Human beta-globin promoter and coding sequences transcribed by RNA polymerase III

Identification of nucleotide sequences and some proteins involved in polyadenylation of RNA transcribed by Pol III from SINEs

We have previously reported that not only transcripts of RNA polymerase II (pol II), but also one type of RNA transcribed by RNA polymerase III (pol III), undergo AAUAAA-dependent polyadenylation. Such an unusual feature is inherent in Short Interspersed Elements (SINEs) from genomes of certain mammals. For polyadenylation of its transcript, SINE should contain, besides an AATAAA hexamer and a transcription terminator, two specific regions: β, located downstream of box B of a promoter, and τ, preceding AATAAA. Here, using nucleotide substitutions in SINEs B2 (mouse) and Ves (bat), we identified nucleotides of β regions necessary for polyadenylation of their transcripts. These sequences (β signals) are the following: ACCACATgg in B2 and GGGCATGT in Ves. Using this approach, we identified τ signal of SINE B2 (GCTACagTGTACTTACAT), where TGTA tetramer is most important for polyadenylation. In Ves, τ region is a long polypyrimidine motif which is able to interact with PTB protein in Ves transcripts. We demonstrated by knockdown that B2 and Ves transcript polyadenylation is performed by canonical poly(A) polymerase with the participation of proteins CSPF-160 and Fip1, the known factors of mRNA polyadenylation. We also showed that a factor CFIm partaking in polyadenylation of many mRNAs, is involved only in polyadenylation of B2 transcripts. CFIm seems to interact with τ signal of В2 RNA and thereby facilitates the recruiting of other proteins engaged in polyadenylation. Thus, SINEs utilize at least some proteins involved in polyadenylation of pol II transcripts to polyadenylate their pol III transcripts.

Principles of miRNA-target regulation in metazoan models

MicroRNAs (miRs) are key post-transcriptional regulators that silence gene expression by direct base pairing to target sites of RNAs. They have a wide variety of tissue expression patterns and are differentially expressed during development and disease. Their activity and abundance is subject to various levels of control ranging from transcription and biogenesis to miR response elements on RNAs, target cellular levels and miR turnover. This review summarizes and discusses current knowledge on the regulation of miR activity and concludes with novel non-canonical functions that have recently emerged.

alpha-Amanitin resistance is developmentally regulated in carrot

Carrot cells are capable of inactivating alpha-amanitin only in embryogenic conditions (regenerating cells and embryoids). Instead, the mutant line a3 is capable of inactivating the drug also in nonembryogenic conditions (vegetative growth). The mutation is dominant in somatic hybrids and is pleiotropic, allowing expression during vegetative growth of other embryonal functions. The inactivation of alpha-amanitin is due to the oxidative activity of tyrosinase.

TLS inhibits RNA polymerase III transcription

RNA transcription by all the three RNA polymerases (RNAPs) is tightly controlled, and loss of regulation can lead to, for example, cellular transformation and cancer. While most transcription factors act specifically with one polymerase, a small number have been shown to affect more than one polymerase to coordinate overall levels of transcription in cells. Here we show that TLS (translocated in liposarcoma), a protein originally identified as the product of a chromosomal translocation and which associates with both RNAP II and the spliceosome, also represses transcription by RNAP III. TLS was found to repress transcription from all three classes of RNAP III promoters in vitro and to associate with RNAP III genes in vivo, perhaps via a direct interaction with the pan-specific transcription factor TATA-binding protein (TBP). Depletion of TLS by small interfering RNA (siRNA) in HeLa cells resulted in increased steady-state levels of RNAP III transcripts as well as increased RNAP III and TBP occupancy at RNAP III-transcribed genes. Conversely, overexpression of TLS decreased accumulation of RNAP III transcripts. These unexpected findings indicate that TLS regulates both RNAPs II and III and supports the possibility that cross-regulation between RNA polymerases is important in maintaining normal cell growth.

Chromatin structure analyses identify miRNA promoters

Although microRNAs (miRNAs) are key regulators of gene expression in normal human physiology and disease, transcriptional regulation of miRNAs is poorly understood, because most miRNA promoters have not yet been characterized. We identified the proximal promoters of 175 human miRNAs by combining nucleosome mapping with chromatin signatures for promoters. We observe that one-third of intronic miRNAs have transcription initiation regions independent from their host promoters and present a list of RNA polymerase II- and III-occupied miRNAs. Nucleosome mapping and linker sequence analyses in miRNA promoters permitted accurate prediction of transcription factors regulating miRNA expression, thus identifying nine miRNAs regulated by the MITF transcription factor/oncoprotein in melanoma cells. Furthermore, DNA sequences encoding mature miRNAs were found to be preferentially occupied by positioned-nucleosomes, and the 3' end sites of known genes exhibited nucleosome depletion. The high-throughput identification of miRNA promoter and enhancer regulatory elements sheds light on evolution of miRNA transcription and permits rapid identification of transcriptional networks of miRNAs.

Non-coding transcripts far upstream of the epsilon-globin gene are distinctly expressed in human primary tissues and erythroleukemia cell lines

Non-coding exons of epsilon-globin mRNA originating within the 236 kb upstream region of the epsilon-globin gene were identified in human primary tissues and K562 cells. One predominant type of upstream epsilon mRNA, which originated in the -76 kb region 5' to the epsilon gene, was present in human primary tissues, whereas 11 other isoforms were identified in K562 cells. Fragment from the -76 kb region possessed promoter activity and a prominent DNase I hypersensitive site was formed in the region approximately 2 kb 5' to the -76 kb promoter in human fetal liver, but not in K562 cells. The promoter activity in the -236 kb region resided in a retrotransposon in K562 cells. A DNase I hypersensitive site was formed at the -236 kb promoter in K562 cells, but not in human fetal liver. We discussed these results in the context of intergenic transcription and chromatin opening in the beta-globin gene cluster.

