Construction and expression in vivo of an internally deleted mouse alpha-fetoprotein gene: presence of a transcribed Alu-like repeat within the first intervening sequence

Inhibitory effect of naked neural BC1 RNA or BC200 RNA on eukaryotic in vitro translation systems is reversed by poly(A)-binding protein (PABP)

Regulated protein biosynthesis in dendrites of neurons might be a key mechanism underlying learning and memory. Neuronal dendritic BC1 RNA and BC200 RNA and similar small untranslated RNAs inhibit protein translation in vitro systems, such as rabbit reticulocyte lysate. Likewise, co-transfection of these RNAs with reporter mRNA suppressed translation levels in HeLa cells. The oligo(A)-rich region of all active small RNAs were identified as the RNA domains chiefly responsible for the inhibitory effects. Addition of recombinant human poly(A)-binding protein (PABP) significantly compensated the inhibitory effect of the small oligo(A)-rich RNA. In vivo, all BC1 RNA appears to be complexed with PABP. Nevertheless, in the micro-environment of dendritic spines of neuronal cells, BC1 RNPs or BC200 RNPs might mediate regulatory functions by differential interactions with locally limited PABP and/or directly or indirectly, with other translation initiation factors.

Targeting of high mobility group-14/-17 proteins in chromatin is independent of DNA sequence

Chromosomal proteins high mobility group (HMG)-14 and HMG-17 are nucleosomal-binding proteins that unfold the chromatin fiber and enhance transcription from chromatin templates. Their intracellular organization is dynamic and related to both cell cycle and transcription. Here we examine possible mechanisms for targeting HMG-14/-17 to specific regions in chromatin. Chromatin immunoprecipitation assays indicate that HMG-17 protein is not preferentially associated with chromatin regions containing transcriptionally active genes, or any type of specific DNA. We used a modification of the random amplified polymorphic DNA method to analyze DNA in various HMG-14/-17.nucleosome complexes. We found that although HMG-14 or HMG-17 proteins preferentially associate with core particles in which the DNA has a low frequency of CG dinucleotides, the genome does not contain consensus sequences that serve as specific targeting sites for the binding of either HMG-14 or HMG-17 proteins to nucleosomes. We used size exclusion and ion exchange chromatography to demonstrate that nuclei contain a large portion of HMG-17 associated with other proteins in a multiprotein complex. We suggest that these complexes regulate the dynamic organization of HMG-14/-17 in the nucleus and serve to target the proteins to specific sites in chromatin.

Terminator-specific recycling of a B1-Alu transcription complex by RNA polymerase III is mediated by the RNA terminus-binding protein La

Efficient synthesis of many small abundant RNAs is achieved by the proficient recycling of RNA polymerase (pol) III and stable transcription complexes. Cellular Alu and related retroposons represent unusual pol III genes that are normally repressed but are activated by viral infection and other conditions. The core sequences of these elements contain pol III promoters but must rely on fortuitous downstream oligo(dT) tracts for terminator function. We show that a B1-Alu gene differs markedly from a classical pol III gene (tRNAiMet) in terminator sequence requirements. B1-Alu genes that differ only in terminator sequence context direct differential RNA 3' end formation. These genes are assembled into stable transcription complexes but differ in their ability to be recycled in the presence of the La transcription termination factor. La binds to the nascent RNA 3' UUUOH end motif that is generated by transcriptional termination within the pol III termination signal, oligo(dT). We found that the recycling efficiency of the B1-Alu genes is correlated with the ability of La to access the 3' end of the nascent transcript and protect it from 3'-5' exonucleolytic processing. These results illuminate a relationship between RNA 3' end formation and transcription termination, and La-mediated reinitiation by pol III.

Association of repeat sequences with integrated retroviruses in a murine leukaemia cell line

An analysis was made of the retroviral integration sites for retroviruses in a murine lymphoid precursor cell line, C1-V13D, derived following in vitro infection with RadLV, an ecotropic murine retrovirus. A genomic library was constructed and lambda clones were selected for their capacity to hybridize with the specific RadLV gp70 ecotropic env probe. Analysis of these clones by a combination of approaches, including subcloning, partial restriction mapping and sequencing, has confirmed the existence of multiple recombinant and defective viruses in C1-V13D. To check for the presence of coding sequences in flanking genomic DNA, 32P-labelled cDNA from C1-V13D was used to probe HindIII- and Psti-digested virus-positive lambda clones by Southern analysis. Regions hybridizing specifically with 32P-labelled C1-V13D cDNA were subcloned and analysed. A notable feature of these cDNA+ regions was the frequent presence of B1, B2 and simple repeats. These repeat elements were found to be present in high frequency in the genomic regions flanking the proviruses, in numbers higher than expected for the genome as a whole. All full-length viruses isolated appeared to represent integration events into regions rich in repeat elements. Some B1 and B2 repeats have been shown to code for functional proteins and to play regulatory roles. Viral integration in the vicinity of these genetic elements could contribute to oncogenesis if the integration event were to disrupt normal gene function.

A new variant of B1 elements, vB1, identified upstream of a retroviral integration site

A new variant of the murine B1 retroposon family, vB1, was identified in antisense orientation 165 bases upstream of the integration site of RFB MuLV in infected NIH3T3 fibroblasts. vB1 revealed a characteristic B1 structure, but contained two additional unique repeats. This variant facilitates identification of related vB1 elements which are considered to represent a minor subgroup of B1 elements.

Eukaryotic transcription termination factor La mediates transcript release and facilitates reinitiation by RNA polymerase III

Ample evidence indicates that Alu family interspersed elements retrotranspose via primary transcripts synthesized by RNA polymerase III (pol III) and that this transposition sometimes results in genetic disorders in humans. However, Alu primary transcripts can be processed posttranscriptionally, diverting them away from the transposition pathway. The pol III termination signal of a well-characterized murine B1 (Alu-equivalent) element inhibits RNA 3' processing, thereby stabilizing the putative transposition intermediary. We used an immobilized template-based assay to examine transcription termination by VA1, 7SL, and Alu class III templates and the role of transcript release in the pol III terminator-dependent inhibition of processing of B1-Alu transcripts. We found that the RNA-binding protein La confers this terminator-dependent 3' processing inhibition on transcripts released from the B1-Alu template. Using pure recombinant La protein and affinity-purified transcription complexes, we also demonstrate that La facilitates multiple rounds of transcription reinitiation by pol III. These results illustrate an important role for La in RNA production by demonstrating its ability to clear the termination sites of class III templates, thereby promoting efficient use of transcription complexes by pol III. The role of La as a potential regulatory factor in transcript maturation and how this might apply to Alu interspersed elements is discussed.

