Multiple Cis-regulatory Elements Research Articles

Multiple cis-regulatory elements regulate distinct and complex patterns of developmental and wound-induced expression of Arabidopsis thaliana 4CL gene family members

Lignin is an important biopolymer that is deposited in secondary cell walls of plant cells (e.g., tracheary elements) and in response to stresses such as wounding. Biosynthesis of lignin monomers occurs via the phenylpropanoid pathway, in which the enzyme 4-coumarate:CoA ligase (4CL) plays a key role by catalyzing the formation of hydroxycinnamoyl-CoA esters, subsequently reduced to the corresponding monolignols (hydroxycinnamoyl alcohols). 4CL is encoded by a family of four genes in Arabidopsis thaliana (At4CL1-At4CL4), which are developmentally regulated and co-expressed with other phenylpropanoid genes. We investigated in detail the wound-induced expression of At4CL1-At4CL4, and found that At4CL1 and At4CL2 mRNA accumulation follows biphasic kinetics over a period of 72 h, while At4CL4 expression is rapidly activated for a period of at least 12 h before declining. In order to localize cis-regulatory elements involved in the developmental and wound-induced regulation of the At4CL gene family members, At4CL promoter-beta-glucuronidase (GUS) reporter gene fusions were constructed and transferred into Arabidopsis plants. Analysis of these plants revealed that the promoter fragments direct discrete and distinct patterns of expression, some of which did not recapitulate expected patterns of wound-induced expression. The locations of regulatory elements associated with the At4CL2 gene were investigated in detail using a series of transgenic Arabidopsis plants containing promoter fragments and parts of the transcribed region of the gene fused to GUS. Positive and negative regulatory elements effective in modulating developmental expression or wound responsiveness of the gene were located both in the promoter and transcribed regions of the At4CL2 gene.

Biased dA/dT somatic hypermutation as regulated by the heavy chain intronic iEμ enhancer and 3′Eα enhancers in human lymphoblastoid B cells

Somatic hypermutation (SHM) in immunoglobulin gene (Ig) variable (V) regions is critical for the maturation of the antibody response. It is dependent on the expression of activation-induced cytidine deaminase (AID) and translesion DNA polymerases in germinal center B cells as well as Ig V transcription, as regulated by the Ig heavy chain (H) intronic enhancer (iEμ) and the 3′ enhancer (3′Eα) region. We analyzed the role of these cis elements in SHM by stably transfecting Ramos human lymphoblastoid B cells with a rearranged human IgH chain VD (diversity) J (joining) DNA construct containing a V H promoter at the 5′ end and C H1 and C H2 exons of Cγ1 at the 3′ end. In this construct, mutations preferentially targeted dA/dT basepairs in the RGYW/WRCY hotspot. Most of the dA/dT mutations and accompanying dC/dG mutations were transitions. Deletion of iEμ resulted in decreased SHM which could be partially restored by insertion of the IgH hs1,2 enhancer. Other two 3′Eα enhancers, hs3-hs4, did not significantly increase the mutation frequency, but further strengthened the dA/dT bias. The frequency and spectrum of the mutations were independent of the genomic integration of the transgene or V gene transcription level. Thus, we have established a novel in vitro system to analyze SHM and identify the role of multiple cis-regulatory elements in regulating dA/dT biased SHM. This model system will be useful to further address the role of other cis-regulating elements and recruited trans- acting factors in expressing the modalities of SHM.

Synergistic activation of the insulin gene promoter by the β-cell enriched transcription factors MafA, Beta2, and Pdx1

Specific expression of the insulin gene in pancreatic islet β-cells requires multiple cis-regulatory elements in its promoter. Pdx1, MafA, and Beta2 have been identified as β-cell enriched transcription factors that bind to these elements. Pdx1 has been shown to bind to A1, A3, A5, and GG2, and Beta2 binds to E1 by forming a heterodimer with the ubiquitous factor E47. MafA was recently identified as a C1-element binding factor. However, interactions between these factors and the promoter have not been characterized in detail. In this report, we show that these transactivators synergistically stimulate insulin promoter activity. Among multiple binding sites for Pdx1, MafA, and Beta2, at least GG2, C1, and E1 elements located in the promoter region between −150 and −100 base pairs are necessary for the synergism. We also found that neither MafB nor c-Maf, close relatives of MafA, showed synergistic activation. These results suggest that co-expression and functional synergism of these β-cell enriched transactivators, MafA, Pdx1, and Beta2, are critical for establishing the β-cell-specific and efficient expression of the insulin gene.

