Sequence requirements for transcriptional arrest in exon 1 of the murine adenosine deaminase gene

Transfer of Tat and release of TAR RNA during the activation of the human immunodeficiency virus type-1 transcription elongation complex

The HIV-1 trans-activator protein, Tat, is a potent activator of transcriptional elongation. Tat is recruited to the elongating RNA polymerase during its transit through the trans-activation response region (TAR) because of its ability to bind directly to TAR RNA expressed on the nascent RNA chain. We have shown that transcription complexes that have acquired Tat produce 3-fold more full-length transcripts than complexes not exposed to Tat. Western blotting experiments demonstrated that Tat is tightly associated with the paused polymerases. To determine whether TAR RNA also becomes attached to the transcription complex, DNA oligonucleotides were annealed to the nascent chains on the arrested complexes and the RNA was cleaved by RNase H. After cleavage, the 5' end of the nascent chain, carrying TAR RNA, is quantitatively removed, but the 3' end of the transcript remains associated with the transcription complex. Even after the removal of TAR RNA, transcription complexes that have been activated by Tat show enhanced processivity. We conclude that Tat, together with cellular co-factors, becomes attached to the transcription complex and stimulates processivity, whereas TAR RNA does not play a direct role in the activation of elongation and is used simply to recruit Tat and cellular co-factors.

Control of transcription arrest in intron 1 of the murine adenosine deaminase gene

Transcription arrest plays a key role in the regulation of the murine adenosine deaminase (ADA) gene, as well as a number of other cellular and viral genes. We have previously characterized the ADA intron 1 arrest site, located 145 nucleotides downstream of the transcription start site, with respect to sequence and elongation factor requirements. Here, we show that the optimal conditions for both intron 1 arrest and overall ADA transcription involve the addition of high concentrations of KCl soon after initiation. As we have further delineated the sequence requirements for intron 1 arrest, we have found that sequences downstream of the arrest site are unnecessary for arrest. Also, a 24-bp fragment containing sequences upstream of the arrest site is sufficient to generate arrest downstream of the adenovirus major late promoter only in the native orientation. Surprisingly, we found that deletion of sequences encompassing the ADA transcription start site substantially reduced intron 1 arrest, with no effect on overall levels of transcription. At the same time, deletion of sequences upstream of the TATA box had no significant effect on either process. We believe the start site mutations have disrupted either the assembly or the composition of the transcription complex such that intron 1 site read-through is now favored. This finding, coupled with the increase in overall transcription after high-concentration KCl treatment, allows us to further refine our model of ADA gene regulation.

Control of transcription arrest in intron 1 of the murine adenosine deaminase gene

Transcription arrest plays a key role in the regulation of the murine adenosine deaminase (ADA) gene, as well as a number of other cellular and viral genes. We have previously characterized the ADA intron 1 arrest site, located 145 nucleotides downstream of the transcription start site, with respect to sequence and elongation factor requirements. Here, we show that the optimal conditions for both intron 1 arrest and overall ADA transcription involve the addition of high concentrations of KCl soon after initiation. As we have further delineated the sequence requirements for intron 1 arrest, we have found that sequences downstream of the arrest site are unnecessary for arrest. Also, a 24-bp fragment containing sequences upstream of the arrest site is sufficient to generate arrest downstream of the adenovirus major late promoter only in the native orientation. Surprisingly, we found that deletion of sequences encompassing the ADA transcription start site substantially reduced intron 1 arrest, with no effect on overall levels of transcription. At the same time, deletion of sequences upstream of the TATA box had no significant effect on either process. We believe the start site mutations have disrupted either the assembly or the composition of the transcription complex such that intron 1 site read-through is now favored. This finding, coupled with the increase in overall transcription after high-concentration KCl treatment, allows us to further refine our model of ADA gene regulation.

