Structure of the rat L-type pyruvate kinase gene

Regulation of rat hepatic L-pyruvate kinase promoter composition and activity by glucose, n-3 polyunsaturated fatty acids, and peroxisome proliferator-activated receptor-alpha agonist

Carbohydrate regulatory element-binding protein (ChREBP), MAX-like factor X (MLX), and hepatic nuclear factor-4alpha (HNF-4alpha) are key transcription factors involved in the glucose-mediated induction of hepatic L-type pyruvate kinase (L-PK) gene transcription. n-3 polyunsaturated fatty acids (PUFA) and WY14643 (peroxisome proliferator-activated receptor alpha (PPARalpha) agonist) interfere with glucose-stimulated L-PK gene transcription in vivo and in rat primary hepatocytes. Feeding rats a diet containing n-3 PUFA or WY14643 suppressed hepatic mRNA(L-PK) but did not suppress hepatic ChREBP or HNF-4alpha nuclear abundance. Hepatic MLX nuclear abundance, however, was suppressed by n-3 PUFA but not WY14643. In rat primary hepatocytes, glucose-stimulated accumulation of mRNA(LPK) and L-PK promoter activity correlated with increased ChREBP nuclear abundance. This treatment also increased L-PK promoter occupancy by RNA polymerase II (RNA pol II), acetylated histone H3 (Ac-H3), and acetylated histone H4 (Ac-H4) but did not significantly impact L-PK promoter occupancy by ChREBP or HNF-4alpha. Inhibition of L-PK promoter activity by n-3 PUFA correlated with suppressed RNA pol II, Ac-H3, and Ac-H4 occupancy on the L-PK promoter. Although n-3 PUFA transiently suppressed ChREBP and MLX nuclear abundance, this treatment did not impact ChREBP-LPK promoter interaction. HNF4alpha-LPK promoter interaction was transiently suppressed by n-3 PUFA. Inhibition of L-PK promoter activity by WY14643 correlated with a transient decline in ChREBP nuclear abundance and decreased Ac-H4 interaction with the L-PK promoter. WY14643, however, had no impact on MLX nuclear abundance or HNF4alpha-LPK promoter interaction. Although overexpressed ChREBP or HNF-4alpha did not relieve n-3 PUFA suppression of L-PK gene expression, overexpressed MLX fully abrogated n-3 PUFA suppression of L-PK promoter activity and mRNA(L-PK) abundance. Overexpressed ChREBP, but not MLX, relieved the WY14643 inhibition of L-PK. In conclusion, n-3 PUFA and WY14643/PPARalpha target different transcription factors to control L-PK gene transcription. MLX, the heterodimer partner for ChREBP, has emerged as a novel target for n-3 PUFA regulation.

Targeting of therapeutic gene expression to the liver by using liver-type pyruvate kinase proximal promoter and the SV40 viral enhancer active in multiple cell types

To achieve the liver-directed expression in sufficient amounts of therapeutic genes for successful and safe gene therapy, natural liver-specific promoters can be used to direct the expression of therapeutic genes in the liver, whereas strong viral enhancers were used to obtain sufficient amounts of expressed therapeutic gene products. However, very often use of either the former or the latter does not guarantee both potent and liver-specific therapeutic gene expression. Here we conglomerate them and thus create a potent tissue-specific promoter by characterizing and using the liver-type pyruvate kinase proximal promoter (LPKPP) harboring its TATA box and a HNF-1alpha binding site. Alone it hardly activated its reporter gene expression in non-hepatocytes or hepatocytes. However, in the presence of the SV40 viral enhancer (SV40VE), which is active in multiple cell types, it was able to potently activate its reporter gene expression specifically in hepatocytes. The tissue-specific activation of the LPKPP by the viral enhancer was attributed to HNF-1alpha binding to the LPKPP. Taken together, these results support the idea that the constitutively active SV40VE could be used to activate the LPKPP in a tissue-specific manner in the presence of HNF-1alpha. To our knowledge, this is the first study to utilize HNF-1alpha and its binding site, in the context of the LPKPP, to generate a basal promoter that is transcriptionally activated potently in a tissue-specific manner by a viral enhancer that is active in multiple cell types.

Glucose regulated production of human insulin in rat hepatocytes

Insulin gene therapy requires that insulin secretion be coupled to metabolic requirements. To this end, we have developed an insulin transgene whose transcription is stimulated by glucose and inhibited by insulin. Glucose- and insulin-sensitive promoters were constructed by inserting glucose-responsive elements (GlREs) from the rat L-pyruvate kinase (L-PK) gene into the insulin-sensitive, liver-specific, rat insulin-like growth factor binding protein-1 (IGFBP-1) promoter. Glucose (5 to 25 mM) stimulated, and insulin (10-10 to 10-7 M) inhibited, luciferase expression driven by these promoters in primary cultured rat hepatocytes. The capacity of transfected hepatocytes to secrete mature, biologically active insulin was demonstrated using a human proinsulin cDNA (2xfur), modified to allow protein processing by endogenous endopeptidase activity. Medium conditioned by insulin-producing hepatocytes contained greater than 300 microU/ml immunoreactive insulin, while denaturing SDS-PAGE of an anti-insulin immunoprecipitate revealed bands with the mobilities of insulin A, and B chains. Biological activity of hepatocyte-produced insulin was demonstrated in a transfection assay, in which medium conditioned by insulin-producing hepatocytes exerted an effect similar to 10-7 M insulin. We then combined the glucose- and insulin-sensitive promoter with the modified human proinsulin cDNA to create a metabolically sensitive insulin transgene ((GlRE)3BP-1 2xfur). In both H4IIE hepatoma cells stably transfected with this construct, and normal rat hepatocytes (GlRE)3BP-1 2xfur-mediated insulin secretion increased in response to stimulation by glucose. Moreover, a capacity to decrease insulin production in response to diminishing glucose exposure was also demonstrated. We conclude that the transcriptional regulation of insulin production using these glucose- and insulin-sensitive constructs meets the requirements for application in a rodent model of insulin gene therapy. Gene Therapy (2000) 7, 205-214.

