Mapping the spliced and unspliced late lytic SV40 RNAs

Preparation of Mammalian Nascent RNA for Long Read Sequencing

Long read sequencing technologies now allow high-quality sequencing of RNAs (or their cDNAs) that are hundreds to thousands of nucleotides long. Long read sequences of nascent RNA provide single-nucleotide-resolution information about co-transcriptional RNA processing events-e.g., splicing, folding, and base modifications. Here, we describe how to isolate nascent RNA from mammalian cells through subcellular fractionation of chromatin-associated RNA, as well as how to deplete poly(A)+ RNA and rRNA, and, finally, how to generate a full-length cDNA library for use on long read sequencing platforms. This approach allows for an understanding of coordinated splicing status across multi-intron transcripts by revealing patterns of splicing or other RNA processing events that cannot be gained from traditional short read RNA sequencing. © 2020 Wiley Periodicals LLC. Basic Protocol 1: Subcellular fractionation Basic Protocol 2: Nascent RNA isolation and adapter ligation Basic Protocol 3: cDNA amplicon preparation.

Primary transcripts: From the discovery of RNA processing to current concepts of gene expression - Review

The main purpose of this review is to recall for investigators - and in particular students -, some of the early data and concepts in molecular genetics and biology that are rarely cited in the current literature and are thus invariably overlooked. There is a growing tendency among editors and reviewers to consider that only data produced in the last 10-20 years or so are pertinent. However this is not the case. In exact science, sound data and lucid interpretation never become obsolete, and even if forgotten, will resurface sooner or later. In the field of gene expression, covered in the present review, recent post-genomic data have indeed confirmed many of the earlier results and concepts developed in the mid-seventies, well before the start of the recombinant DNA revolution. Human brains and even the most powerful computers, have difficulty in handling and making sense of the overwhelming flow of data generated by recent high-throughput technologies. This was easier when low throughput, more integrative methods based on biochemistry and microscopy dominated biological research. Nowadays, the need for organising concepts is ever more important, otherwise the mass of available data can generate only "building ruins" - the bricks without an architect. Concepts such as pervasive transcription of genomes, large genomic domains, full domain transcripts (FDTs) up to 100 kb long, the prevalence of post-transcriptional events in regulating eukaryotic gene expression, and the 3D-genome architecture, were all developed and discussed before 1990, and are only now coming back into vogue. Thus, to review the impact of earlier concepts on later developments in the field, I will confront former and current data and ideas, including a discussion of old and new methods. Whenever useful, I shall first briefly report post-genomic developments before addressing former results and interpretations. Equally important, some of the terms often used sloppily in scientific discussions will be clearly defined. As a basis for the ensuing discussion, some of the issues and facts related to eukaryotic gene expression will first be introduced. In chapter 2 the evolution in perception of biology over the last 60 years and the impact of the recombinant DNA revolution will be considered. Then, in chapter 3 data and theory concerning the genome, gene expression and genetics will be reviewed. The experimental and theoretical definition of the gene will be discussed before considering the 3 different types of genetic information - the "Triad" - and the importance of post-transcriptional regulation of gene expression in the light of the recent finding that 90% of genomic DNA seems to be transcribed. Some previous attempts to provide a conceptual framework for these observations will be recalled, in particular the "Cascade Regulation Hypothesis" (CRH) developed in 1967-85, and the "Gene and Genon" concept proposed in 2007. A knowledge of the size of primary transcripts is of prime importance, both for experimental and theoretical reasons, since these molecules represent the primary units of the "RNA genome" on which most of the post-transcriptional regulation of gene expression occurs. In chapter 4, I will first discuss some current post-genomic topics before summarising the discovery of the high Mr-RNA transcripts, and the investigation of their processing spanning the last 50 years. Since even today, a consensus concerning the real form of primary transcripts in eukaryotic cells has not yet been reached, I will refer to the viral and specialized cellular models which helped early on to understand the mechanisms of RNA processing and differential splicing which operate in cells and tissues. As a well-studied example of expression and regulation of a specific cellular gene in relation to differentiation and pathology, I will discuss the early and recent work on expression of the globin genes in nucleated avian erythroblasts. An important concept is that the primary transcript not only embodies protein-coding information and regulation of its expression, but also the 3D-structure of the genomic DNA from which it was derived. The wealth of recent post-genomic data published in this field emphasises the importance of a fundamental principle of genome organisation and expression that has been overlooked for years even though it was already discussed in the 1970-80ties. These issues are addressed in chapter 5 which focuses on the involvement of the nuclear matrix and nuclear architecture in DNA and RNA biology. This section will make reference to the Unified Matrix Hypothesis (UMH), which was the first molecular model of the 3D organisation of DNA and RNA. The chapter on the "RNA-genome and peripheral memories" discusses experimental data on the ribonucleoprotein complexes containing pre-mRNA (pre-mRNPs) and mRNA (mRNPs) which are organised in nuclear and cytoplasmic spaces respectively. Finally, "Outlook " will enumerate currently unresolved questions in the field, and will propose some ideas that may encourage further investigation, and comprehension of available experimental data still in need of interpretation. In chapter 8, some propositions and paradigms basic to the authors own analysis are discussed. "In conclusion" the raison d'être of this review is recalled and positioned within the overall framework of scientific endeavour.

Reflections on the history of pre-mRNA processing and highlights of current knowledge: a unified picture

Several strong conclusions emerge concerning pre-mRNA processing from both old and newer experiments. The RNAPII complex is involved with pre-mRNA processing through binding of processing proteins to the CTD (carboxyl terminal domain) of the largest RNAPII subunit. These interactions are necessary for efficient processing, but whether factor binding to the CTD and delivery to splicing sites is obligatory or facilitatory is unsettled. Capping, addition of an m(7)Gppp residue (cap) to the initial transcribed residue of a pre-mRNA, occurs within seconds. Splicing of pre-mRNA by spliceosomes at particular sites is most likely committed during transcription by the binding of initiating processing factors and ∼50% of the time is completed in mammalian cells before completion of the primary transcript. This fact has led to an outpouring in the literature about "cotranscriptional splicing." However splicing requires several minutes for completion and can take longer. The RNAPII complex moves through very long introns and also through regions dense with alternating exons and introns at an average rate of ∼3 kb per min and is, therefore, not likely detained at each splice site for more than a few seconds, if at all. Cleavage of the primary transcript at the 3' end and polyadenylation occurs within 30 sec or less at recognized polyA sites, and the majority of newly polyadenylated pre-mRNA molecules are much larger than the average mRNA. Finally, it seems quite likely that the nascent RNA most often remains associated with the chromosomal locus being transcribed until processing is complete, possibly acquiring factors related to the transport of the new mRNA to the cytoplasm.