Eukaryotic transcription termination factor La mediates transcript release and facilitates reinitiation by RNA polymerase III

Ample evidence indicates that Alu family interspersed elements retrotranspose via primary transcripts synthesized by RNA polymerase III (pol III) and that this transposition sometimes results in genetic disorders in humans. However, Alu primary transcripts can be processed posttranscriptionally, diverting them away from the transposition pathway. The pol III termination signal of a well-characterized murine B1 (Alu-equivalent) element inhibits RNA 3' processing, thereby stabilizing the putative transposition intermediary. We used an immobilized template-based assay to examine transcription termination by VA1, 7SL, and Alu class III templates and the role of transcript release in the pol III terminator-dependent inhibition of processing of B1-Alu transcripts. We found that the RNA-binding protein La confers this terminator-dependent 3' processing inhibition on transcripts released from the B1-Alu template. Using pure recombinant La protein and affinity-purified transcription complexes, we also demonstrate that La facilitates multiple rounds of transcription reinitiation by pol III. These results illustrate an important role for La in RNA production by demonstrating its ability to clear the termination sites of class III templates, thereby promoting efficient use of transcription complexes by pol III. The role of La as a potential regulatory factor in transcript maturation and how this might apply to Alu interspersed elements is discussed.

Multiple dispersed loci produce small cytoplasmic Alu RNA

Alu repeats are short interspersed elements (SINEs) of dimeric structure whose transposition sometimes leads to heritable disorders in humans. Human cells contain a poly(A)- small cytoplasmic transcript of -120 nucleotides (nt) homologous to the left Alu monomer. Although its monomeric size indicates that small cytoplasmic Alu (scAlu) RNA is not an intermediary of human Alu transpositions, a less abundant poly(A)-containing Alu transcript of dimeric size and specificity expected of a transposition intermediary is also detectable in HeLa cells (A. G. Matera, U. Hellmann, M. F. Hintz, and C. W. Schmid, Mol. Cell. Biol. 10:5424-5432, 1990). Although its function is unknown, the accumulation of Alu RNA and its ability to interact with a conserved protein suggest a role in cell biology (D.-Y. Chang and R. J. Maraia, J. Biol. Chem. 268:6423-28, 1993). The relationship between the -120- and -300-nt Alu transcripts had not been determined. However, a B1 SINE produces scB1 RNA by posttranscriptional processing, suggesting a similar pathway for scAlu. An Alu SINE which recently transposed into the neurofibromatosis 1 locus was expressed in microinjected frog oocytes. This neurofibromatosis 1 Alu produced a primary transcript followed by the appearance of the scAlu species. 3' processing of a synthetic -300-nt Alu RNA by HeLa nuclear extract in vitro also produced scAlu RNA. Primer extension of scAlu RNA indicates synthesis by RNA polymerase III. HeLa-derived scAlu cDNAs were cloned so as to preserve their 5'-terminal sequences and were found to correspond to polymerase III transcripts of the left monomeric components of three previously identified Alu SINE subfamilies. Rodent x human somatic cell hybrids express Alu RNAs whose size, heterogeneous length, and chromosomal distribution indicate their derivation from SINEs. The coexpression of dimeric and monomeric Alu RNA in several hybrids suggests a precursor-product relationship.

Multiple dispersed loci produce small cytoplasmic Alu RNA

Alu repeats are short interspersed elements (SINEs) of dimeric structure whose transposition sometimes leads to heritable disorders in humans. Human cells contain a poly(A)- small cytoplasmic transcript of -120 nucleotides (nt) homologous to the left Alu monomer. Although its monomeric size indicates that small cytoplasmic Alu (scAlu) RNA is not an intermediary of human Alu transpositions, a less abundant poly(A)-containing Alu transcript of dimeric size and specificity expected of a transposition intermediary is also detectable in HeLa cells (A. G. Matera, U. Hellmann, M. F. Hintz, and C. W. Schmid, Mol. Cell. Biol. 10:5424-5432, 1990). Although its function is unknown, the accumulation of Alu RNA and its ability to interact with a conserved protein suggest a role in cell biology (D.-Y. Chang and R. J. Maraia, J. Biol. Chem. 268:6423-28, 1993). The relationship between the -120- and -300-nt Alu transcripts had not been determined. However, a B1 SINE produces scB1 RNA by posttranscriptional processing, suggesting a similar pathway for scAlu. An Alu SINE which recently transposed into the neurofibromatosis 1 locus was expressed in microinjected frog oocytes. This neurofibromatosis 1 Alu produced a primary transcript followed by the appearance of the scAlu species. 3' processing of a synthetic -300-nt Alu RNA by HeLa nuclear extract in vitro also produced scAlu RNA. Primer extension of scAlu RNA indicates synthesis by RNA polymerase III. HeLa-derived scAlu cDNAs were cloned so as to preserve their 5'-terminal sequences and were found to correspond to polymerase III transcripts of the left monomeric components of three previously identified Alu SINE subfamilies. Rodent x human somatic cell hybrids express Alu RNAs whose size, heterogeneous length, and chromosomal distribution indicate their derivation from SINEs. The coexpression of dimeric and monomeric Alu RNA in several hybrids suggests a precursor-product relationship.

The RNA polymerase III terminator used by a B1-Alu element can modulate 3' processing of the intermediate RNA product

The dispersion of short interspersed elements (SINEs) probably occurred through an RNA intermediate. B1 is a murine homolog of the human SINE Alu; these elements are composed of 5' G + C-rich regions juxtaposed to A-rich tracts and are flanked by direct repeats. Internal promoters direct RNA polymerase III to transcribe B1 and Alu elements and proceed into the 3' flanking DNA until it reaches a (dT)4 termination signal. The resulting transcripts contain 3'-terminal oligo(U) tracts which can presumably base pair with the A-rich tract to form self-primed templates for reverse transcriptase and retrotransposition. Nuclear extracts from mouse tissue culture cells contain an RNA processing activity that removes the A-rich and 3'-terminal regions from purified B1 RNAs (R. Maraia, Nucleic Acids Res. 19:5695-5702, 1991). In this study, we examined transcription and RNA processing in these nuclear extracts. In contrast to results with use of purified RNA, nascent transcripts synthesized in nuclear extract by RNA polymerase III are not processed, suggesting that the transposition-intermediate-like RNA is shielded from processing by a protein(s). Alteration of an AATTTT TAA termination signal to a GCTTTTGC signal activated processing by greater than 100-fold in coupled transcription/processing reactions. A similar difference was found when expression was compared in frog oocytes. No difference in processing was found if the transcripts were made by T7 RNA polymerase in the presence of the nuclear extract, indicating that the different processing effects of the two terminators were dependent on synthesis by polymerase III. The modulation of processing of B1-Alu transcripts and the potential for retrotransposition of B1 and Alu DNA sequences are discussed.

