induced differentiation of P19 embryonal carcinoma (EC) cells. Our results show, that c-jun is expressed at low but detectable levels in undifferentiated P19 EC cells and at elevated levels in its RA differentiated derivatives, corresponding with increased expression of Jun and TRE binding activity. Jun D is constitutively expressed at constant levels in both undifferentiated and differentiated P19 cells, while jun B and c-fos are not expressed. Addition of TPA to undifferentiated P19 cells does not result in induction of c-jun, jun B and c-fos, while these genes are transiently induced in RA-differentiated P19 cells. In addition, TPA treatment resulted in expression of Fos and Jun protein in RA-differentiated, but not in undifferentiated P19 cells. Addition of TPA to P19 EC cells expressing low levels of TRE binding proteins is neither followed by transcriptional activation of the TRE reporter gene nor by induction of c-jun, previously shown to be autoregulated by its own gene product. By contrast, in P19 cells differentiated by RA that contain elevated levels of TRE binding proteins, TRE dependent transcription is enhanced upon TPA treatment.

An inducible 50-kilodalton NF kappa B-like protein and a constitutive protein both bind the acute-phase response element of the angiotensinogen gene

The rat angiotensinogen gene is induced in the course of the hepatic acute-phase response. We demonstrate that monocyte conditioned medium can stimulate transcription of a stably introduced reporter construct driven by 615 base pairs of the angiotensinogen 5'-flanking sequence, as well as the endogenous gene, in Reuber H35 cells. Point mutations of a cis-acting element, located 545 base pairs from the transcription start site and sharing sequence identity with known nuclear factor kappa B (NF kappa B)-binding sites, led to loss of cytokine inducibility. When cloned upstream of a minimal promoter, this cis-acting element imparted transcriptional inducibility by monocyte conditioned medium, interleukin-1, and tumor necrosis factor on a luciferase reporter gene in HepG2 cells. Two distinct proteins bound this element in vitro: a heat-stable, constitutively present, hepatic nuclear protein that gave rise to a DNase I-protected footprint covering the functionally defined element; and a binding protein of different mobility, induced by monocyte conditioned medium, which also recognized the NF kappa B-binding site of the murine kappa light-chain enhancer. UV cross-linking showed this inducible protein to have an apparent molecular mass of 50 kilodaltons, similar to that described for NF kappa B and distinct from the constitutively present protein that was shown by Southwestern (DNA-protein) blot to have a molecular mass of 32 kilodaltons. Methylation interference analysis showed that the induced species made contact points with guanine residues in the NF kappa B consensus sequence typical of NF kappa B. Induction of this binding activity did not require new protein synthesis, and 12-O-tetradecanoylphorbol-13-acetate could mimic the induction by cytokines. We thus provide direct evidence for involvement of NF kappa B or a similar factor in the hepatic acute-phase response and discuss the potential role of the presence of a constitutive nuclear factor binding the same cis element.

Functional heterogeneity of a large family of human LTR-like promoters and enhancers

The human genome contains a variety of elements similar in structure to retroviruses and retrotransposons. We have shown that the long terminal repeat (LTR) sequences of a large family of human retrovirus-like elements, RTVL-H, are heterogeneous in their ability to regulate the expression of linked genes. Although all of five LTRs tested could promote expression of the chloramphenicol acetyltransferase (CAT) gene, their relative promoter activities as well as range of activities varied widely. Several of the LTRs tested also exhibited bidirectional promoter activity either alone or when activated by an SV40 early enhancer. One LTR, H6, displayed strong promoter activity in human (NTera2D1, 293, Hep2), monkey (COS-1), and mouse (3T3) cells. In fact, the activity of this LTR was similar to that of the SV40 early promoter/enhancer in 293, COS-1, and 3T3 cells. RNA mapping studies have localized the transcription start site to the expected location in the H6 LTR. RTVL-H LTRs were also shown to contain sequences which could increase transcription from the human beta-globin promoter and be influenced by SV40 enhancer sequences. As the human genome contains several hundred related RTVL-H sequences and a similar number of solitary LTRs, these findings raise the possibility that RTVL-H LTRs could have diverse effects on the expression of adjacent cellular genes.