A novel factor binding to the glucose response elements of liver pyruvate kinase and fatty acid synthase genes

Transcription of the liver type pyruvate kinase and lipogenesis enzyme genes is induced by high carbohydrate in liver. We have found a novel protein factor in rat liver nuclei that binds to the glucose response element (CACGTG motifs) of the pyruvate kinase gene (Liu, Z. , Thompson, K. S., and Towle, H. C. (1993) J. Biol. Chem. 268, 12787-12795) and the "insulin response element" of fatty acid synthase gene. The amounts of this DNA-binding protein, termed "glucose response element binding protein" (GRBP) in the nuclear extract, were increased in liver by a high carbohydrate diet and decreased by starvation, high fat, and high protein diet. GRBP also occurs in cytosols of liver and is dependent on carbohydrate. Both the nuclear and the cytosolic GRBP showed similar properties, except the former was more resistant to thermal inactivation than the latter. Kinetics of glucose activation of the cytosolic GRBP in a primary culture of hepatocytes indicated that a half-maximum activation was achieved after 6 h, and glucose concentration required for the maximum activation of the GRBP was approximately 12 mM. Dibutyryl-cAMP, okadaic acid, and forskolin inhibited glucose activation of both GRBP and liver pyruvate kinase transcription. These results suggested that GRBP may be a factor that recognizes the glucose response motif site and may be involved in mediating carbohydrate response of the pyruvate kinase gene.

Complete genomic sequence of the human PK-L/R-gene includes four intragenic polymorphisms defining different haplotype backgrounds of normal and mutant PK-genes

The human pyruvate kinase L/R-gene has been completely sequenced in unrelated normal individuals and in pyruvate kinase-deficient patients by a PCR-based direct genomic sequencing approach and analyzed for polymorphisms. The total length of the gene is 8409 nucleotides. Four polymorphic sites have been detected: C/A1705 and C/T1992 in exon 12, a T-stretch in intron 1 occurring in the two polymorphic forms (T)10 and (T)19 and an (ATT)n microsatellite in intron J which has been found in the variation (ATT)11-17. Haplotype analysis using these four markers has been applied to trace the genetic background in PK-deficiencies. The results support the idea of a single origin of most of the individual PK-mutations.

Gene expression of mouse M1 and M2 pyruvate kinase isoenzymes correlates with differential poly[A] tract extension of their mRNAs during the development of spermatogenesis

In eukaryotes, different isoenzymes for pyruvate kinase have been characterized. M2-type Pk cDNA from a mouse fetal ovary library was isolated and differential expression for M1 and M2-types during testis development was observed. While the presence of M2 mRNAs decreases throughout the development of spermatogenesis, we deduced that M1 type expression increases in adult testis coinciding with the presence of elongating spermatids in the seminiferous epithelium. Polyadenylation tests showed a concurrent increase in the length of the polyadenylation tail of transcribed M1-type pyruvate kinase mRNAs in prepuberal to adult seminiferous tubules. A similar relationship between poly[A] tail extension and differential increase of gene expression was detected for M1-type mRNA in adult brain and muscle. Length of poly[A] tail of M2-type transcripts is shown to decrease during the development of mouse testis. These results suggest that changes in the length of the poly[A] tail of transcripts are associated with differential expression of both regulated isoenzymes during testicular development.

Mouse USF1 gene cloning: comparative organization within the c-myc gene family

Upstream stimulatory factors (USF/MLTF) belong to the c-myc family of transcription factors. Through binding to target DNA as dimers, the ubiquitous USF proteins regulate a variety of genes. USF proteins are encoded by two genes, USF1 and USF2. Protein sequences of USF1 and 2 are highly homologous across species, suggesting functional conservation. To determine whether the genomic organization was conserved between USF1 and USF2, we isolated the murine USF1 gene and characterized its genomic structure. Both genes are similarly organized in 10 exons spanning over 10 kbp. By the 5'-rapid amplification of cDNA ends and S1 nuclease mapping methods, exon 1 was defined and the transcription initiation sites were mapped. The sequence of 8 kb of the gene, including 1.75 kb of 5'-flanking DNA, was determined. The promoter region is GC rich and lacks a typical TATA or CCAAT element. Strikingly, a comparison of the murine and human untranslated sequences reveals regions that exhibit greater than 73% sequence identity. A genomic alignment of the dimerization and DNA binding domains is presented for five genes of the c-myc family, suggesting a hypothetical common ancestor gene.

Intestinal apolipoprotein AI gene transcription is regulated by multiple distinct DNA elements and is synergistically activated by the orphan nuclear receptor, hepatocyte nuclear factor 4

We have used apolipoprotein genes to investigate the signal transduction mechanisms involved in the control of intestinal specific gene expression. The human apoAI, apoCIII, and apoAIV genes are tandemly organized within a 15-kb DNA segment and are expressed predominantly in the liver and intestine. Transient transfection of various human apoAI gene plasmid constructs into human hepatoma (HepG2) and colon carcinoma (Caco-2) cells showed that apoAI gene transcription is under the control of two separate and distinct cell-specific promoters. The region between nucleotides -192 and -41 is essential for expression in HepG2 cells, whereas the region from -595 to -192 is essential for expression in Caco-2 cells. A third 0.6 kb DNA fragment in the apoCIII gene promoter region, approximately 5 kb down-stream from the human apoAI gene, enhances transcription mediated by either of these two tissue-specific apoAI promoters. In Caco-2 cells, expression of the apoAI gene and activation by the distal enhancer required the presence of a nuclear hormone receptor response element (NHRRE) located in the -214 to -192 apoAI promoter region. Overexpression of the orphan receptor hepatocyte nuclear factor 4 (HNF-4), which binds to the NHRRE, dramatically stimulates apoAI gene expression in Caco-2 cells but not in HepG2 cells. Maximal stimulation of transcription by HNF-4 in Caco-2 cells required the presence of both the intestinal specific promoter, the NHRRE, and distal enhancer elements. Transactivation by HNF-4 thus appears to result from functional synergy between the NHRRE binding HNF-4 and distal DNA elements containing intestinal-specific DNA binding activities. The apoAI gene provides a model system to define the mechanism(s) governing intestinal cell specific gene regulation and the role of nuclear hormone receptors in the establishment and regulation of enterocytic gene transcription.