Sp1 is essential for both enhancer-mediated and basal activation of the TATA-less human adenosine deaminase promoter

Tissue-specific expression of the human adenosine deaminase (ADA) gene is mediated by transcriptional activation over a thousand-fold range. Cis-regulatory regions responsible for high and basal levels of activation include an enhancer and the proximal promoter region. While analyses of the T-cell specific enhancer have been carried out, detailed studies of the the promoter region or promoter-enhancer interactions have not. Examination of the promoter region by homology searches revealed six putative Sp1 binding sites. DNase I footprinting showed that Sp1 is able to bind these sites. Deletion analysis indicated that the proximal Sp1 site is required for activation of a reporter gene to detectable levels and that the more distal Sp1 sites further activate the level of expression. Inclusion of an ADA enhancer-containing fragment in these deletion constructions demonstrated that Sp1 sites are also essential for enhancer function. Apparently Sp1 controls not only low level expression but is also an integral part of the mechanism by which the enhancer achieves high level ADA expression. Mutagenesis of a potential TBP binding site at base pairs -21 to -26 decreased activity only two-fold indicating that it is not essential for transcriptional activation or enhancement.

Premature termination of tubulin gene transcription in Xenopus oocytes is due to promoter-dependent disruption of elongation

We have shown previously that the Xenopus alpha-tubulin gene, X alpha T14, exhibits premature termination of transcription when injected into oocyte nuclei. The 3' ends of prematurely terminated transcripts are formed immediately downstream of a stem-loop sequence found in the first 41 bp of the 5' leader. We show here, using deleted constructs, that premature termination requires the presence only of sequences from -200 to +19 relative to the initiation site. Deletion of the stem-loop does not increase the production of extended transcripts, and premature termination apparently continues at nonspecific sites. This finding indicates that disruption of the elongation phase of transcription rather than abrogation of a specific antitermination mechanism is the cause of premature termination in X alpha T14. We also found that disruption of elongation on a reporter gene could be induced specifically by competition with X alpha T14 promoters. To identify which elements of the promoter might interact with elongation determinants to cause this competition, we constructed a series of internal promoter mutants. Most mutations in the -200 to -60 region of the promoter had some effect on initiation frequency but did not cause any significant change in levels of premature termination. However, mutations in the core promoter that removed the TATA box consensus causes major change in initiation and resulted in a marked decrease in the production of prematurely terminated transcripts relative to extended transcripts. We discuss why such promoters can apparently escape the disruption of elongation that leads to premature termination.

Premature termination of tubulin gene transcription in Xenopus oocytes is due to promoter-dependent disruption of elongation

We have shown previously that the Xenopus alpha-tubulin gene, X alpha T14, exhibits premature termination of transcription when injected into oocyte nuclei. The 3' ends of prematurely terminated transcripts are formed immediately downstream of a stem-loop sequence found in the first 41 bp of the 5' leader. We show here, using deleted constructs, that premature termination requires the presence only of sequences from -200 to +19 relative to the initiation site. Deletion of the stem-loop does not increase the production of extended transcripts, and premature termination apparently continues at nonspecific sites. This finding indicates that disruption of the elongation phase of transcription rather than abrogation of a specific antitermination mechanism is the cause of premature termination in X alpha T14. We also found that disruption of elongation on a reporter gene could be induced specifically by competition with X alpha T14 promoters. To identify which elements of the promoter might interact with elongation determinants to cause this competition, we constructed a series of internal promoter mutants. Most mutations in the -200 to -60 region of the promoter had some effect on initiation frequency but did not cause any significant change in levels of premature termination. However, mutations in the core promoter that removed the TATA box consensus causes major change in initiation and resulted in a marked decrease in the production of prematurely terminated transcripts relative to extended transcripts. We discuss why such promoters can apparently escape the disruption of elongation that leads to premature termination.