An inducible 50-kilodalton NF kappa B-like protein and a constitutive protein both bind the acute-phase response element of the angiotensinogen gene

The rat angiotensinogen gene is induced in the course of the hepatic acute-phase response. We demonstrate that monocyte conditioned medium can stimulate transcription of a stably introduced reporter construct driven by 615 base pairs of the angiotensinogen 5'-flanking sequence, as well as the endogenous gene, in Reuber H35 cells. Point mutations of a cis-acting element, located 545 base pairs from the transcription start site and sharing sequence identity with known nuclear factor kappa B (NF kappa B)-binding sites, led to loss of cytokine inducibility. When cloned upstream of a minimal promoter, this cis-acting element imparted transcriptional inducibility by monocyte conditioned medium, interleukin-1, and tumor necrosis factor on a luciferase reporter gene in HepG2 cells. Two distinct proteins bound this element in vitro: a heat-stable, constitutively present, hepatic nuclear protein that gave rise to a DNase I-protected footprint covering the functionally defined element; and a binding protein of different mobility, induced by monocyte conditioned medium, which also recognized the NF kappa B-binding site of the murine kappa light-chain enhancer. UV cross-linking showed this inducible protein to have an apparent molecular mass of 50 kilodaltons, similar to that described for NF kappa B and distinct from the constitutively present protein that was shown by Southwestern (DNA-protein) blot to have a molecular mass of 32 kilodaltons. Methylation interference analysis showed that the induced species made contact points with guanine residues in the NF kappa B consensus sequence typical of NF kappa B. Induction of this binding activity did not require new protein synthesis, and 12-O-tetradecanoylphorbol-13-acetate could mimic the induction by cytokines. We thus provide direct evidence for involvement of NF kappa B or a similar factor in the hepatic acute-phase response and discuss the potential role of the presence of a constitutive nuclear factor binding the same cis element.

Identification of the HeLa tumor-associated antigen, p75/150, as intestinal alkaline phosphatase and evidence for its transcriptional regulation

Prior studies identified a cell-surface antigen, p75/150, that exclusively associated with the tumorigenic phenotype of the HeLa parent and the tumorigenic phenotype of the HeLa parent and the tumorigenic segregants of suppressed, nontumorigenic HeLa x human fibroblast cell hybrids. Candidate p75/150 cDNA clones were isolated from a D98/AH.2 (HeLa) cDNA library using oligonucleotide probes derived from p75/150 partial peptide sequence data. A data base search revealed close similarity of p75/150 with intestinal alkaline phosphatase (IAP) [Berger, J., Garantini, E., Hua, J. C. & Udenfriend, S. (1987) Proc. Natl. Acad. Sci. USA 84, 695-698]. We demonstrate that p75/150 is identical to HeLa IAP by the following criteria: (i) 47/49 amino acid identity of p75 peptide sequence with IAP, (ii) restriction maps for the p75/150 candidate cDNA clone and IAP are identical, (iii) partial DNA sequence analysis of p75/150 candidate cDNA clones revealed complete nucleotide identity with IAP, except for a single nucleotide substitution in the 5' untranslated region, (iv) transfection of a p75/150 cDNA expression vector into the nontumorigenic hybrid, CGL1, yielded p75/150 antibody-positive transfectants that also expressed partially heat-resistant alkaline phosphatase activity. Northern blot analysis demonstrated that high levels of HeLa IAP mRNA were expressed in D98/AH.2 and the tumorigenic segregant CGL4; however, no mRNA was detected in CGL1. Nuclear run-on analyses indicate that HeLa IAP mRNA expression in the HeLa x fibroblast hybrids is regulated at the level of transcription initiation. Furthermore, evidence is discussed supporting the involvement of a chromosome 11 tumor suppressor locus in the regulation of HeLa IAP gene expression.

Two distinct transcription factors that bind the immunoglobulin enhancer microE5/kappa 2 motif

Activity of the immunoglobulin heavy and kappa light chain gene enhancers depends on a complex interplay of ubiquitous and developmentally regulated proteins. Two complementary DNAs were isolated that encode proteins, denoted ITF-1 and ITF-2, that are expressed in a variety of cell types and bind the microE5/kappa 2 motif found in both heavy and kappa light chain enhancers. The complementary DNAs are the products of distinct genes, yet both ITF-1 and ITF-2 are structurally and functionally similar. The two proteins interact with one another through their putative helix-loop-helix motifs and each possesses a distinct domain that dictates transcription activation.