The viroporin activity of the minor structural proteins VP2 and VP3 is required for SV40 propagation

For nonenveloped viruses such as Simian Virus 40, the mechanism used to translocate viral components across membranes is poorly understood. Previous results indicated that the minor structural proteins, VP2 and VP3, might act as membrane proteins during infection. Here, purified VP2 and VP3 were found to form pores in host cell membranes. To identify possible membrane domains, individual hydrophobic domains from VP2 and VP3 were expressed in a model protein and tested for their ability to integrate into membranes. Several domains from the late proteins supported endoplasmic reticulum membrane insertion as transmembrane domains. Mutations in VP2 and VP3 were engineered that inhibited membrane insertion and pore formation. When these mutations were introduced into the viral genome, viral propagation was inhibited. This comprehensive approach revealed that the viroporin activity of VP2 and VP3 was inhibited by targeted disruptions of individual hydrophobic domains and the loss of membrane disruption activity impaired viral infection.

Physical Analysis of Autographa californica Nuclear Polyhedrosis Virus Transcripts for Polyhedrin and 10,000-Molecular-Weight Protein

In Autographa californica nuclear polyhedrosis virus-infected cells, polyhedrin, the major structural polypeptide of the viral occlusions, and a low-molecular-weight viral protein with a molecular weight of approximately 10,000 (10K) accumulated to high levels late in infection. Two polyadenylated RNAs 1,200 and 630 bases in size were the most abundant viral transcripts present in the cytoplasm at 48 h postinfection. Evidence is presented that these RNAs were the transcripts for polyhedrin and 10K proteins. The 630-base RNA and five other major polyadenylated RNAs present at 48 h postinfection mapped within or near A. californica nuclear polyhedrosis virus EcoRI-P. The DNA sequences that code for polyhedrin mRNA were examined by S1 nuclease analysis. The polyhedrin gene contained no detectable introns and mapped at 3,990 to 5,200 base pairs to the right of the origin of the circular A. californica nuclear polyhedrosis virus physical map. Heterogeneity at the 5' end of polyhedrin mRNA was observed by using S1 nuclease analysis with 5' end-labeled DNA probes.

Genetic test for involvement of intervening sequences in transport of nuclear RNA

The construction of a recombinant virus in the late region of simian virus 40 is presented. The small intervening sequence of late 19S RNA (0.760 to 0.765 map unit) was cloned and inserted into the EcoRI site (1.0 map unit) in the late region of simian virus 40. This is a mutant virus that now has two intervening sequences, one at the normal position (0.760 map unit) and another out of the context of its flanking sequence and now at 1.0 map unit. The recombinant appears poisonous, as repeated attempts to plaque it as a virus with a standard helper virus were unsuccessful. The transcription of this recombinant was, therefore, studied after direct DNA transfection onto CV-1 cells. Nuclease S1 analysis of mutant RNA indicates that the major nuclear transcript was a spliced but nuclear 16S RNA species. Normally, 16S RNA is not found in the nucleus. This result was shown to be an artifact of the DNA transfection protocol. When the glycerol shock was done after infection with virus, a similar alteration in the makeup of nuclear RNA was seen. A transient stock of this double-intron mutant was finally obtained, using a nonrevertable helper virus. The transcriptional analysis of this mutant showed that unspliced 19S RNA was not transported and remained within the nucleus, whereas spliced 19S and 16S RNAs were transported. We conclude that the retention of nuclear transcripts within the nucleus is not simply due to the presence of intronic sequences, as spliced 19S and 16S RNAs which contain the second intron were efficiently transported.

Genetic test for involvement of intervening sequences in transport of nuclear RNA

The construction of a recombinant virus in the late region of simian virus 40 is presented. The small intervening sequence of late 19S RNA (0.760 to 0.765 map unit) was cloned and inserted into the EcoRI site (1.0 map unit) in the late region of simian virus 40. This is a mutant virus that now has two intervening sequences, one at the normal position (0.760 map unit) and another out of the context of its flanking sequence and now at 1.0 map unit. The recombinant appears poisonous, as repeated attempts to plaque it as a virus with a standard helper virus were unsuccessful. The transcription of this recombinant was, therefore, studied after direct DNA transfection onto CV-1 cells. Nuclease S1 analysis of mutant RNA indicates that the major nuclear transcript was a spliced but nuclear 16S RNA species. Normally, 16S RNA is not found in the nucleus. This result was shown to be an artifact of the DNA transfection protocol. When the glycerol shock was done after infection with virus, a similar alteration in the makeup of nuclear RNA was seen. A transient stock of this double-intron mutant was finally obtained, using a nonrevertable helper virus. The transcriptional analysis of this mutant showed that unspliced 19S RNA was not transported and remained within the nucleus, whereas spliced 19S and 16S RNAs were transported. We conclude that the retention of nuclear transcripts within the nucleus is not simply due to the presence of intronic sequences, as spliced 19S and 16S RNAs which contain the second intron were efficiently transported.

A complete alpha1,3-galactosyltransferase gene is present in the human genome and partially transcribed

The synthesis of Galalpha1-3Gal-terminated oligosaccharides (alpha-Gal) epitopes has been interrupted during the course of evolution, starting with Old World primates. Partial sequences similar to the alpha1,3-galactosyltransferase (alpha1,3GalT) gene, which governs the synthesis of alpha-Gal epitopes, have been detected in the human genome and were found to correspond to pseudogenes. We completed the sequence of the human alpha1,3GalT pseudogene present on chromosome 9 and found it to be organized like the murine alpha1,3GalT gene. In human cell lines and several normal and tumor tissues we detected truncated transcripts corresponding to this pseudogene. Considering these mRNAs, translation of an open reading frame containing the first four translated exons but missing the two catalytic exons could predict a truncated alpha1,3GalT polypeptide that should be enzymatically inactive. We show that transcription of human alpha1,3GalT is prematurely terminated at the level of a strong transcriptional stop signal in the middle of intron VII. We were able to reproduce this effect in vitro by subcloning the implicated DNA region upstream from a reporter cDNA. The premature transcriptional arrest of human alpha1,3-GalT gene leads to an ectopic splicing event and to the connection of a short intronic sequence downstream from translated exons. Finally, we show that these truncated transcripts are overexpressed in cell lines with modifications of O-glycans.

Expression of the mouse dihydrofolate reductase complementary deoxyribonucleic acid in simian virus 40 vectors

A mouse complementary deoxyribonucleic acid segment coding for the enzyme dihydrofolate reductase has been cloned in two general classes of vectors containing simian virus 40 deoxyribonucleic acid: (i) those that can be propagated as virions in permissive cells and (ii) those that can be introduced into and maintained stably in various mammalian cells. Both types of vectors express the mouse dihydrofolate reductase by using signals supplied by simian virus 40 deoxyribonucleic acid sequences. Moreover, plasmid vectors carrying the complementary deoxyribonucleic acid segment can complement Chinese hamster ovary cells lacking dihydrofolate reductase.

The human 180-kDa receptor for secretory phospholipases A2. Molecular cloning, identification of a secreted soluble form, expression, and chromosomal localization

Secretory phospholipases A2 (sPLA2) are structurally related enzymes found in mammals as well as in insect and snake venoms. They have been associated with several physiological, pathological, and toxic processes. Some of these effects are apparently linked to the existence of specific receptors for both venom and mammalian sPLA2s. We report here the molecular cloning and expression of one of these sPLA2 receptors from human kidney. Two transcripts were detected. One encodes for a transmembrane form of the sPLA2 receptor and the other one is an alternatively processed transcript, caused by polyadenylation occurring at a site within an intron in the C terminus part of the transcriptional unit. This transcript encodes for a shortened secreted soluble sPLA2 receptor lacking the coding region for the transmembrane segment. Quantitative polymerase chain reaction experiments indicate a 1.6:1 ratio between the levels of transcripts encoding for the membrane-bound and soluble forms of the receptor, respectively. Soluble and membrane-bound human sPLA2 receptors both bind sPLA2 with high affinities. However, the binding properties of the human receptors are different from those obtained with the rabbit membrane-bound sPLA2 receptor. The 180-kDa human sPLA2 receptor gene has been mapped in the q23-q24 bands of chromosome 2.