Functional analysis of a stable transcription arrest site in the first intron of the murine adenosine deaminase gene

Transcription arrest plays a role in regulating the expression of a number of genes, including the murine adenosine deaminase (ADA) gene. We have previously identified two prominent arrest sites at the 5' end of the ADA gene: one in the first exon and one in the first intron (J. W. Innis and R. E. Kellems, Mol. Cell. Biol. 11:5398-5409, 1991). Here we report the functional characterization of the intron 1 arrest site, located 137 to 145 nucleotides downstream of the cap site. We have determined, using gel filtration, that the intron 1 arrest site is a stable RNA polymerase II pause site and that the transcription elongation factor SII promotes read-through at this site. Additionally, the sequence determinants for the pause are located within a 37-bp fragment encompassing this site (+123 to +158) and can direct transcription arrest in an orientation-dependent manner in the context of the ADA and adenovirus major late promoters. Specific point mutations in this region increase or decrease the relative pausing efficiency. We also show that the sequence determinants for transcription arrest can function when placed an additional 104 bp downstream of their natural position.

Functional analysis of a stable transcription arrest site in the first intron of the murine adenosine deaminase gene

Transcription arrest plays a role in regulating the expression of a number of genes, including the murine adenosine deaminase (ADA) gene. We have previously identified two prominent arrest sites at the 5' end of the ADA gene: one in the first exon and one in the first intron (J. W. Innis and R. E. Kellems, Mol. Cell. Biol. 11:5398-5409, 1991). Here we report the functional characterization of the intron 1 arrest site, located 137 to 145 nucleotides downstream of the cap site. We have determined, using gel filtration, that the intron 1 arrest site is a stable RNA polymerase II pause site and that the transcription elongation factor SII promotes read-through at this site. Additionally, the sequence determinants for the pause are located within a 37-bp fragment encompassing this site (+123 to +158) and can direct transcription arrest in an orientation-dependent manner in the context of the ADA and adenovirus major late promoters. Specific point mutations in this region increase or decrease the relative pausing efficiency. We also show that the sequence determinants for transcription arrest can function when placed an additional 104 bp downstream of their natural position.

Transcription elongation in the human c-myc gene is governed by overall transcription initiation levels in Xenopus oocytes

Both transcription initiation and transcription elongation contribute to the regulation of steady-state c-myc RNA levels. We have used the Xenopus oocyte transcription assay to study premature transcription termination which occurs in the first exon and intron of the human c-myc gene. Previous studies showed that after injection into Xenopus oocytes transcription from the c-myc P1 promoter resulted in read-through transcripts whereas transcription from the stronger P2 promoter resulted in a combination of prematurely terminated and read-through transcripts. We now demonstrate that this promoter-specific processivity results from the overall amount of RNA polymerase II transcription occurring from either promoter. Parameters that reduce the amount of transcription from P1 or P2, such as decreased concentration of template injected or decreased incubation time, result in a reduction in the ratio of terminated to read-through c-myc transcripts. Conversely, when transcription levels are increased by higher concentrations of injected template, increased incubation time, or coinjection with competing template, the ratio of terminated to read-through transcripts increases. We hypothesize that an RNA polymerase II processivity function is depleted above a threshold level of transcription initiation, resulting in high levels of premature transcription termination. These findings account for the promoter-specific effects on transcription elongation previously seen in this assay system and suggest a mechanism whereby limiting transcription elongation factors may contribute to transcription regulation in other eukaryotic cells.

Transcription elongation in the human c-myc gene is governed by overall transcription initiation levels in Xenopus oocytes

Both transcription initiation and transcription elongation contribute to the regulation of steady-state c-myc RNA levels. We have used the Xenopus oocyte transcription assay to study premature transcription termination which occurs in the first exon and intron of the human c-myc gene. Previous studies showed that after injection into Xenopus oocytes transcription from the c-myc P1 promoter resulted in read-through transcripts whereas transcription from the stronger P2 promoter resulted in a combination of prematurely terminated and read-through transcripts. We now demonstrate that this promoter-specific processivity results from the overall amount of RNA polymerase II transcription occurring from either promoter. Parameters that reduce the amount of transcription from P1 or P2, such as decreased concentration of template injected or decreased incubation time, result in a reduction in the ratio of terminated to read-through c-myc transcripts. Conversely, when transcription levels are increased by higher concentrations of injected template, increased incubation time, or coinjection with competing template, the ratio of terminated to read-through transcripts increases. We hypothesize that an RNA polymerase II processivity function is depleted above a threshold level of transcription initiation, resulting in high levels of premature transcription termination. These findings account for the promoter-specific effects on transcription elongation previously seen in this assay system and suggest a mechanism whereby limiting transcription elongation factors may contribute to transcription regulation in other eukaryotic cells.