The RNA polymerase III terminator used by a B1-Alu element can modulate 3' processing of the intermediate RNA product

The dispersion of short interspersed elements (SINEs) probably occurred through an RNA intermediate. B1 is a murine homolog of the human SINE Alu; these elements are composed of 5' G + C-rich regions juxtaposed to A-rich tracts and are flanked by direct repeats. Internal promoters direct RNA polymerase III to transcribe B1 and Alu elements and proceed into the 3' flanking DNA until it reaches a (dT)4 termination signal. The resulting transcripts contain 3'-terminal oligo(U) tracts which can presumably base pair with the A-rich tract to form self-primed templates for reverse transcriptase and retrotransposition. Nuclear extracts from mouse tissue culture cells contain an RNA processing activity that removes the A-rich and 3'-terminal regions from purified B1 RNAs (R. Maraia, Nucleic Acids Res. 19:5695-5702, 1991). In this study, we examined transcription and RNA processing in these nuclear extracts. In contrast to results with use of purified RNA, nascent transcripts synthesized in nuclear extract by RNA polymerase III are not processed, suggesting that the transposition-intermediate-like RNA is shielded from processing by a protein(s). Alteration of an AATTTT TAA termination signal to a GCTTTTGC signal activated processing by greater than 100-fold in coupled transcription/processing reactions. A similar difference was found when expression was compared in frog oocytes. No difference in processing was found if the transcripts were made by T7 RNA polymerase in the presence of the nuclear extract, indicating that the different processing effects of the two terminators were dependent on synthesis by polymerase III. The modulation of processing of B1-Alu transcripts and the potential for retrotransposition of B1 and Alu DNA sequences are discussed.

Methylation of an alpha-foetoprotein gene intragenic site modulates gene activity

By comparing the methylation pattern of Mspl/Hpall sites in the 5' region of the mouse alpha-foetoprotein (AFP) gene of different cells (hepatoma cells, foetal and adult liver, fibroblasts), we found a correlation between gene expression and unmethylation of a site located in the first intron of the gene. Other sites did not show this correlation. In transfection experiments of unmethylated and methylated AFP-CAT chimeric constructions, we then showed that methylation of the intronic site negatively modulates expression of CAT activity. We also found that a DNA segment centered on this site binds nuclear proteins; however methylation did not affect protein binding.

The subset of mouse B1 (Alu-equivalent) sequences expressed as small processed cytoplasmic transcripts

B1 (Alu-equivalent) is a murine short interspersed element whose amplification probably involved an RNA intermediate. B1-homologous RNA comprise a population of heterogenous transcripts of questionable function. A cloned B1 is expressed in the injected frog oocyte by RNA polymerase III transcription, ribonucleoprotein formation, post-transcriptional 3'-processing, and nucleocytoplasmic transport. The present study characterizes small cytoplasmic B1 transcripts of mouse cells. Analyses of ten cDNA clones revealed a subset of a high degree of sequence identity (98%) from which a novel consensus was developed. Structural analyses of these RNAs demonstrated a conserved Alu domain originally identified as part of the 7SL RNA within the translational control domain of the signal recognition particle, while this structure was not conserved in the majority of B1s in the sequence database. Furthermore, it was demonstrated that 3'-processing occurred in only a subset of B1 transcripts in-vitro using homologous nuclear extracts, and in the injected oocyte. The data demonstrate that a limited set of B1 sequences are expressed as processed RNA polymerase III-transcripts of a high degree of structural conservation. Although this subset is transcriptionally active, the selective expression may be due to regulation at the levels of processing and cytoplasmic accumulation. Their lack of Poly-(A) or 3'-oligo-(U) tracts argue that these RNAs are unlikely to represent transposition intermediates. Rather, their cytosolic compartmentalization and conservation of a biologically recognized structure, suggests potential involvement in other aspects of cellular metabolism.

Evolution of mouse B1 repeats: 7SL RNA folding pattern conserved

In a recent report mouse B1 genomic repeats were divided into six families representing different waves of fixation of B1 variants, consistent with the retroposition model of human Alu elements. These data are used to examine the distribution of nucleotide substitutions in individual genomic repeats with respect to family consensus sequences and to compare the minimal energy structures of the corresponding B1 RNAs. By an enzymatic approach the predicted structure of B1 RNAs is experimentally confirmed using as a model sequence an RNA of a young B1 family member transcribed in vitro by T7 RNA polymerase. B1 RNA preserves folding domains of the Alu fragment of 7SL RNA, its progenitor molecule. Our results reveal similarities among 7SL-like retroposons, human Alu, and rodent B1 repeats, and relate the evolutionary conservation of B1 family consensus sequences to selection at the RNA level.

Integration of woodchuck hepatitis virus (WHV) DNA at two chromosomal sites (Vk and gag-like) in a hepatocellular carcinoma

Integration of woodchuck hepatitis virus (WHV) DNA into the liver DNA of a woodchuck infected by the virus was investigated. Clonal viral integration was not detected three months before the appearance of four hepatocellular carcinomas (HCC). Integration of the viral DNA was detected in all four HCCs, of which one was chosen to determine the structure of the viral integration completely in a single tumor. The integration occurred in two sites. One part contains the viral DNA from the middle of the gene encoding surface antigen to two-thirds of the way through the gene encoding X protein (X) with no structural changes. The coding frame of the truncated X gene continues into the chromosomal sequence to make a possible fusion protein. The integration seems to have occurred by recombination within two direct repeats of the viral genome in one junction and by homologous recombination between viral DNA and chromosomal DNA in the other junction. The viral DNA is integrated into a spacer of the immunoglobulin L-chain Vk (IgVk) region without any chromosomal rearrangement accompanying the integration. The viral DNA at the second site has a complex structural rearrangement: part of the preS gene is duplicated and attached to the terminus of the gene encoding core antigen in a head-to-tail fashion, followed by three small fragments derived from other parts of the viral DNA. The integrated preS gene has its own 5' regulatory element and a coding frame consisting of the truncated preS gene, the other parts of viral DNA and the chromosomal sequence.(ABSTRACT TRUNCATED AT 250 WORDS)

Nucleolin gene organization in rodents: highly conserved sequences within three of the 13 introns