Characterization of a bovine herpesvirus 4 immediate-early RNA encoding a homolog of the Epstein-Barr virus R transactivator

Immediate-early (IE) RNA 2, the less abundant of two bovine herpesvirus 4 (BHV-4) RNAs detected in Madin-Darby bovine kidney cells infected in the presence of cycloheximide, is a 1.8-kb cytoplasmic polyadenylated RNA transcribed from the 8.3-kb HindIII fragment F. The structure of IE RNA 2 has been determined by S1 nuclease and exonuclease VII mapping, primer extension analysis, and sequencing of a partial cDNA. IE RNA 2 consists of a short, approximately 60-nucleotide 5' exon spliced to a 1.8-kb 3' exon. DNA sequence analysis revealed an open reading frame encoding 551 amino acids with sequence homology to the Epstein-Barr virus (EBV) R transactivator and its homolog in herpesvirus saimiri, HVS.R.IE 2 and HVS.R show higher homology to each other than to the EBV R transactivator. The homology is highest in the approximately 320 amino-terminal amino acids. All three proteins have acidic carboxyl termini but have little amino acid sequence homology in this region. In transient expression cotransfection assays, IE 2 activated expression from the BHV-4 early promoter-regulatory region of the major DNA-binding protein homolog over 100-fold in bovine turbinate cells. IE 1 was not necessary for this transactivation and did not augment it. However, IE 2 did not transactivate EBV or herpesvirus saimiri early promoter-regulatory regions that are transactivated by the EBV R transactivator or HVS.R.

Reduced secreted mu mRNA synthesis in selective IgM deficiency of Bloom's syndrome

Serum IgM concentrations were low although serum IgG and IgA concentrations were normal in both our patients with Bloom's syndrome. Although the percentages of surface IgM-bearing cells were not reduced, the numbers of IgM-secreting cells were markedly reduced. The membrane-bound mu (microns) and secreted mu (microseconds) mRNAs are produced from transcripts of a single immunoglobulin mu gene by alternative RNA processing pathways. The control of microseconds mRNA synthesis depends on the addition of poly(A) to microseconds C-terminal segment. In both patients, mu mRNA was well detected but microseconds C-terminal mRNA was scarcely detected, suggesting that microns mRNA was well transcribed but microseconds mRNA was not. There was, at least, no mutation or deletion in the microseconds C-terminal coding sequence, the RNA splice site (GG/TAAAC) at the 5' end of microseconds C-terminal segment and the AATAAA poly(A) signal sequence in both patients. Our results suggest that selective IgM deficiency in Bloom's syndrome is due to an abnormality in the maturation of surface IgM-bearing B cells into IgM-secreting cells and a failure of microseconds mRNA synthesis. Moreover, reduced microseconds mRNA synthesis may be due to the defect on developmental regulation of the site at which poly(A) is added to transcripts of the mu gene.

Transcript mapping of Abutilon mosaic virus, a geminivirus

The transcripts of the DNA of Abutilon mosaic virus, a geminivirus with a bipartite genome (DNA A and DNA B), were characterized by Northern blot hybridization, S1 nuclease assay, primer extension analysis, and sequencing of the 3' termini of cDNA clones. It was shown that transcription is bidirectional and that the transcripts are polyadenylated. Two overlapping transcripts of 1.6 and 0.7 kb were mapped to the complementary strand of DNA A and two of 1.3 and 1.2 kb to the complementary strand of DNA B. One transcript of 0.9 kb was mapped to the viral sense in DNA A and one of 1.0 kb to the viral sense in DNA B. The ends of complementary and viral mRNA overlapped in both genome parts in regions rich in polyadenylation signals.

Maturation of polycistronic pre-mRNA in Trypanosoma brucei: analysis of trans splicing and poly(A) addition at nascent RNA transcripts from the hsp70 locus

Numerous protein-coding genes of the protozoan Trypanosoma brucei are arranged in tandem arrays that are transcribed polycistronically. The pre-mRNA transcripts are processed by trans splicing, leading to the addition of a capped 39-nucleotide (nt) miniexon and by poly(A) addition. We wished to determine the order of the RNA processing events at the hsp70 locus and address the potential occurrence of cotranscriptional RNA processing. We determined the rate of transcriptional elongation at the hsp70 locus in isolated nuclei, which measured between 20 and 40 nt/min. This low rate of RNA chain elongation allowed us to label the 3' end of hsp70 nascent RNA with a short (about 180-nt) 32P tail. The structure of the labeled nascent hsp70 RNA could then be analyzed by RNase T1 and RNase T1/RNase A mapping. We show that the trans splicing of hsp70 pre-mRNA did not occur immediately after the synthesis of the 3' splice acceptor site, and nascent RNA molecules that contained about 550 nt of RNA beyond the 3' splice acceptor site still had not acquired a miniexon. In contrast, nascent RNA with a 5' end that mapped to the polyadenylation site of the hsp70 genes could be detected, indicating that maturation of the pre-mRNA in trypanosomes involves a rapid cleavage of the nascent hsp70 RNA (within seconds after synthesis of the site) for poly(A) addition. Our data suggest that polycistronic pre-mRNA is unlikely to be synthesized in toto and rather appears to be processed cotranscriptionally by cleavage for poly(A) addition.

Maturation of polycistronic pre-mRNA in Trypanosoma brucei: analysis of trans splicing and poly(A) addition at nascent RNA transcripts from the hsp70 locus

Numerous protein-coding genes of the protozoan Trypanosoma brucei are arranged in tandem arrays that are transcribed polycistronically. The pre-mRNA transcripts are processed by trans splicing, leading to the addition of a capped 39-nucleotide (nt) miniexon and by poly(A) addition. We wished to determine the order of the RNA processing events at the hsp70 locus and address the potential occurrence of cotranscriptional RNA processing. We determined the rate of transcriptional elongation at the hsp70 locus in isolated nuclei, which measured between 20 and 40 nt/min. This low rate of RNA chain elongation allowed us to label the 3' end of hsp70 nascent RNA with a short (about 180-nt) 32P tail. The structure of the labeled nascent hsp70 RNA could then be analyzed by RNase T1 and RNase T1/RNase A mapping. We show that the trans splicing of hsp70 pre-mRNA did not occur immediately after the synthesis of the 3' splice acceptor site, and nascent RNA molecules that contained about 550 nt of RNA beyond the 3' splice acceptor site still had not acquired a miniexon. In contrast, nascent RNA with a 5' end that mapped to the polyadenylation site of the hsp70 genes could be detected, indicating that maturation of the pre-mRNA in trypanosomes involves a rapid cleavage of the nascent hsp70 RNA (within seconds after synthesis of the site) for poly(A) addition. Our data suggest that polycistronic pre-mRNA is unlikely to be synthesized in toto and rather appears to be processed cotranscriptionally by cleavage for poly(A) addition.