Control of formation of two distinct classes of RNA polymerase II elongation complexes

We have examined elongation by RNA polymerase II initiated at a promoter and have identified two classes of elongation complexes. Following initiation at a promoter, all polymerase molecules enter an abortive mode of elongation. Abortive elongation is characterized by the rapid generation of short transcripts due to pausing of the polymerase followed by termination of transcription. Termination of the early elongation complexes can be suppressed by the addition of 250 mM KCl or 1 mg of heparin per ml soon after initiation. Elongation complexes of the second class carry out productive elongation in which long transcripts can be synthesized. Productive elongation complexes are derived from early paused elongation complexes by the action of a factor which we call P-TEF (positive transcription elongation factor). P-TEF is inhibited by 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole at concentrations which have no effect on the initiation of transcription. By using templates immobilized on paramagnetic particles, we show that isolated preinitiation complexes lack P-TEF and give rise to transcription complexes which can carry out only abortive elongation. The ability to carry out productive elongation can be restored to isolated transcription complexes by the addition of P-TEF after initiation. A model is presented which describes the role of elongation factors in the formation and maintenance of elongation complexes. The model is consistent with the available in vivo data concerning control of elongation and is used to predict the outcome of other potential in vitro and in vivo experiments.

Stability of Drosophila RNA polymerase II elongation complexes in vitro

We show that nuclear extract from Drosophila Kc cells supports efficient elongation by RNA polymerase II initiated from the actin 5C promoter. The addition of 0.3% Sarkosyl, 1 mg of heparin per ml, or 250 mM KCl immediately after initiation has two effects. First, the elongation rate is reduced 80 to 90% as a result of the inhibition of elongation factors. Second, there is an increase in the amount of long runoff RNA, suggesting that there is an early block to elongation that is relieved by the disruptive reagents. Consistent with the first effect, we find that the ability of factor 5 (TFIIF) to stimulate the elongation rate is inhibited by the disruptive agents when assayed in a defined system containing pure RNA polymerase II and a dC-tailed template. The disruptive agents also inhibit the ability of DmS-II to suppress transcriptional pausing but only slightly reduce the ability of DmS-II to increase the elongation rate twofold. The pause sites encountered by RNA polymerase II after initiation at a promoter and subsequent treatment with the disruptive reagents are also recognized by pure polymerase transcribing a dC-tailed template. It has been suggested that 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole inhibits RNA polymerase II during elongation, but we find that the purine nucleoside analog has no effect on elongation complexes containing RNA over 500 nucleotides in length or on the action of factor 5 or DmS-II in the defined system.

Control of formation of two distinct classes of RNA polymerase II elongation complexes

We have examined elongation by RNA polymerase II initiated at a promoter and have identified two classes of elongation complexes. Following initiation at a promoter, all polymerase molecules enter an abortive mode of elongation. Abortive elongation is characterized by the rapid generation of short transcripts due to pausing of the polymerase followed by termination of transcription. Termination of the early elongation complexes can be suppressed by the addition of 250 mM KCl or 1 mg of heparin per ml soon after initiation. Elongation complexes of the second class carry out productive elongation in which long transcripts can be synthesized. Productive elongation complexes are derived from early paused elongation complexes by the action of a factor which we call P-TEF (positive transcription elongation factor). P-TEF is inhibited by 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole at concentrations which have no effect on the initiation of transcription. By using templates immobilized on paramagnetic particles, we show that isolated preinitiation complexes lack P-TEF and give rise to transcription complexes which can carry out only abortive elongation. The ability to carry out productive elongation can be restored to isolated transcription complexes by the addition of P-TEF after initiation. A model is presented which describes the role of elongation factors in the formation and maintenance of elongation complexes. The model is consistent with the available in vivo data concerning control of elongation and is used to predict the outcome of other potential in vitro and in vivo experiments.