Unusual properties of adenovirus E2E transcription by RNA polymerase III

In adenovirus type 5-infected cells, RNA polymerase III transcription of a gene superimposed on the 5' end of the E2E RNA polymerase II transcription unit produces two small (<100-nucleotide) RNAs that accumulate to low steady-state concentrations (W. Huang, R. Pruzan, and S. J. Flint, Proc. Natl. Acad. Sci. USA 91:1265-1269, 1984). To gain a better understanding of the function of this RNA polymerase III transcription, we have examined the properties of the small E2E RNAs and E2E RNA polymerase III transcription in more detail. The accumulation of cytoplasmic E2E RNAs and the rates of E2E transcription by the two RNA polymerases during the infectious cycle were analyzed by using RNase T(1) protection and run-on transcription assays, respectively. Although the RNA polymerase III transcripts were present at significantly lower concentrations than E2E mRNA throughout the period examined, E2E transcription by RNA polymerase III was found to be at least as efficient as that by RNA polymerase II. The short half-lifes of the small E2E RNAs estimated by using the actinomycin D chase method appear to account for their limited accumulation. The transcription of E2E sequences by RNA polymerase II and III in cells infected by recombinant adenoviruses carrying ectopic E2E-CAT (chloramphenicol transferase) reporter genes with mutations in E2E promoter sequences was also examined. The results of these experiments indicate that recognition of the E2E promoter by the RNA polymerase II transcriptional machinery in infected cells limits transcription by RNA polymerase III, and vice versa. Such transcriptional competition and the properties of E2E RNAs made by RNA polymerase III suggest that the function of this viral RNA polymerase III transcription unit is unusual.

Characterization and chromosomal mapping of two pseudogenes of the mouse Pafaha/Lis1 gene: retrointegration hotspots in the mouse genome

Isolated lissencephaly sequence and Miller-Dieker syndrome are related neurodevelopmental disorders caused by defects of the LIS1 gene encoding the alpha subunit of intracellular platelet-activating factor acetylhydrolase. In addition to the ortholog of the human LIS1 gene (Pafaha/Lis1), the mouse genome contains two more homologs. In order to characterize the new members of this gene family, we isolated both Pafaha/Lis1-related genes (Pafaha-ps1 and Pafaha-ps2) from a mouse genomic library. Pafaha-ps1 and Pafaha-ps2 are processed pseudogenes formed by the retroinsertion of 5'-truncated Pafaha/Lis1 cDNAs. Sequence analysis revealed a striking accumulation of retroelements at both loci, identifying two retroinsertion hotspots in the mouse genome. The recognition of tRNA genes flanking Pafaha-ps1 provides an example for the potential association of RNA polymerase III transcription and retroinsertion in mammals. Linkage mapping placed Pafaha-ps1 and Pafaha-ps2 to distal chromosome (Chr) 3 and proximal Chr 7, respectively. Our results indicate that only one of the three LIS1-related mouse loci (Pafaha/Lis1) is functional, in contrast with two closely related functional genes (LIS1 and LIS2) reported in humans. 1998 Elsevier Science B.V.

The consensus sequence of a major Alu subfamily contains a functional retinoic acid response element

Alu repeats are interspersed repetitive DNA elements specific to primates that are present in 500,000 to 1 million copies. We show here that an Alu sequence encodes functional binding sites for retinoic acid receptors, which are members of the nuclear receptor family of transcription factors. The consensus sequences for the evolutionarily recent Alu subclasses contain three hexamer half sites, related to the consensus AGGTCA, arranged as direct repeats with a spacing of 2 bp, which is consistent with the binding specificities of retinoic acid receptors. An analysis was made of the DNA binding and transactivation potential of these sites from an Alu sequence that has been previously implicated in the regulation of the keratin K18 gene. These Alu double half sites are shown to bind bacterially synthesized retinoic acid receptors as assayed by electrophoretic mobility shift assays. These sites are further shown to function as a retinoic acid response element in transiently transfected CV-1 cells, increasing transcription of a reporter gene by a factor of approximately 35-fold. This transactivation requires cotransfection with vectors expressing retinoic acid receptors, as well as the presence of all-trans-retinoic acid, which is consistent with the known function of retinoic acid receptors as ligand-inducible transcription factors. The random insertion of potentially thousands of Alu repeats containing retinoic acid response elements throughout the primate genome is likely to have altered the expression of numerous genes, thereby contributing to evolutionary potential.

Nuclear proteins that interact with the beta maj globin promoter start to accumulate in MEL cells within 12 hours of induction and RNA copies of the promoter successfully compete their binding in vitro

The induction of differentiation in mouse erythroleukemia (MEL) cells by dimethylsulfoxide (DMSO) is characterized by increased transcription of globin genes. We have determined that DMSO treated cells increase the levels of nuclear factors capable of overall interactions with the beta maj globin promoter during the initial 24 h post induction, as measured by gel mobility analysis. Two unprocessed beta maj globin mRNA precursors, which are present in MEL cell nuclei early in differentiation, were previously shown to contain the 5' promoter flanking region, and thereby provided the nucleus with a pool of regulatory sequences in multiple RNA copies. We have studied the effect of RNA copies of the promoter region on binding interactions between DNA sequences of the beta maj globin promoter and nuclear factors that interact with these sequences. The promoter region RNA transcripts competed effectively for DNA binding proteins in vitro, while the antisense RNA from the same region did not. The most pronounced competition was observed with proteins from 12 h after DMSO induction, when the concentration of the DNA binding proteins was still increasing. Since the 'upstream' transcripts predominate at 12 h after DMSO induction, these results indicate that the promoter region transcripts may influence the equilibrium of binding between the beta maj globin promoter and the nuclear factors that bind to this region during DMSO induction.