Multiple cis-regulatory elements and the yeast sulphur regulatory network are required for the regulation of the yeast glutathione transporter, Hgt1p

HGT1 encodes a high-affinity glutathione transporter in the yeast Saccharomyces cerevisiae that is induced under sulphur limitation. The present work demonstrates that repression by organic sulphur sources is under the control of the classic sulphur regulatory network, as seen by the absence of expression in a met4delta background. Cysteine appeared to be the principal regulatory molecule, since elevated levels were seen in str4delta strains (deficient in cysteine biosynthesis) that could be repressed by elevated levels of cysteine, but not by methionine or glutathione. Investigations into cis-regulatory elements revealed that the previously described motif, a 9-bp cis element, CCGCCACAC, located at the -356 to -364 region of the promoter could in fact be refined to a 7-bp CGCCACA motif that is also repeated at -333 to -340. The second copy of this motif was essential for activity, since mutations in the core region of the second copy completely abolished activity and regulation by sulphur sources. Activity, but not regulation, could be restored by reintroducing an additional copy upstream of the first copy. A third region, GCCGTCTGCAAGGCA, conserved in the HGT1 promoters of the different Saccharomyces spp, was observed at -300 to -285 but, while mutations in this region did not lead to any loss in repression, the basal and induced levels were significantly increased. In contrast to a previous report, no evidence was found for regulation by the VDE endonuclease. The strong repression at the transport level by glutathione seen in strains overexpressing HGT1 was due to a glutathione-dependent toxicity in these cells.

Spatial organization of gene expression: the active chromatin hub.

Developmental and tissue-specific expression of higher eukaryotic genes involves activation of transcription at the appropriate time and place and keeping it silent otherwise. Unlike housekeeping genes, tissue-specific genes generally do not cluster on the chromosomes. They can be found in gene-dense regions of chromosomes as well as in regions of repressive chromatin. Depending on the location, shielding against positive or negative regulatory effects from neighboring chromatin may be required and hence insulator and boundary models were proposed. They postulate that chromosomes are partitioned into physically distinct expression domains, each containing a gene or gene cluster with its cis-regulatory elements. Specialized elements at the borders of such domains are proposed to prevent cross-talk between domains, and thus to be crucial in establishing independent expression domains. However, genes and associated cis-acting sequences often do not occupy physically distinct domains on the chromosomes. Rather, genes can overlap and cis-acting sequences can be found tens or hundreds of kilobases away from the target gene, sometimes with unrelated genes in between. Therefore the ability of a gene to communicate with positive cis-regulatory elements rather than the presence of specialized boundary elements appears to be key to establishing an independent expression profile. Our recent finding that active beta-globin genes physically interact in the nuclear space with multiple cis-regulatory elements, with inactive genes looping out, has provided a potential mechanistic framework for this model. We refer to such a spatial unit of regulatory DNA elements as an active chromatin hub (ACH). We propose that productive ACH formation underlies correct gene expression, requiring the presence of protein factors with the appropriate affinities for each other bound to their cognate DNA sequences. Proximity and specificity determines which cis-acting sequences and promoter(s) form an ACH, and thus which gene will be expressed. Other regulatory sequences can interfere with transcription by blocking the appropriate physical interaction between an enhancer and promoter in the ACH. Possible mechanisms by which distal DNA elements encounter each other in the 3D nuclear space will be discussed.

