The human immunodeficiency virus type 1 polyadenylylation signal: a 3' long terminal repeat element upstream of the AAUAAA necessary for efficient polyadenylylation

Application of the iPLUS non-coding sequence in improving biopharmaceuticals production

The biotechnological landscape has witnessed significant growth in biological therapeutics particularly in the field of recombinant protein production. Here we investigate the function of 3'UTR cis-regulatory elements in increasing mRNA and protein levels in different biological therapeutics and model systems, spanning from monoclonal antibodies to mRNA vaccines. We explore the regulatory function of iPLUS - a universal sequence capable of consistently augmenting recombinant protein levels. By incorporating iPLUS in a vector to express a monoclonal antibody used in immunotherapy, in a mammalian cell line used by the industry (ExpiCHO), trastuzumab production increases by 2-fold. As yeast Pichia pastoris is widely used in the manufacture of industrial enzymes and pharmaceuticals, we then used iPLUS in tandem (3x) and iPLUSv2 (a variant of iPLUS) to provide proof-of-concept data that it increases the production of a reporter protein more than 100-fold. As iPLUS functions by also increasing mRNA levels, we hypothesize that these sequences could be used as an asset in the mRNA vaccine industry. In fact, by including iPLUSv2 downstream of Spike we were able to double its production. Moreover, the same effect was observed when we introduced iPLUSv2 downstream of MAGEC2, a tumor-specific antigen tested for cancer mRNA vaccines. Taken together, our study provides data (TLR4) showing that iPLUS may be used as a valuable asset in a variety of systems used by the biotech and biopharmaceutical industry. Our results underscore the critical role of non-coding sequences in controlling gene expression, offering a promising avenue to accelerate, enhance, and cost-effectively optimize biopharmaceutical production processes.

Origin and functional role of antisense transcription in endogenous and exogenous retroviruses

Most proteins expressed by endogenous and exogenous retroviruses are encoded in the sense (positive) strand of the genome and are under the control of regulatory elements within the 5' long terminal repeat (LTR). A number of retroviral genomes also encode genes in the antisense (negative) strand and their expression is under the control of negative sense promoters within the 3' LTR. In the case of the Human T-cell Lymphotropic Virus 1 (HTLV-1), the antisense protein HBZ has been shown to play a critical role in the virus lifecycle and in the pathogenic process, while the function of the Human Immunodeficiency Virus 1 (HIV-1) antisense protein ASP remains unknown. However, the expression of 3' LTR-driven antisense transcripts is not always demonstrably associated with the presence of an antisense open reading frame encoding a viral protein. Moreover, even in the case of retroviruses that do express an antisense protein, such as HTLV-1 and the pandemic strains of HIV-1, the 3' LTR-driven antisense transcript shows both protein-coding and noncoding activities. Indeed, the ability to express antisense transcripts appears to be phylogenetically more widespread among endogenous and exogenous retroviruses than the presence of a functional antisense open reading frame within these transcripts. This suggests that retroviral antisense transcripts may have originated as noncoding molecules with regulatory activity that in some cases later acquired protein-coding function. Here, we will review examples of endogenous and exogenous retroviral antisense transcripts, and the ways through which they benefit viral persistence in the host.

Sequence determinants of polyadenylation-mediated regulation

The cleavage and polyadenylation reaction is a crucial step in transcription termination and pre-mRNA maturation in human cells. Despite extensive research, the encoding of polyadenylation-mediated regulation of gene expression within the DNA sequence is not well understood. Here, we utilized a massively parallel reporter assay to inspect the effect of over 12,000 rationally designed polyadenylation sequences (PASs) on reporter gene expression and cleavage efficiency. We find that the PAS sequence can modulate gene expression by over five orders of magnitude. By using a uniquely designed scanning mutagenesis data set, we gain mechanistic insight into various modes of action by which the cleavage efficiency affects the sensitivity or robustness of the PAS to mutation. Furthermore, we employ motif discovery to identify both known and novel sequence motifs associated with PAS-mediated regulation. By leveraging the large scale of our data, we train a deep learning model for the highly accurate prediction of RNA levels from DNA sequence alone (R = 0.83). Moreover, we devise unique approaches for predicting exact cleavage sites for our reporter constructs and for endogenous transcripts. Taken together, our results expand our understanding of PAS-mediated regulation, and provide an unprecedented resource for analyzing and predicting PAS for regulatory genomics applications.

Multiple sequence elements are involved in RNA 3' end formation in spleen necrosis virus

The function of the poly(A) signal in spleen necrosis virus (SNV) is dependent upon the distance between the cap site and the poly(A) site, while the function of the SV40 late poly(A) signal is independent of the distance. Deletions in the SNV poly(A) sequence do not alter the distance-dependent function. SNV/SV40 chimeric poly(A) signals show intermediate behavior between the SNV and SV40 poly(A) signals. These results indicate that multiple sequence elements are involved in the functions of either the SNV or SV40 poly(A) signals. This intermediate behavior is also observed with poly(A) signals from the mouse alpha-globin and herpes simplex virus thymidine kinase genes.

Omni-PolyA: a method and tool for accurate recognition of Poly(A) signals in human genomic DNA

BACKGROUND

Polyadenylation is a critical stage of RNA processing during the formation of mature mRNA, and is present in most of the known eukaryote protein-coding transcripts and many long non-coding RNAs. The correct identification of poly(A) signals (PAS) not only helps to elucidate the 3'-end genomic boundaries of a transcribed DNA region and gene regulatory mechanisms but also gives insight into the multiple transcript isoforms resulting from alternative PAS. Although progress has been made in the in-silico prediction of genomic signals, the recognition of PAS in DNA genomic sequences remains a challenge.

RESULTS

In this study, we analyzed human genomic DNA sequences for the 12 most common PAS variants. Our analysis has identified a set of features that helps in the recognition of true PAS, which may be involved in the regulation of the polyadenylation process. The proposed features, in combination with a recognition model, resulted in a novel method and tool, Omni-PolyA. Omni-PolyA combines several machine learning techniques such as different classifiers in a tree-like decision structure and genetic algorithms for deriving a robust classification model. We performed a comparison between results obtained by state-of-the-art methods, deep neural networks, and Omni-PolyA. Results show that Omni-PolyA significantly reduced the average classification error rate by 35.37% in the prediction of the 12 considered PAS variants relative to the state-of-the-art results.

CONCLUSIONS

The results of our study demonstrate that Omni-PolyA is currently the most accurate model for the prediction of PAS in human and can serve as a useful complement to other PAS recognition methods. Omni-PolyA is publicly available as an online tool accessible at www.cbrc.kaust.edu.sa/omnipolya/ .

Construction of a chimeric secretory IgA and its neutralization activity against avian influenza virus H5N1

Secretory immunoglobulin A (SIgA) acts as the first line of defense against respiratory pathogens. In this assay, the variable regions of heavy chain (VH) and Light chain (VL) genes from a mouse monoclonal antibody against H5N1 were cloned and fused with human IgA constant regions. The full-length chimeric light and heavy chains were inserted into a eukaryotic expressing vector and then transfected into CHO/dhfr-cells. The chimeric monomeric IgA antibody expression was confirmed by using ELISA, SDS-PAGE, and Western blot. In order to obtain a dimeric secretory IgA, another two expressing plasmids, namely, pcDNA4/His A-IgJ and pcDNA4/His A-SC, were cotransfected into the CHO/dhfr-cells. The expression of dimeric SIgA was confirmed by using ELISA assay and native gel electrophoresis. In microneutralization assay on 96-well immunoplate, the chimeric SIgA showed neutralization activity against H5N1 virus on MDCK cells and the titer was determined to be 1 : 64. On preadministrating intranasally, the chimeric SIgA could prevent mice from lethal attack by using A/Vietnam/1194/04 H5N1 with a survival rate of 80%. So we concluded that the constructed recombinant chimeric SIgA has a neutralization capability targeting avian influenza virus H5N1 infection in vitro and in vivo.