Identification of a liver-specific promoter for the ovine growth hormone receptor

Growth hormone (GH) receptor cDNA clones from several species are characterized by heterogeneity in the 5' untranslated region (5'UT). This has been attributed to different promoters directing the expression of the gene from exons encoding 5'UT's which are alternatively spliced onto a common splice acceptor 11 basepairs (bp) upstream of the initiating AUG on exon 2. The following study identifies exon 1A of the ovine (o) GH receptor gene, corresponding to the 5'UT of a developmentally regulated, liver-specific transcript. Exon 1A spans 206 bp at a position 17 kilobases (kb) upstream of exon 2. Sequencing of the 669 bp region 5' to the transcription initiation site (+1) reveals a TATA box at -31, a CCAAT box at -88, and putative binding sites for several transcription factors involved in liver-specific gene expression. Two repetitive sequence elements are located in the 5' and 3' flanking regions of exon 1A. Functional analysis of the 4.5 kb region upstream of exon 1A was performed by transfecting the human hepatoma cell line HuH7 with luciferase reporter gene constructs. Positive and negative regulatory regions are identified, with basal promoter activity within 473 bp of the transcription initiation site. A 47 bp region containing putative binding sites for the activated glucocorticoid receptor and C/EBP-like proteins, between -180 and -133, is essential for transcriptional activation.

Myf5, MyoD, myogenin and MRF4 myogenic derivatives of the embryonic mesenchymal cell line C3H10T1/2 exhibit the same adult muscle phenotype

Cells of the embryonic mesenchymal cell line C3H10T1/2 have revealed the potential that the four regulatory factors belonging to the MyoD family have to activate myogenesis. In the present study we have further investigated the myogenic phenotype of C3H10T1/2 cells stably transfected with either Myf5, MyoD, myogenin or MRF4 cDNAs. We have studied the influence of each transfected cDNA on expression of the four endogenous muscle regulatory genes and on the ability of these embryonic myogenic derivatives to express adult muscle genes. No trace of endogenous transcripts distinct from the exogenous one was found in any of the four converted populations at the myoblast stage. This indicates that cross-activation within the MyoD family does not occur at the myoblast stage in these cells. Similarly, evidence was obtained that auto- or cross-activation of the Myf5 gene occurs neither at the myoblast stage nor at the myotube stage and that no autoactivation of the MRF4 gene occurs. Our results together with previous observations indicate that in C3H10T1/2 myogenic derivatives: (1) Autoactivation at the myoblast stage is restricted to MyoD (2) Expression from each cDNA alone is sufficient to establish and maintain the myoblast phenotype (3) The endogenous Myf5 gene is not mobilized. We have also observed that endogenous transcripts for MyoD and myogenin begin to accumulate at the onset of differentiation in the four myogenic derivatives, whereas accumulation of endogenous MRF4 transcripts starts after myotubes have formed and occurs at a much lower level (100- to 500-fold lower) than in differentiated cultures of myosatellite cells.(ABSTRACT TRUNCATED AT 250 WORDS)

Establishment of renal proximal tubule cell lines by targeted oncogenesis in transgenic mice using the L-pyruvate kinase-SV40 (T) antigen hybrid gene

Targeted oncogenesis allowed us to obtain two cell lines which have been derived from the proximal tubule of kidney from transgenic mice harbouring the simian virus (SV40) large T and small t antigens placed under the control of the 5′ regulatory sequence from the rat L-type pyruvate kinase (L-PK) gene. The cell lines (PKSV-PCT and PKSV-PR cells) were derived from early (PCT) and late (Pars Recta, PR) microdissected proximal tubules grown in D-glucose-enriched medium. In such conditions of culture, both cell lines exhibited L-PK transcripts, a stable expression of SV40-encoded nuclear large T antigen, a prolonged life span but failed to induce tumors when injected sub-cutaneously into athymic (nu-nu) mice. Confluent cells, grown on plastic support or porous filters, were organized as monolayers of polarized cuboid cells with well developed apical microvilli and formed domes. Both cell lines exhibited morphological features of proximal tubule cells with villin located in the apical brush-border and substantial amounts of hydrolase activity. By immunofluorescence studies using specific antibodies, aminopeptidase N appeared restricted to the apical microvillar domain, whereas the H2 histocompatibility antigen was distributed in the cytoplasm and lateral membranes. These results demonstrate that the proximal morphological phenotype has been fully preserved in these cultured cells derived from tissue-specific targeted oncogenesis in transgenic mice.

Structure of the gene encoding potato cytosolic pyruvate kinase

The polymerase chain reaction (PCR) has been used to generate a series of overlapping genomic clones representing 43 bp of 5' untranslated sequence, 63 bp of 3' untranslated sequence and the entire coding sequence of the gene encoding potato cytosolic pyruvate kinase (PKc). This portion of the gene is approximately 4.5 kb in length and is interrupted by three introns, one of which is present in the 5' untranslated region. Southern blot analysis indicates that PKc is encoded by a small gene family, and sequence data from a number of PCR-derived genomic clones indicate that there are as many as six PKc genes. Sequence differences between the PCR-generated genomic clones and a PKc cDNA clone are discussed with respect to the fidelity of Taq polymerase. An alignment of intron placement in the potato PKc gene with intron placement in PK genes from other sources indicates that two of the potato introns correspond to intron positions in other species.

Elements responsible for hormonal control and tissue specificity of L-type pyruvate kinase gene expression in transgenic mice

L-type pyruvate kinase (L-PK) is a key enzyme of the glycolytic pathway specifically expressed in the liver and, to a lesser degree, in the small intestine and kidney. One important characteristic of L-PK gene expression is its strong activation by glucose and insulin and its complete inhibition by fasting or glucagon treatment. Having previously established that the entire rat L-PK gene plus 3.2 kbp of 5'-flanking region functions in mice in a tissue-specific and hormonally regulated manner, various deletions of these 3.2 kbp of 5'-flanking regions were tested in transgenic animals to map the cis-acting elements involved in transcriptional gene regulation. Our experiments indicate that the proximal region between -183 and +11 confers tissue specificity and contains all the information necessary for dietary and hormonal control of L-PK gene expression in vivo. We found, however, that the transcriptional activity generated by this proximal promoter fragment can be modulated by distal sequences in a tissue-specific manner. (i) Sequences between bp -183 and -392 seem to play a dual role in the liver and small intestine; they induce L-PK expression in the liver but repress it in the small intestine. (ii) Sequences from bp -392 up to -1170 do not seem to have any additional effect on promoter activity. (iii) Between bp -1170 and -2080, we found a putative extinguisher whose transcriptional inhibitory effect is much more marked in the small intestine than in the liver. (iv) Finally, between bp -2080 and -3200, we identified an activating sequence required for full expression of the gene in the liver.