Ligation-mediated amplification of RNA from murine erythroid cells reveals a novel class of beta globin mRNA with an extended 5'-untranslated region

Ligation-mediated RNA amplification was developed as a tool for analysis and determination of the termini of RNA molecules [Volloch et al. (1991) Proc. Natl. Acad. Sci. USA 88: 10671-10675]. In this approach, T4 RNA ligase is used to join cellular RNA with a defined ribo-oligonucleotide. Although several additional enzymatic steps are involved in this type of analysis, the reliability of the entire procedure is determined by the initial ligation step, which marks and preserves the termini of cellular RNA molecules. We applied this approach to the analysis of the 5' terminus of beta globin mRNA in various murine erythroid cells. As expected, we detected RNA molecules with 5' ends terminating at the regular cap site as well as globin RNA molecules truncated at the 5' end. Unexpectedly, we also detected a class of beta globin mRNA which is identical to regular beta globin mRNA in every respect but contains 17, 29, or 31 additional nucleotides 5' to the regular cap site. These extensions correspond precisely to the genomic segments just upstream of the regular cap site and are probably generated by initiation of transcription of the globin gene upstream from the regular cap site. It is likely that the extended globin RNA is transcribed not from the TATA promoter, which regulates the transcription of regular murine globin mRNA, but from the GATA regulatory element located 30 nucleotides upstream of the 31-nucleotide extension, in a position identical to that of the active GATA promoter of the TATA-less chicken beta globin gene. The evolutionary conservation of this relationship suggests the importance of the GATA promoter element of the mouse beta globin gene and its possible involvement in developmental regulation of expression of this gene.

Evolutionary selection against change in many Alu repeat sequences interspersed through primate genomes

Mutations have been examined in the 1500 interspersed Alu repeats of human DNA that have been sequenced and are nearly full length. There is a set of particular changes at certain positions that rarely occur (termed suppressed changes) compared to the average of identical changes of identical nucleotides in the rest of the sequence. The suppressed changes occur in positions that are clustered together in what appear to be sites for protein binding. There is a good correlation of the suppression in different positions, and therefore the joint probability of absence of mutation at many pairs of such positions is significantly higher than that expected at random. The suppression of mutation appears to result from selection that is not due to requirements for Alu sequence replication. The implication is that hundreds of thousands of Alu sequences have sequence-dependent functions in the genome that are selectively important for primates. In a few known cases Alu inserts have been adapted to function in the regulation of gene transcription.

tRNA genes as transcriptional repressor elements

Eukaryotic genomes frequently contain large numbers of repetitive RNA polymerase III (pol III) promoter elements interspersed between and within RNA pol II transcription units, and in several instances a regulatory relationship between the two types of promoter has been postulated. In the budding yeast Saccharomyces cerevisiae, tRNA genes are the only known interspersed pol III promoter-containing repetitive elements, and we find that they strongly inhibit transcription from adjacent pol II promoters in vivo. This inhibition requires active transcription of the upstream tRNA gene but is independent of its orientation and appears not to involve simple steric blockage of the pol II upstream activator sites. Evidence is presented that different pol II promoters can be repressed by different tRNA genes placed upstream at varied distances in both orientations. To test whether this phenomenon functions in naturally occurring instances in which tRNA genes and pol II promoters are juxtaposed, we examined the sigma and Ty3 elements. This class of retrotransposons is always found integrated immediately upstream of different tRNA genes. Weakening tRNA gene transcription by means of a temperature-sensitive mutation in RNA pol III increases the pheromone-inducible expression of sigma and Ty3 elements up to 60-fold.

tRNA genes as transcriptional repressor elements

Eukaryotic genomes frequently contain large numbers of repetitive RNA polymerase III (pol III) promoter elements interspersed between and within RNA pol II transcription units, and in several instances a regulatory relationship between the two types of promoter has been postulated. In the budding yeast Saccharomyces cerevisiae, tRNA genes are the only known interspersed pol III promoter-containing repetitive elements, and we find that they strongly inhibit transcription from adjacent pol II promoters in vivo. This inhibition requires active transcription of the upstream tRNA gene but is independent of its orientation and appears not to involve simple steric blockage of the pol II upstream activator sites. Evidence is presented that different pol II promoters can be repressed by different tRNA genes placed upstream at varied distances in both orientations. To test whether this phenomenon functions in naturally occurring instances in which tRNA genes and pol II promoters are juxtaposed, we examined the sigma and Ty3 elements. This class of retrotransposons is always found integrated immediately upstream of different tRNA genes. Weakening tRNA gene transcription by means of a temperature-sensitive mutation in RNA pol III increases the pheromone-inducible expression of sigma and Ty3 elements up to 60-fold.

Activity of chimeric U small nuclear RNA (snRNA)/mRNA genes in transfected protoplasts of Nicotiana plumbaginifolia: U snRNA 3'-end formation and transcription initiation can occur independently in plants

Formation of the 3' ends of RNA polymerase II (Pol II)-specific U small nuclear RNAs (U snRNAs) in vertebrate cells is dependent upon transcription initiation from the U snRNA gene promoter. Moreover, U snRNA promoters are unable to direct the synthesis of functional polyadenylated mRNAs. In this work, we have investigated whether U snRNA 3'-end formation and transcription initiation are also coupled in plants. We have first characterized the requirements for 3'-end formation of an Arabidopsis U2 snRNA expressed in transfected protoplasts of Nicotiana plumbaginifolia. We found that the 3'-end-adjacent sequence CA (N)3-10AGTNNAA, conserved in plant Pol II-specific U snRNA genes, is essential for the 3'-end formation of U2 transcripts and, similar to the vertebrate 3' box, is highly tolerant to mutation. The 3'-flanking regions of an Arabidopsis U5 and a maize U2 snRNA gene can effectively substitute for the Arabidopsis U2 3'-end formation signal, indicating that these signals are functionally equivalent among different Pol II-transcribed snRNA genes. The plant U snRNA 3'-end formation signal can be recognized irrespective of whether transcription initiation occurs at U snRNA or mRNA gene promoters, although efficiency of 3' box utilization is higher when transcription initiation occurs at the U snRNA promoter. Moreover, transcripts initiated from the U2 gene promoter can be spliced and polyadenylated. Transcription from a Pol III-specific plant U snRNA gene promoter is not compatible with polyadenylation. Finally, we reveal that initiation at a Pol II-specific plant U snRNA gene promoter can occur in the absence of the snRNA coding region and a functional snRNA 3'-end formation signal, demonstrating that these sequences play no role in determining the RNA polymerase specificity of plant U snRNA genes.