In vivo SELEX of single-stranded domains in the HIV-1 leader RNA

The 5' untranslated leader region of the human immunodeficiency virus type 1 (HIV-1) RNA genome is a strongly conserved sequence that encodes several regulatory motifs important for viral replication. Most of these motifs are exposed as hairpin structures, including the dimerization initiation signal (DIS), the major splice donor site (SD), and the packaging signal (Ψ), which are connected by short single-stranded regions. Mutational analysis revealed many functions of these hairpins, but only a few studies have focused on the single-stranded purine-rich sequences. Using the in vivo SELEX (systematic evolution of ligands by exponential enrichment) approach, we probed the sequence space in these regions that is compatible with efficient HIV-1 replication and analyzed the impact on the RNA secondary structure of the leader RNA. Our results show a strong sequence requirement for the DIS hairpin flanking regions. We postulate that these sequences are important for the binding of specific protein factors that support leader RNA-mediated functions. The sequence between the SD and Ψ hairpins seems to have a less prominent role, despite the strong conservation of the stretch of 5 A residues in natural isolates. We hypothesize that this may reflect the subtle evolutionary pressure on HIV-1 to acquire an A-rich RNA genome. In silico analyses indicate that sequences are avoided in all 3 single-stranded domains that affect the local or overall leader RNA folding. IMPORTANCE Many regulatory RNA sequences are clustered in the untranslated leader domain of the HIV-1 RNA genome. Several RNA hairpin structures in this domain have been proposed to fulfill specific roles, e.g., mediating RNA dimer formation to facilitate HIV-1 recombination. We now focus on the importance of a few well-conserved single-stranded sequences that connect these hairpins. We created libraries of HIV-1 variants in which these segments were randomized and selected the best-replicating variants. For two segments we document the selection of the (nearly) wild-type sequence, thus demonstrating the importance of these primary nucleotide sequences and the power of the in vivo SELEX approach. However, for the third segment a large variety of sequences is compatible with efficient HIV-1 replication. Interestingly, the A-rich sequence of this segment is highly conserved among HIV-1 isolates, which likely reflects the evolutionary tendency of HIV-1 to adopt A-rich sequences.

Lentiviral vector-mediated RNA silencing in the central nervous system

RNA silencing is an established method for investigating gene function and has attracted particular interest because of the potential for generating RNA-based therapeutics. Using lentiviral vectors as an efficient delivery system that offers stable, long-term expression in postmitotic cells further enhances the applicability of an RNA-based gene therapy for the CNS. In this review we provide an overview of both lentiviral vectors and RNA silencing along with design considerations for generating lentiviral vectors capable of RNA silencing. We go on to describe the current preclinical data regarding lentiviral vector-mediated RNA silencing for CNS disorders and discuss the concerns of side effects associated with lentiviral vectors and small interfering RNAs and how these might be mitigated.

Regulation of retroviral polyadenylation

Cellular and viral preRNAs are extensively cotranscriptionally modified. These modifications include the processing of the 3' end. Most preRNAs are polyadenylated, which is required for nuclear export, RNA stability, and efficient translation. Integrated retroviral genomes are flanked by 3' and 5' long terminal repeats (LTRs). Both LTRs are identical on the nucleotide level, but 3' processing has to be limited to the 3'LTR. Otherwise, polyadenylation at the 5'LTR would result in prematurely terminated, noncoding viral RNAs. Retroviruses have developed a variety of different mechanisms to restrict polyadenylation to the 3'LTR, although the overall structure of the LTRs is similar among all retroviruses. In general, these mechanisms can be divided into three main groups: (1) activation of polyadenylation only at the 3' end by encoding the essential polyadenylation signal in the unique 3 region; (2) suppression of polyadenylation at the 5'LTR by downstream elements such as the major splice donor; and (3) the usage of weak polyadenylation sites, which results in some premature polyadenylated noncoding RNAs and in read-through transcripts at the 3'LTR. All these mechanisms exhibit intrinsic problems, and retroviruses have evolved additional regulatory elements to promote polyadenylation at the 3'LTR only. In this review, we describe the molecular regulation of retroviral polyadenylation and highlight the different mechanisms used for polyadenylation control.

Characterization of the distal polyadenylation site of the ß-adducin (Add2) pre-mRNA

Most genes have multiple polyadenylation sites (PAS), which are often selected in a tissue-specific manner, altering protein products and affecting mRNA stability, subcellular localization and/or translability. Here we studied the polyadenylation mechanisms associated to the beta-adducin gene (Add2). We have previously shown that the Add2 gene has a very tight regulation of alternative polyadenylation, using proximal PAS in erythroid tissues, and a distal one in brain. Using chimeric minigenes and cell transfections we identified the core elements responsible for polyadenylation at the distal PAS. Deletion of either the hexanucleotide motif (Hm) or the downstream element (DSE) resulted in reduction of mature mRNA levels and activation of cryptic PAS, suggesting an important role for the DSE in polyadenylation of the distal Add2 PAS. Point mutation of the UG repeats present in the DSE, located immediately after the cleavage site, resulted in a reduction of processed mRNA and in the activation of the same cryptic site. RNA-EMSA showed that this region is active in forming RNA-protein complexes. Competition experiments showed that RNA lacking the DSE was not able to compete the RNA-protein complexes, supporting the hypothesis of an essential important role for the DSE. Next, using a RNA-pull down approach we identified some of the proteins bound to the DSE. Among these proteins we found PTB, TDP-43, FBP1 and FBP2, nucleolin, RNA helicase A and vigilin. All these proteins have a role in RNA metabolism, but only PTB has a reported function in polyadenylation. Additional experiments are needed to determine the precise functional role of these proteins in Add2 polyadenylation.

Long-distance regulation of Add2 pre-mRNA3'end processing

Accurate 3′end processing depends on the correct recognition of polyadenylation regulatory elements by specific protein complexes. In addition to the well-known hexanucleotide motif and downstream sequence element (DSE), less-defined auxiliary elements are usually found to modulate cleavage and polyadenylation. They are generally located in close proximity to the core polyadenylation elements but, in most of the cases, the molecular mechanisms involved are not well defined. We concentrated our studies on the regulation of the mouse β adducin (Add2) pre-mRNA cleavage and polyadenylation. It contains two proximal erythroid-specific (PAS1 and PAS2-3) and one distal brain-specific (PAS4) polyadenylation sites along the 3′UTR. Using an in vivo approach based in the transfection of minigenes containing the Add2 polyadenylation signals, we previously identified the core regulatory elements responsible for PAS4 activity. Here, we have identified two novel non-canonical cis-acting elements regulating 3′end processing at PAS4, which show long-distance activities. The first of these elements, which spans for 257 nucleotides and is located at more than 5 kb upstream the PAS4, was essential to enable processing at the Add2 PAS4. The second element, located at about 4.5 kb upstream of the PAS4, reduces PAS4 processing. Both elements display long-distance activities and, to our knowledge, long-distance upstream polyadenylation regulatory elements have not been previously described in non-viral eukaryotic transcripts. These results highlight the complexity of the regulatory mechanisms directing Add2 pre-mRNA 3′end processing, and suggests that pre-mRNA 3′ end processing of other genes may also be unexpectedly regulated by non-canonical auxiliary elements.