In vitro and in vivo protein--DNA interactions on the rat erythroid-specific L' pyruvate kinase gene promoter

The rat L-type pyruvate kinase gene possesses two alternative tissue-specific promoters, located 472 bp apart; the upstream L' promoter is erythroid-specific and the downstream L promoter is hepatocyte-specific. The erythroid-specific L' promoter is strongly active in fetal liver at day 17 of gestation, while its activity rapidly decreases thereafter. A L' promoter fragment spanning from nucleotide -320 to +10 with respect to the cap site is able to direct a weak but erythroid-specific transcription in a cell-free system. We have used DNAse I footprinting and gel mobility shift assays to characterize and identify the binding of nuclear factors from both 17-day-old fetal liver and adult liver nuclear extracts to a 320 bp fragment of the 5' flanking region of the gene in vitro. Two clusters of erythroid-specific interactions were found. The proximal cluster consists of two GATA-1 binding sites at -50 bp and -65 bp from the transcription initiation site, immediately downstream of a CACC motif and two G/C-rich elements. The distal cluster of cis-elements, located 130 bp upstream, corresponds to two GATA-1 sequences. These two sequences overlap NF1 motifs interacting with ubiquitous NF1 transcriptional factors in presence of adult hepatic extracts. Furthermore, we have examined in vivo protein-DNA interactions by DMS footprinting in livers of 17-day-old rat fetuses and adult rats. We found that the sites characterized in vitro are occupied in vivo. Therefore, in adult liver the L' promoter, although inactive, nevertheless interacts with ubiquitous factors.

Elements responsible for hormonal control and tissue specificity of L-type pyruvate kinase gene expression in transgenic mice

L-type pyruvate kinase (L-PK) is a key enzyme of the glycolytic pathway specifically expressed in the liver and, to a lesser degree, in the small intestine and kidney. One important characteristic of L-PK gene expression is its strong activation by glucose and insulin and its complete inhibition by fasting or glucagon treatment. Having previously established that the entire rat L-PK gene plus 3.2 kbp of 5'-flanking region functions in mice in a tissue-specific and hormonally regulated manner, various deletions of these 3.2 kbp of 5'-flanking regions were tested in transgenic animals to map the cis-acting elements involved in transcriptional gene regulation. Our experiments indicate that the proximal region between -183 and +11 confers tissue specificity and contains all the information necessary for dietary and hormonal control of L-PK gene expression in vivo. We found, however, that the transcriptional activity generated by this proximal promoter fragment can be modulated by distal sequences in a tissue-specific manner. (i) Sequences between bp -183 and -392 seem to play a dual role in the liver and small intestine; they induce L-PK expression in the liver but repress it in the small intestine. (ii) Sequences from bp -392 up to -1170 do not seem to have any additional effect on promoter activity. (iii) Between bp -1170 and -2080, we found a putative extinguisher whose transcriptional inhibitory effect is much more marked in the small intestine than in the liver. (iv) Finally, between bp -2080 and -3200, we identified an activating sequence required for full expression of the gene in the liver.

Structural analysis of human pyruvate kinase L-gene and identification of the promoter activity in erythroid cells

The human pyruvate kinase (PK) L-gene is organized in 12 exons over 9.5 kilobases, and the first and second exons are specifically transcribed to the R- and L-type PK mRNA. The 5'-flanking region upstream the first exon has two CAC boxes and four GATA motifs within 250 bp from the translational initiation codon. Comparison with the rat L-gene revealed four well-conserved elements in the region. The transient transfection demonstrated that the 270-bp upstream region was a powerful promoter in K562 cells, whereas deletion of the distal 150-bp sequences, which included three GATA motifs, resulted in drastic reduction of the activity. When the hypersensitive site 2 of the human beta-globin gene locus was joined to the promoter, the activity of the proximal 120-bp region was enhanced. We concluded that the proximal 120-bp region had a basal promoter activity and that the distal 150-bp region acted as an enhancer in erythroid cells.

Housekeeping Na,K-ATPase alpha 1 subunit gene promoter is composed of multiple cis elements to which common and cell type-specific factors bind

Na,K-ATPase alpha 1 subunit gene (ATP1A1) is one of the housekeeping genes involved in homeostasis of Na+ and K+ in all animal cells. We identified and characterized the cis-acting elements that regulate the expression of ATP1A1. The region between -155 and -49 was determined as a positive regulatory region in five cultured cell lines of different tissue origins (MDCK, B103, L6, 3Y1, and HepG2). The region was divided into three subregions: from -120 to -106 (including the Sp1 binding site), from -102 to -61, and from -58 to -49 (including an Sp1 consensus sequence). Cell type-specific factors binding to the middle subregion (from -102 to -61) were detected by gel retardation analysis, using nuclear extracts prepared from MDCK and B103 cells. Two gel retardation complexes were formed in the B103 nuclear extract, and three were formed in the MDCK nuclear extract. DNA binding regions of these factors were located at -88 to -69 and differed from each other in DNase I footprinting experiments. These factors also showed different binding characteristics in gel retardation competition and methylation interference experiments. The identified cis element was named the ATP1A1 regulatory element. The core sequence of this element is found in several other genes involved in cellular energy metabolism, suggesting that the sequence is a common regulatory element responsive to the state of energy metabolism.

Housekeeping Na,K-ATPase alpha 1 subunit gene promoter is composed of multiple cis elements to which common and cell type-specific factors bind

Na,K-ATPase alpha 1 subunit gene (ATP1A1) is one of the housekeeping genes involved in homeostasis of Na+ and K+ in all animal cells. We identified and characterized the cis-acting elements that regulate the expression of ATP1A1. The region between -155 and -49 was determined as a positive regulatory region in five cultured cell lines of different tissue origins (MDCK, B103, L6, 3Y1, and HepG2). The region was divided into three subregions: from -120 to -106 (including the Sp1 binding site), from -102 to -61, and from -58 to -49 (including an Sp1 consensus sequence). Cell type-specific factors binding to the middle subregion (from -102 to -61) were detected by gel retardation analysis, using nuclear extracts prepared from MDCK and B103 cells. Two gel retardation complexes were formed in the B103 nuclear extract, and three were formed in the MDCK nuclear extract. DNA binding regions of these factors were located at -88 to -69 and differed from each other in DNase I footprinting experiments. These factors also showed different binding characteristics in gel retardation competition and methylation interference experiments. The identified cis element was named the ATP1A1 regulatory element. The core sequence of this element is found in several other genes involved in cellular energy metabolism, suggesting that the sequence is a common regulatory element responsive to the state of energy metabolism.