Activity of chimeric U small nuclear RNA (snRNA)/mRNA genes in transfected protoplasts of Nicotiana plumbaginifolia: U snRNA 3'-end formation and transcription initiation can occur independently in plants

Formation of the 3' ends of RNA polymerase II (Pol II)-specific U small nuclear RNAs (U snRNAs) in vertebrate cells is dependent upon transcription initiation from the U snRNA gene promoter. Moreover, U snRNA promoters are unable to direct the synthesis of functional polyadenylated mRNAs. In this work, we have investigated whether U snRNA 3'-end formation and transcription initiation are also coupled in plants. We have first characterized the requirements for 3'-end formation of an Arabidopsis U2 snRNA expressed in transfected protoplasts of Nicotiana plumbaginifolia. We found that the 3'-end-adjacent sequence CA (N)3-10AGTNNAA, conserved in plant Pol II-specific U snRNA genes, is essential for the 3'-end formation of U2 transcripts and, similar to the vertebrate 3' box, is highly tolerant to mutation. The 3'-flanking regions of an Arabidopsis U5 and a maize U2 snRNA gene can effectively substitute for the Arabidopsis U2 3'-end formation signal, indicating that these signals are functionally equivalent among different Pol II-transcribed snRNA genes. The plant U snRNA 3'-end formation signal can be recognized irrespective of whether transcription initiation occurs at U snRNA or mRNA gene promoters, although efficiency of 3' box utilization is higher when transcription initiation occurs at the U snRNA promoter. Moreover, transcripts initiated from the U2 gene promoter can be spliced and polyadenylated. Transcription from a Pol III-specific plant U snRNA gene promoter is not compatible with polyadenylation. Finally, we reveal that initiation at a Pol II-specific plant U snRNA gene promoter can occur in the absence of the snRNA coding region and a functional snRNA 3'-end formation signal, demonstrating that these sequences play no role in determining the RNA polymerase specificity of plant U snRNA genes.

Modular transposition and the dynamical structure of eukaryote regulatory evolution

This paper examines a model in which transposable elements provide a modular architecture for the cellular genome, complemented by cellular recombinational transformations, arising in turn as a dynamical consequence of this modular structure. It is proposed that the ecology of transposable elements in a given organism is a function of recombinational protocols of the evolving cellular genome. In mammals this is proposed to involve coordinated meiosis-phased activation of LINEs, SINEs and retrogenes complemented by endogenous retroviral transfer between cells.

Fifty years of amanitin

Pharmacokinetic studies have provided new insights into human Amanita poisoning, but it appears to be impossible to treat this intoxication by immunotherapy. New synthetic analogs have revealed structure-activity relationships that were unknown so far. The main toxin, alpha-amanitin, is in constant use as a tool in molecular biology and in biological research. First experiments have been reported in which amanitin bound to polymers could be internalized into tumor cells via a receptor-mediated endocytosis.

Unique sequence organization and erythroid cell-specific nuclear factor-binding of mammalian theta 1 globin promoters

The theta 1 globin gene is an alpha globin-like gene, and started to diverge from the other members of the alpha globin family 260 million years ago. DNA sequencing and transcriptional analysis indicated that it is functional in erythroid cells of the higher primates, but not in prosimians and rabbit. The theta 1 promoter region of higher primates including man consists of GC-rich sequences characteristic of housekeeping gene promoters, and CCAAT and TATA boxes located further upstream. It is shown here that the housekeeping gene promoter-like region of human theta 1 contains two tandemly arranged, GC-rich motifs (GC-I and GC-II). Of these, GC-II interacts with nuclear factor(s) present in the globin-expressing, erythroleukemia cell line K562, before and after hemin induction. GC-I, however, interacts with nuclear factor(s) only present in hemin-induced K562 cells. These factors are different from previously reported erythroid cell-specific factors, and are not detectable in non-erythroid Hela cells. Furthermore, the sequence of the motif GC-I and its location relative to ATG codon have been conserved among all known mammalian theta 1 globin genes. Finally, and most interestingly, the CCAAT box of theta 1 is contained within a 38 bp internal segment of Alu repeat sequence. Immediately upstream from this CCAAT box-containing Alu repeat segment is a 241 bp Alu repeat pointing in the opposite direction. The conservation of this novel arrangement among the higher primates suggests that an inserted Alu family repeat and its flanking genomic sequence have co-evolved, for at least 30 million years, to provide the canonical CCAAT and TATA promoter elements of the theta 1 globin genes in higher primates.

Isolation and characterization of a maize chlorophyll a/b binding protein gene that produces high levels of mRNA in the dark

A cDNA library prepared using mRNA isolated from red-light irradiated maize seedlings was screened by a difference procedure for clones that represent red-light regulated mRNA. Two such clones were found to represent mRNA for a chlorophyll a/b binding protein (CAB), and one of these (pAB1084) was used to screen a maize genomic library. One positive genomic clone (lambda AB1084) was isolated and sequenced. The gene represented by lambda AB1084, which we designate maize cab-1, contains extensive nucleotide homology within its protein coding region to CAB genes from other species. The boundaries of the transcribed region of the cab-1 gene were determined by S1 nuclease mapping. The 5' terminus of cab-1 mRNA is located 52-54 nucleotides (nt) upstream of the translation start site and 34 nt downstream of a TATA box. As in the case of petunia CAB genes, several poly(A) addition sites are present in mRNA from the cab-1 gene. The 5' flanking DNA of cab-1 contains sequences related to elements that have been implicated in the light-regulated expression of CAB and rbcS genes in other plant systems. Quantitative Northern blot hybridization analysis using a gene specific probe for cab-1 indicates that the mRNA for this gene is present at 0.4% of the total mRNA and up to 80% of the total CAB mRNA in the leaves of dark-grown seedlings. In consequence, although the degree of up-regulation by white light is only moderate (3- to 6-fold), cab-1 transcripts account for approximately 2% of the mRNA in the leaves of light-grown seedlings.

