The regulated production of mu m and mu s mRNA is dependent on the relative efficiencies of mu s poly(A) site usage and the c mu 4-to-M1 splice

Demultiplexing Ig repertoires by parallel mRNA/DNA sequencing shows major differential alterations in severe COVID-19

To understand the fine differential elements that can lead to or prevent acute respiratory distress syndrome (ARDS) in COVID-19 patients, it is crucial to investigate the immune response architecture. We herein dissected the multiple layers of B cell responses by flow cytometry and Ig repertoire analysis from acute phase to recovery. Flow cytometry with FlowSOM analysis showed major changes associated with COVID-19 inflammation such as an increase of double-negative B-cells and ongoing plasma cell differentiation. This paralleled COVID-19-driven expansion of two disconnected B-cell repertoires. Demultiplexing successive DNA and RNA Ig repertoire patterns characterized an early expansion of IgG1 clonotypes with atypically long and uncharged CDR3, the abundance of this inflammatory repertoire being correlated with ARDS and likely pejorative. A superimposed convergent response included convergent anti-SARS-CoV-2 clonotypes. It featured progressively increasing somatic hypermutation together with normal-length or short CDR3 and it persisted until a quiescent memory B-cell stage after recovery.

LABRAT reveals association of alternative polyadenylation with transcript localization, RNA binding protein expression, transcription speed, and cancer survival

BACKGROUND

The sequence content of the 3' UTRs of many mRNA transcripts is regulated through alternative polyadenylation (APA). The study of this process using RNAseq data, though, has been historically challenging.

RESULTS

To combat this problem, we developed LABRAT, an APA isoform quantification method. LABRAT takes advantage of newly developed transcriptome quantification techniques to accurately determine relative APA site usage and how it varies across conditions. Using LABRAT, we found consistent relationships between gene-distal APA and subcellular RNA localization in multiple cell types. We also observed connections between transcription speed and APA site choice as well as tumor-specific transcriptome-wide shifts in APA isoform abundance in hundreds of patient-derived tumor samples that were associated with patient prognosis. We investigated the effects of APA on transcript expression and found a weak overall relationship, although many individual genes showed strong correlations between relative APA isoform abundance and overall gene expression. We interrogated the roles of 191 RNA-binding proteins in the regulation of APA isoforms, finding that dozens promote broad, directional shifts in relative APA isoform abundance both in vitro and in patient-derived samples. Finally, we find that APA site shifts in the two classes of APA, tandem UTRs and alternative last exons, are strongly correlated across many contexts, suggesting that they are coregulated.

CONCLUSIONS

We conclude that LABRAT has the ability to accurately quantify APA isoform ratios from RNAseq data across a variety of sample types. Further, LABRAT is able to derive biologically meaningful insights that connect APA isoform regulation to cellular and molecular phenotypes.

Upregulation of functional Kv11.1a isoform expression by modified U1 small nuclear RNA

The KCNH2 or human ether-a go-go-related gene (hERG) encodes the Kv11.1 potassium channel that conducts the rapidly activating delayed rectifier potassium current in the heart. The expression of Kv11.1 C-terminal isoforms is directed by the alternative splicing and polyadenylation of intron 9. Splicing of intron 9 leads to the formation of a functional, full-length Kv11.1a isoform and polyadenylation of intron 9 results in the production of a non-functional, C-terminally truncated Kv11.1a-USO isoform. The relative expression of Kv11.1a and Kv11.1a-USO plays an important role in regulating Kv11.1 channel function. In the heart, only one-third of KCNH2 pre-mRNA is processed to Kv11.1a due to the weak 5' splice site of intron 9. We previously showed that the weak 5' splice site is caused by sequence deviation from the consensus, and that mutations toward the consensus sequence increased the efficiency of intron 9 splicing. It is well established that 5' splice sites are recognized by complementary base-paring with U1 small nuclear RNA (U1 snRNA). In this study, we modified the sequence of U1 snRNA to increase its complementarity to the 5' splice site of KCNH2 intron 9 and observed a significant increase in the efficiency of intron 9 splicing. RNase protection assay and western blot analysis showed that modified U1 snRNA increased the expression of the functional Kv11.1a isoform and concomitantly decreased the expression of the non-functional Kv11.1a-USO isoform. In patch-clamp experiments, modified U1 snRNA significantly increased Kv11.1 current. Our findings suggest that relative expression of Kv11.1 C-terminal isoforms can be regulated by modified U1 snRNA.