Stability of Drosophila RNA polymerase II elongation complexes in vitro

We show that nuclear extract from Drosophila Kc cells supports efficient elongation by RNA polymerase II initiated from the actin 5C promoter. The addition of 0.3% Sarkosyl, 1 mg of heparin per ml, or 250 mM KCl immediately after initiation has two effects. First, the elongation rate is reduced 80 to 90% as a result of the inhibition of elongation factors. Second, there is an increase in the amount of long runoff RNA, suggesting that there is an early block to elongation that is relieved by the disruptive reagents. Consistent with the first effect, we find that the ability of factor 5 (TFIIF) to stimulate the elongation rate is inhibited by the disruptive agents when assayed in a defined system containing pure RNA polymerase II and a dC-tailed template. The disruptive agents also inhibit the ability of DmS-II to suppress transcriptional pausing but only slightly reduce the ability of DmS-II to increase the elongation rate twofold. The pause sites encountered by RNA polymerase II after initiation at a promoter and subsequent treatment with the disruptive reagents are also recognized by pure polymerase transcribing a dC-tailed template. It has been suggested that 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole inhibits RNA polymerase II during elongation, but we find that the purine nucleoside analog has no effect on elongation complexes containing RNA over 500 nucleotides in length or on the action of factor 5 or DmS-II in the defined system.

Sequence requirements for transcriptional arrest in exon 1 of the human adenosine deaminase gene

We have previously demonstrated that a transcriptional arrest site exists in exon 1 of the human adenosine deaminase (ADA) gene and that this site may play a role in ADA gene expression (Z. Chen, M. L. Harless, D. A. Wright, and R. E. Kellems, Mol. Cell. Biol. 10:4555-4564, 1990). Sequences involved in this process are not known precisely. To further define the template requirements for transcriptional arrest within exon 1 of the human ADA gene, various ADA templates were constructed and their abilities to confer transcriptional arrest were determined following injection into Xenopus oocytes. The exon 1 transcriptional arrest signal functioned downstream of several RNA polymerase II promoters and an RNA polymerase III promoter, implying that the transcriptional arrest site in exon 1 of the ADA gene is promoter independent. We identified a 43-bp DNA fragment which functions as a transcriptional arrest signal. Additional studies showed that the transcriptional arrest site functioned only in the naturally occurring orientation. Therefore, we have identified a 43-bp DNA fragment which functions as a transcriptional arrest signal in an orientation-dependent and promoter-independent manner. On the basis of our findings, we hypothesize that tissue-specific expression of the ADA gene is governed by factors that function as antiterminators to promote transcriptional readthrough of the exon 1 transcriptional arrest site.

Premature termination of transcription from the P1 promoter of the mouse c-myc gene

Modulation of transcriptional elongation within the c-myc gene is thought to play a major role in determining levels of c-myc mRNA in both normal and tumor cells. A discrete site of blockage to transcriptional elongation has previously been localized at the 3' end of exon 1 of the mouse and human c-myc genes. We here identify an additional site of transcriptional attenuation that is located between the P1 and P2 promoters of the c-myc gene and that mediates premature termination of transcripts initiating from the P1 promoter. A 95-nucleotide DNA fragment derived from this region prematurely terminated transcription when placed downstream from the promoter of the H-2Kbm1 gene and assayed by expression in Xenopus oocytes. We also show that the previously identified attenuation signal in exon 1 of the mouse c-myc gene can mediate premature termination of P1-initiated transcripts. Premature termination of P1-initiated transcripts presumably increases transcription from the downstream P2 promoter; aberrant regulation of this termination may explain the increased use of the P1 promoter that is characteristic of certain tumors in which myc is overexpressed.