The complete nucleotide (nt) sequence of the rat nuc gene encoding nucleolin, the major nucleolar-specific protein in eukaryotic exponentially growing cells, is compared with the corresponding locus recently characterized in mouse. [Bourbon et al., J. Mol. Biol. 200 (1988) 627-638]. In both murine species the genomic organization has been strikingly conserved during evolution, i.e., the coding region extends over 9 kb and is split into 14 exons, encoding a 712-amino acid protein. Moreover, all the exon-intron junction positions were strictly maintained during evolution. More unexpectedly, this analysis revealed that several introns contain highly conserved sequence elements of about 120 nt. The nt sequence of the homologous locus isolated from a Chinese hamster genomic clone established that these regions were under unusually high selective constraints (84-96% identity between the hamster and murine nuc genes) and, although they do not contain open reading frames, they surprisingly appear to be more conserved than most of the exons, suggesting that they play an important role. Such an element of 130 nt presents features of known genes transcribed by RNA polymerase III. Furthermore, in the rat nuc pre-mRNA the 5'- and 3'-end regions of the last intron are fully complementary over 16 nt, and so are predicted to be included in a prominent stem structure. Moreover, an homologous RNA stem structure can be derived from the mouse sequence, including two compensatory nt changes. As the secondary structure would occlude the canonical sequences required for the proper excision of this intron in both murine species, this remarkable finding could be relevant to the regulation of the nuc gene expression at the RNA processing level.

Negative regulation of the human epsilon-globin gene by transcriptional interference: role of an Alu repetitive element

The human epsilon-globin gene has a number of alternative transcription initiation sites which correspond with regions of DNase I hypersensitivity upstream of the canonical cap site. Transcripts originating from the promoters located -4.3/-4.5 and -1.48 kilobase pairs (kbp) and -900 and -200 base pairs (bp) upstream of the major epsilon-globin cap site can, at certain stages of erythroid differentiation, extend through the gene and are polyadenylated. The 350-bp PolIII transcripts, originating within the Alu repetitive element -2.2 kbp upstream of the cap site, extend in the opposite direction from the gene, are nonpolyadenylated, nucleus confined, and are detectable only in mature K562 cells or mature embryonic red blood cells where the epsilon-globin major cap site is maximally transcribed. Fragments containing the promoters located between -4.5 and -4.3 kbp upstream of the gene down regulate transcription from the epsilon-globin gene 20- to 30-fold in a transient expression assay in which both erythroid and nonerythroid cell lines were used. This occurs only when the direction of transcription from the -4.3/-4.5-kbp promoters is towards the gene, and we hypothesize that down regulation is caused by transcriptional interference. Fragments containing the Alu repetitive element -2.2 kbp upstream of the gene can overcome down regulation of the epsilon-globin gene by the -4.5-kbp element when interposed in the direct orientation between this element and the epsilon-globin gene.

Negative regulation of the human epsilon-globin gene by transcriptional interference: role of an Alu repetitive element

The human epsilon-globin gene has a number of alternative transcription initiation sites which correspond with regions of DNase I hypersensitivity upstream of the canonical cap site. Transcripts originating from the promoters located -4.3/-4.5 and -1.48 kilobase pairs (kbp) and -900 and -200 base pairs (bp) upstream of the major epsilon-globin cap site can, at certain stages of erythroid differentiation, extend through the gene and are polyadenylated. The 350-bp PolIII transcripts, originating within the Alu repetitive element -2.2 kbp upstream of the cap site, extend in the opposite direction from the gene, are nonpolyadenylated, nucleus confined, and are detectable only in mature K562 cells or mature embryonic red blood cells where the epsilon-globin major cap site is maximally transcribed. Fragments containing the promoters located between -4.5 and -4.3 kbp upstream of the gene down regulate transcription from the epsilon-globin gene 20- to 30-fold in a transient expression assay in which both erythroid and nonerythroid cell lines were used. This occurs only when the direction of transcription from the -4.3/-4.5-kbp promoters is towards the gene, and we hypothesize that down regulation is caused by transcriptional interference. Fragments containing the Alu repetitive element -2.2 kbp upstream of the gene can overcome down regulation of the epsilon-globin gene by the -4.5-kbp element when interposed in the direct orientation between this element and the epsilon-globin gene.

The transcription control region of the rat alpha-fetoprotein gene. DNA sequence and homology studies

The alpha-fetoprotein (AFP) gene, an important system for studying developmental and tissue-specific gene expression, is regulated mostly through the control of transcription. The promoter and cis-acting DNA elements which regulate the rat gene lie within a 7 kbp region upstream of the cap site. We have determined the sequence of this entire region. It contains several repetitive elements and a species-specific distribution of DNA methylation sites. We aligned our rat AFP sequence with fragmentary mouse and human AFP sequences to define blocks of highly conserved sequence, which we then analyzed for homology to known transcription regulatory sequences. Our analysis demonstrates that the regulatory region of the rat AFP gene is unusually complex.

Successive waves of fixation of B1 variants in rodent lineage history

A new method of analyzing phylogenetic relations among members of sequence family (Quentin 1988) discriminates at least six possible B1 subfamilies in the mouse genome. Several additional and independent observations suggest that these groupings have evolutionary significance, and that successive waves of fixation of new variants occur during rodent lineage history. We have reason to believe that, in a genome, the founder sequences of different families of retroposons are in competition with regard to the amplification/fixation process.

Two regulatory domains flank the mouse H19 gene

The mouse H19 gene was identified by virtue of its coordinate regulation with the mouse alpha-fetoprotein gene. Both genes are expressed in the fetal liver, gut, and visceral endoderm of the yolk sac and are repressed shortly after birth in the liver and gut. They are both under the control of two trans-acting loci: raf, which affects the adult basal levels of the two mRNAs, and Rif, which affects their inducibility during liver regeneration. One crucial difference between the two genes is the activation of the H19 gene in mesoderm derivatives, skeletal and cardiac muscle. As a strategy for explaining both the similarities and differences in their modes of expression, the regulatory domains responsible for the expression of the H19 gene in liver were identified by transiently introducing the gene into a human hepatoma cell line. Two regions necessary for high-level expression of the gene could be identified, a promoter-proximal domain immediately preceding the start of transcription and an enhancer domain which lies between 5 and 6.5 kilobases 3' of the polyadenylation site. The 3' domain consists of two separable enhancer elements, each of which exhibits the properties of tissue-specific enhancers. Nucleotide sequence comparisons between the two H19 and three alpha-fetoprotein enhancers revealed limited similarities which are candidates for binding of common regulatory factors. Sequences which lie 3' of the gene are also required for the expression of the H19 gene following differentiation of teratocarcinoma cells into visceral endoderm.