Distal transcript of the dystrophin gene initiated from an alternative first exon and encoding a 75-kDa protein widely distributed in nonmuscle tissues

A transcript generated by the distal part of the Duchenne Muscular Dystrophy (DMD) gene was initially detected in cells where the full size 14-kilobase (kb) messenger RNA is not found at a significant level. This transcript, approximately 4.5 kb long, corresponds to the cysteine-rich and carboxyl-terminal domains of dystrophin. It begins with a novel 80- to 100-nucleotide exon containing an ATG start site for a new coding sequence of 17 nucleotides in-frame with the consecutive dystrophin cDNA sequence from exon 63. This result suggests the existence of a third promoter that would be localized about 8 kilobases upstream from exon 63 of the DMD gene. The distal transcript is widely distributed but is absent in adult skeletal and myometrial muscle. It is much more abundant in fetal tissues. With an antibody directed against the dystrophin carboxyl terminus, the protein corresponding to this transcript was detected as a 70- to 75-kDa entity on Western blots. It was found in all tissues analyzed except in skeletal muscle. It was not found in lymphoblastoid cells from a Duchenne patient with a complete deletion of the dystrophin gene. The role and subcellular localization of this protein is not known. It may explain extramuscular symptoms exhibited by some Duchenne patients.

Developmental regulation of villin gene expression in the epithelial cell lineages of mouse digestive and urogenital tracts

The expression of villin, an actin-binding protein and major structural component of the brush border of specialized absorptive cells, was studied during mouse embryogenesis. We show that the ontogeny of villin expression is limited to the epithelial cell lineages of the digestive and uro-genital tracts and accounts for the tissue-specific expression observed in adult mice. This spatiotemporal pattern of villin expression is distinctive in sequence, intensity, regional distribution and polarization. During the development of the primitive gut, villin is faintly and discontinuously expressed in the invaginating foregut but it is expressed in every cell bordering the hindgut pocket. Later, villin expression increases along the developing intestine and concentrates in the brush border of the epithelium bordering the villi. In gut derivatives, villin is present in liver and pancreas primordia but only biliary and pancreatic cells maintain a faint villin expression as observed in adults. In the urogenital tract, mesonephric tubules are the first mesodermal derived structures to express villin. This expression is maintained in the ductuli efferents, paradidymis and epoophoron. Villin then appears in the proximal metanephric tubules and later increases and concentrates in the brush border of the renal proximal tubular epithelial cells. Thus villin expression can be considered as an early marker of the endodermal cell lineage during the development of the digestive system. Conversely, during the development of the excretory and genital system, villin is only expressed after the mesenchyme/epithelium conversion following the appearance of tubular structures. These observations emphasize the multiple levels of regulation of villin gene activity that occur during mouse embryogenesis and account for the strict pattern of tissue-specific expression observed in adults. In the future, regulatory elements of the villin gene may be used to target the early expression of oncogenes to the digestive and urogenital tracts of transgenic mice.

DNase-I hypersensitivity analysis of the L-type pyruvate kinase gene in rats and transgenic mice

The rat L-type pyruvate kinase gene possesses two promoters located 500 bp apart. The L' promoter is specific to erythroid cells. The L promoter is specific to liver and is regulated by diet and hormones; positively by glucose and insulin and negatively by glucagon via cAMP. The DNA elements involved in this tissue-specific and hormone-regulated gene expression are located within 3.2 kbp of 5' flanking region as previously demonstrated by transgenic mice analysis [Tremp, G. L., Boquet, D., Ripoche, M. A., Cognet, M., Yu-Chun, L., Jami, J., Kahn, A. and Daegelen, D. (1989) J. Biol. Chem. 264, 19,904-19,910]. Moreover, we have observed in these mice that gene expression was dependent on the transgene copy number and independent of the integration site. We present here DNase-I-hypersensitivity analysis of the endogenous rat L-type pyruvate kinase gene and of two transgene constructs in relation to development, tissue differentiation, nutritional and hormonal status. In rats, two groups of proximal sites were detected on the endogenous gene; hypersensitive site (HSS) HSS-1 in adult liver and HSS-A in fetal liver (a major erythropoietic tissue). Both groups are probably related to the transcriptional initiation complexes at either the L or L' promoter. Two other distal groups were detected; HSS-2 at -3 kbp (with respect to the liver-specific cap site) in adult liver and HSS-B around -4 kbp in fetal liver. These sites are thought to correspond to activating sequences; in adult liver, deletion of a fragment encompassing HSS-2 provokes a dramatic reduction of transcription starting at the L promoter of the transgene. In adult liver, HSS-1 appears to be a transcription-associated site, being greatly weakened in fasted rats, while HSS-2 is transcription independent. The pattern of DNase-I hypersensitivity is similar for the rat endogenous gene and for the complete rat transgene; the liver-specific HSS-1 and HSS-2 are present and the intensity of the sites is correlated to the number of integrated copies. Interestingly, HSS-1 is still detectable and its intensity remains proportional to the number of integrated copies in a truncated transgene with HSS-2 deletion, while this transgene is very weakly (but nevertheless tissue-specifically) expressed. These results strongly suggest that each transgene copy possesses a complete set of specific nucleoprotein complexes and that, with or without HSS-2, the DNA is in a potentially active configuration.