Expression and promoter analysis of SLC19A2 in the human intestine

The molecular mechanism and regulation of the intestinal uptake process of dietary thiamine is not well understood. Previous studies have established the involvement of a carrier-mediated system for thiamine uptake in the human intestine. Recently a human thiamine transporter, SLC19A2, was cloned from a number of human tissues. Little, however, is known about expression of the SLC19A2 message along the native human gastrointestinal tract, and no analysis of its promoter in intestinal tissue is available. Therefore, the current studies were aimed at investigating the expression of SLC19A2 in the human gastrointestinal tract and at analyzing the promoter of this potential intestinal thiamine transporter. First we cloned SLC19A2 cDNA from a human intestinal cell line (Caco-2) by reverse transcriptase–polymerase chain reaction, then used this cDNA as a probe in Northern blot analysis. SLC19A2 message was found to be expressed in all gastrointestinal tissues in the following order: liver>stomach>duodenum>jejunum>colon>cecum>rectum>ileum. SLC19A2 was also expressed at the protein level in Caco-2 cells and in native human small intestine by Western blot analysis. We also cloned the 5′-regulatory region of the SLC19A2 gene and confirmed activity of its promoter following transfection into intestinal epithelial Caco-2 cells. Furthermore, we identified the minimal promoter region required for basal activity of SLC19A2 in these cells which was found to be mainly encoded in a sequence between −356 and −36, and included multiple cis-regulatory elements. Transcription initiation sites of the SLC19A2 gene in intestinal epithelial Caco-2 cells were also identified by 5′-rapid amplification of cDNA ends. These results demonstrate that SLC19A2 is expressed in various regions of the human gastrointestinal tract. In addition, the results provide the first characterization of the SLC19A2 promoter. These findings raise the possibility that SLC19A2 may play a role in the normal intestinal thiamine absorption process.

Transcriptional Regulation of the Human PAX6 Gene Promoter

PAX6, a member of the highly conserved paired-type homeobox gene family, is expressed in a spatially and temporally restricted pattern during early embryogenesis, and its mutation is responsible for human aniridia. Here we examined the transcriptional regulation of the PAX6 gene by transient transfection assays and identified multiple cis-regulatory elements that function differently in different cell lines. The transcriptional initiation site was identified by RNase protection and primer extension assay. Examination of the genomic DNA sequence indicated that the PAX6 promoter has a TATA like-box (ATATTTT) at -26 base pairs (bp), and two CCAAT boxes are positioned at -70 and -100 bp. A 38-bp poly(CA) sequence was located 992 bp upstream from the initiation site. Transient transfection assays in glioblastoma cells and leukemia cells indicate that a 92-bp region was required for basal level PAX6 promoter activity. A negative transcriptional element, silencer (bases -1518 to -1268), functioned differently in different cell lines. The activation of the promoter is positively correlated with the expression of PAX6 transcripts in all cells tested. These results indicate that a cis-regulatory element or elements is responsible for selective activation of the PAX6 promoter in cells that can express PAX6 mRNA.

Characterization of the human surfactant protein D promoter: transcriptional regulation of SP-D gene expression by glucocorticoids.

We have previously described the characterization of genomic clones encoding the entire translated sequence of human pulmonary surfactant protein D (SP-D). We now describe the characterization of a genomic fragment (H5E7) that encodes the entirety of the first translated exon (Exon 2), Intron 1, a short transcribed untranslated sequence (Exon 1; 39 bp), and approximately 4 kb of sequence upstream from the transcription initiation site. The start site was identified by 5'-RACE-PCR cloning and primer extension. A putative TATA box (CATAAATA) was identified approximately 30 bp upstream of the start site. Complete sequencing of a HindIII/SacI fragment (HS-1674) encoding approximately 1.7 kb of sequence 5' to the TATA demonstrated multiple potential cis-regulatory elements including half-site glucocorticoid response elements (GRE), a canonical AP-1 consensus, several AP-1 like sequences, E-box sequences, NF-IL-6 and PEA3 motifs, and putative interferon response elements. H441 lung adenocarcinoma cells, which express low levels of SP-D mRNA, and liver HepG2 cells, were transiently co-transfected with chloramphenicol acetyl transferase (CAT) reporter constructs containing up to 3,000 base pairs of upstream sequence, and with constructs encoding beta-gal. H441 cells transfected with constructs containing at least 161 bp of upstream sequence gave normalized levels of CAT activity greater than or equal to that obtained for parallel positive control transfections using pTK-CAT. Treatment of the cells for 48 h with 50 nM dexamethasone (Dex) gave a 2- to 5-fold increase in CAT activity. Interestingly, a 5'-deletion construct containing 161 bp of upstream sequence (pFS161-CAT) conferred both cell type-restricted and dexamethasone-responsive expression. These studies emphasize the potential complexity of SP-D gene regulation, and further support the hypothesis that the effects of glucocorticoids on SP-D production in vivo are regulated at the level of transcription.