Transcription of rat aldolase B gene: minor RNAs are transcribed by RNA polymerase III

Rat aldolase B gene was confirmed to have multiple transcriptional initiation sites; one site for the major transcript and at least two sites for the minor transcripts which are located at about 30 to 60 bases upstream of the major site. Although the transcription of the minor transcripts was entirely resistant to 1 microgram/ml of alpha-amanitin, which inhibits RNA polymerase II, it was completely blocked by 1000 micrograms/ml of the drug which inhibits RNA polymerase III. The box A- and B-like sequences, which are known to exist in the internal split promoter region of class III genes, were also found to be located around the initiation sites of two minor transcripts from the rat aldolase B gene. Analyses using deletion mutants of the promoter region of the gene suggested that the synthesis of the minor transcripts depends on the box A- and B-like sequences, but does not depend on a TATA promoter element. Northern blot analysis indicated that the minor transcripts are only a few percent of the total transcripts derived from the aldolase B gene. Some of the minor transcripts analyzed were shown to have a mature size in the poly(A)+ RNA fraction. Thus, the minor transcripts of rat aldolase B gene are apparently transcribed by RNA polymerase III, and subsequently normally processed and polyadenylated. The possible function of these minor transcripts will be discussed.

Tissue-specific effects of maize bronze gene promoter mutations induced by Ds1 insertion and excision

Bz-wm is an allele of the Bz locus of maize isolated by McClintock (1962) as a derivative of bz-m2. It contains a Ds1 insertion 63 bp upstream of the start of transcription and a 3 bp insertion in the coding region at the site of the Ac element that was present in bz-m2. Bz-wm produces, in the aleurone layer of the endosperm, low amounts (approximately 1% of wild-type) of a Bz-gene encoded UDP-glucose: flavoid 3-0-glucosyltransferase (UFGT) polypeptide with altered thermal stability. Three phenotypically wild-type derivatives, Bz' (wm)-1, Bz' (wm)-2 and Bz' (wm)-3, were isolated in the presence of Ac and shown to have excised the Ds1 element but not fully restored UFGT activity in endosperm assays. In the studies reported here, we have further analyzed these Bz' derivatives of Bz-wm by determining the DNA sequences left behind on Ds1 excision, and by measuring the amount of UFGT activity and/or Bz mRNA conditioned by Bz-wm and the Bz' derivatives in different tissues. The data indicate that tissue-specific differences in expression of the Bz gene have been produced in alleles with mutations caused by transposable elements Ac and Ds. These mutations may affect either the amount of Bz transcription or the stability of the UFGT polypeptide. The sequence or spacing in the -63 region of the Bz promoter appears to be critical for maximum expression in aleurone and husk but not in pollen and pigmented seedling tissue.

Alternative mechanisms for gene activation induced by poly(rI).poly(rC) and Newcastle disease virus

After poly(rI).poly(rC) induction of FS-4 fibroblasts, both human interferon-beta (IFN-beta) mRNA and an additional induced RNA class (12S RNA) hybridize to a genomic cosmid clone containing the human IFN-beta gene as well as 35 kbp of flanking sequences. However, this coinduced 12S RNA does not originate from regions in the neighborhood of the IFN-beta gene, but hybridizes to the genomic cosmid clone via repetitive Alu-family sequences. While IFN-beta mRNA rapidly decays after reaching a maximum 2-4 h after induction, this 12S RNA is stably maintained in the fibroblast cell for more than 16 h. Contrary to IFN-beta mRNA, the level of the 12S RNA is not further elevated by superinduction conditions (cycloheximide treatment) during poly(rI).poly(rC) induction. However, subsequent to treatment with the weaker viral inducer Newcastle disease virus (NDV) both IFN-beta and the 12S RNA transcripts are induced to a higher level in the presence of cycloheximide. Cell-free translation of hybrid-selected 12S RNA leads to detection of an induced protein of 14 kDa. cDNA cloning reveals that the 12S RNA contains part of an Alu-family sequence in the 5'-untranslated region. The 12S RNA is probably not an RNA polymerase III transcript and codes for a protein of 9 kDa (as monitored by in vitro cell-free translation). This discrepancy in molecular mass can be attributed to a retarded migration of the protein in SDS/PAGE.

Poly(A) shortening and degradation of the 3' A+U-rich sequences of human c-myc mRNA in a cell-free system

The early steps in the degradation of human c-myc mRNA were investigated, using a previously described cell-free mRNA decay system. The first detectable step was poly(A) shortening, which generated a pool of oligoadenylated mRNA molecules. In contrast, the poly(A) of a stable mRNA, gamma globin, was not excised, even after prolonged incubation. The second step, degradation of oligoadenylated c-myc mRNA, generated decay products whose 3' termini were located within the A+U-rich portion of the 3' untranslated region. These products disappeared soon after they were formed, consistent with rapid degradation of the 3' region. In contrast, the 5' region, corresponding approximately to c-myc exon 1, was stable in vitro. The data indicate a sequential degradation pathway in which 3' region cleavages occur only after most or all of the poly(A) is removed. To account for rapid deadenylation, we suggest that the c-myc poly(A)-poly(A)-binding protein complex is readily dissociated, generating a protein-depleted poly(A) tract that is no longer resistant to nucleases.

Poly(A) shortening and degradation of the 3' A+U-rich sequences of human c-myc mRNA in a cell-free system

The early steps in the degradation of human c-myc mRNA were investigated, using a previously described cell-free mRNA decay system. The first detectable step was poly(A) shortening, which generated a pool of oligoadenylated mRNA molecules. In contrast, the poly(A) of a stable mRNA, gamma globin, was not excised, even after prolonged incubation. The second step, degradation of oligoadenylated c-myc mRNA, generated decay products whose 3' termini were located within the A+U-rich portion of the 3' untranslated region. These products disappeared soon after they were formed, consistent with rapid degradation of the 3' region. In contrast, the 5' region, corresponding approximately to c-myc exon 1, was stable in vitro. The data indicate a sequential degradation pathway in which 3' region cleavages occur only after most or all of the poly(A) is removed. To account for rapid deadenylation, we suggest that the c-myc poly(A)-poly(A)-binding protein complex is readily dissociated, generating a protein-depleted poly(A) tract that is no longer resistant to nucleases.