Structural model of the complete poly(A) region of HIV-1 pre-mRNA

In the HIV-1 retrovirus, identical sequences encompassing the AAUAAA hexamer and the U/GU-rich downstream sequence element (DSE) that compose the core poly(A) site are present at both the 5' and 3' ends of the HIV-1 pre-mRNA. The AAUAAA hexamer is partly occluded by base pairing in the upper part of a semi-stable polyA hairpin. This sets the stage for regulation of HIV-1 polyadenylation, which involves reaction suppression at the 5' end and its stimulation at the 3' end. Efficient utilization of the 3' core poly(A) site is promoted by major and minor upstream sequence elements (USEs) which are uniquely present at the 3' end of the HIV-1 transcript. The structures of the HIV-1 5' and 3' poly(A) sites are defined by overall architecture of complete 5' and 3' untranslated terminal regions (UTRs). To our knowledge, there is still no structural model of a complete 3' UTR of the HIV-1 pre-mRNA and complete 3' poly(A) region including the USEs except the fact that the polyA and transactivation response (TAR) hairpins are present at both ends of the HIV-1 pre-mRNA. In this work, we predicted a secondary structure of the 3' UTR of HIV-1 pre-mRNA based on our observation that the minor USEs are located in a region with a high potential to form G-quadruplex structures. We first present structural models for the major USE, complete 3' poly(A) region, and almost entire 3' UTR of HIV-1 pre-mRNA. Our models are built based on the mfold and UNAFold secondary structure prediction of these regions for about 1500 HIV-1 isolates of different subtypes and recombinant forms. We have demonstrated that these models are valid for most of the HIV-1 isolates studied. The proposed models include the known TAR and polyA hairpins and new structural elements containing the U-rich tract of the major USE and U/GU-rich DSE which are fully exposed and accessible to the polyadenylation machinery, which confirms the functional competence of our models.

Ending the message: poly(A) signals then and now

Polyadenylation [poly(A)] signals (PAS) are a defining feature of eukaryotic protein-coding genes. The central sequence motif AAUAAA was identified in the mid-1970s and subsequently shown to require flanking, auxiliary elements for both 3'-end cleavage and polyadenylation of premessenger RNA (pre-mRNA) as well as to promote downstream transcriptional termination. More recent genomic analysis has established the generality of the PAS for eukaryotic mRNA. Evidence for the mechanism of mRNA 3'-end formation is outlined, as is the way this RNA processing reaction communicates with RNA polymerase II to terminate transcription. The widespread phenomenon of alternative poly(A) site usage and how this interrelates with pre-mRNA splicing is then reviewed. This shows that gene expression can be drastically affected by how the message is ended. A central theme of this review is that while genomic analysis provides generality for the importance of PAS selection, detailed mechanistic understanding still requires the direct analysis of specific genes by genetic and biochemical approaches.

Characterization and prediction of mRNA polyadenylation sites in human genes

The accurate identification of potential poly(A) sites has contributed to all many studies with regard to alternative polyadenylation. The aim of this study was the development of a machine-learning methodology that will help to discriminate real polyadenylation signals from randomly occurring signals in genomic sequence. Since previous studies have revealed that RNA secondary structure in certain genes has significant impact, the authors tried to computationally pinpoint common structural patterns around the poly(A) sites and to investigate how RNA secondary structure may influence polyadenylation. This involved an initial study on the impact of RNA structure and it was found using motif search tools that hairpin structures might be important. Thus, it was propose that, in addition to the sequence pattern around poly(A) sites, there exists a widespread structural pattern that is also employed during human mRNA polyadenylation. In this study, the authors present a computational model that uses support vector machines to predict human poly(A) sites. The results show that this predictive model has a comparable performance to the current prediction tool. In addition, it was identified common structural patterns associated with polyadenylation using several motif finding programs and this provides new insight into the role of RNA secondary structure plays in polyadenylation.

Destabilization of the TAR hairpin leads to extension of the polyA hairpin and inhibition of HIV-1 polyadenylation

Background

Two hairpin structures that are present at both the 5' and 3' end of the HIV-1 RNA genome have important functions in the viral life cycle. The TAR hairpin binds the viral Tat protein and is essential for Tat-mediated activation of transcription. The adjacent polyA hairpin encompasses the polyadenylation signal AAUAAA and is important for the regulation of polyadenylation. Specifically, this RNA structure represses polyadenylation at the 5' side, and enhancer elements on the 3' side overcome this suppression. We recently described that the replication of an HIV-1 variant that does not need TAR for transcription was severely impaired by destabilization of the TAR hairpin, even though a complete TAR deletion was acceptable.

Results

In this study, we show that the TAR-destabilizing mutations result in reduced 3' polyadenylation of the viral transcripts due to an extension of the adjacent polyA hairpin. Thus, although the TAR hairpin is not directly involved in polyadenylation, mutations in TAR can affect this process.

Conclusion

The stability of the HIV-1 TAR hairpin structure is important for the proper folding of the viral RNA transcripts. This study illustrates how mutations that are designed to study the function of a specific RNA structure can change the structural presentation of other RNA domains and thus affect viral replication in an indirect way.

Alternative polyadenylation: a twist on mRNA 3' end formation

Regulation of gene expression by RNA processing mechanisms is now understood to be an important level of control in mammalian cells. Regulation at the level of RNA transcription, splicing, polyadenylation, nucleo-cytoplasmic transport, and translation into polypeptides has been well-studied. Alternative RNA processing events, such as alternative splicing, also have been recognized as key contributors to the complexity of mammalian gene expression. Pre-messenger RNAs (pre-mRNAs) may be polyadenylated in several different ways due to more than one polyadenylation signal, allowing a single gene to encode multiple mRNA transcripts. However, alternative polyadenylation has only recently taken the field as a major player in gene regulation. This review summarizes what is currently known about alternative polyadenylation. It covers results from bioinformatics, as well as those from investigations of viral and tissue-specific studies and, importantly, will set the stage for what is yet to come.

3' end mRNA processing: molecular mechanisms and implications for health and disease

Recent advances in the understanding of the molecular mechanism of mRNA 3' end processing have uncovered a previously unanticipated integrated network of transcriptional and RNA-processing mechanisms. A variety of human diseases impressively reflect the importance of the precision of the complex 3' end-processing machinery and gene specific deregulation of 3' end processing can result from mutations of RNA sequence elements that bind key specific processing factors. Interestingly, more general deregulation of 3' end processing can be caused either by mutations of these processing factors or by the disturbance of the well-coordinated equilibrium between these factors. From a medical perspective, both loss of function and gain of function can be functionally relevant, and an increasing number of different disease entities exemplifies that inappropriate 3' end formation of human mRNAs can have a tremendous impact on health and disease. Here, we review the mechanistic hallmarks of mRNA 3' end processing, highlight the medical relevance of deregulation of this important step of mRNA maturation and illustrate the implications for diagnostic and therapeutic strategies.

Improving transcriptional termination of self-inactivating gamma-retroviral and lentiviral vectors

Adverse events relating to insertional mutagenesis have reinforced the interest in self-inactivating (SIN) gamma-retroviral and lentiviral vectors without enhancer-promoter sequences in the U3 region of the long terminal repeats. However, SIN vectors suffer from leaky transcriptional termination, increasing the probability of read-through into cellular genes. To improve 3' end processing, we incorporated seven upstream polyadenylation enhancer elements (or upstream sequence elements, USEs) derived from viral or cellular genes into the 3' U3 region of gamma-retroviral and lentiviral SIN vectors. A 100-base-pair sequence representing a recombinant direct repeat of the USE derived from simian virus 40 (2xSV USE) gave the best results, improving both titer and gene expression. In both gamma-retroviral and lentiviral SIN vectors, the 2xSV USE partially substituted for effects provided by the much larger post-transcriptional regulatory element derived from woodchuck hepatitis virus (wPRE). By northern blot and reporter assays, we found that the 2xSV USE greatly improved proper messenger RNA (mRNA) processing at the retroviral termination signal. Importantly, the 2xSV USE was superior to the wPRE in suppressing transcriptional read-through, improving not only vector efficiency but potentially also biosafety.