Isolation and characterization of the Aspergillus niger pyruvate kinase gene

The Aspergillus niger gene encoding pyruvate kinase was cloned by heterologous hybridization using a fragment from the corresponding yeast gene as a probe. The primary structure of the gene, including 5' and 3' flanking sequences, was determined. The structural part of the A. niger pkiA gene is 2054 bp long and is interrupted by seven putative introns. Splicing of the intron sequences results in an open reading frame of 1578 bp, encoding a protein of 526 amino-acid residues and a molecular weight of 58,130 Da. Extensive homology is found with pyruvate kinase from A. nidulans; only 33 amino acids are different between both proteins. Transformation experiments using the pyrA gene as a selection marker and the subcloned pkiA gene as a co-transforming marker led to increased levels of pyruvate kinase. Analysis of the transformants showed that in none of the transformants integration had occurred at the pkiA locus. Predominantly co-integration of the pyrA- and the pkiA-containing plasmids was found in the cases examined.

The proximal promoter of the aldolase A gene remains active during myogenesis in vitro and muscle development in vivo

The gene for aldolase A in mouse has been shown to be regulated by alternative promoters with attendant alternative first exons. The distal promoter/exon M functions only in muscle while the proximal promoter/exon H is active in early muscle development and in most other tissues. We have analyzed the developmental expression of M and H promoters in mouse throughout myogenesis both in vitro and in vivo. In C2C12 cells RNase protection assays revealed the M promoter is induced within 24 hr of the onset of myogenic differentiation, and both M- and H-specific mRNAs accumulate over 5 days in culture. Nuclear run-on transcription and in situ hybridization with an exon-specific probe demonstrate that the H promoter remains transcriptionally active even in differentiated myotubes. The in vitro results were then compared to similar RNase protection studies of M and H expression during muscle development in vivo. These data show a marked similarity between promoter activation and steady-state transcript accumulation in vivo and in vitro, but within a limited developmental time frame (E15 to 1 week postnatal). In situ hybridizations suggest that simultaneous transcription from both promoters may also occur early in muscle development. Furthermore, the M promoter shows no fiber-type restriction until 1 to 3 weeks postnatally, coincident with muscle maturation, while the H promoter remains transcriptionally active at all stages of development and in all fiber types.

Positive and negative regulation of gene expression by insulin and glucagon: the model of L-type pyruvate kinase gene

L-type pyruvate kinase gene regulation is an excellent model of gene control by hormones and diet. In vivo and ex vivo experiments allowed us to established that thyroid hormones and glucocorticoids act on pyruvate kinase gene expression at the post-transcriptional level. In contrast, glucose and insulin together stimulate transcription of this gene while glucagon inhibits it. Insulin or glucose are individually inefficient and glucagon-dependent transcriptional inhibition seems to be dominant in insulin + glucose-dependent activation. A 14-kbp fragment encompassing the entire pyruvate kinase gene and 3.2-kbp of 5' flanking sequences is expressed in transgenic mice exactly like the endogenous gene; the 3.2-kbp upstream region is sufficient to confer this tissue-specific and hormone/diet-regulated expression to reporter genes. In vivo, DNAse I hypersensitivity analysis revealed the presence of 3 liver-specific groups of hypersensitive sites (HSS). The proximal sites, between + 1 and -183 bp with respect to the start site of transcription, were, in addition, transcription-dependent. The nature and functional role of proteins binding to this proximal upstream sequence were analyzed by in vitro binding and cell free transcription experiments. The existence of more upstream cis-acting elements was investigated by transient transfection assays using differentiated hepatoma cell lines and hepatocytes in primary culture. These experiments permitted the detection of an extinguisher active in hepatoma Hep G2 cells but not in hepatocytes, and of an activating element which could correspond to a distal HSS. Unfortunately, this investigation has not yet allowed us to determine with accuracy the DNA elements responsible for response to diet and hormones.

The structure of the human liver-type phosphofructokinase gene

We have isolated the gene for the human liver-type phosphofructokinase, from upstream to the 5' mRNA terminus to beyond the polyadenylation site. The gene is at least 28 kb long and is divided into 22 exons; it contains conventional splice-junction sequences and one polyadenylation signal. Exons and introns are quite rich in G and C residues; some 60% of all nucleotides are either G or C. Five possible sites of polymorphism have been found. The gene structure reveals no signs of internal similarities despite protein sequence evidence which suggests that the PFK molecule is divided into two similar halves. The structure and organization of the human liver-type PFK gene are shown to be extremely similar to those of the rabbit muscle-type PFK.

Pyruvate kinase deficiency

Pyruvate kinase (PK) deficiency was initially described by Valentine et al. in 1961. Since then, more than 300 cases have been described, including 65 in Japan. PK deficiency is the most common hereditary nonspherocytic hemolytic anemia among several red cell enzyme defects of the Embden-Meyerhof glycolytic pathway. The clinical manifestations are highly variable. Splenectomy usually increases the hemoglobin level by about 2 g/100 mL. Standardization of methods for characterization of PK variants was achieved in 1979. There are four PK isozymes, M1, M2, L and R, in mammalian tissues. We have clarified the switch from M2-type to L-type PK during maturation of erythroid precursor cells. Recently we cloned and sequenced a full length human L-type PK cDNA. It will be useful to clarify the molecular basis of PK deficiency.

Quantitative estimation of minor mRNAs by cDNA-polymerase chain reaction. Application to dystrophin mRNA in cultured myogenic and brain cells

Amplification of the mRNA polymerase chain reaction is a very sensitive technique to detect low-abundance transcripts. We describe in this paper conditions necessary to make this technique quantitative. Quantification is performed in the exponential phase of the amplification process and the results are standardized with respect to those obtained with an exogenous mRNA which is co-reverse-transcribed and co-amplified in the same reaction as the analyzed transcripts. The primers are chosen in different exons to distinguish the amplification of mRNA fragments from the amplification of contaminating DNA. Analysis of the kinetics of amplification and parameters influencing this kinetics shows that: (a) in the exponential phase of amplification, the amount of amplified fragments is proportional to the initial amount of transcripts; (b) in a certain range of length fragment, the yield of amplification is inversely proportional to the length of the amplified fragments. Using this method we have demonstrated that the dystrophin gene is already activated at the myoblastic stage. A quantitative estimation of the transcript showed that the expression of this gene increases strongly in the course of in vitro myogenesis. In primary culture of mouse brain cells, the dystrophin gene was found to be more expressed in neuronal than in glial cells.