Transcription of tobacco phytochrome-A genes initiates at multiple start sites and requires multiple cis-acting regulatory elements.

Promoter regions of the Nicotiana tabacum PHYA1 and PHYA2 genes display 89% sequence identity. Analysis of the 5' ends of both the PHYA1 and the PHYA2 transcript revealed multiple, distinct mRNA species, each differing in length and in abundance. The levels of the major PHYA1, PHYA2 transcripts were found to be auto-regulated by phytochrome. This auto-regulation was most efficient in 2-8-day old seedlings. Furthermore, we examined the expression pattern of the PHYA1-GUS reporter gene, containing a 4700 bp PHYA1 promoter fragment or its 5'-deletion derivatives, by GUS histochemistry and by RNase protection assays in transgenic tobacco plants. Our data indicate that the PHYA1 promoter contains three regions which are necessary for the maximum level and regulated expression. We show that a 264 bp promoter fragment contains a cis-regulatory element(s) responsible for expression in the root tips of transgenic seedlings. The major cis-regulatory elements required for high-level transcription and expression in other organs are located in separate regions of the PHYA1 promoter. These data indicate the contribution of multiple cis-regulatory elements for the maximum and regulated expression of tobacco genes coding for phytochrome A protein.

Promoter of the POU-M1/SGF-3 gene involved in the expression of Bombyx silk genes.

To characterize the transcription regulation of the POU-M1/SGF-3 gene, we have cloned a genomic DNA fragment encompassing the whole coding region and its flanking sequences. This gene does not contain any intron. The 5'-flanking region of the gene contains several interesting motifs, such as homeodomain-binding motifs, sequences resembling the transcriptional factor Sp1-binding site, and TGTTT motifs, but lacks some of the typical transcriptional regulatory sequences, such as TATA and CCAAT boxes. Transcriptional analysis of a series of deletion mutants of the gene in the nuclear extracts prepared from the middle silk gland of 2-day-old fifth instar larvae revealed the presence of multiple cis-regulatory elements located both upstream and downstream of the initiation site. One of these elements, the homeodomain-binding element, was identified to mediate negative regulation. By mobility shift assay using the POU-M1 specific antibodies, we found that this negative element interacts with the POU-M1/SGF-3. Transcription analysis in vitro using templates mutagenized in the PB region and one of the POU-M1 antibodies indicated that the PB region is an autoregulatory element responsible for SGF-3-dependent transcriptional repression.

Deformed autoregulatory element from Drosophila functions in a conserved manner in transgenic mice

The striking similarities in the structure, organization and anterior-posterior expression patterns between the murine Hox gene system and the Drosophila homeotic gene complexes, called HOM-C (ref. 3), may point to highly conserved mechanisms for specifying positional identities (reviewed in ref. 4). Strong support for this concept lies in the observation of conserved colinearity between the genomic order of the Hox/HOM genes and their unique successive expression domains along the anterior-posterior axes of both mouse and fly embryos. These unique and precise expression patterns appear to be facilitated by multiple cis-regulatory elements (reviewed in ref. 5). One of the few elements characterized in detail is the autoregulatory enhancer of the homeotic gene Deformed (Dfd), which supports expression in subregions of posterior head segments of Drosophila embryos. Here we present evidence that this enhancer is capable of conferring reporter gene expression to a discrete subregion of the hindbrain in transgenic mouse embryos. Remarkably, this anterior-posterior subregion lies within the common anterior expression domain of the Dfd cognate Hox genes in the postotic hindbrain. Our results indicate that the Dfd autoregulatory enhancer is part of a highly conserved mechanism for establishing region-specific gene expression along the anterior-posterior axis of the embryo.