Overlapping enhancer/promoter and transcriptional termination signals in the lentiviral long terminal repeat

Oncoretrovirus, but not lentivirus, displays a high transcriptional readthrough activity in the 3' long terminal repeat (LTR) (Zaiss et al. J. Virol. 76, 7209–7219, 2002). However, the U3-deleted, self-inactivating (SIN) lentiviral LTR also exhibits high transcriptional readthrough activity. Since the canonical "core" polyadenylation signal (AAUAAA) of the lentivirus is located in the R-U5 region, the above finding suggests that additional RNA termination signals must be present in the U3 region. Insertion of alternative termination signals including panhuman T cell leukemia virus type I polyadenylation signal, a 3' end small intron, and a tertiary tRNA motif into the lentiviral SIN LTR did not restore the transcriptional termination function. Functional dissection of the U3 region revealed that 70–80% of the termination signals reside in the transcriptional control region within 124 nt overlapping NFκB, Sp1 and TATA binding sites. Serial deletion analysis of the transcriptional control region indicates that the lentiviral enhancer/promoter elements are essential to the RNA termination function. These results characterize the mechanism of lentiviral transcriptional readthrough, which addresses important fundamental and practical issue of RNA readthrough influencing lentiviral gene function and vector safety.

Two G-rich regulatory elements located adjacent to and 440 nucleotides downstream of the core poly(A) site of the intronless melanocortin receptor 1 gene are critical for efficient 3' end processing

Cleavage and polyadenylation is an essential processing reaction required for the maturation of pre-mRNAs into stable, export- and translation-competent mature mRNA molecules. This reaction requires the assembly of a multimeric protein complex onto a bipartite core sequence element consisting of an AAUAAA hexamer and a GU/U-rich downstream sequence element. In this study we have analyzed 3' end processing of the human melanocortin 1 receptor gene (MC1R). The MC1R gene is an intron-free transcription unit, and its poly(A) site lacks a defined U/GU-rich element. We describe two G-rich sequence elements that are critical for efficient cleavage at the MC1R poly(A) site. The first element is located 30 nucleotides downstream of the cleavage site and acts as an essential closely positioned enhancer. The second G-rich region is positioned more than 440 nucleotides downstream of the MC1R processing site and is instrumental for optimal processing efficiency. Both G-rich sequences contain clusters of heterogeneous nuclear ribonucleoprotein binding motifs and act together to enhance cleavage at the MC1R poly(A) site.

Structural differentiation of the HIV-1 polyA signals

The Human Immunodeficiency Virus Type 1 (HIV-1) encodes the polyadenylation (polyA) signal (AAUAAA) within the highly conserved untranslated region (UTR) at both 5' and 3' terminals of the viral transcript. In polyadenylation, an RNA transcript is cleaved and then elongated with adenine nucleotides while repression of the 5' signal and utilization of the 3' signal occurs. Because experimental studies have yet to analyze the structures of both 5' and 3' signals from a global perspective, other structural conformations involving these signals may exist and could be pivotal to understanding key functional processes. To distinguish the differential regulation of the 5' and 3' polyA signals, we studied the structural tendencies of both the 5' and 3' UTR in HIV-1. Through computational folding predictions of multiple HIV-1 strains using the Massively Parallel Genetic Algorithm (MPGAfold) capable of dynamically elucidating key alternative conformations, the 5' polyA signal was found to be dominantly occluded in a hairpin loop while the 3' polyA signal showed variability between hairpin and linear conformations with a propensity for the linear structure with an asymmetric internal loop. Furthermore, the energies and predictions of these structures indicate that the polyA signals have some metastable characteristics indicating an ability to switch into different conformations that can regulate viral function.

Bioinformatic identification of candidate cis-regulatory elements involved in human mRNA polyadenylation

Polyadenylation is an essential step for the maturation of almost all cellular mRNAs in eukaryotes. In human cells, most poly(A) sites are flanked by the upstream AAUAAA hexamer or a close variant, and downstream U/GU-rich elements. In yeast and plants, additional cis elements have been found to be located upstream of the poly(A) site, including UGUA, UAUA, and U-rich elements. In this study, we have developed a computer program named PROBE (Polyadenylation-Related Oligonucleotide Bidimensional Enrichment) to identify cis elements that may play regulatory roles in mRNA polyadenylation. By comparing human genomic sequences surrounding frequently used poly(A) sites with those surrounding less frequently used ones, we found that cis elements occurring in yeast and plants also exist in human poly(A) regions, including the upstream U-rich elements, and UAUA and UGUA elements. In addition, several novel elements were found to be associated with human poly(A) sites, including several G-rich elements. Thus, we suggest that many cis elements are evolutionarily conserved among eukaryotes, and human poly(A) sites have an additional set of cis elements that may be involved in the regulation of mRNA polyadenylation.

Analysis of a noncanonical poly(A) site reveals a tripartite mechanism for vertebrate poly(A) site recognition

At least half of all human pre-mRNAs are subject to alternative 3' processing that may modulate both the coding capacity of the message and the array of post-transcriptional regulatory elements embedded within the 3' UTR. Vertebrate poly(A) site selection appears to rely primarily on the binding of CPSF to an A(A/U)UAAA hexamer upstream of the cleavage site and CstF to a downstream GU-rich element. At least one-quarter of all human poly(A) sites, however, lack the A(A/U)UAAA motif. We report that sequence-specific RNA binding of the human 3' processing factor CFI(m) can function as a primary determinant of poly(A) site recognition in the absence of the A(A/U)UAAA motif. CFI(m) is sufficient to direct sequence-specific, A(A/U)UAAA-independent poly(A) addition in vitro through the recruitment of the CPSF subunit hFip1 and poly(A) polymerase to the RNA substrate. ChIP analysis indicates that CFI(m) is recruited to the transcription unit, along with CPSF and CstF, during the initial stages of transcription, supporting a direct role for CFI(m) in poly(A) site recognition. The recognition of three distinct sequence elements by CFI(m), CPSF, and CstF suggests that vertebrate poly(A) site definition is mechanistically more similar to that of yeast and plants than anticipated.

Analysis of a noncanonical poly(A) site reveals a tripartite mechanism for vertebrate poly(A) site recognition

At least half of all human pre-mRNAs are subject to alternative 3' processing that may modulate both the coding capacity of the message and the array of post-transcriptional regulatory elements embedded within the 3' UTR. Vertebrate poly(A) site selection appears to rely primarily on the binding of CPSF to an A(A/U)UAAA hexamer upstream of the cleavage site and CstF to a downstream GU-rich element. At least one-quarter of all human poly(A) sites, however, lack the A(A/U)UAAA motif. We report that sequence-specific RNA binding of the human 3' processing factor CFI(m) can function as a primary determinant of poly(A) site recognition in the absence of the A(A/U)UAAA motif. CFI(m) is sufficient to direct sequence-specific, A(A/U)UAAA-independent poly(A) addition in vitro through the recruitment of the CPSF subunit hFip1 and poly(A) polymerase to the RNA substrate. ChIP analysis indicates that CFI(m) is recruited to the transcription unit, along with CPSF and CstF, during the initial stages of transcription, supporting a direct role for CFI(m) in poly(A) site recognition. The recognition of three distinct sequence elements by CFI(m), CPSF, and CstF suggests that vertebrate poly(A) site definition is mechanistically more similar to that of yeast and plants than anticipated.