The organization of repetitive sequences in the albumin and alpha-fetoprotein gene loci in the rat

The distribution of middle repetitive sequences in the genic and extragenic regions of the rat albumin and alpha-fetoprotein genes was analyzed. Their presence was determined by probing Southern blots of restriction fragments of albumin and alpha-fetoprotein genomic subclones with 32P-labeled total rat DNA. Repetitive sequences were detected in both genes. They were classified as weak, moderate and intense hybridizing elements according to the intensity of hybridization. Weak repetitive sequences were characterized as dG.dT repeats by using 32P-labeled poly-(dG.dT)(dC.dA) oligomer probe. They occurred in 5' and 3' extragenic regions of the two genes and in introns 4 and 5 of the albumin gene. The moderate repetitive sequence present in intron 6 of the albumin gene was identified as the rat SINES element. 4D12. The intense repetitive sequence, localized in the 3' non-coding region of the albumin gene, corresponded to the terminal segment of a rat high repeat long interspersed DNA family, L1Rn. 4D12 and L1Rn sequences were also scattered throughout the alpha-fetoprotein locus as moderate and intense repetitive elements, respectively, but their distribution was different from that of the albumin genomic region. These results indicate that repetitive sequences invaded the two loci in a non-conservative manner.

Pathway of B1-Alu expression in microinjected oocytes: Xenopus laevis proteins associated with nuclear precursor and processed cytoplasmic RNAs

We have previously characterized B1-Alu gene expression by microinjected Xenopus laevis oocytes. The transcription, endonucleolytic processing and its kinetics, nuclear transport kinetics, and subsequent cellular compartmentalization have been described previously (Adeniyi-Jones and Zasloff, Nature 317:81-84, 1985). Briefly, a B1-Alu gene is transcribed by RNA polymerase III to a 210-nucleotide (210nt) primary transcript which is processed to yield 135nt and 75nt RNAs. After processing, the 135nt RNA enters the cytoplasmic compartment, where it remains stable, while the 75nt RNA is degraded. In this report we characterize this pathway further and show that the RNAs involved are complexed with specific X. laevis proteins. The primary transcript was associated with an X. laevis protein of 63 kilodaltons (p63) as well as La, a protein known to be associated with RNA polymerase III transcripts. After processing, the cytoplasmic 135nt RNA remained associated only with the X. laevis p63 in the form of a small ribonucleoprotein. Human autoimmune antibodies were purified by affinity chromatography to X. laevis p63 and used to immunoprecipitate human ribonucleoprotein containing a 63-kilodalton polypeptide and small RNAs. These data suggest that Alu-analogous ribonucleoproteins and their metabolic pathways are conserved across species and provide insight as to their possible functions.

Two regulatory domains flank the mouse H19 gene

The mouse H19 gene was identified by virtue of its coordinate regulation with the mouse alpha-fetoprotein gene. Both genes are expressed in the fetal liver, gut, and visceral endoderm of the yolk sac and are repressed shortly after birth in the liver and gut. They are both under the control of two trans-acting loci: raf, which affects the adult basal levels of the two mRNAs, and Rif, which affects their inducibility during liver regeneration. One crucial difference between the two genes is the activation of the H19 gene in mesoderm derivatives, skeletal and cardiac muscle. As a strategy for explaining both the similarities and differences in their modes of expression, the regulatory domains responsible for the expression of the H19 gene in liver were identified by transiently introducing the gene into a human hepatoma cell line. Two regions necessary for high-level expression of the gene could be identified, a promoter-proximal domain immediately preceding the start of transcription and an enhancer domain which lies between 5 and 6.5 kilobases 3' of the polyadenylation site. The 3' domain consists of two separable enhancer elements, each of which exhibits the properties of tissue-specific enhancers. Nucleotide sequence comparisons between the two H19 and three alpha-fetoprotein enhancers revealed limited similarities which are candidates for binding of common regulatory factors. Sequences which lie 3' of the gene are also required for the expression of the H19 gene following differentiation of teratocarcinoma cells into visceral endoderm.

Pathway of B1-Alu expression in microinjected oocytes: Xenopus laevis proteins associated with nuclear precursor and processed cytoplasmic RNAs

We have previously characterized B1-Alu gene expression by microinjected Xenopus laevis oocytes. The transcription, endonucleolytic processing and its kinetics, nuclear transport kinetics, and subsequent cellular compartmentalization have been described previously (Adeniyi-Jones and Zasloff, Nature 317:81-84, 1985). Briefly, a B1-Alu gene is transcribed by RNA polymerase III to a 210-nucleotide (210nt) primary transcript which is processed to yield 135nt and 75nt RNAs. After processing, the 135nt RNA enters the cytoplasmic compartment, where it remains stable, while the 75nt RNA is degraded. In this report we characterize this pathway further and show that the RNAs involved are complexed with specific X. laevis proteins. The primary transcript was associated with an X. laevis protein of 63 kilodaltons (p63) as well as La, a protein known to be associated with RNA polymerase III transcripts. After processing, the cytoplasmic 135nt RNA remained associated only with the X. laevis p63 in the form of a small ribonucleoprotein. Human autoimmune antibodies were purified by affinity chromatography to X. laevis p63 and used to immunoprecipitate human ribonucleoprotein containing a 63-kilodalton polypeptide and small RNAs. These data suggest that Alu-analogous ribonucleoproteins and their metabolic pathways are conserved across species and provide insight as to their possible functions.

Fine-structure mapping of the three mouse alpha-fetoprotein gene enhancers

Multiple cellular enhancers have been identified previously in the 5'-flanking region of the mouse alpha-fetoprotein gene by transient expression assay. In this report the enhancers have been localized to three regions 200 to 300 base pairs in length at 2.5, 5.0, and 6.5 kilobases of DNA upstream of the transcriptional start site. Nucleotide sequence analysis of the three enhancers revealed areas of homology among them, the most significant of which were two regions of 10 and 18 nucleotides in length. Two of the enhancers were analyzed in detail and shown to be composed of multiple nonidentical domains, none of which was sufficient for full enhancer activity; rather, they acted in an additive fashion in generating the full activity of the enhancer. The tissue-specific activity of the enhancer at -2.5 kilobases was assessed by comparing the activities of subdomains in liver- and non-liver-derived cell lines and was found to be the result of both positive elements within the enhancer and at least one negative element to its 5' end. In contrast, the tissue specificity of the enhancer at -5.0 kilobases was maintained when the minimal essential region was tested alone. The nucleotide sequence similarities, as well as the differences among the enhancers, may explain their differing biological activities both in tissue culture and in vivo.