Analysis by cell-free transcription of the liver-specific pyruvate kinase gene promoter

A DNA fragment spanning nucleotides -183 to -4 with respect to the cap site of the rat L-type pyruvate kinase (L-PK) gene contains at least four binding sites for putative transcriptional factors: hepatocyte nuclear factor 1 (HNF1), liver factor A1 (LF-A1), nuclear factor 1 (NF1), and major late transcription factor (MLTF). This fragment was used to direct transcription of a reporter sequence (a G-free cassette) in cell extracts. This L-PK promoter was active in liver nuclear extracts, but not in extracts from nonhepatic tissues. A reduction of 50% of the activity was obtained with a deleted L-PK promoter containing only the HNF1-binding site. In contrast, deletion of the HNF1-binding site inactivated the promoter by more than 90%. These results were confirmed by titration experiments with synthetic oligonucleotides. Titration of HNF1 resulted in an 85% decrease of transcriptional activity, while titration of LF-A1 resulted in only a 40% decrease. The influence of NF1 and MLTF seemed to be marginal in this system. The proximal 5'-flanking sequence of the L-PK gene therefore appears to function in vitro as an efficient liver-specific promoter which requires the binding of the liver factor HNF1 and which is also stimulated by the binding of another liver-specific factor, LF-A1.

The primary structure of human liver type phosphofructokinase and its comparison with other types of PFK

The complete mRNA sequence of the human liver-type phosphofructokinase (hPFKL) was determined. The sequence included 55 nucleotides of 5' and 515 of 3' noncoding regions, as well as 2,337 nucleotides encoding the 779 amino acids of the hPFKL. Extensive similarity (approximately 90%) in the coding region was observed between the hPFKL and the mouse PFKL, whereas the degree of similarity between different types of PFK, i.e., hPFKL and human muscle-type PFK (hPFKM), was merely 68%. Nevertheless, striking similarity between these different types of PFK was noticed when the amino acid residues creating the various active sites of the enzyme were compared. Human PFK L- and M-specific probes were constructed and used to quantitate the mRNA levels in fetal and adult brains and fetal liver. It was found that while relative amount of PFKL mRNA in adult brain was one-fourth of that detected in fetal brain the level of PFKM mRNA in adult brain was slightly higher than in fetal tissue, suggesting that PFK expression might be controlled at the transcriptional level.

The liver-specific transcription factor LF-B1 contains a highly diverged homeobox DNA binding domain

The nuclear protein LF-B1 (also referred to as HNF-1) is a transcription activator required for the expression of several liver-specific genes. LF-B1 has been purified to homogeneity from rat liver nuclear extracts. The sequence of the protein has been partially determined and, subsequently, overlapping cDNA clones containing the entire open reading frame of LF-B1 were isolated. The full-length cDNA encodes a 628 amino acid protein and directs the synthesis in vitro of a protein capable of binding DNA with the same specificity as LF-B1. The cDNA was recombined into a vaccinia virus vector and active LF-B1 was obtained from infected HeLa cells. Addition of the vaccinia recombinant protein to rat spleen extracts results in activation of transcription of an LF-B1-dependent promoter. The DNA binding domain of LF-B1 is located in the amino-terminal part of the protein and displays distant structural similarity to the homeobox domain. The distribution of LF-B1 mRNA is restricted to liver, which correlates with the tissue-specific expression of its target genes.

Analysis by cell-free transcription of the liver-specific pyruvate kinase gene promoter

A DNA fragment spanning nucleotides -183 to -4 with respect to the cap site of the rat L-type pyruvate kinase (L-PK) gene contains at least four binding sites for putative transcriptional factors: hepatocyte nuclear factor 1 (HNF1), liver factor A1 (LF-A1), nuclear factor 1 (NF1), and major late transcription factor (MLTF). This fragment was used to direct transcription of a reporter sequence (a G-free cassette) in cell extracts. This L-PK promoter was active in liver nuclear extracts, but not in extracts from nonhepatic tissues. A reduction of 50% of the activity was obtained with a deleted L-PK promoter containing only the HNF1-binding site. In contrast, deletion of the HNF1-binding site inactivated the promoter by more than 90%. These results were confirmed by titration experiments with synthetic oligonucleotides. Titration of HNF1 resulted in an 85% decrease of transcriptional activity, while titration of LF-A1 resulted in only a 40% decrease. The influence of NF1 and MLTF seemed to be marginal in this system. The proximal 5'-flanking sequence of the L-PK gene therefore appears to function in vitro as an efficient liver-specific promoter which requires the binding of the liver factor HNF1 and which is also stimulated by the binding of another liver-specific factor, LF-A1.

Proteins binding to the liver-specific pyruvate kinase gene promoter. A unique combination of known factors

A 183 base-pair fragment of the liver-specific promoter of the L-type puruvate kinase (L-PK) gene has been shown by transfection assay to be sufficient to confer a tissue-specific expression to a reporter gene. The proteins binding in vitro to this fragment have been investigated by a combination of DNase I footprinting, gel retardation of synthetic oligonucleotides and ultraviolet cross-linking. Four proteins from liver nuclear extracts bind to the investigated fragment. They were called, from 3' to 5', L1 to L4 binding factors. The L1 site (nucleotides -95 to -66 with respect to the cap site) binds hepatocyte nuclear factor 1 (HNF1), a liver-specific protein. The L2 site (nucleotides -114 to -97) binds the ubiquitous nuclear factor 1 (NF1), or a related factor. The L3 site (nucleotides -144 to -126) binds liver factor A1 (LF-A1), another liver-specific protein. Finally, the L4 site (nucleotides -168 to -145) binds major late transcription factor (MLTF/USF/UEF), an ubiquitous protein. Each of these proteins has been detected in other liver-specific promoters, but their combination is unique to the liver-specific promoter of the L-PK gene.

The brain-specific gene for rat aldolase C possesses an unusual housekeeping-type promoter

A DNA fragment encompassing the first exon and about 750 bp of the 5'-flanking sequence has been isolated and sequenced. The gene has multiple start sites of transcription which are dispersed over about 200 bp. The promoter lacks TATA and CAAT boxes and is very G + C-rich, with putative binding sites for the transcriptional factors Sp1 and AP2. Similar features are shared with two other brain-specific genes encoding thy-1 antigen and gamma-enolase. The existence of a conserved block of similarity upstream of the human and rat aldolase C genes suggests that this region could be involved in tissue-specific expression whose mechanism seem to be, at least in part, transcriptional.