Polypyrimidine tract binding protein modulates efficiency of polyadenylation

Polypyrimidine tract binding protein (PTB) is a major hnRNP protein with multiple roles in mRNA metabolism, including regulation of alternative splicing and internal ribosome entry site-driven translation. We show here that a fourfold overexpression of PTB results in a 75% reduction of mRNA levels produced from transfected gene constructs with different polyadenylation signals (pA signals). This effect is due to the reduced efficiency of mRNA 3' end cleavage, and in vitro analysis reveals that PTB competes with CstF for recognition of the pA signal's pyrimidine-rich downstream sequence element. This may be analogous to its role in alternative splicing, where PTB competes with U2AF for binding to pyrimidine-rich intronic sequences. The pA signal of the C2 complement gene unusually possesses a PTB-dependent upstream sequence, so that knockdown of PTB expression by RNA interference reduces C2 mRNA expression even though PTB overexpression still inhibits polyadenylation. Consequently, we show that PTB can act as a regulator of mRNA expression through both its negative and positive effects on mRNA 3' end processing.

Tissue-specific transcriptional targeting of a replication-competent retroviral vector

The inability of replication-defective viral vectors to efficiently transduce tumor cells in vivo has prevented the successful application of such vectors in gene therapy of cancer. To address the need for more efficient gene delivery systems, we have developed replication-competent retroviral (RCR) vectors based on murine leukemia virus (MLV). We have previously shown that such vectors are capable of transducing solid tumors in vivo with very high efficiency. While the natural requirement of MLV infection for cell division imparts a certain degree of specificity for tumor cells, additional means for confining RCR vector replication to tumor cells are desirable. Here, we investigated the parameters critical for successful tissue-specific transcriptional control of RCR vector replication by replacing various lengths of the MLV enhancer/promoter with sequences derived either from the highly prostate-specific probasin (PB) promoter or from a more potent synthetic variant of the PB promoter. We assessed the transcriptional specificity of the resulting hybrid long terminal repeats (LTRs) and the cell type specificity and efficiency of replication of vectors containing these LTRs. Incorporation of PB promoter sequences effectively restricted transcription from the LTR to prostate-derived cells and imparted prostate-specific RCR vector replication but required the stronger synthetic promoter and retention of native MLV sequences in the vicinity of the TATA box for optimal replicative efficiency and specificity. Our results have thus identified promoter strength and positioning within the LTR as important determinants for achieving both high transduction efficiency and strict cell type specificity in transcriptionally targeted RCR vectors.

Upstream elements present in the 3'-untranslated region of collagen genes influence the processing efficiency of overlapping polyadenylation signals

3'-Untranslated regions (UTRs) of genes often contain key regulatory elements involved in gene expression control. A high degree of evolutionary conservation in regions of the 3'-UTR suggests important, conserved elements. In particular, we are interested in those elements involved in regulation of 3' end formation. In addition to canonical sequence elements, auxiliary sequences likely play an important role in determining the polyadenylation efficiency of mammalian pre-mRNAs. We identified highly conserved sequence elements upstream of the AAUAAA in three human collagen genes, COL1A1, COL1A2, and COL2A1, and demonstrate that these upstream sequence elements (USEs) influence polyadenylation efficiency. Mutation of the USEs decreases polyadenylation efficiency both in vitro and in vivo, and inclusion of competitor oligoribonucleotides representing the USEs specifically inhibit polyadenylation. We have also shown that insertion of a USE into a weak polyadenylation signal can enhance 3' end formation. Close inspection of the COL1A2 3'-UTR reveals an unusual feature of two closely spaced, competing polyadenylation signals. Taken together, these data demonstrate that USEs are important auxiliary polyadenylation elements in mammalian genes.

RNA 3' readthrough of oncoretrovirus and lentivirus: implications for vector safety and efficacy

The expression of reporter genes driven by the same human elongation factor 1alpha (EF1alpha) promoter in murine leukemia virus (MLV)- and human immunodeficiency virus type 1 (HIV-1)-based vectors was studied in either transfected or virally transduced cells. The HIV-1 vectors consistently expressed 3 to 10 times higher activity than the MLV vectors at both the RNA and protein levels. The difference was not attributable to transcriptional interference, alternative enhancer/silencer, or differential EF1alpha intron splicing. Based on nuclear run-on assays, both vectors exhibited similar EF1alpha transcriptional activity. The reduced RNA levels of MLV vectors could not be explained by the decrease in RNA half-lives. Southern analysis of proviral DNA indicated that both HIV-1 and MLV vectors efficiently propagated the EF1alpha intron in the transduced cells. To decipher the discrepancy in transgene expression between MLV and HIV-1 vectors, the role of RNA 3'-end processing was examined using a sensitive Cre/lox reporter assay. The results showed that MLV vectors, but not HIV-1 vectors, displayed high frequencies of readthrough of the 3' polyadenylation signal. Interestingly, the polyadenylation signal of a self-inactivating (SIN) HIV-1 vector was as leaky as that of the MLV vectors, suggesting a potential risk of oncogene activation by the lentiviral SIN vectors. Together, our results suggest that an efficient polyadenylation signal would improve both the efficacy and the safety of these vectors.

Characterization of specific protein-RNA complexes associated with the coupling of polyadenylation and last-intron removal

Polyadenylation and splicing are highly coordinated on substrate RNAs capable of coupled polyadenylation and splicing. Individual elements of both splicing and polyadenylation signals are required for the in vitro coupling of the processing reactions. In order to understand more about the coupling mechanism, we examined specific protein-RNA complexes formed on RNA substrates, which undergo coupled splicing and polyadenylation. We hypothesized that formation of a coupling complex would be adversely affected by mutations of either splicing or polyadenylation elements known to be required for coupling. We defined three specific complexes (A(C)', A(C), and B(C)) that form rapidly on a coupled splicing and polyadenylation substrate, well before the appearance of spliced and/or polyadenylated products. The A(C)' complex is formed by 30 s after mixing, the A(C) complex is formed between 1 and 2 min after mixing, and the B(C) complex is formed by 2 to 3 min after mixing. A(C)' is a precursor of A(C), and the A(C)' and/or A(C) complex is a precursor of B(C). Of the three complexes, B(C) appears to be a true coupling complex in that its formation was consistently diminished by mutations or experimental conditions known to disrupt coupling. The characteristics of the A(C)' complex suggest that it is analogous to the spliceosomal A complex, which forms on splicing-only substrates. Formation of the A(C)' complex is dependent on the polypyrimidine tract. The transition from A(C)' to A(C) appears to require an intact 3'-splice site. Formation of the B(C) complex requires both splicing elements and the polyadenylation signal. A unique polyadenylation-specific complex formed rapidly on substrates containing only the polyadenylation signal. This complex, like the A(C)' complex, formed very transiently on the coupled splicing and polyadenylation substrate; we suggest that these two complexes coordinate, resulting in the B(C) complex. We also suggest a model in which the coupling mechanism may act as a dominant checkpoint in which aberrant definition of one exon overrides the normal processing at surrounding wild-type sites.

Polyadenylate polymerase (PAP) and 3' end pre-mRNA processing: function, assays, and association with disease

Polyadenylate polymerase (PAP) is one of the enzymes involved in the formation of the polyadenylate tail of the 3' end of mRNA. Poly (A) tail formation is a significant component of 3' processing, a link in the chain of events, including transcription, splicing, and cleavage/polyadenylation of pre-mRNA. Transcription, capping, splicing, polyadenylation, and transport take place as coupled processes that can regulate one another. The poly(A) tail is found in almost all eukaryotic mRNA and is important in enhancing translation initiation and determining mRNA stability. Control of poly(A) tail synthesis could possibly be a key regulatory step in gene expression. PAP-specific activity values are measured by a highly sensitive assays and immunocytochemical methods. High levels of PAP activity are associated with rapidly proliferating cells, it also prevents apoptosis. Changes of PAP activity may cause a decrease in the rate of polyadenylation in the brain during epileptic seizures. Testis-specific PAP may play an important role in spermiogenesis. PAP was found to be an unfavorable prognostic factor in leukemia and breast cancer. Furthermore, measurements of PAP activity may contribute to the definition of the biological profile of tumor cells. It is crucial to know the specific target causing the elevation of serum PAP, for it to be used as a marker for disease. This review summarizes the recently accumulated knowledge on PAP including its function, assays, and association with various human diseases, and proposes future avenues for research.