Efficiency of utilization of the simian virus 40 late polyadenylation site: effects of upstream sequences

The late polyadenylation signal of simian virus 40 functions with greater efficiency than the early polyadenylation signal, in turn affecting steady-state mRNA levels. Two chloramphenicol acetyltransferase (CAT) transient expression vectors, pL-EPA and pL-LPA, that differ only in their polyadenylation signals were constructed by using the early and late polyadenylation signals, respectively. In transfections of Cos, CV-1P, or HeLa cells and subsequent Northern blot analysis of CAT-specific RNA, approximately five times more steady-state CAT mRNA was produced in transfections with pL-LPA than with pL-EPA. The basis for this difference was not related to the specific promoter used or to RNA stability. Overall, the difference in steady-state mRNA levels derived from the two plasmids appeared to be attributable to intrinsic properties of the two polyadenylation signals, resulting in distinctly different cleavage and polyadenylation efficiencies. Additionally, we found that the utilization of the late polyadenylation site was dramatically reduced by deletion of sequences between 48 and 29 nucleotides 5' of the AAUAAA hexanucleotide. This reduction of mRNA levels was shown not to be caused by altered stability of mutant precursor RNAs or mRNAs, suggesting that these upstream sequences constitute an element of the late polyadenylation signal and may cause, at least to some extent, the greater efficiency of utilization of the late polyadenylation site.

Efficiency of utilization of the simian virus 40 late polyadenylation site: effects of upstream sequences

The late polyadenylation signal of simian virus 40 functions with greater efficiency than the early polyadenylation signal, in turn affecting steady-state mRNA levels. Two chloramphenicol acetyltransferase (CAT) transient expression vectors, pL-EPA and pL-LPA, that differ only in their polyadenylation signals were constructed by using the early and late polyadenylation signals, respectively. In transfections of Cos, CV-1P, or HeLa cells and subsequent Northern blot analysis of CAT-specific RNA, approximately five times more steady-state CAT mRNA was produced in transfections with pL-LPA than with pL-EPA. The basis for this difference was not related to the specific promoter used or to RNA stability. Overall, the difference in steady-state mRNA levels derived from the two plasmids appeared to be attributable to intrinsic properties of the two polyadenylation signals, resulting in distinctly different cleavage and polyadenylation efficiencies. Additionally, we found that the utilization of the late polyadenylation site was dramatically reduced by deletion of sequences between 48 and 29 nucleotides 5' of the AAUAAA hexanucleotide. This reduction of mRNA levels was shown not to be caused by altered stability of mutant precursor RNAs or mRNAs, suggesting that these upstream sequences constitute an element of the late polyadenylation signal and may cause, at least to some extent, the greater efficiency of utilization of the late polyadenylation site.

Regulation of human argininosuccinate synthetase gene: induction by positive-acting nuclear mechanism in canavanine-resistant cell variants

Nonhepatic human cell variants resistant to the arginine analog, canavanine, express argininosuccinate synthetase (AS) mRNA at levels 200-fold higher than parental cells without amplification of AS gene sequences. In this report we show that this regulation occurs in the nucleus prior to polyadenylation of AS precursor RNA and occurs through a positive-acting mechanism operating in canavanine-resistant cells. The half-life of cytoplasmic AS mRNA was estimated by blocking cellular transcription with actinomycin D. In both parental and canavanine-resistant variants of RPMI 2650 cells, the AS mRNA decayed with a half-life of 12-24 h, showing that cytoplasmic mRNA stabilization was not involved in this regulation. Quantification of AS RNA following cell fractionation showed that AS precursor RNA was present at greatly elevated amounts in the nuclei of canavanine-resistant cells. Similar results were obtained when nonpolyadenylated RNA was examined. Thus, the mechanism underlying high expression of AS mRNA in canavanine-resistant cells is an early nuclear event, and the processes of polyadenylation and transport of RNA to the cytoplasm are not involved. Intraspecific somatic cell hybrids were constructed to test whether the induction of AS mRNA was due to a gain of a function in canavanine-resistant cells or to a loss of a function in parental cells. Quantification of AS mRNA in hybrid cell lines showed that such cells contained high levels similar to those found in the canavanine-resistant parent. These findings show that the induction of AS mRNA is due to a positive-acting mechanism operating in the nucleus of canavanine-resistant cells.

Identification of an alternative polyadenylation site in the human C3b/C4b receptor (complement receptor type 1) transcriptional unit and prediction of a secreted form of complement receptor type 1

The human C3b/C4b receptor or complement receptor type one (CR1) is an approximately 200-kD single chain membrane glycoprotein of human peripheral blood cells that mediates the binding, processing, and transport of C3b-bearing immune complexes and regulates the activity of the complement cascade. Analysis of partial cDNA clones has shown that the COOH terminus is composed predominantly of three tandemly repeated regions of 450 amino acids each (15). In this report, we present a cDNA sequence that encodes the NH2 terminus of CR1. It appears to have been derived from an alternatively processed transcript, caused by polyadenylation occurring at a site within an intron in the CR1 transcriptional unit. The resulting truncated messenger carries an open reading frame that would produce a short, secreted CR1 form. We present genomic sequences and Northern blots which support this hypothesis and we propose that the NH2-terminal end of CR1 is a likely location for active sites. In addition, we report evidence for a CR1-like sequence in the human genome and we present a model for the organization of CR1.

Splice commitment dictates neuron-specific alternative RNA processing in calcitonin/CGRP gene expression

The calcitonin/CGRP gene is a complex transcription unit in which developmentally regulated cell-specific alternative RNA processing results in the production of CGRP mRNA in neurons, and of calcitonin mRNA in thyroid C cells. Alternative poly(A) site selection and exon splicing lead to the production of these alternative mature transcripts. The wild-type and a series of mutated calcitonin/CGRP genes were expressed in heterologous cell types, which produced predominantly calcitonin or CGRP mRNA. The results of these studies suggest that neurons express machinery or a factor that determines a specific alternative splicing pathway and consequently its associated alternative poly(A) site selection. It is hypothesized that a splice commitment regulatory factor might modulate pre-mRNA secondary structure, revealing a cryptic splice site required to generate CGRP mRNA in the brain.

Characterization of the simian virus 40 late promoter: relative importance of sequences within the 72-base-pair repeats differs before and after viral DNA replication

We examined sequences involved in the simian virus 40 (SV40) late promoter in vivo, by using quantitative S1 nuclease analysis of a series of deletion mutants within the SV40 regulatory region. These mutants were constructed so as to place the altered promoter region in its normal position relative to the SV40 late genes. The effects of the deletions on late transcriptional activity were analyzed before and after viral DNA replication, by omitting or including SV40 large T antigen. The data show that (i) in the absence of large T antigen, the deletion of the 21-base-pair (bp) repeats results in a fourfold increase in late transcription, and (ii) the sequences within the 72-bp repeats are a component of the SV40 late promoter, acting not only before, but also after viral DNA replication. We identified two domains which contain sequences important for efficient late transcription. Domain I, at the late proximal end of each 72-bp repeat, was found to function before replication and was possibly also involved after replication. The contribution of domain II, at the late distal end of each 72-bp repeat, was much more significant after replication but only of minor importance before replication.