Illegitimate transcription: transcription of any gene in any cell type

Using in vitro amplification of cDNA by the polymerase chain reaction, we have detected spliced transcripts of various tissue-specific genes (genes for anti-Müllerian hormone, beta-globin, aldolase A, and factor VIIIc) in human nonspecific cells, such as fibroblasts, hepatoma cells, and lymphoblasts. In rats, erythroid- and liver-type pyruvate kinase transcripts were also detected in brain, lung, and muscle. The abundance of these "illegitimate" transcripts is very low; yet, their existence and the possibility of amplifying them by the cDNA polymerase chain reaction provide a powerful tool to analyze pathological transcripts of any tissue-specific gene by using any accessible cell.

Transfection of hepatic genes into adult rat hepatocytes in primary culture and their tissue-specific expression

We describe in this paper a method for studying transient gene expression in a primary culture of adult rat hepatocytes. After isolation by collagenase perfusion, hepatocytes in a monolayer were transfected with foreign DNA by the calcium phosphate precipitation technique during the first 24 hours after plating. When they were transfected with a plasmid containing the gene for chloramphenicol acetyltransferase driven by the early promoter of simian virus 40, hepatocytes reproducibly expressed high levels of chloramphenicol acetyltransferase (CAT); this transient expression was much higher than that obtained with the rat hepatoma cell line H4II. Different medium conditions have been tested; an optimal level of CAT activity can be obtained using a serum-free, hormonally defined medium. Using these techniques, we have investigated the expression of liver-specific genes transferred into hepatocytes. We show that the L-pyruvate kinase promoter is active in these hepatocytes while it is silent in fibroblasts. Moreover, the use of serum-free medium may allow investigation of the role of hormones and nutrients in cells which respond normally to these effectors.

Human M2-type pyruvate kinase: cDNA cloning, chromosomal assignment and expression in hepatoma

Two overlapping clones, covering the entire coding sequence of human M2-type pyruvate kinase (PK) cDNA, were isolated and sequenced. Nucleotide sequencing results showed that they contained the 109-bp 5'-untranslated region, the 1593-bp coding region and the 585-bp 3'-untranslated region. Nucleotide sequence homology was 90% and 69% with rat M2-type and L-type PK cDNA, respectively. In situ hybridization using the human M2-type PK cDNA probe disclosed that the gene for M2-type PK is located at band q22 on chromosome 15. Northern blot analysis with RNA from human hepatoma demonstrated that M2-type PK was predominantly expressed in hepatoma cells, whereas L-type PK was preferentially expressed in the non-tumor portion of the liver.

Structure of the Aspergillus nidulans pyruvate kinase gene

The complete nucleotide sequence of the Aspergillus nidulans pyruvate kinase gene, including its flanking sequences, is presented. The gene has a 1,578 bp coding sequence that encodes a protein of 526 amino acids; the latter is strongly homologous to the pyruvate kinases found in Saccharomyces cerevisiae (66%) and mammals (53%). The gene is interrupted by seven introns, three of which are in a conserved position compared to those present in the mammalian pyruvate kinase genes sequenced thus far. A fourth intron within the mononucleotide binding fold domain is in a conserved position with respect to the position of an intron within the NAD+ binding region of maize ADH I. The transcription start site has been determined; a major site of transcription was found 80 bp before the translation initiation codon. The promoter region of the A. nidulans pyruvate kinase gene contains no direct homologies with the TATA or CCAAT sequences in the expected region (30-70 bp) before the transcription initiation site. However, extended CT-enriched regions are found in the promotor region, similar to what has been observed in genes that are highly expressed in Saccharomyces cerevisiae and filamentous fungi.

Purified hepatocyte nuclear factor 1 interacts with a family of hepatocyte-specific promoters

During development cell types arise through the activation or repression of classes of specific genes. One hypothesis is that this phenomenon is realized by tissue-specific factors playing a role at the transcription level. Recently we have described a liver-specific nuclear protein, hepatocyte nuclear factor 1, that appears to be involved in the transcription of the fibrinogen and alpha 1-antitrypsin genes. In this report we describe the purification of hepatocyte nuclear factor 1 and demonstrate that it interacts with essential promoter regions of many liver-specific genes, including albumin, alpha-fetoprotein, and transthyretin. This finding suggests that hepatocyte nuclear factor 1 could be one factor necessary for establishing the liver phenotype. We also show that this protein binds to the promoter of the surface-antigen gene of the hepatitis B virus, a virus characterized by a high degree of hepatotropism.

Transcription of the dystrophin gene in human muscle and non-muscle tissue

The gene that is defective in patients with Duchenne and Becker muscular dystrophy consists of about 60 short exons scattered along a gigantic DNA region that spans some 2 megabase pairs. The encoded protein, dystrophin, was recently characterized as a component of muscle intracellular membranes of low abundance. The dystrophin messenger RNA is difficult to study in both normal and pathological tissue specimens because it is large (14 kilobases) and scarce (0.01-0.001% of total muscle mRNA). We report here that efficient in vitro co-amplifications of the mRNAs of the dystrophin gene and of a reporter gene, aldolase A, by the polymerase chain reaction procedure enables us to obtain a quantitative estimate of the dystrophin gene transcript. A processed, transcribed segment was thus detected in 13 different human tissues. It ranged from 0.02-0.12% of total mRNA in skeletal muscle to 25,000 times less in lymphoblastoid cells.

Human liver type pyruvate kinase: complete amino acid sequence and the expression in mammalian cells

Pyruvate kinase (PK) has four isozymes (L, R, M1, M2) that are encoded by two different genes. Among these isozymes, abnormalities of liver (L)-type PK is considered to be associated with hereditary nonspherocytic hemolytic anemia in humans. We isolated and determined the full-length sequence of human L-type PK cDNA. The cDNA contains 1629 base pairs encoding 543 amino acids, 68 base pairs of 5'-noncoding sequence, and 734 base pairs of 3'-noncoding sequence. The similarity between human and rat L-type PK was 86.9% at the nucleotide sequence level and 92.4% at the amino acid sequence level. The full-length L-type PK cDNA was placed under the promoter of simian virus 40 and introduced into monkey COS cells. Human L-type PK activity was detected in the extract of COS cells by the classical PK electrophoresis method.