Promoter characterization of the novel human matrix metalloproteinase-26 gene: regulation by the T-cell factor-4 implies specific expression of the gene in cancer cells of epithelial origin

A novel matrix metalloproteinase-26 (MMP-26) is known to be specifically expressed in epithelial carcinomas. To facilitate studies of MMP-26 transcriptional regulation, we have cloned and characterized a 1 kb 5'-flanking region of the human MMP-26 gene. Altogether, our findings indicate that the MMP-26 promoter has distinctive structural and functional features among MMP genes. An unusual polyadenylation site proximal to the transcription-factor-binding sites protects transcription of the MMP-26 gene from the upstream promoters and represents a part of the stringent transcriptional regulation of the gene. The MMP-26 gene has a consensus TATA-box and one transcriptional start site located 60 and 35 nucleotides upstream of the translational start site, respectively. The MMP-26 promoter was able to drive luciferase expression in human A549 lung carcinoma, HT1080 fibrosarcoma and HEK293 embryonic kidney cells. The basal transcription efficiency of the MMP-26 promoter is relatively low, thereby explaining the minute expression of the gene in most cells and tissues. When compared with other MMP genes, the MMP-26 promoter contains binding sites for a few transcription factors. Sequential deletion and mutation analysis, and electrophoretic mobility-shift assay have identified the T-cell factor-4 (Tcf-4) motif and the activator protein-1 site as the major regulatory elements of the MMP-26 promoter. Since previous studies have established that the Tcf-4 transcription factor is subjected exclusively to regulation through the beta-catenin/E(epithelial)-cadherin pathway, this implies the specific expression of MMP-26 in cancer cells of epithelial origin.

The retroviruses human immunodeficiency virus type 1 and Moloney murine leukemia virus adopt radically different strategies to regulate promoter-proximal polyadenylation

Maximal gene expression in retroviruses requires that polyadenylation in the 5' long terminal repeat (LTR) is suppressed. In human immunodeficiency virus type 1 (HIV-1) the promoter-proximal poly(A) site is blocked by interaction of U1 snRNP with the closely positioned major splice donor site (MSD) 200 nucleotides downstream. Here we investigated whether the same mechanism applies to down-regulate 5' LTR polyadenylation in Moloney murine leukemia virus (MoMLV). Although the same molecular architecture is present in both viruses, the MoMLV poly(A) signal in the 5' LTR is active whether or not the MSD is mutated. This surprising difference between the two retroviruses is not due to their actual poly(A) signals or MSD sequences, since exchange of either element between the two viral sequences does not alter their ability to regulate 5' LTR poly(A) site use. Instead we demonstrate that sequence between the cap and AAUAAA is required for MSD-dependent poly(A) regulation in HIV-1, indicating a key role for this part of the LTR in poly(A) site suppression. We also show that the MoMLV poly(A) signal is an intrinsically weak RNA-processing signal. This suggests that in the absence of a poly(A) site suppression mechanism, MoMLV is forced to use a weak poly(A) signal.

High-level transgene expression in human hematopoietic progenitors and differentiated blood lineages after transduction with improved lentiviral vectors

Recent experiments point to the great value of lentiviral vectors for the transduction of human hematopoietic stem cells (hHSCs). Vectors used so far, however, have been poorly satisfying in terms of either biosafety or efficiency of transgene expression. Herein is described the results obtained with human immunodeficiency virus–based vectors optimized in both of these aspects. It is thus shown that vectors containing the EF1α and, to a lesser extent, the phosphoglycerate kinase (PGK) promoter, govern high-level gene expression in human hematopoietic progenitors as well as derived hematopoietic lineages of therapeutic relevance, such as erythrocytes, granulocytes, monocytes, dendritic cells, and megakaryocytes. EF1α promoter-containing lentiviral vectors can also induce strong transgene expression in primary T lymphocytes isolated from peripheral blood. A self-inactivating design did not affect the performance of EF1α promoter-based vectors but significantly reduced expression from the PGK promoter. This negative effect could nevertheless be largely rescued by inserting the post-transcriptional regulatory element of woodchuck hepatitis virus upstream of the vector 3′ long terminal repeat. These results have important practical implications for the genetic treatment of lymphohematologic disorders as well as for the study of hematopoiesis via the lentivector-mediated modification of hHSCs.

High-level transgene expression in human hematopoietic progenitors and differentiated blood lineages after transduction with improved lentiviral vectors

Recent experiments point to the great value of lentiviral vectors for the transduction of human hematopoietic stem cells (hHSCs). Vectors used so far, however, have been poorly satisfying in terms of either biosafety or efficiency of transgene expression. Herein is described the results obtained with human immunodeficiency virus–based vectors optimized in both of these aspects. It is thus shown that vectors containing the EF1α and, to a lesser extent, the phosphoglycerate kinase (PGK) promoter, govern high-level gene expression in human hematopoietic progenitors as well as derived hematopoietic lineages of therapeutic relevance, such as erythrocytes, granulocytes, monocytes, dendritic cells, and megakaryocytes. EF1α promoter-containing lentiviral vectors can also induce strong transgene expression in primary T lymphocytes isolated from peripheral blood. A self-inactivating design did not affect the performance of EF1α promoter-based vectors but significantly reduced expression from the PGK promoter. This negative effect could nevertheless be largely rescued by inserting the post-transcriptional regulatory element of woodchuck hepatitis virus upstream of the vector 3′ long terminal repeat. These results have important practical implications for the genetic treatment of lymphohematologic disorders as well as for the study of hematopoiesis via the lentivector-mediated modification of hHSCs.

Functionally significant secondary structure of the simian virus 40 late polyadenylation signal

The structure of the highly efficient simian virus 40 late polyadenylation signal (LPA signal) is more complex than those of most known mammalian polyadenylation signals. It contains efficiency elements both upstream and downstream of the AAUAAA region, and the downstream region contains three defined elements (two U-rich elements and one G-rich element) instead of the single U- or GU-rich element found in most polyadenylation signals. Since many reports have indicated that the secondary structure in RNA may play a significant role in RNA processing, we have used nuclease structure analysis techniques to determine the secondary structure of the LPA signal. We find that the LPA signal has a functionally significant secondary structure. Much of the region upstream of AAUAAA is sensitive to single-strand-specific nucleases. The region downstream of AAUAAA has both double- and single-stranded characteristics. Both U-rich elements are predominately sensitive to the double-strand-specific nuclease RNase V(1), while the G-rich element is primarily single stranded. The U-rich element closest to AAUAAA contains four distinct RNase V(1)-sensitive regions, which we have designated structural region 1 (SR1), SR2, SR3, and SR4. Linker scanning mutants in the downstream region were analyzed both for structure and for function by in vitro cleavage analyses. These data show that the ability of the downstream region, particularly SR3, to form double-stranded structures correlates with efficient in vitro cleavage. We discuss the possibility that secondary structure downstream of the AAUAAA may be important for the functions of polyadenylation signals in general.