Simian virus 40 agnoprotein facilitates normal nuclear location of the major capsid polypeptide and cell-to-cell spread of virus

The simian virus 40 agnoprotein is a 61-amino-acid, highly basic polypeptide that is coded within the 5' leader of late 16S mRNAs. To better understand agnoprotein function and to more effectively differentiate cis-from trans-acting effects of an agnogene mutation, we constructed a mutant virus that carries a single-base-pair substitution and fails to produce agnoprotein. pm 1493 contains a T/A to A/T transversion at sequence position 335. This mutation converts the agnoprotein initiation codon from ATG to TTG, preventing synthesis of the protein. The mutant displays only a modest growth defect in CV-1P and AGMK cells and no defect in BSC-1 cells. Early-gene expression, DNA replication, synthesis of late viral products, and the kinetics of virion assembly all appear normal in pm 1493-infected CV-1P cells. Immunofluorescent studies, however, indicate that localization of the major capsid polypeptide VP1 is different in mutant- than wild-type virus-infected cells. Furthermore, the lack of agnoprotein led to inefficient release of mature virus from the infected cell. Agnogene mutants could be severely compromised in their ability to propagate in monkeys given their reduced capacity for cell-to-cell spread.

Sequences upstream from the mouse c-mos oncogene may function as a transcription termination signal

A region upstream from the mouse c-mos proto-oncogene, termed upstream mouse sequence (UMS), prevents expression of mos transforming activity. Previous studies suggested that the UMS prevented transcription readthrough. In this study, we constructed a recombinant DNA clone, pHTS3MS, with the UMS inserted downstream from both the mos gene and a truncated long terminal repeat containing only the U3 enhancer region. In this position UMS did not inhibit mos transforming activity. We examined cells transformed by pHTS3MS for RNA expression. S1 nuclease analysis showed that the UMS provides two polyadenylation signals to mos-containing RNA and nuclear run-on transcription showed that the primary transcripts terminate in UMS. In addition, using portions of the UMS, we found that a 360-bp fragment containing the UMS polyadenylation signals and sites inserted between the herpes simplex virus type 1 (HSV-1) thymidine kinase gene (tk) and its promoter inhibits tk transforming activity by 99% and prevents detectable expression of this construct in transient expression assays. Thus, the UMS must contain signals for polyadenylation and appears to function as a transcription terminator.

Mapping 5' termini of JC virus late RNA

The 5' termini of late mRNAs were mapped 17 to 19 days after primary human fetal glial cells were infected with JC virus. The major 5' start sites spanned a region of approximately 250 nucleotides, starting at nucleotide 5114, which was on the early side of the replication origin, and extending to nucleotide 242, which was on the late side of the 98-base-pair (bp) repeats. The sequence TATATAT was contained within each of the 98-bp repeats but does not specify 5' start sites in vivo. However, the sequence TACCTA, which occurred 25 to 30 bp upstream of the simian virus 40 nucleotide position 325 start site (J. Brady, M. Radonovich, M. Vodkin, V. Natarajan, M. Thoren, G. Das, J. Janik, and N. P. Salzman, Cell 31:625-633, 1982) and functions as a surrogate TATA box, was present 30 bp upstream of two JC virus start sites.

Expression of the late gene of simian virus 40 under the control of the simian virus 40 early-region promoter in monkey and mouse cells

We constructed a recombinant plasmid (pVNR4) with the simian virus 40 (SV40) early promoter positioned 30 nucleotides upstream from the major SV40 late transcription initiation site at residue 325. After transfection of the recombinant plasmid DNA into COS and mouse L cells, the transcripts of the SV40 late region were analyzed by S1 nuclease and primer extension analysis. The following are the principal findings. (i) The 16S and 19S late RNAs used the characteristic wild-type splice; no detectable levels of 19S unspliced RNA were observed. (ii) The majority of the late RNAs were heterogeneous and initiated in the early region (upstream and downstream from the Hogness-Goldberg sequence), and a minor population initiated at residue 325, the principal 5' terminus of the wild-type late RNA. (iii) During SV40 lytic infection there was a shift in initiation sites used to transcribe the early region from sites that are downstream to sites which are upstream (up RNA) of the origin of DNA replication. We observed that unlike lytic infection, T antigen and viral DNA replication were not needed for the appearance of up RNA in mouse L cells. (iv) In mouse L cells late RNAs were made, and the residue 325 5' end was utilized in the absence of T antigen or DNA replication. (v) In COS cells we found down RNA and up RNA transcribed from the extrachromosomally replicating plasmid but only down RNA produced by the integrated SV40 genome.

Simian virus 40 replication pause sites map with the nucleosomes

The locations of replication pause sites in the simian virus 40 minichromosome which were determined by sizing cloned fragments of nascent DNA (Zannis-Hadjopoulos et al., J. Mol. Biol. 165:599-607, 1983) were compared with the positions of simian virus 40 nucleosomes in the genome, as obtained by sequence-directed mapping (G. Mengeritsky and E. N. Trifonov, Nucleic Acids Res. 11:3833-3851, 1983; Mengeritsky and Trifonov, Cell Biophys. 6:1-8, 1984). Clear correlation between these two maps is demonstrated, suggesting that nucleosomes hinder propagation of the replication forks.

Sequences on the 3' side of hexanucleotide AAUAAA affect efficiency of cleavage at the polyadenylation site

The hexanucleotide AAUAAA has been demonstrated to be part of the signal for cleavage and polyadenylation at appropriate sites on eucaryotic mRNA precursors. Since this sequence is not unique to polyadenylation sites, it cannot be the entire signal for the cleavage event. We have extended the definition of the polyadenylation cleavage signal by examining the cleavage event at the site of polyadenylation for the simian virus 40 late mRNAs. Using viable mutants, we have determined that deletion of sequences between 3 and 60 nucleotides on the 3' side of the AAUAAA decreases the efficiency of utilization of the normal polyadenylation site. These data strongly indicate a second major element of the polyadenylation signal. The phenotype of these deletion mutants is an enrichment of viral late transcripts longer than the normally polyadenylated RNA in infected cells. These extended transcripts appear to have an increased half-life due to the less efficient cleavage at the normal polyadenylation site. The enriched levels of extended transcripts in cells infected with the deletion mutants allowed us to examine regions of the late transcript which normally are difficult to study. The extended transcripts have several discrete 3' ends which we have analyzed in relation to polyadenylation and other RNA processing events. Two of these ends map to nucleotides 2794 and 2848, which lie within a region of extensive secondary structure which marks the putative processing signal for the formation of the simian virus 40-associated small RNA. A third specific 3' end reveals a cryptic polyadenylation site at approximately nucleotides 2980 to 2985, more than 300 nucleotides beyond the normal polyadenylation site. This site appears to be utilized only in mutants with debilitated normal sites. The significance of sequences on the 3' side of an AAUAAA for efficient polyadenylation at a specific site is discussed.