RNA processing of beta-globin transcripts containing 5' flanking and structural gene sequences

RNA species have been identified in murine erythroid cells which contain both 5' flanking and structural gene sequences from the beta maj globin gene. Two nonpolyadenylated RNA transcripts, average 3700 and 1800-1900 nucleotides long, were identified by denaturing agarose gel electrophoresis and were found to hybridize to both 5' and 3' beta maj globin flanking sequences. This finding suggests that transcription initiated in the 5' flanking region does proceed past the polyadenylation site. The apparent higher concentration of the 5' flanking sequences in precursor RNA molecules, as compared to mature polyadenylated globin mRNA, suggests increased precursor stability of beta globin transcripts initiated in the 5' flanking region.

Specificity of RNA maturation pathways: RNAs transcribed by RNA polymerase III are not substrates for splicing or polyadenylation

To analyze the specificity of RNA processing reactions, we constructed hybrid genes containing RNA polymerase III promoters fused to sequences that are normally transcribed by polymerase II and assessed their transcripts following transfection into human 293 cells. Transcripts derived from these chimeric constructs were analyzed by using a combined RNase H and S1 nuclease assay to test whether RNAs containing consensus 5' and 3' splicing signals could be efficiently spliced in intact cells, even though they were transcribed by RNA polymerase III. We found that polymerase III-derived RNAs are not substrates for splicing. Similarly, we were not able to detect poly(A)+ RNAs derived from genes that contained a polymerase III promoter linked to sequences that were necessary and sufficient to direct 3'-end cleavage and polyadenylation when transcribed by RNA polymerase II. Our findings are consistent with the view that in vivo splicing and polyadenylation pathways are obligatorily coupled to transcription by RNA polymerase II.

Primate brain-specific cytoplasmic transcript of the Alu repeat family

A 200-nucleotide RNA homologous to the left monomer of Alu elements was expressed in monkey and human brain and in cell lines but not in nonneural monkey tissues. Similar brain-specific transcription of identifier sequences was observed in rats. Thus, expression of selected repetitive DNA families is a conserved process in mammalian brain.

Specificity of RNA maturation pathways: RNAs transcribed by RNA polymerase III are not substrates for splicing or polyadenylation

To analyze the specificity of RNA processing reactions, we constructed hybrid genes containing RNA polymerase III promoters fused to sequences that are normally transcribed by polymerase II and assessed their transcripts following transfection into human 293 cells. Transcripts derived from these chimeric constructs were analyzed by using a combined RNase H and S1 nuclease assay to test whether RNAs containing consensus 5' and 3' splicing signals could be efficiently spliced in intact cells, even though they were transcribed by RNA polymerase III. We found that polymerase III-derived RNAs are not substrates for splicing. Similarly, we were not able to detect poly(A)+ RNAs derived from genes that contained a polymerase III promoter linked to sequences that were necessary and sufficient to direct 3'-end cleavage and polyadenylation when transcribed by RNA polymerase II. Our findings are consistent with the view that in vivo splicing and polyadenylation pathways are obligatorily coupled to transcription by RNA polymerase II.

Primate brain-specific cytoplasmic transcript of the Alu repeat family

A 200-nucleotide RNA homologous to the left monomer of Alu elements was expressed in monkey and human brain and in cell lines but not in nonneural monkey tissues. Similar brain-specific transcription of identifier sequences was observed in rats. Thus, expression of selected repetitive DNA families is a conserved process in mammalian brain.

Changes in minor transcripts from the alpha 1 and beta maj globin and glutathione peroxidase genes during erythropoiesis

We have analysed the transcriptional regulation of the murine alpha 1 and beta maj globin genes and the glutathione peroxidase (GSHPx) gene, which are all highly expressed during erythropoiesis. The levels of minor RNAs compared to the major message were monitored throughout differentiation within the erythroid lineage. For each gene, upstream transcripts arise from distinct clusters of sites which are regulated differently during differentiation: some occur only during early erythropoiesis, some occur early and persist to the terminal stages, while others accumulate later and roughly in parallel with the main RNA transcript. In addition, opposite strand transcripts from the GSHPx gene were found in increasing amounts during later stages of erythropoiesis. The initiation sites for specific subsets of these minor transcripts lie close to sequences known to be involved in globin gene regulation (i.e. the TATA, CAAT and the CACCCT boxes) or other conserved sequences; others lie close to developmentally regulated DNase I hypersensitive sites around the globin and GSHPx genes.

Noncoding 3' sequences of the transferrin receptor gene are required for mRNA regulation by iron

The cell-surface receptor for transferrin mediates cellular uptake of iron from serum. Transferrin receptor protein and mRNA levels are increased in cells treated with iron chelating agents, and are decreased by treatment with iron salts or hemin. Here we report that expression of human transferrin receptor cDNA constructions in stably transfected mouse fibroblasts is regulated both by the iron chelator, desferrioxamine, and by hemin. We found that sequences within the 3' noncoding region are required for the iron-dependent feed-back regulation of receptor expression, whereas the presence of the transferrin receptor promoter region is not necessary. Regulation by iron is observed when transcription is initiated at either the SV-40 early promoter or the transferrin receptor promoter, but deletion of a 2.3 kb fragment within the 2.6 kb 3' noncoding region of the cDNA abolishes regulation and increases the constitutive level of receptor expression. Furthermore, the 3' deletion does not affect the decrease in receptors which is observed in response to growth arrest, indicating that transferrin receptor expression is controlled by at least two distinct mechanisms.

Minor transcription initiation events indicate that both human mitochondrial promoters function bidirectionally

Human mitochondrial DNA is transcribed from two distinct, strand-specific promoters located in the displacement loop region of the genome. The transcriptional control sequences identified by deletion mapping and site-directed mutagenesis studies span short regions surrounding the initiation sites and bear no obvious sequence homology to any nuclear or procaryotic promoters. In vitro transcription analyses also revealed several minor initiation sites that are characterized by a pyrimidine-rich region followed by a purine-rich region, a feature that is shared by the two major promoters. In this paper, we report a new class of minor promoters in human mitochondrial DNA. These minor promoters were localized to the same duplex DNA sequences that direct major transcriptional events, but they had transcriptional polarity opposite to that of the major promoters. Furthermore, nucleotide changes that affected the major form of transcription similarly affected transcription in the opposite direction. For one of these minor promoters, a corresponding in vivo RNA species initiating from the same site was identified. These observations indicate that the major transcriptional promoters in human mitochondria can function bidirectionally both in vivo and in vitro.