Fine-structure mapping of the three mouse alpha-fetoprotein gene enhancers

Multiple cellular enhancers have been identified previously in the 5'-flanking region of the mouse alpha-fetoprotein gene by transient expression assay. In this report the enhancers have been localized to three regions 200 to 300 base pairs in length at 2.5, 5.0, and 6.5 kilobases of DNA upstream of the transcriptional start site. Nucleotide sequence analysis of the three enhancers revealed areas of homology among them, the most significant of which were two regions of 10 and 18 nucleotides in length. Two of the enhancers were analyzed in detail and shown to be composed of multiple nonidentical domains, none of which was sufficient for full enhancer activity; rather, they acted in an additive fashion in generating the full activity of the enhancer. The tissue-specific activity of the enhancer at -2.5 kilobases was assessed by comparing the activities of subdomains in liver- and non-liver-derived cell lines and was found to be the result of both positive elements within the enhancer and at least one negative element to its 5' end. In contrast, the tissue specificity of the enhancer at -5.0 kilobases was maintained when the minimal essential region was tested alone. The nucleotide sequence similarities, as well as the differences among the enhancers, may explain their differing biological activities both in tissue culture and in vivo.

The regulation of albumin and alpha-fetoprotein gene expression in mammals

Albumin and alpha-fetoprotein (AFP) are two plasma proteins synthesized by the liver and the yolk sac. The production of these major proteins is subject to considerable and characteristic variations during both the course of development and hepatic carcinogenesis. It is therefore a system of choice for the analysis of genetic expression during normal differentiation and the cancerous state of eukaryotic cells. The knowledge of regulatory mechanisms at the cellular and molecular levels of the albumin and AFP genes has recently made great progress: 1) the cells which are responsible for the synthesis of albumin and AFP in the liver and other organs have been defined by conjointly using in vitro and in vivo molecular hybridization techniques; 2) the organization of these genes and their adjoining regions has been established in the rat, the mouse and man; 3) the level at which the synthesis of these two proteins is regulated has been determined; it is the transcriptional level. The transcriptional regulation of the albumin and AFP genes could be the result of genome and/or chromatin conformation level modifications. Different groups have shown that: 1) the global structure of the albumin and AFP genes does not change during the course of development and hepatic carcinogenesis; 2) modifications at the level of the methylation of certain specific cytosines could be associated with the variations in the transcription of these genes; 3) global or local (hypersensitive sites with DNase I) changes of chromatin conformation could be correlated to the potential or the overt activity of the transcription of these genes. Very recently certain 'regulatory' regions having cis 'enhancer' or 'silencer' properties have been detected upstream from the albumin and AFP genes. These regions are hypothesized to be DNA 'target' sequences on which trans-acting regulatory factors are fixed and which control the transcription of these genes. Starting from the framework of this recent work, a model of albumin and AFP gene regulation is proposed.

Structure, polymorphism, and novel repeated DNA elements revealed by a complete sequence of the human alpha-fetoprotein gene

The human alpha-fetoprotein gene spans 19,489 base pairs from the putative "Cap" site to the polyadenylation site. It is composed of 15 exons separated by 14 introns, which are symmetrically placed within the three domains of alpha-fetoprotein. In the 5' region, a putative TATAAA box is at position -21, and a variant sequence, CCAAC, of the common CAT box is at -65. Enhancer core sequences GTGGTTTAAAG are found in introns 3 and 4, and several copies of glucocorticoid response sequences AGATACAGTA are found on the template strand of the gene. There are six polymorphic sites within 4690 base pairs of contiguous DNA derived from two allelic alpha-fetoprotein genes. This amounts to a measured polymorphic frequency of 0.13%, or 6.4 X 10(-4)/site, which is about 5-10 times lower than values estimated from studies on polymorphic restriction sites in other regions of the human genome. There are four types of repetitive sequence elements in the introns and flanking regions of the human alpha-fetoprotein gene. At least one of these is apparently a novel structure (designated Xba) and is found as a pair of direct repeats, with one copy in intron 7 and the other in intron 8. It is conceivable that within the last 2 million years the copy in intron 8 gave rise to the repeat in intron 7. Their present location on both sides of exon 8 gives these sequences a potential for disrupting the functional integrity of the gene in the event of an unequal crossover between them. There are three Alu elements, one of which is in intron 4; the others are located in the 3' flanking region. A solitary Kpn repeat is found in intron 3. The Xba and Kpn repeats were only detected by complete sequencing of the introns. Neither X, Xba, nor Kpn elements are present in the related human albumin gene, whereas Alu's are present in different positions. From phylogenetic evidence, it appears that Alu elements were inserted into the alpha-fetoprotein gene at some time postdating the mammalian radiation 85 million years ago.

Multiple regulatory elements in the intergenic region between the alpha-fetoprotein and albumin genes

Three enhancer elements spanning a distance of 7 kilobases have been found at the 5' end of the alpha-fetoprotein (AFP) gene. These elements were identified by transient expression assay after the introduction of a modified mouse AFP gene with variable amounts of 5' flanking sequence into a human hepatoma cell line, Hep G2. These regulatory elements function in a position-independent and orientation-independent manner that is typical of enhancers. All three elements will stimulate transcription from the promoter of the herpes simplex virus thymidine kinase gene. In Hep G2 cells, transcriptional activation from the heterologous promoter was approximately 25- to 50-fold higher than the basal levels obtained in the absence of AFP enhancer elements. In HeLa cells, the increase in thymidine kinase gene transcription varied from 6- to 14-fold, indicating that the enhancer elements exhibit some cell type specificity. Deletion analysis of the region proximal to the AFP transcription initiation site identified an essential region between 85 and 52 bases upstream of the site of initiation of transcription whose removal resulted in almost complete extinction of transcriptional activity. This region, which has been shown to be dispensable for transcription in HeLa cells, defines a second tissue-specific regulatory region in the gene.

Polymorphism in an androgen-regulated mouse gene is the result of the insertion of a B1 repetitive element into the transcription unit

The single-copy RP2 gene in mice produces three major mRNAs, the abundances of which are significantly increased in the kidneys by the administration of testosterone. S1 nuclease analysis of the kidney mRNAs indicated that they differ in the lengths of their 3' untranslated regions as a result of the use of different polyadenylation sites. When the mRNAs from different inbred mouse strains were examined by Northern blot analysis, it was observed that the largest mRNA varies in size, whereas the sizes of the other mRNAs remain the same. In DBA/LiHa and DBA/2J mice, the largest mRNA is approximately 2,150 nucleotides long, whereas the corresponding mRNA in C57BL/6J and BALB/cJ mice is only 1,950 nucleotides in length. All of these strains also have RP2 mRNAs that are 1,450 and 1,350 nucleotides long. By S1 nuclease mapping and comparison of the sequence of cDNA clones representing these mRNAs in DBA/LiHa and C57BL/6J mice, we determined that this size difference or polymorphism observed in the largest mRNA is the result of the insertion of a member of the B1 family of repeats into the 3' untranslated region of the RP2 gene in DBA mice. This particular B1 repeat is transcribed by RNA polymerase III in vitro, and its transcriptional orientation is opposite to that of the RP2 transcript. The polymorphism described here is evidence for the mobility of B1 repetitive elements within the genome.