Processing and nucleo-cytoplasmic transport of histone gene transcripts

Precursors of Xenopus and sea urchin histone mRNAs were synthesized in vitro with the SP6 transcription system, and their maturation and nucleo-cytoplasmic transport was studied by frog oocyte injection. 3' processing is most rapid for homologous histone messenger sequences and does not require either genuine 5' or specific 3' ends of the precursor, but capping of the 5' terminus strongly influences the efficiency of 3' processing. No generation of 5' histone mRNA ends can be detected when precursors containing 5' spacer sequence extensions are injected into the oocyte nucleus. This finding may have some implications for the question whether histone gene transcription could be polycistronic. Using a novel oocyte technique, we have separated nuclei from cytoplasm and have studied the time course of exit of the processed RNA from the oocyte nucleus into the cytoplasm. The results suggest that RNA maturation and nucleo-cytoplasmic transport are not temporally coupled processes.

Sequences on the 3' side of hexanucleotide AAUAAA affect efficiency of cleavage at the polyadenylation site

The hexanucleotide AAUAAA has been demonstrated to be part of the signal for cleavage and polyadenylation at appropriate sites on eucaryotic mRNA precursors. Since this sequence is not unique to polyadenylation sites, it cannot be the entire signal for the cleavage event. We have extended the definition of the polyadenylation cleavage signal by examining the cleavage event at the site of polyadenylation for the simian virus 40 late mRNAs. Using viable mutants, we have determined that deletion of sequences between 3 and 60 nucleotides on the 3' side of the AAUAAA decreases the efficiency of utilization of the normal polyadenylation site. These data strongly indicate a second major element of the polyadenylation signal. The phenotype of these deletion mutants is an enrichment of viral late transcripts longer than the normally polyadenylated RNA in infected cells. These extended transcripts appear to have an increased half-life due to the less efficient cleavage at the normal polyadenylation site. The enriched levels of extended transcripts in cells infected with the deletion mutants allowed us to examine regions of the late transcript which normally are difficult to study. The extended transcripts have several discrete 3' ends which we have analyzed in relation to polyadenylation and other RNA processing events. Two of these ends map to nucleotides 2794 and 2848, which lie within a region of extensive secondary structure which marks the putative processing signal for the formation of the simian virus 40-associated small RNA. A third specific 3' end reveals a cryptic polyadenylation site at approximately nucleotides 2980 to 2985, more than 300 nucleotides beyond the normal polyadenylation site. This site appears to be utilized only in mutants with debilitated normal sites. The significance of sequences on the 3' side of an AAUAAA for efficient polyadenylation at a specific site is discussed.

Mapping of polyadenylated transcripts of a monkey lymphotropic papova virus

Polyadenylated transcripts of a monkey lymphotropic papovavirus (LPV), which can be propagated in monkey and human lymphoblastoid cell lines, were identified and mapped. Polyadenylated RNA was purified from cells of the human line BJA/B infected with LPV, and was hybridized with various LPV DNA fragments. The hybrids were treated with S1 endonuclease and analyzed by alkaline gel electrophoresis. This analysis revealed two groups of RNA molecules encoded in two regions of the LPV genome. One group includes four colinear transcripts of 2.3, 2.1, 1.85, and 1.2 kb, whose polyadenylated termini map at a single site on the LPV DNA. The second group includes two less-abundant transcripts of 1.8 and 1.95 kb. The polarities of the LPV transcripts were determined by hybridizing cDNA complementary to their 3' termini with LPV DNA fragments. The two groups were found to have opposite polarities. It is shown that the four major transcripts can be aligned with, and may be functionally related to, SV40 and polyoma virus "late" mRNAs. It is also inferred that the 1.8- and 1.95-kb RNA species may be functionally related to the "early" transcripts of these papovaviruses.

Are U4 small nuclear ribonucleoproteins involved in polyadenylation?

The mechanism whereby eukaryotic pre-messenger RNAs are polyadenylated is unknown. Most models for polyadenylation invoke cleavage of precursor transcripts at the site of poly(A) addition followed by polymerization of A residues by poly(A) polymerase. Analysis of the sequences surrounding poly(A) addition sites has identified the consensus recognition sequence element AAUAAA as necessary but not sufficient for polyadenylation. A second recognition sequence element CACUG , was observed by Benoit et al. to be adjacent to the site of poly(A) addition in several sequenced RNAs. Here, we analyse 61 vertebrate poly(A) addition sequences, define a more extensive recognition sequence for polyadenylation than previously recognized and suggest how the site of poly(A) addition may be chosen. Furthermore, we find that the defined recognition sequence has elements which are complementary to regions within the small nuclear RNA U4, suggesting that U4 small nuclear ribonucleoproteins (snRNPs) may mediate polyadenylation in a fashion similar to the role of U1 snRNPs in splicing. The model invokes hybridization of U4 RNA to AAUAAA recognition elements as related to primary site selection, and hybridization to CAYUG recognition elements as related to cleavage site selection.

Expression of unspliced NS1 mRNA, spliced NS2 mRNA, and a spliced chimera mRNA from cloned influenza virus NS DNA in an SV40 vector

Influenza virus gene 8 codes for two nonstructural proteins (NS1 and NS2) which are translated, respectively, from a colinear and an interrupted mRNA. To investigate the mechanism of transcription processing by splicing, cloned full-length NS DNA was inserted into the late region of an SV40 vector. In this manner, transcription of NS RNA from the recombinant initiates and terminates using SV40 control sequences. RNA mapping and sequence analysis showed that the RNA transcripts are processed to produce both the spliced and unspliced NS mRNAs in approximately equal abundance. The junction sequence of the spliced mRNA is identical to that of NS2 mRNA found in influenza virus-infected cells. In addition, another mRNA species was found to contain a chimera splice between SV40 and NS sequences. Both NS1 and NS2 polypeptides are produced in the recombinant-infected cells as predicted from sequence analysis. These studies establish that during influenza virus infections processing of the NS1 mRNA transcript undergoes a mechanism of splicing similar to that occurring with DNA-directed RNA transcription.

Simian virus 40 late promoter region able to initiate simian virus 40 early gene transcription in the absence of the simian virus 40 origin sequence

To improve our knowledge of the simian virus 40 (SV40) late promoter control region, we took advantage of the fact that T antigen can be expressed with a heterologous promoter. We constructed three chimeric plasmids (pEMP-273, pEMP-LCAP-162, and pEMP-LCAP-113) each with a putative late promoter sequence positioned immediately upstream from the SV40 early gene coding region but in an orientation opposite to its natural orientation in the SV40 genome. After transfection of the recombinant DNA into HeLa or CV1 cells, T antigen accumulation, as scored by indirect immunofluorescence, was used as a functional test for promoter activity. We found that the sequence mapping from nucleotides 332 to 273 is not sufficient for promoting transcription of SV40 early gene but does potentiate the promoter activity of the 72-base-pair repeats in initiating the transcription at natural late cap sites. Considering that both plasmids pEMP-LCAP-162 and pEMP-LCAP-113 lack all of the sequence of the SV40 replication origin, we conclude that SV40 transcription can be mediated through a putative late promoter in the absence of the sequence for the SV40 replication origin.