An arginine to glutamine mutation in residue 109 of human ornithine transcarbamylase completely abolishes enzymatic activity in Cos1 cells

Ornithine transcarbamylase (OTC) is an important enzyme in the detoxification of ammonia to urea, and its deficiency is the most common inborn error of ureagenesis in humans. Among 24 cases of OTC deficiency previously examined, three unrelated individuals all showed loss of a Taq I site in the OTC gene corresponding to codon 109, suggesting that this Taq I site may be prone to mutation. Two of these patients demonstrated the same C----T transition (in antisense strand) converting Arg109 to Gln. Although these studies implied a strong association between the missense mutation and OTC-deficient phenotype, a causal relationship could not be firmly established. We have investigated this relationship by reconstructing the mutation in vitro. A full-length human OTC cDNA was cloned into an SV40-based expression vector and has been reproducibly expressed at high levels in the cell line Cos1. By site-directed mutagenesis of this wild type sequence, we constructed a missense mutation which contains the C----T transition. Electroporation and transient assay in Cos1 indicated that the specific activity of mutant OTC was 100-fold lower than that of wild type. This result confirms that the Taq I alteration leading to the Gln missense is responsible for the OTC deficiency affecting the above patients.

Identification of a myocyte nuclear factor that binds to the muscle-specific enhancer of the mouse muscle creatine kinase gene

The muscle creatine kinase (MCK) gene is transcriptionally induced when skeletal muscle myoblasts differentiate into myocytes. The gene contains two muscle-specific enhancer elements, one located 1,100 nucleotides (nt)5' of the transcriptional start site and one located in the first intron. We have used gel mobility shift assays to characterize the trans-acting factors that interact with a region of the MCK gene containing the 5' enhancer. MM14 and C2C12 myocyte nuclear extracts contain a sequence-specific DNA-binding factor which recognizes a site within a 110-nt fragment of the MCK enhancer region shown to be sufficient for enhancer function. Preparative mobility shift gels were combined with DNase I footprinting to determine the site of binding within the 110-nt fragment. Site-directed mutagenesis within the footprinted region produced a 110-nt fragment which did not bind the myocyte factor in vitro. The mutant fragment had about 25-fold-less activity as a transcriptional enhancer in myocytes than did the wild-type fragment. Complementary oligomers containing 21 base pairs spanning the region protected from DNase degradation were also specifically bound by MM14 and C2C12 myocyte nuclear factors. The oligomer-binding activity was not found in nuclear extracts from the corresponding myoblasts, in nuclear extracts from a variety of nonmuscle cell types (including differentiation-defective MM14-DD1 cells and 10T1/2 mesodermal stem cells), or in cytoplasmic extracts. Both the 5' and intron 1 enhancer-containing fragments competed for factors that bind the oligomer probe, while total mouse genomic DNA and several DNA fragments containing viral and cellular enhancers did not. Interestingly, a 5' MCK proximal promoter fragment that also contains muscle-specific positive regulatory elements did not compete for factor binding to the oligomer. We have designated the factor which interacts with the two MCK enhancers myocyte-specific enhancer-binding nuclear factor 1 (MEF 1). A consensus for binding sites in muscle-specific regulatory regions is proposed.

Identification of a myocyte nuclear factor that binds to the muscle-specific enhancer of the mouse muscle creatine kinase gene

The muscle creatine kinase (MCK) gene is transcriptionally induced when skeletal muscle myoblasts differentiate into myocytes. The gene contains two muscle-specific enhancer elements, one located 1,100 nucleotides (nt)5' of the transcriptional start site and one located in the first intron. We have used gel mobility shift assays to characterize the trans-acting factors that interact with a region of the MCK gene containing the 5' enhancer. MM14 and C2C12 myocyte nuclear extracts contain a sequence-specific DNA-binding factor which recognizes a site within a 110-nt fragment of the MCK enhancer region shown to be sufficient for enhancer function. Preparative mobility shift gels were combined with DNase I footprinting to determine the site of binding within the 110-nt fragment. Site-directed mutagenesis within the footprinted region produced a 110-nt fragment which did not bind the myocyte factor in vitro. The mutant fragment had about 25-fold-less activity as a transcriptional enhancer in myocytes than did the wild-type fragment. Complementary oligomers containing 21 base pairs spanning the region protected from DNase degradation were also specifically bound by MM14 and C2C12 myocyte nuclear factors. The oligomer-binding activity was not found in nuclear extracts from the corresponding myoblasts, in nuclear extracts from a variety of nonmuscle cell types (including differentiation-defective MM14-DD1 cells and 10T1/2 mesodermal stem cells), or in cytoplasmic extracts. Both the 5' and intron 1 enhancer-containing fragments competed for factors that bind the oligomer probe, while total mouse genomic DNA and several DNA fragments containing viral and cellular enhancers did not. Interestingly, a 5' MCK proximal promoter fragment that also contains muscle-specific positive regulatory elements did not compete for factor binding to the oligomer. We have designated the factor which interacts with the two MCK enhancers myocyte-specific enhancer-binding nuclear factor 1 (MEF 1). A consensus for binding sites in muscle-specific regulatory regions is proposed.