Restriction enzyme evidence for Alu sequence-mediated dispersion of microinjected genes in transgenic mice

A human bacteriophage clone containing adult beta-globin genes with four Alu sequences was microinjected to produce transgenic mice. Southern blot analysis on the spleen of a transgenic mouse revealed an unusual hybridization pattern that suggested extensive dispersion of human DNA throughout the mouse genome. This pattern was reproducible using several restriction enzymes, including a noncutting enzyme. The hybridization pattern was not observed in other tissues, and sequences were not detected in progeny using the bacteriophage probe. However, hybridization of spleen DNA of offspring against a human Alu probe revealed genetic transmission of human Alu sequences. The results suggest dispersion of microinjected Alu sequences throughout the genome.

Nucleotide sequence of the promoter region of a tissue-specific human retroposon: comparison with its housekeeping progenitor

The intronless autosomal phosphoglycerate kinase gene (Pgk-2) is a functional retroposon expressed in a tissue-specific manner in the meiotic and postmeiotic stages of mammalian spermatogenesis. The nucleotide sequence of the promoter region of this gene and its transcription start point are compared with those of Pgk-1, an intron-containing, X-linked, housekeeping gene expressed constitutively in all somatic cells and premeiotic germ cells. The location of flanking direct repeats and apparent conservation of specific regulatory sequences suggest the Pgk-2 retroposon arose from reverse transcriptase-mediated processing of an aberrant Pgk-1 transcript that included the endogenous Pgk-1 promoter elements. Specific sequences that may be involved in mediating differences observed in both the level and cell-type specificity of expression of these genes in spermatogenesis are identified.

Point mutation associated with hereditary persistence of fetal hemoglobin decreases RNA polymerase III transcription upstream of the affected gamma-globin gene

A base substitution in the 5'-flanking region of a human fetal globin gene is associated with abnormal fetal hemoglobin production. It also reduces by 5- to 10-fold in vitro transcription of the gene by RNA polymerase III. We discuss potential links between polymerase III transcription and abnormal hemoglobin production.

3' end formation of U1 snRNA precursors is coupled to transcription from snRNA promoters

Promoters of small nuclear RNA (snRNA) genes are partly responsible for 3' end formation of snRNA precursors. In injected X. laevis oocytes, substitution of an mRNA promoter (HSV tk) for the snRNA promoter significantly reduces the utilization of a conserved snRNA 3' end signal and permits recognition of a downstream polyadenylation site. Neither the U1 enhancer nor the U1 coding region is essential for recognition of the snRNA 3' end signal. Deletion of the U1 3' end signal from genes with a U1 promoter results in utilization of "cryptic" signals resembling the consensus sequence. However, these snRNA gene-promoted transcripts are not polyadenylated, in spite of the functional polyadenylation signal they contain. Thus, the ability to recognize 3' end signals is determined during initiation, presumably by interaction of transcription complexes with specific processing or termination factors.

Point mutation associated with hereditary persistence of fetal hemoglobin decreases RNA polymerase III transcription upstream of the affected gamma-globin gene

A base substitution in the 5'-flanking region of a human fetal globin gene is associated with abnormal fetal hemoglobin production. It also reduces by 5- to 10-fold in vitro transcription of the gene by RNA polymerase III. We discuss potential links between polymerase III transcription and abnormal hemoglobin production.

RNA polymerase specificity of mRNA production and enhancer action

To examine the RNA polymerase (EC 2.7.7.6) specificity of RNA maturation/utilization and transcriptional enhancement, we constructed a chimeric plasmid (pPolI-CAT) in which a promoter for mouse rRNA gene transcription was placed adjacent the coding sequences for chloramphenicol acetyltransferase (CAT; EC 2.3.1.28). A number of other constructs, including plasmids also containing a murine sarcoma virus enhancer or lacking any natural eukaryotic promoter sequences, were also prepared. In apparent agreement with earlier conclusions that an RNA polymerase I transcript can act as a messenger RNA, transient transfection of mouse L cells with pPolI-CAT yielded both high levels of transcription from the RNA polymerase I promoter and enzymatically active CAT protein. However, further examination revealed that CAT protein is not translated from RNA that begins at the normal rRNA transcription initiation site. Polysomal RNA is devoid of such RNA and instead consists of CAT-encoding transcripts that begin elsewhere in the mouse ribosomal DNA (rDNA) region. Since transcription of these aberrant RNAs is stimulated by the addition of a murine sarcoma virus enhancer segment, they are probably transcribed by RNA polymerase II. Transcripts that map to the authentic rRNA start site are not similarly enhanced. Moreover, unlike the RNAs deriving from the rRNA initiation site, these aberrant RNAs are more stable and the level of translatable CAT transcripts is suppressed by inclusion of larger segments of the rDNA promoter regions. Fortuitously initiated mRNAs are also formed in the absence of any natural eukaryotic promoter sequence. From these data we conclude that there is no evidence that normal RNA polymerase I transcription yields functional mRNA and that transcriptional enhancement appears to be RNA polymerase specific.

Cloning and expression of the rat interleukin-3 gene

Genomic clones carrying the rat interleukin-3 (IL-3) gene have been isolated and the nucleotide sequence of the gene determined. Alignment of this sequence with that of the mouse IL-3 gene has allowed the structure of the rat IL-3 gene to be deduced. The intron-exon boundaries are conserved and extensive nucleotide homology (approx 90%) is present in the 5' flanking region and the portion of the gene coding for the signal peptide. Several proposed regulatory sequences are conserved and an analogous element to the tandem repeat in intron 2 of the mouse gene is also present. The predicted amino acid sequence for mature rat IL-3 shows surprisingly low homology (54%) with its murine counterpart, although all four cysteine residues are conserved. The rat IL-3 gene was expressed in monkey COS-1 cells and colony assays established that rat IL-3 is a multi-lineage haemopoietic growth regulator. There was little cross-reactivity of the respective IL-3 species on mouse and rat bone marrow cells suggesting that rat IL-3, in concert with its receptor, has evolved significantly away from the mouse IL-3/receptor system.