S1 mapping of purified nascent transcripts of simian virus 40

We purified nascent simian virus 40 late transcripts by incubating viral transcriptional complexes, isolated from infected BSC-1 cells, in a reaction mixture that contained mercurated CTP; RNA molecules that had incorporated mercurated residues in vitro were isolated by sulfhydrylcellulose affinity chromatography. The nascent RNA was hybridized to an end-labeled HindIII C probe fragment (0.646 to 0.86 map unit), and the hybrids were analyzed by S1 mapping. Most of the products of digestion corresponded to unspliced transcripts with 5' ends mapping at nucleotides 325, 260, and 195, which are positions of the 5' ends of mature, cytoplasmic late mRNA species. In addition, two minor products diagnostic of splicing at the acceptor junctions mapping at nucleotides 556 and 443 were detected. Because the abundance of these products was not diminished by repurifying the nascent RNA through a second round of sulfhydrylcellulose chromatography, these products did not originate from contaminating non-nascent RNA. Moreover, the generation of these products was not affected when a higher salt concentration and lower temperature were used for S1 digestion, conditions that should decrease artifactual cleavage by S1 in A + U-rich regions of colinear hybrids. Therefore, it is likely that some simian virus 40 RNA chains are spliced before release from the template.

Simian virus 40 major late promoter: an upstream DNA sequence required for efficient in vitro transcription

We have previously identified an 11-base DNA sequence, 5'-G-G-T-A-C-C-T-A-A-C-C-3' (simian virus 40 [SV40] map position 294 to 304), which is important in the control of SV40 late RNA expression in vitro and in vivo (Brady et al., Cell 31:625-633, 1982). We report here the identification of another domain of the SV40 late promoter. A series of mutants with deletions extending from SV40 map position 0 to 300 was prepared by nuclease BAL 31 treatment. The cloned templates were then analyzed for efficiency and accuracy of late SV40 RNA expression in the Manley in vitro transcription system. Our studies showed that, in addition to the promoter domain near map position 300, there are essential DNA sequences between nucleotide positions 74 and 95 that are required for efficient expression of late SV40 RNA. Included in this SV40 DNA sequence were two of the six GGGCGG SV40 repeat sequences and an 11-nucleotide segment which showed strong homology with the upstream sequences required for the efficient in vitro and in vivo expression of the histone H2A gene. This upstream promoter sequence supported transcription with the same efficiency even when it was moved 72 nucleotides closer to the major late cap site. In vitro promoter competition analysis demonstrated that the upstream promoter sequence, independent of the 294 to 304 promoter element, is capable of binding polymerase-transcription factors required for SV40 late gene transcription. Finally, we show that DNA sequences which control the specificity of RNA initiation at nucleotide 325 lie downstream of map position 294.

Site-specific polyadenylation in a cell-free reaction

A soluble HeLa cell extract accurately polyadenylates RNA transcribed from DNA templates containing the adenovirus L3 polyadenylation site. Regardless of the length of these DNA templates, the major polyadenylated species had 3' termini corresponding to the in vivo site. Polyadenylated RNA appears after an hour lag and only reaches maximum levels after 4 hr of incubation, a time course similar to that of splicing in this extract. Inhibitor studies suggest that the polyadenylation reaction is not coupled to active transcription. Unlike splicing in this extract where exogenous substrate is processed, addition of purified RNA precursor to the reaction does not yield product polyadenylated at L3 but rather results in addition of poly (A) to termini of the precursor. This suggests that part of the specificity of polyadenylation is established by in situ synthesis of RNA. Surprisingly, synthesis of accurately polyadenylated RNA may involve small nuclear ribonucleoprotein particles (snRNPs). The reaction is inhibited by antisera of Sm and U1 RNP specificities as well as antiserum to the nuclear antigen La, but is not inhibited by control serum and anti-(U2)RNP serum.

Simian virus 40 major late promoter: an upstream DNA sequence required for efficient in vitro transcription

We have previously identified an 11-base DNA sequence, 5'-G-G-T-A-C-C-T-A-A-C-C-3' (simian virus 40 [SV40] map position 294 to 304), which is important in the control of SV40 late RNA expression in vitro and in vivo (Brady et al., Cell 31:625-633, 1982). We report here the identification of another domain of the SV40 late promoter. A series of mutants with deletions extending from SV40 map position 0 to 300 was prepared by nuclease BAL 31 treatment. The cloned templates were then analyzed for efficiency and accuracy of late SV40 RNA expression in the Manley in vitro transcription system. Our studies showed that, in addition to the promoter domain near map position 300, there are essential DNA sequences between nucleotide positions 74 and 95 that are required for efficient expression of late SV40 RNA. Included in this SV40 DNA sequence were two of the six GGGCGG SV40 repeat sequences and an 11-nucleotide segment which showed strong homology with the upstream sequences required for the efficient in vitro and in vivo expression of the histone H2A gene. This upstream promoter sequence supported transcription with the same efficiency even when it was moved 72 nucleotides closer to the major late cap site. In vitro promoter competition analysis demonstrated that the upstream promoter sequence, independent of the 294 to 304 promoter element, is capable of binding polymerase-transcription factors required for SV40 late gene transcription. Finally, we show that DNA sequences which control the specificity of RNA initiation at nucleotide 325 lie downstream of map position 294.

Tissue-specific expression of two mRNA species transcribed from a single vimentin gene

We have isolated chicken cDNA and genomic clones for the intermediate filament subunit vimentin and show that the gene for this protein, which exists in a single copy in the haploid chicken genome, is transcribed into two mature mRNA species with approximate lengths of 2.0 and 2.3 kb. We have found cell-specific regulation in the expression of these two mRNAs; whereas both mRNA species are present in muscle cells, fibroblasts, spinal cord and lens, erythroid cells from 10- and 15-day-old chicken embryos express predominantly the lower molecular weight RNA. The difference between these two mRNAs is due to different lengths of their 3' untranslated regions, suggesting that the cell-specific regulation of their expression occurs either by specific termination of transcription or by differential post-transcriptional processing of the 3' untranslated region. Additionally, a remarkable induction (40- to 50-fold) in the abundance of the vimentin mRNA is observed in erythroid cells as chicken development proceeds from 4 to 15 days, which suggests that the level of expression of vimentin during erythroid development is regulated at the transcriptional level.

A splice junction deletion deficient in the transport of RNA does not polyadenylate nuclear RNA

A late region deletion mutant of simian virus 40 (dl5) was previously shown to be deficient in the transport of nuclear RNA. This is a splice junction deletion that has lost the 3' end of an RNA leader, an intervening sequence, and the 5' end of the splice acceptor site on the body of the mRNA. In this report, we analyzed the steady-state structure of the untransported nuclear RNA. The 5' ends of this RNA are heterogeneous but contain a prominent 5' end at the normal position (nucleotide 325) in addition to several other prominent 5' ends not seen in wild-type RNA. The 3' end of this RNA does not occur at the usual position (nucleotide 2674) of polyadenylation; instead, this RNA is non-polyadenylated, with the 3' end occurring either downstream or upstream of the normal position.