Self-inactivating lentiviral vectors with U3 and U5 modifications

Lentiviral vectors have gained much attention in recent years mainly because they integrate into nondividing host-cell genomes. For clinical applications, a safe and efficient lentiviral vector system is required. Previously, we have established a human immunodeficiency virus type 1 (HIV-1)-derived three-plasmid lentiviral vector system for viral vector production which includes a packaging vector pHP, a transducing vector pTV, and an envelope-encoding plasmid pHEF-VSVG. Cotransfection of these three plasmids into TE671 human rhabdomyosarcoma cells routinely yields 10(5)-10(6) infectious units per milliliter in 24 h. Here we have extensively modified long terminal repeats (LTRs) of pTV to generate a safer lentiviral vector system. The 5' U3 was replaced with a truncated cytomegalovirus (CMV) immediate early (IE) enhancer/TATA promoter and the 3' U3 (except for the integration attachment site) was also deleted. These modifications resulted in a vector with 80% wild-type vector efficiency. Further deletion of 3' U5 impaired vector function; however, this problem was solved by replacing the 3' U5 with bovine growth hormone polyadenylation (bGHpA) sequence. The pTV vector containing all these modifications including the 5' promoter substitution, the 3' U3 deletion, and the substitution of 3' U5 with bGHpA exhibited a self-inactivating (SIN) phenotype after transduction, transduced both dividing and nondividing cells at similar efficiencies, and produced vector titers twice as high as that of the wild-type construct. Thus, both safety and efficacy of the HP/TV vector have been improved by these LTR modifications. Further deletion of 5' U5 impaired vector efficiency, suggesting that the 5' U5 has critical roles in vector function.

Utilization of splicing elements and polyadenylation signal elements in the coupling of polyadenylation and last-intron removal

Polyadenylation (PA) is the process by which the 3' ends of most mammalian mRNAs are formed. In nature, PA is highly coordinated, or coupled, with splicing. In mammalian systems, the most compelling mechanistic model for coupling arises from data supporting exon definition (2, 34, 37). We have examined the roles of individual functional components of splicing and PA signals in the coupling process by using an in vitro splicing and PA reaction with a synthetic pre-mRNA substrate containing an adenovirus splicing cassette and the simian virus 40 late PA signal. The effects of individually mutating splicing elements and PA elements in this substrate were determined. We found that mutation of the polypyrimidine tract and the 3' splice site significantly reduced PA efficiency and that mutation of the AAUAAA and the downstream elements of the PA signal decreased splicing efficiency, suggesting that these elements are the most significant for the coupling of splicing and PA. Although mutation of the upstream elements (USEs) of the PA signal dramatically decreased PA, splicing was only modestly affected, suggesting that USEs modestly affect coupling. Mutation of the 5' splice site in the presence of a viable polypyrimidine tract and the 3' splice site had no effect on PA, suggesting no effect of this element on coupling. However, our data also suggest that a site for U1 snRNP binding (e.g., a 5' splice site) within the last exon can negatively effect both PA and splicing; hence, a 5' splice site-like sequence in this position appears to be a modulator of coupling. In addition, we show that the RNA-protein complex formed to define an exon may inhibit processing if the definition of an adjacent exon fails. This finding indicates a mechanism for monitoring the appropriate definition of exons and for allowing only pre-mRNAs with successfully defined exons to be processed.

Formation of mRNA 3' ends in eukaryotes: mechanism, regulation, and interrelationships with other steps in mRNA synthesis

Formation of mRNA 3' ends in eukaryotes requires the interaction of transacting factors with cis-acting signal elements on the RNA precursor by two distinct mechanisms, one for the cleavage of most replication-dependent histone transcripts and the other for cleavage and polyadenylation of the majority of eukaryotic mRNAs. Most of the basic factors have now been identified, as well as some of the key protein-protein and RNA-protein interactions. This processing can be regulated by changing the levels or activity of basic factors or by using activators and repressors, many of which are components of the splicing machinery. These regulatory mechanisms act during differentiation, progression through the cell cycle, or viral infections. Recent findings suggest that the association of cleavage/polyadenylation factors with the transcriptional complex via the carboxyl-terminal domain of the RNA polymerase II (Pol II) large subunit is the means by which the cell restricts polyadenylation to Pol II transcripts. The processing of 3' ends is also important for transcription termination downstream of cleavage sites and for assembly of an export-competent mRNA. The progress of the last few years points to a remarkable coordination and cooperativity in the steps leading to the appearance of translatable mRNA in the cytoplasm.

Formation of mRNA 3' ends in eukaryotes: mechanism, regulation, and interrelationships with other steps in mRNA synthesis

Formation of mRNA 3' ends in eukaryotes requires the interaction of transacting factors with cis-acting signal elements on the RNA precursor by two distinct mechanisms, one for the cleavage of most replication-dependent histone transcripts and the other for cleavage and polyadenylation of the majority of eukaryotic mRNAs. Most of the basic factors have now been identified, as well as some of the key protein-protein and RNA-protein interactions. This processing can be regulated by changing the levels or activity of basic factors or by using activators and repressors, many of which are components of the splicing machinery. These regulatory mechanisms act during differentiation, progression through the cell cycle, or viral infections. Recent findings suggest that the association of cleavage/polyadenylation factors with the transcriptional complex via the carboxyl-terminal domain of the RNA polymerase II (Pol II) large subunit is the means by which the cell restricts polyadenylation to Pol II transcripts. The processing of 3' ends is also important for transcription termination downstream of cleavage sites and for assembly of an export-competent mRNA. The progress of the last few years points to a remarkable coordination and cooperativity in the steps leading to the appearance of translatable mRNA in the cytoplasm.

Reduction of syndecan-1 mRNA in cervical-carcinoma cells is involved with the 3' untranslated region

Syndecan-1 is a transmembrane proteoglycan expressed predominantly in epithelial cells. Studies with immunohistochemistry have shown that syndecan-1 expression is reduced in carcinoma derived from human epidermis. Here we show that syndecan-1 mRNA, which is abundant in human primary keratinocyte (HK) and HaCaT spontaneous immortalized keratinocyte, is decreased in cervical-carcinoma cell lines. Further, in relation to a long and well-conserved 3' untranslated region (3' UTR) of syndecan-1 cDNA, we examined whether 3' UTR is involved with syndecan-1-mRNA reduction in cervical-carcinoma cells. A stable transfection experiment showed that addition of the 3' UTR does not affect expression in HaCaT, but that syndecan-1 cDNA containing the 3' UTR is not expressed efficiently selectively in cervical-carcinoma cell lines. The transient assay with CAT reporter plasmids linking the 3' UTR confirmed this, and indicated that the 3' end of the 3' UTR (nt 2285-2410) is required to influence expression in cervical-carcinoma cells. Further excessive expression of syndecan-1 suppressed growth in cervical-carcinoma cells. These results demonstrate that the reduction of syndecan-1 mRNA involved with the 3' untranslated region gives growth advantage to cervical-carcinoma cells.

The ability of the HIV-1 AAUAAA signal to bind polyadenylation factors is controlled by local RNA structure

The 5' and 3' ends of HIV-1 transcripts are identical in sequence. This repeat region (R) folds a stem-loop structure that is termed the poly(A) hairpin because it contains polyadenylation or poly(A) signals: the AAUAAA hexamer motif, the cleavage site and part of the GU-rich downstream element. Obviously, HIV-1 gene expression necessitates differential regulation of the two poly(A) sites. Previous transfection experiments indicated that the wild-type poly(A) hairpin is slightly inhibitory to the process of polyadenylation, and further stabilization of the hairpin inhibited polyadenylation completely. In this study, we tested wild-type and mutant transcripts with poly(A) hairpin structures of differing thermodynamic stabilities for the in vitro binding of polyadenylation factors. Mutant transcripts with a destabilized hairpin efficiently bound the polyadenylation factors, which were provided either as purified proteins or as nuclear extract. The RNA mutant with a stabilized hairpin did not form this 'poly(A) complex'. Additional mutations that repair the stability of this hairpin restored the binding capacity. Thus, an inverse correlation was measured between the stability of the poly(A) hairpin and its ability to interact with polyadenylation factors. The wild-type HIV-1 transcript bound the polyadenylation factors suboptimally, but full activity was obtained in the presence of the USE enhancer element that is uniquely present upstream of the 3' poly(A) site. We also found that sequences of the HIV-1 leader, which are uniquely present downstream of the 5' poly(A) site, inhibit formation of the poly(A) complex. This inhibition could not be ascribed to a specific leader sequence, as we measured a gradual loss of complex formation with increasing leader length. We will discuss the regulatory role of RNA structure and the repressive effect of leader sequences in the context of differential HIV-1 polyadenylation.