The myosin gene switching in human cardiac hypertrophy.

Cardiac hypertrophy is associated with qualitative as well as quantitative changes in myocardial cells. To analyze the molecular basis of isozymic transitions of cardiac myosins in response to pressure overload, we have constructed and characterized two types of myosin heavy chain (MHC) cDNA clones, specifying alpha- and beta-MHCs, and two types of myosin alkali light chain cDNA clones, complementary to atrial type (ALC1) and ventricular type (VLC1) mRNAs from a human fetal heart cDNA library. Using the S1 nuclease mapping procedure, we showed that the MCH isozymic transitions from alpha- to beta-MHC in the pressure overloaded atria are produced by changes in the relative level of alpha- and beta-MHC gene expression. In addition, we observed that the expression of VLC1 gene is also induced in the atria subjected to severe pressure overload. Thus, it appears that the increased expression of VLC1 gene, together with the isogene switch from alpha- to beta-MHC gene, may participate in the adaptation of myocardium to new functional requirement. Then, to get a better understanding of the genetic mechanisms involved in the regulation of isogene expression, we have isolated and sequenced genomic clone for VLC1 isoform. Sequence analysis has identified multiple potential cis regulatory elements within a 686-bp upstream region. This region includes 28-bp alternating purine/pyrimidine sequences and two segment exhibiting homology to consensus sequence proposed for viral and cellular enhancer elements. In particular, a comparison of the VLC1 upstream gene sequence with those available for several muscle-specific genes revealed that CC(A + T-rich)6GG elements and CATTCCT sequence are conserved. These results suggested that CArG box (-96 to -87) has an important role in the positive regulation of the VLC1 gene and this element may be involved in the co-regulation of VLC1 and cardiac alpha-actin genes.

Tissue-specific regulation of human alpha 1-antitrypsin gene expression in transgenic mice.

The 5'-flanking sequence of the human alpha 1-antitrypsin (AAT) gene contains multiple cis-regulatory elements, including a distal enhancer and proximal sequences essential for its transcription in cultured hepatoma cells. To understand better the promoter specificity of the AAT gene in vivo, transgenic mice harboring the AAT-SV40 hybrid promoter or the natural AAT promoter fused to a reporter gene (CAT) were generated. Examination of CAT activity in various tissues indicated that the CAT gene was expressed primarily in the liver and also, to a lesser extent, in tissues known to express the AAT gene. In addition, the cis-acting elements of the human AAT gene were utilized to drive the transcription of the SV40 T antigen gene in transgenic mice. Hepatocellular malignancy was found in all founder animals examined, while sporadic occurrence of malignancy was also observed in stomach, pancreas, and kidney. These results verify that the 5'-flanking region of the human AAT gene contains cis-regulatory elements sufficient to confer tissue specificity in vivo.

Multiple cis Regulatory Elements for Maximal Expression of the Cauliflower Mosaic Virus 35S Promoter in Transgenic Plants

Multiple cis Regulatory Elements for Maximal Expression of the Cauliflower Mosaic Virus 35S Promoter in Transgenic Plants

Multiple cis regulatory elements for maximal expression of the cauliflower mosaic virus 35S promoter in transgenic plants.