Structure and in vitro transcription of a mouse B1 cluster containing a unique B1 dimer

A highly repetitive DNA element located 950 bp upstream from a mouse U2 small nuclear RNA gene has been cloned and characterized. The repetitive element is composed of a simple sequence repeat and a cluster of three B1 sequences. Two of these B1 elements are arranged head-to-tail and are joined by an oligo(dA)-rich linker. This unique B1 dimer, comprised of 339 bp, resembles the dimeric structure of primate Alu-family sequences, particularly that of a prototypic human Alu element. The other B1 element within the mouse cluster is a typical monomeric unit. Transcription studies performed in HeLa cell extracts with deletion mutants of the B1 cluster reveal that the single B1 unit is expressed at least 50 times more efficiently than the B1 dimer region. Furthermore, the B1 dimer which contains mutations in the first polymerase III promoter region is not transcribed end-to-end. We conclude that this B1 dimer is unlikely to give rise to a new dimeric retroposon family in the mouse genome.

Transcriptional inactivity of Alu repeats in HeLa cells

The in vivo transcription of human Alu family members has been investigated by a sensitive primer extension method. The selected primers represent various regions of the Alu family consensus sequence, thus assaying the transcriptional activity of the entire family rather than the activity of an individual member sequence. Using this method, a very small number of RNA molecules per HeLa cell is found to have a distribution of 5' ends centered on the in vitro Alu transcription start site. The distribution of these 5' ends suggests that they are more likely the result of hnRNA degradation rather than transcription start sites. Therefore, despite their great numerical abundance, Alu family members are transcriptionally silent in HeLa cells.

Multiple regulatory elements in the intergenic region between the alpha-fetoprotein and albumin genes

Three enhancer elements spanning a distance of 7 kilobases have been found at the 5' end of the alpha-fetoprotein (AFP) gene. These elements were identified by transient expression assay after the introduction of a modified mouse AFP gene with variable amounts of 5' flanking sequence into a human hepatoma cell line, Hep G2. These regulatory elements function in a position-independent and orientation-independent manner that is typical of enhancers. All three elements will stimulate transcription from the promoter of the herpes simplex virus thymidine kinase gene. In Hep G2 cells, transcriptional activation from the heterologous promoter was approximately 25- to 50-fold higher than the basal levels obtained in the absence of AFP enhancer elements. In HeLa cells, the increase in thymidine kinase gene transcription varied from 6- to 14-fold, indicating that the enhancer elements exhibit some cell type specificity. Deletion analysis of the region proximal to the AFP transcription initiation site identified an essential region between 85 and 52 bases upstream of the site of initiation of transcription whose removal resulted in almost complete extinction of transcriptional activity. This region, which has been shown to be dispensable for transcription in HeLa cells, defines a second tissue-specific regulatory region in the gene.

In vitro transcription of RU, a middle repetitive element of the rat genome

Repetitive DNA sequences have been found within as well as adjacent to the rat growth hormone (rGH) gene (1,2). In vitro transcription of the rGH gene yields transcripts predominantly from a tandemly duplicated repeat (RU) in the second intron of the gene. The relative alpha-amanitin sensitivity of this transcription indicates that it is carried out by RNA polymerase III. Transcription initiates within a 5' flanking 15 base-pair repeat, and terminates within a stretch of A residues at the end of each repeat, a termination site that is notably unlike most of those used by polymerase III. Approximately 75% of the transcripts stop at the end of the first repeat; the remainder "read-through" to a homologous termination region at the end of the second repeat.

Gene within a gene: nested Drosophila genes encode unrelated proteins on opposite DNA strands

A pupal cuticle protein gene has been found within an intron of a Drosophila gene that encodes three purine pathway enzymatic activities. The intronic gene is encoded on the DNA strand opposite the purine pathway gene and is itself interrupted by an intron. Whereas the purine pathway gene is active throughout development, the intronic cuticle protein gene is expressed primarily over a 3 hr period in the abdominal epidermal cells of prepupae that secrete the pupal cuticle. Therefore, a housekeeping gene and a developmentally regulated gene function in a nested arrangement.

Polymorphism in an androgen-regulated mouse gene is the result of the insertion of a B1 repetitive element into the transcription unit

The single-copy RP2 gene in mice produces three major mRNAs, the abundances of which are significantly increased in the kidneys by the administration of testosterone. S1 nuclease analysis of the kidney mRNAs indicated that they differ in the lengths of their 3' untranslated regions as a result of the use of different polyadenylation sites. When the mRNAs from different inbred mouse strains were examined by Northern blot analysis, it was observed that the largest mRNA varies in size, whereas the sizes of the other mRNAs remain the same. In DBA/LiHa and DBA/2J mice, the largest mRNA is approximately 2,150 nucleotides long, whereas the corresponding mRNA in C57BL/6J and BALB/cJ mice is only 1,950 nucleotides in length. All of these strains also have RP2 mRNAs that are 1,450 and 1,350 nucleotides long. By S1 nuclease mapping and comparison of the sequence of cDNA clones representing these mRNAs in DBA/LiHa and C57BL/6J mice, we determined that this size difference or polymorphism observed in the largest mRNA is the result of the insertion of a member of the B1 family of repeats into the 3' untranslated region of the RP2 gene in DBA mice. This particular B1 repeat is transcribed by RNA polymerase III in vitro, and its transcriptional orientation is opposite to that of the RP2 transcript. The polymorphism described here is evidence for the mobility of B1 repetitive elements within the genome.

Alternative splicing caused by RNA secondary structure

mRNA precursors with stable hairpins were constructed by inserting inverted repeats into an adenovirus transcriptional template that encoded the three late leader exons. When the loop of the hairpin contained the second exon and the flanking splice sites, most of the RNA spliced in vitro had the first exon joined directly to the third exon. The remainder was spliced normally. The same types of alternatively spliced RNAs were formed when a similar template was introduced into HeLa cells by transfection. Thus both in extracts and in cells, an exon became optional when sequestered in a hairpin loop. Perhaps a related mechanism creates the alternative splicing patterns of complex transcription units.