Sequence requirements for transcriptional arrest in exon 1 of the human adenosine deaminase gene

We have previously demonstrated that a transcriptional arrest site exists in exon 1 of the human adenosine deaminase (ADA) gene and that this site may play a role in ADA gene expression (Z. Chen, M. L. Harless, D. A. Wright, and R. E. Kellems, Mol. Cell. Biol. 10:4555-4564, 1990). Sequences involved in this process are not known precisely. To further define the template requirements for transcriptional arrest within exon 1 of the human ADA gene, various ADA templates were constructed and their abilities to confer transcriptional arrest were determined following injection into Xenopus oocytes. The exon 1 transcriptional arrest signal functioned downstream of several RNA polymerase II promoters and an RNA polymerase III promoter, implying that the transcriptional arrest site in exon 1 of the ADA gene is promoter independent. We identified a 43-bp DNA fragment which functions as a transcriptional arrest signal. Additional studies showed that the transcriptional arrest site functioned only in the naturally occurring orientation. Therefore, we have identified a 43-bp DNA fragment which functions as a transcriptional arrest signal in an orientation-dependent and promoter-independent manner. On the basis of our findings, we hypothesize that tissue-specific expression of the ADA gene is governed by factors that function as antiterminators to promote transcriptional readthrough of the exon 1 transcriptional arrest site.

A heat-labile factor promotes premature 3' end formation in exon 1 of the murine adenosine deaminase gene in a cell-free transcription system

An elongation block to RNA polymerase II transcription in exon 1 is a major regulatory step in expression of the murine adenosine deaminase (ADA) gene. Previous work in the laboratory identified abundant short transcripts with 3' termini in exon 1 in steady-state RNA from injected oocytes. Using a cell-free system to investigate the mechanism of premature 3' end formation, we found that polymerase II generates prominent ADA transcripts approximately 96 to 100 nucleotides in length which are similar to the major short transcripts found in steady-state RNA from oocytes injected with ADA templates. We have determined that these transcripts are the processed products of 108- to 112-nucleotide precursors. Precursor formation is (i) favored in reactions using circular templates, (ii) not the result of a posttranscriptional processing event, (iii) sensitive to low concentrations of Sarkosyl, and (iv) dependent on a factor(s) which is inactivated in crude extracts at 47 degrees C for 15 min. The cell-free system will allow further characterization of the template and factor requirements involved in the control of premature 3' end formation by RNA polymerase II.

A heat-labile factor promotes premature 3' end formation in exon 1 of the murine adenosine deaminase gene in a cell-free transcription system

An elongation block to RNA polymerase II transcription in exon 1 is a major regulatory step in expression of the murine adenosine deaminase (ADA) gene. Previous work in the laboratory identified abundant short transcripts with 3' termini in exon 1 in steady-state RNA from injected oocytes. Using a cell-free system to investigate the mechanism of premature 3' end formation, we found that polymerase II generates prominent ADA transcripts approximately 96 to 100 nucleotides in length which are similar to the major short transcripts found in steady-state RNA from oocytes injected with ADA templates. We have determined that these transcripts are the processed products of 108- to 112-nucleotide precursors. Precursor formation is (i) favored in reactions using circular templates, (ii) not the result of a posttranscriptional processing event, (iii) sensitive to low concentrations of Sarkosyl, and (iv) dependent on a factor(s) which is inactivated in crude extracts at 47 degrees C for 15 min. The cell-free system will allow further characterization of the template and factor requirements involved in the control of premature 3' end formation by RNA polymerase II.