A hairpin structure in the R region of the human immunodeficiency virus type 1 RNA genome is instrumental in polyadenylation site selection

Some retroviruses with an extended repeat (R) region encode the polyadenylation signal within the R region such that this signal is present at both the 5' and 3' ends of the viral transcript. This necessitates differential regulation to either repress recognition of the 5' polyadenylation signal or enhance usage of the 3' signal. The human immunodeficiency virus type 1 (HIV-1) genome encodes an inherently efficient polyadenylation signal within the 97-nucleotide R region. Polyadenylation at the 5' HIV-1 polyadenylation site is inhibited by downstream splicing signals, and usage of the 3' polyadenylation site is triggered by an upstream enhancer element. In this paper, we demonstrate that this on-off switch of the HIV-1 polyadenylation signal is controlled by a secondary RNA structure that occludes part of the AAUAAA hexamer motif, which we have termed the polyA hairpin. Opening the 5' hairpin by mutation triggered premature polyadenylation and caused reduced synthesis of viral RNA, indicating that the RNA structure plays a pivotal role in repression of the 5' polyadenylation site. Apparently, the same hairpin structure does not interfere with efficient usage of the 3' polyadenylation site, which may be due to the presence of the upstream enhancer element. However, when the 3' hairpin was further stabilized by mutation, we measured a complete loss of 3' polyadenylation. Thus, the thermodynamic stability of the polyA hairpin is delicately balanced to allow nearly complete repression of the 5' site yet efficient activation of the 3' site. This is the first report of regulated polyadenylation that is mediated by RNA secondary structure. A similar hairpin motif that occludes the polyadenylation signal can be proposed for other lentiviruses and members of the spumaretroviruses, suggesting that this represents a more general gene expression strategy of complex retroviruses.

Polypyrimidine tract-binding protein positively regulates inclusion of an alternative 3'-terminal exon

Polypyrimidine tract-binding protein (PTB) is an abundant vertebrate hnRNP protein. PTB binding sites have been found within introns both upstream and downstream of alternative exons in a number of genes that are negatively controlled by the binding of PTB. We have previously reported that PTB binds to a pyrimidine tract within an RNA processing enhancer located adjacent to an alternative 3'-terminal exon within the gene coding for calcitonin and calcitonin gene-related peptide. The enhancer consists of a pyrimidine tract and CAG directly abutting on a 5' splice site sequence to form a pseudoexon. Here we show that the binding of PTB to the enhancer pyrimidine tract is functional in that exon inclusion increases when in vivo levels of PTB increase. This is the first example of positive regulation of exon inclusion by PTB. The binding of PTB was antagonistic to the binding of U2AF to the enhancer-located pyrimidine tract. Altering the enhancer pyrimidine tract to a consensus sequence for the binding of U2AF eliminated enhancement of exon inclusion in vivo and exon polyadenylation in vitro. An additional PTB binding site was identified close to the AAUAAA hexanucleotide sequence of the exon 4 poly(A) site. These observations suggest a dual role for PTB in facilitating recognition of exon 4: binding to the enhancer pyrimidine tract to interrupt productive recognition of the enhancer pseudoexon by splicing factors and interacting with the poly(A) site to positively affect polyadenylation.

Self-inactivating lentivirus vector for safe and efficient in vivo gene delivery

In vivo transduction of nondividing cells by human immunodeficiency virus type 1 (HIV-1)-based vectors results in transgene expression that is stable over several months. However, the use of HIV-1 vectors raises concerns about their safety. Here we describe a self-inactivating HIV-1 vector with a 400-nucleotide deletion in the 3' long terminal repeat (LTR). The deletion, which includes the TATA box, abolished the LTR promoter activity but did not affect vector titers or transgene expression in vitro. The self-inactivating vector transduced neurons in vivo as efficiently as a vector with full-length LTRs. The inactivation design achieved in this work improves significantly the biosafety of HIV-derived vectors, as it reduces the likelihood that replication-competent retroviruses will originate in the vector producer and target cells, and hampers recombination with wild-type HIV in an infected host. Moreover, it improves the potential performance of the vector by removing LTR sequences previously associated with transcriptional interference and suppression in vivo and by allowing the construction of more-stringent tissue-specific or regulatable vectors.

Development of a self-inactivating lentivirus vector

We have constructed a new series of lentivirus vectors based on human immunodeficiency virus type 1 (HIV-1) that can transduce nondividing cells. The U3 region of the 5' long terminal repeat (LTR) in vector constructs was replaced with the cytomegalovirus (CMV) promoter, resulting in Tat-independent transcription but still maintaining high levels of expression. A self-inactivating (SIN) vector was constructed by deleting 133 bp in the U3 region of the 3' LTR, including the TATA box and binding sites for transcription factors Sp1 and NF-kappaB. The deletion is transferred to the 5' LTR after reverse transcription and integration in infected cells, resulting in the transcriptional inactivation of the LTR in the proviruses. SIN viruses can be generated with no significant decreases in titer. Injection of viruses into the rat brain showed that a SIN vector containing the green fluorescent protein gene under the control of the internal CMV promoter transduced neurons as efficiently as a wild-type vector. Interestingly, a wild-type vector without an internal promoter also successfully transduced neurons in the brain, indicating that the HIV-1 LTR promoter is transcriptionally active in neurons even in the absence of Tat. Furthermore, injection of viruses into the subretinal space of the rat eye showed that wild-type vector transduced predominantly retinal pigment epithelium and photoreceptor cells, while SIN vector was able to transduce other types of retinal cells, including bipolar, Müller, horizontal, and amacrine cells. This finding suggests that the HIV-1 LTR can negatively influence the internal CMV promoter in some cell types. SIN HIV vectors should be safer for gene therapy, and they also have broader applicability as a means of high-level gene transfer and expression in nondividing cells.

The Tat protein of equine infectious anemia virus (EIAV) activates cellular gene expression by read-through transcription

The Tat protein of equine infectious anemia virus, EIAV, was shown to augment viral gene expression, presumably through interaction with the Tat responsive element, TAR. Recently, cell-free polyadenylation assays suggested that perturbation of the EIAV TAR secondary structure diminished polyadenylation efficiency. The present study indicates that the EIAV TAR regulates the efficiency of the 3'-end processing of viral RNA also in transfected cells. Moreover, our data suggest that the provision of the EIAV Tat protein in trans potentiates read-through transcription through the 3' viral long terminal repeat (3' LTR), thus suggesting activation of downstream-located cellular genes.

The upstream sequence element of the C2 complement poly(A) signal activates mRNA 3' end formation by two distinct mechanisms

The poly(A) signal of the C2 complement gene is unusual in that it possesses an upstream sequence element (USE) required for full activity in vivo. We describe here in vitro experiments demonstrating that this USE enhances both the cleavage and poly(A) addition reactions. We also show that the C2 USE can be cross-linked efficiently to a 55-kD protein that we identify as the polypyrimidine tract-binding protein (PTB), implicated previously in modulation of pre-mRNA splicing. Mutation of the PTB-binding site significantly reduces the efficiency of the C2 poly(A) site both in vivo and in vitro. Furthermore, addition of PTB to reconstituted processing reactions enhances cleavage at the C2 poly(A) site, indicating that PTB has a direct role in recognition of this signal. The C2 USE, however, also increases the affinity of general polyadenylation factors independently for the C2 poly(A) signal as detected by enhanced binding of cleavage-stimulaton factor (CstF). Strikingly, this leads to a novel CstF-dependant enhancement of the poly(A) synthesis phase of the reaction. These studies both emphasize the interconnection between splicing and polyadenylation and indicate an unexpected flexibility in the organization of mammalian poly(A) sites.