Inhibition of RNA cleavage but not polyadenylation by a point mutation in mRNA 3' consensus sequence AAUAAA

A single U leads to G transversion in the 3' consensus sequence AAUAAA of the adenovirus early region 1A gene was constructed and the effect of this mutation on processing of the 3' end of the nuclear early region 1A RNAs was analysed. The results demonstrate that the intact AAUAAA is not required for RNA polyadenylation but is required for the cleavage step preceding polyadenylation to occur efficiently.

The structure of the mouse immunoglobulin in gamma 3 membrane gene segment

The genomic region containing the mouse immunoglobulin gamma 3 heavy chain membrane (M) exons has been located and sequenced. The exon structure is highly similar to that of the other mouse gamma chains, with strong sequence conservation in the coding regions and the intron 5' to the M1 exon. The intron between M1 and M2 shows moderate sequence homology but very strong conservation of size. RNA blots suggest that gamma 3 membrane exon usage is similar to that seen in other immunoglobulin membrane heavy chain mRNAs. The transmembrane region contains the invariant residues which have been noted in all other heavy chain sequences and which were previously proposed to be interactive in a two-chain model for insertion through the lymphocyte membrane. Conserved residues with similar spacing have been seen in class II histocompatibility antigens, which are also two-chain transmembrane molecules, but not in class I antigens, which span cell membranes with a single chain.

A splice junction deletion deficient in the transport of RNA does not polyadenylate nuclear RNA

A late region deletion mutant of simian virus 40 (dl5) was previously shown to be deficient in the transport of nuclear RNA. This is a splice junction deletion that has lost the 3' end of an RNA leader, an intervening sequence, and the 5' end of the splice acceptor site on the body of the mRNA. In this report, we analyzed the steady-state structure of the untransported nuclear RNA. The 5' ends of this RNA are heterogeneous but contain a prominent 5' end at the normal position (nucleotide 325) in addition to several other prominent 5' ends not seen in wild-type RNA. The 3' end of this RNA does not occur at the usual position (nucleotide 2674) of polyadenylation; instead, this RNA is non-polyadenylated, with the 3' end occurring either downstream or upstream of the normal position.

Accurate and specific polyadenylation of mRNA precursors in a soluble whole-cell lysate

Conditions have been developed which allow for the efficient, accurate, and specific polyadenylation of exogenously added mRNA precursors in a whole-cell lysate derived from HeLa cells. Precursors are prepared by in vitro transcription using linear DNA templates in a HeLa whole-cell lysate, purified, and added to another lysate. Under optimal conditions (which are quite precise with respect to several variables), 70% or more of the precursor molecules become polyadenylated, and the length of the poly(A) segment added is controlled much as it is in vivo, giving rise to 150-300-nucleotide long stretches of poly(A). Under suboptimal conditions, both the fraction of precursor RNA that becomes polyadenylated and also the length of the poly(A) segment added are reduced. The in vitro polyadenylation reaction is also remarkably specific: Only in vitro-synthesized pre-mRNAs that contain a 3' end located at or slightly downstream from the corresponding in vivo mRNA 3' end site can be efficiently polyadenylated in vitro. These results suggest that the poly(A) polymerase requires one or more protein (or RNA) factors in order to bring about accurate and specific polyadenylation in vitro, and that the poly(A) polymerase complex must interact with a specific recognition signal at the 3' end of mRNA precursors in order to catalyze subsequent polyadenylation.

Evidence of transcription from the late region of the integrated simian virus 40 genome in transformed cells: location of the 5' ends of late transcripts in cells abortively infected and in cells transformed by simian virus 40

By means of S1 mapping, we observed that spliced 16S and 19S viral late mRNAs--in addition to early mRNAs--were present in cytoplasmic polyadenylated RNA preparations from simian virus 40-transformed cell lines of rat or mouse origin containing no detectable amount of free viral DNA. The amounts of early and late virus-specific mRNAs in these lines were quantified by hybridization of radioactive cytoplasmic polyadenylated RNA with cloned region-specific restriction fragments. The relative amount of late viral mRNA produced in these transformed cells was found to be of the same order as that produced in simian virus 40-infected, nonpermissive baby mouse kidney cells. Moreover, by using the S1 nuclease protection method, we compared the 5' ends of late mRNAs produced (i) in transformed cells, (ii) in abortively infected mouse cells, and (iii) in the late phase of the lytic cycle. The 5' ends of late mRNAs both in abortively infected and in transformed cells were less heterogeneous than the 5' ends of late mRNAs produced during the lytic cycle; however, they were a subset of the 5' ends of late transcripts produced in the lytic cycle.

Analysis in Cos-1 cells of processing and polyadenylation signals by using derivatives of the herpes simplex virus type 1 thymidine kinase gene

Bal31 nuclease was used to resect the herpes simplex virus type 1 thymidine kinase (tk) gene from its 3' end, and a plasmid, pTK206, was isolated that lacked the processing and polyadenylation signals normally found at the 3' end of the gene. The wild-type gene, pTK2, and pTK206 were each transferred to pSV010, a plasmid containing the simian virus 40 (SV40) origin of DNA replication, allowing replication and analysis of the patterns of transcription in Cos-1 cells. Fragments of DNA containing processing and polyadenylation signals from SV40 and polyoma virus were inserted into the 3' end of the resected tk gene, pTK206. We found that tk gene expression requires a processing and polyadenylation signal, that signals from SV40 and polyoma virus could substitute for the herpes simplex virus tk signal, and that considerable differences in the levels of tk mRNA were present in Cos-1 cells transfected by these gene constructs. In addition, tk gene expression was restored to a low level after the insertion of an 88-base-pair fragment from the middle of the SV40 early region. Processing and polyadenylation do not occur in the vicinity of this fragment in SV40, even though it contains the hexanucleotide 5'-AAUAAA-3'.

A cDNA cloning vector that permits expression of cDNA inserts in mammalian cells

This paper describes a plasmid vector for cloning cDNAs in Escherichia coli; the same vector also promotes expression of the cDNA segment in mammalian cells. Simian virus 40 (SV40)-derived DNA segments are arrayed in the pcD vector to permit transcription, splicing, and polyadenylation of the cloned cDNA segment. A DNA fragment containing both the SV40 early region promoter and two introns normally used to splice the virus 16S and 19S late mRNAs is placed upstream of the cDNA cloning site to ensure transcription and splicing of the cDNA transcripts. An SV40 late region polyadenylation sequence occurs downstream of the cDNA cloning site, so that the cDNA transcript acquires a polyadenylated 3' end. By using pcD-alpha-globin cDNA as a model, we confirmed that the alpha-globin transcript produced in transfected cells is initiated correctly, spliced at either of the two introns, and polyadenylated either at the site coded in the cDNA segment or at the distal SV40 polyadenylation signal. A cDNA clone library constructed with mRNA from SV40-transformed human fibroblasts and this vector (about 1.4 X 10(6) clones) yielded full-length cDNA clones that express hypoxanthine-guanine phosphoribosyltransferase (Jolly et al., Proc. Natl. Acad. Sci. U.S.A., in press).