The 35S promoter is a major promoter of the cauliflower mosaic virus that infects crucifers. This promoter is still active when excised from cauliflower mosaic virus and integrated into the nuclear genome of transgenic tobacco. Previous work has shown that the -343 to -46 upstream fragment is responsible for the majority of the 35S promoter strength (Odell, J.T., Nagy, F., and Chua, N.-H. [1985]. Nature 313, 810-812). Here we show by 5', 3', and internal deletions that this upstream fragment can be subdivided into three functional regions, -343 to -208, -208 to -90, and -90 to -46. The first two regions can potentiate transcriptional activity when tested with the appropriate 35S promoter sequence. In contrast, the -90 to -46 region by itself has little activity but it plays an accessory role by increasing transcriptional activity of the two distal regions. Finally, we show that monomers and multimers of a 35S fragment (-209 to -46) can act as enhancers to potentiate transcription from a heterologous promoter.

In vitro analysis of the Antennapedia P2 promoter: identification of a new Drosophila transcription factor.

We have investigated the transcriptional regulation of the Antennapedia P2 (Antp P2) promoter using nuclear extracts prepared from Drosophila embryos. Transcriptional analysis of deletion mutants reveals the presence of multiple cis-regulatory elements located both upstream and downstream of the start site. One of the elements appears to mediate negative regulation, since deletion of this element results in higher levels of transcription. Several factors that interact with these control elements have been detected and isolated. One DNA-binding protein, Drosophila Transcription Factor-1 (DTF-1), specifically recognizes the consensus sequence GCAACAT/CG/C that is reiterated four times within an upstream activating element. DTF-1 was purified by sequence-specific DNA affinity chromatography and identified as a doublet of approximately 50 kD. Purified DTF-1 enhances transcription from the Antp P2 promoter 7- to 15-fold in a binding site-dependent manner.

Amplification of a chorion gene cluster in Drosophila is subject to multiple cis-regulatory elements and to long-range position effects

We have used P-element transformation to study cis-acting elements involved in the control of amplification of the third chromosome chorion gene cluster (66D12-15) in Drosophila melanogaster. To reduce position effects large fragments (5.7 to 12 kb; kb = 10 3 bases) of chorion DNA and the 7.2 kb ry + fragment were used to “buffer” these putative elements from sequences at the insertion site. Nevertheless, even the longest constructs were profoundly affected by the insertion sites and showed amplification levels ranging from undetectable to higher than in the endogenous locus. Any amplification was tissue and temporally correct and extended into the neighboring ry + sequences. Analysis of amplification levels at various points along two constructs bearing the same 10 kb chorion insert in opposite orientations showed maximal levels occurring at one end of the chorion fragment, irrespective of whether that end was buffered at the middle of the transposon or exposed close to the insertion site. The maximally amplifying region encompasses the amplification control element (ACE), which has been shown to be necessary for amplification, in agreement with its putative role as a replication origin. We have additionally identified amplification-enhancing elements present elsewhere in the 10 kb chorion fragment, which are needed for attainment of high copy number. These elements, distinct from the ACE, have been only coarsely localized within two 2.25 to 2.3 kb regions. Some interesting sequence similarities between these two regions and the ACE element are pointed out.

Tissue-specific expression of the human alpha 1-antitrypsin gene is controlled by multiple cis-regulatory elements.

Human alpha 1-antitrypsin (AAT) is expressed in the liver, and a 318 bp fragment immediately flanking the CAP site of the gene was found to be sufficient to drive the expression of a reporter gene (CAT) specifically in hepatoma cells. The enhancing activity however, was orientation-dependent. The DNA fragment was separated into a distal region and a proximal region. A "core enhancer" sequence GTGGTTTC is present within the distal region and is capable of activity enhancement in both orientations when complemented by the proximal region in the sense orientation. The results strongly suggest that there are multiple cis-acting elements in the human AAT gene that confer cell specificity for its expression. Nuclear proteins prepared from the hepatoma cells bound specifically to the proximal region in a band-shifting assay that was resistant to competition by the globin promoter DNA. Foot-printing analysis showed a protected domain within the proximal region that contains a nearly perfect palindromic sequence TGGTTAATATTCACCA, which may be important in the regulation of AAT expression in the liver.