Specific transcription of a 15-kilodalton zene gene in HeLa cell extracts

A maize genomic clone containing a 15 kilodalton zein gene was used as a template in an in vitro transcription system for HeLa cells. A runoff assay indicated transcription was initiating 5' to the map position of the open reading frame for the protein. Fine-structure mapping of RNAs synthesized in vitro showed two transcription start sites separated by 24 bases. One start site is 27 bases downstream of a consensus TATA sequence; the other is 30 bases downstream of a TATG sequences. The initiation sites for RNA synthesized in vitro map to the same region of the genomic clone as zein RNA isolated from developing maize kernels.

Estradiol-dependent transcription initiation upstream from the chicken apoVLDLII gene coding for the very-low-density apolipoprotein II

We have investigated RNAs originating from the 5'-flanking region of the chicken very-low-density apolipoprotein II (apoVLDLII) gene. S1 nuclease mapping and primer extension experiments revealed two minor upstream transcription start points located 1105 and 1530 nucleotides in front of the apoVLDLII gene. Transcription starting at these points is dependent upon estradiol as is transcription from the major start points. The transcripts are polyadenylated, but are not detectable in polysomes. Run-on assays indicated that the low concentration of the upstream initiated transcripts is due both to low transcription levels and to low transcript stability. The sequence around the upstream start points does not show strong homologies with consensus sequences of promoters for eukaryotic protein encoding genes. Nevertheless, the upstream sequences are transcribed in vivo by RNA polymerase II.

Accurate in vitro initiation of beta-globin gene transcription in induced Friend-cell nuclei

The initiation of transcription by RNA polymerase II in isolated murine erythroleukemia cell nuclei was investigated by isolating newly synthesized gamma-thio (gamma-S-)-triphosphate-labeled transcripts by Hg-agarose chromatography. The 5' terminus of transcripts initiated in vitro with [gamma-35S]ATP or [gamma-35S]GTP was identified as the thiotetraphosphate in alkaline hydrolysis products from Hg-agarose-selected RNA. Additional control experiments analyzing the nuclear transcription of two well characterized tRNA genes showed that each gene was initiated with the proper triphosphate, either gamma-S-ATP or gamma-S-GTP, indicating little, if any, exchange of the gamma-S-labeled substrate to the other triphosphates. As determined by S1 mapping, newly synthesized beta-globin gene transcripts initiate only with gamma-S-ATP. Their 5'-terminus is located at the cap site, and their synthesis is inhibited by 1 microgram alpha-amanitin/ml. In reactions containing gamma-S-ATP but not gamma-S-GTP, several additional initiation sites are observed that are located in the 5'-flanking region. We conclude that RNA polymerase II can initiate transcription at the cap site in isolated nuclei.

Minor transcription initiation events indicate that both human mitochondrial promoters function bidirectionally

Human mitochondrial DNA is transcribed from two distinct, strand-specific promoters located in the displacement loop region of the genome. The transcriptional control sequences identified by deletion mapping and site-directed mutagenesis studies span short regions surrounding the initiation sites and bear no obvious sequence homology to any nuclear or procaryotic promoters. In vitro transcription analyses also revealed several minor initiation sites that are characterized by a pyrimidine-rich region followed by a purine-rich region, a feature that is shared by the two major promoters. In this paper, we report a new class of minor promoters in human mitochondrial DNA. These minor promoters were localized to the same duplex DNA sequences that direct major transcriptional events, but they had transcriptional polarity opposite to that of the major promoters. Furthermore, nucleotide changes that affected the major form of transcription similarly affected transcription in the opposite direction. For one of these minor promoters, a corresponding in vivo RNA species initiating from the same site was identified. These observations indicate that the major transcriptional promoters in human mitochondria can function bidirectionally both in vivo and in vitro.

Anatomy of region L1 from adenovirus type 2

The structure of r-strand-specific RNAs encoded between coordinates 26 and 32 on the adenovirus type 2 genome was mapped by a combination of S1 endonuclease analysis, primer extension, and in vitro transcription. The region includes the third leader segment (coordinates 26.8 to 27.0), the genes for the low-molecular-weight virus-associated RNAs (VA RNAs) (coordinates 29.5 to 30.7), and the amino-terminal end of the gene for the L1 52,000-55,000 polypeptide (coordinates 30.7 to 32.1). The positions at which the tripartite leader was attached to the three longest L1 mRNAs were mapped at the nucleotide level. The leader splice junction of species L1a was located at coordinate 26.8 and coincided with the 3' splice site for the third leader segment, whereas the leader-body splice junction of species L1b and L1c were located at coordinates 29.0 and 30.7, respectively. No protein products have so far been assigned to the L1a and L1b mRNAs, although it can be predicted from the nucleotide sequence that species L1b encodes a 8,300 polypeptide. The third RNA, species L1c, encodes the well-characterized 52,000-55,000 polypeptide. It was also shown that a previously unidentified class of VA RNAs exists predominantly in the poly(A)-fraction of late RNA preparations. These RNAs are heterogeneous in length (up to 3,000 nucleotides) because of irregular transcription termination and have 5' ends which map precisely to the initiation sites for VA RNAI and VA RNAII transcription. Finally it was shown that an RNA with a 5' end coinciding with the 5' splice site for the third leader segment exists in the poly(A)-fraction of late cytoplasmic RNA. This RNA species might represent an excised intron.

Alpha-amanitin insensitive transcription of the human epsilon-globin gene

In vitro transcription was used to show that RNA polymerase III is responsible for the initiation of transcription at a position 200 bp upstream from the epsilon-globin major cap site. High levels of -200 transcription interferes with the RNA polymerase II major cap site transcription. Using DNA mediated transient expression, the ratio of -200 to +1 transcription can be modulated by either the direction of replication or the presence of an enhancing element in the vector. We suggest that this heterogeneous usage of cap sites is not related to epsilon-globin gene transcription in vivo, but is instead the result of a combination of factors inherent to transient expression experiments.