Upstream sequences modulate the internal promoter of the human 7SL RNA gene

The human genome is rich in sequences which are structurally related to the 7SL RNA component of the signal recognition particle. The 7SL DNA sequence family consists of four 7SL genes, 500 7SL pseudogenes (which are truncated at one or both ends of the 7SL sequence) and 500,000 Alu sequences. Both 7SL genes and Alu elements are transcribed by RNA polymerase III, and we show here that the internal 7SL promoter lies within the Alu-like part of the 7SL gene. Why then does RNA polymerase III transcribe the few 7SL genes so efficiently, while transcripts from the far more abundant Alu elements are not readily detectable? We find that a human 7SL gene and a synthetic Alu sequence derived from it are expressed 50-100-fold more efficiently in vitro than either a representative Alu element or two 7SL pseudogenes. 5' Deletion and insertion mutants of the 7SL gene demonstrate that, in conjunction with the internal promoter, the first 37 nucleotides upstream from the transcription start site are essential for efficient and accurate initiation in vitro. We suggest that the genomic sequences upstream from most Alu elements and 7SL pseudogenes do not contain this element, and consequently that only a small subset of such sequences can be transcribed in vivo. This may help to explain the homogeneity of the Alu family within each mammalian genome, as well as the species-specific differences between mammalian Alu families.

Nucleotide sequence of small polyadenylated B2 RNA

Small poly(A)-containing RNA molecules which hybridize to the ubiquitous short repetitive sequence B2 and which are transcribed by RNA polymerase III have been identified in the cytoplasm of mouse cells. Here, we describe the structure of this small B2 RNA. A cDNA library was prepared from low-molecular-weight cytoplasmic poly(A)+RNA isolated from Ehrlich carcinoma cells and the clones which hybridized to B2 sequence were selected. The clones were sequenced and shown to contain B2 sequences followed by a poly(A) tract. The sequences of the cloned B2 RNAs different from each other by 3-10%, being similar in this respect to genomic B2 copies. Thus, B2 RNA is transcribed from many different B2 sequences in the genome. The 5'-ends of B2 RNA at least in most molecules coincide with the beginning of B2 genomic sequence. The poly(A) segments located at the 3'-end of small B2 RNA are the same size as in mRNA molecules, suggesting posttranscriptional formation. In some clones, additional sequences were detected between the 3'-end of B2 sequence and the poly(A) stretch. They seem to result from a lesion in the RNA polymerase III terminator in the corresponding B2 sequences. The possible significance of B2 sequences and small B2 RNA is discussed.

Transcription, processing and nuclear transport of a B1 Alu RNA species complementary to an intron of the murine alpha-fetoprotein gene

The Alu sequence family comprises the major dispersed repeat sequences of rodent and primate genomes, numbering greater than 300,000 copies in the human haploid genome. The function of these elements is unknown. The sequences can be transcribed by RNA polymerase III and represent a substantial fraction of total heterogeneous nuclear RNA. Alu sequences can be found both in the flanking regions and within the transcription units of several well-characterized genes. Here we show that some members of the mouse B1 Alu sequence family encode a small cytoplasmic RNA. The mouse B1 sequence is congruent to 130 nucleotides long and shows homology with the monomeric units of the dimeric 300-nucleotide primate sequence. By means of microinjection studies in the Xenopus laevis oocyte, we have elucidated a novel pathway leading to the appearance of a processed B1-type Alu RNA species in the cytoplasm. The abundance of this small Alu RNA differs between various mouse tissues, suggesting a role in tissue-specific gene expression.

Stable transcription complex on a class III gene in a minichromosome

We have constructed recombinant simian virus 40 molecules containing Xenopus 5S RNA and tRNA genes. Recombinant minichromosomes containing these genes were isolated to study the interaction of RNA polymerase III transcription factors with these model chromatin templates. Minichromosomes containing a tRNAMet gene can be isolated in a stable complex with transcription factors (IIIB and IIIC) and are active in vitro templates for purified RNA polymerase III. In contrast, minichromosomes containing a 5S RNA gene are refractory to transcription by purified RNA polymerase III in either the absence or the presence of other factors.

Biosynthesis and cytoplasmic distribution of small poly(A)-containing B2 RNA

Previously, we described a small polyadenylated RNA predominantly located in cytoplasm and hybridizing with the ubiquitous B2 sequence of the mouse genome (Kramerov, D.A., Lekakh, I.V., Samarina, O.P. and Ryskov, A.P. (1982) Nucleic Acids Res. 10, 7477-7491). This 180-300 nucleotide long RNA was designated B2 RNA. Here, we demonstrate that B2 RNA is complementary to just one of the strands of cloned B2 sequence. The synthesis of B2 is rather resistant to ultraviolet irradiation of Ehrlich ascites carcinoma cells. The treatment of the cells with alpha-amanitin at a concentration completely blocking the formation of small nuclear RNAs U1, U2 and U3 does not interfere with the B2 RNA synthesis. These results suggest that B2 RNA formation is directly transcribed with the aid of RNA polymerase III, rather than being formed in the course of the processing of large RNA molecules which are known to contain a lot of B2 sequences. We also surprisingly found that the synthesis of up to 50% of long poly(A) +RNA in Ehrlich carcinoma cells is rather resistant to alpha-amanitin. The possible role of genetic elements including B2 sequences able to promote large RNA-polymerase III transcripts is discussed. B2 RNA in the cytoplasm is incorporated into the ribonucleoprotein particles, both small (12-18 S) and heavy. The latter probably correspond to informosomes. After deproteinization of heavy particles, a major part of B2 RNA still cosediments with mRNA and is split from it only after denaturation. We suggest that the B2 RNA of heavy ribonucleoproteins is associated with mRNA by short complementary stretches. About half of the B2 RNA is recovered in the cytoskeletal fraction. The possible role of B2 RNA in mRNA transport or in translation regulation is discussed.

Stable transcription complex on a class III gene in a minichromosome

We have constructed recombinant simian virus 40 molecules containing Xenopus 5S RNA and tRNA genes. Recombinant minichromosomes containing these genes were isolated to study the interaction of RNA polymerase III transcription factors with these model chromatin templates. Minichromosomes containing a tRNAMet gene can be isolated in a stable complex with transcription factors (IIIB and IIIC) and are active in vitro templates for purified RNA polymerase III. In contrast, minichromosomes containing a 5S RNA gene are refractory to transcription by purified RNA polymerase III in either the absence or the presence of other factors.