Sequence requirements for premature transcription arrest within the first intron of the mouse c-fos gene

A strong block to the elongation of nascent RNA transcripts by RNA polymerase II occurs in the 5' part of the mammalian c-fos proto-oncogene. In addition to the control of initiation, this mechanism contributes to transcriptional regulation of the gene. In vitro transcription experiments using nuclear extracts and purified transcription templates allowed us to map a unique arrest site within the mouse first intron 385 nucleotides downstream from the promoter. This position is in keeping with that estimated from nuclear run-on assays performed with short DNA probes and thus suggests that it corresponds to the actual block in vivo. Moreover, we have shown that neither the c-fos promoter nor upstream sequences are absolute requirements for an efficient transcription arrest both in vivo and in vitro. Finally, we have characterized a 103-nucleotide-long intron 1 motif comprising the arrest site and sufficient for obtaining the block in a cell-free transcription assay.

Sequence requirements for premature transcription arrest within the first intron of the mouse c-fos gene

A strong block to the elongation of nascent RNA transcripts by RNA polymerase II occurs in the 5' part of the mammalian c-fos proto-oncogene. In addition to the control of initiation, this mechanism contributes to transcriptional regulation of the gene. In vitro transcription experiments using nuclear extracts and purified transcription templates allowed us to map a unique arrest site within the mouse first intron 385 nucleotides downstream from the promoter. This position is in keeping with that estimated from nuclear run-on assays performed with short DNA probes and thus suggests that it corresponds to the actual block in vivo. Moreover, we have shown that neither the c-fos promoter nor upstream sequences are absolute requirements for an efficient transcription arrest both in vivo and in vitro. Finally, we have characterized a 103-nucleotide-long intron 1 motif comprising the arrest site and sufficient for obtaining the block in a cell-free transcription assay.

Identification and characterization of transcriptional arrest sites in exon 1 of the human adenosine deaminase gene

Analysis of human adenosine deaminase (ADA) gene transcription in four different cell lines indicated that a high density of RNA polymerase II complexes is present at the 5' end of the gene and that the extent of transcription elongation beyond the promoter-proximal region governs gene expression. To determine the sequence requirements for a potential transcription arrest site in the promoter-proximal region, genomic clones containing the ADA promoter, exon 1, and various lengths of intron 1 were injected into Xenopus laevis oocyte germinal vesicles. Transcription analysis indicated that nascent ADA transcripts were highly represented at the promoter-proximal region of the injected templates, suggesting that transcription arrest occurred in the oocyte transcription system. Analysis of the transcription products indicated that ADA transcription initiated at the authentic start site and that the most prominent, short ADA transcripts were 105 nucleotides in length. The 3' end of these transcripts mapped within exon 1, 10 nucleotides downstream of the translation initiation codon. Deletion analysis demonstrated that sequences within exon 1 were sufficient to specify the synthesis of the 105-nucleotide transcripts. Taken together, these data suggest that a transcription arrest mechanism operates in the promoter-proximal region of the human ADA gene and that regulation of elongation beyond this point plays a major role in regulating ADA gene expression.

Identification and characterization of transcriptional arrest sites in exon 1 of the human adenosine deaminase gene

Analysis of human adenosine deaminase (ADA) gene transcription in four different cell lines indicated that a high density of RNA polymerase II complexes is present at the 5' end of the gene and that the extent of transcription elongation beyond the promoter-proximal region governs gene expression. To determine the sequence requirements for a potential transcription arrest site in the promoter-proximal region, genomic clones containing the ADA promoter, exon 1, and various lengths of intron 1 were injected into Xenopus laevis oocyte germinal vesicles. Transcription analysis indicated that nascent ADA transcripts were highly represented at the promoter-proximal region of the injected templates, suggesting that transcription arrest occurred in the oocyte transcription system. Analysis of the transcription products indicated that ADA transcription initiated at the authentic start site and that the most prominent, short ADA transcripts were 105 nucleotides in length. The 3' end of these transcripts mapped within exon 1, 10 nucleotides downstream of the translation initiation codon. Deletion analysis demonstrated that sequences within exon 1 were sufficient to specify the synthesis of the 105-nucleotide transcripts. Taken together, these data suggest that a transcription arrest mechanism operates in the promoter-proximal region of the human ADA gene and that regulation of elongation beyond this point plays a major role in regulating ADA gene expression.