Coordination of RNA Polymerase II Pausing and 3' End Processing Factor Recruitment with Alternative Polyadenylation

Most mammalian genes produce transcripts whose 3' ends are processed at multiple alternative positions by cleavage/polyadenylation (CPA). Poly(A) site cleavage frequently occurs cotranscriptionally and is facilitated by CPA factor binding to the RNA polymerase II (Pol II) C-terminal domain (CTD) phosphorylated on Ser2 residues of its heptad repeats (YS2PTSPS). The function of cotranscriptional events in the selection of alternative poly(A) sites is poorly understood. We investigated Pol II pausing, CTD Ser2 phosphorylation, and processing factor CstF recruitment at wild-type and mutant IgM transgenes that use alternative poly(A) sites to produce mRNAs encoding the secreted and membrane-bound forms of the immunoglobulin (Ig) heavy chain. The results show that the sites of Pol II pausing and processing factor recruitment change depending on which poly(A) site is utilized. In contrast, the extent of Pol II CTD Ser2 phosphorylation does not closely correlate with poly(A) site selection. We conclude that changes in properties of the transcription elongation complex closely correlate with utilization of different poly(A) sites, suggesting that cotranscriptional events may influence the decision between alternative modes of pre-mRNA 3' end processing.

Shark IgW C region diversification through RNA processing and isotype switching

Sharks and skates represent the earliest vertebrates with an adaptive immune system based on lymphocyte Ag receptors generated by V(D)J recombination. Shark B cells express two classical Igs, IgM and IgW, encoded by an early, alternative gene organization consisting of numerous autonomous miniloci, where the individual gene cluster carries a few rearranging gene segments and one C region, μ or ω. We have characterized eight distinct Ig miniloci encoding the nurse shark ω H chain. Each cluster consists of VH, D, and JH segments and six to eight C domain exons. Two interspersed secretory exons, in addition to the 3'-most C exon with tailpiece, provide the gene cluster with the ability to generate at least six secreted isoforms that differ as to polypeptide length and C domain combination. All clusters appear to be functional, as judged by the capability for rearrangement and absence of defects in the deduced amino acid sequence. We previously showed that IgW VDJ can perform isotype switching to μ C regions; in this study, we found that switching also occurs between ω clusters. Thus, C region diversification for any IgW VDJ can take place at the DNA level by switching to other ω or μ C regions, as well as by RNA processing to generate different C isoforms. The wide array of pathogens recognized by Abs requires different disposal pathways, and our findings demonstrate complex and unique pathways for C effector function diversity that evolved independently in cartilaginous fishes.

The conserved intronic cleavage and polyadenylation site of CstF-77 gene imparts control of 3' end processing activity through feedback autoregulation and by U1 snRNP

The human gene encoding the cleavage/polyadenylation (C/P) factor CstF-77 contains 21 exons. However, intron 3 (In3) accounts for nearly half of the gene region, and contains a C/P site (pA) with medium strength, leading to short mRNA isoforms with no apparent protein products. This intron contains a weak 5′ splice site (5′SS), opposite to the general trend for large introns in the human genome. Importantly, the intron size and strengths of 5′SS and pA are all highly conserved across vertebrates, and perturbation of these parameters drastically alters intronic C/P. We found that the usage of In3 pA is responsive to the expression level of CstF-77 as well as several other C/P factors, indicating it attenuates the expression of CstF-77 via a negative feedback mechanism. Significantly, intronic C/P of CstF-77 pre-mRNA correlates with global 3′UTR length across cells and tissues. In addition, inhibition of U1 snRNP also leads to regulation of the usage of In3 pA, suggesting that the C/P activity in the cell can be cross-regulated by splicing, leading to coordination between these two processes. Importantly, perturbation of CstF-77 expression leads to widespread alternative cleavage and polyadenylation (APA) and disturbance of cell proliferation and differentiation. Thus, the conserved intronic pA of the CstF-77 gene may function as a sensor for cellular C/P and splicing activities, controlling the homeostasis of CstF-77 and C/P activity and impacting cell proliferation and differentiation.

Autoregulation is commonly used in biological systems to control the homeostasis of certain activity, and cross-regulation coordinates multiple processes. We show that vertebrate genes encoding the cleavage/polyadenylation (C/P) factor CstF-77 contain a conserved intronic C/P site (pA) which regulates CstF-77 expression through a negative feedback loop. Since the usage of this intronic pA is also responsive to the expression of other C/P factors, the pA can function as a sensor for the cellular C/P activity. Because the CstF-77 level is important for the usage of a large number of pAs in the genome and is particularly critical for expression of genes involved in cell cycle, this autoregulatory mechanism has far-reaching implications for cell proliferation and differentiation. The human intron harboring the pA is large and has a weak 5′ splice site, both of which are also highly conserved in other vertebrates. Inhibition of U1 snRNP, which recognizes the 5′ splice site of intron, leads to upregulation of the intronic pA isoform of CstF-77 gene, suggesting that the C/P activity in the cell can be cross-regulated by splicing, leading to coordination between these two processes.

Alternative cleavage and polyadenylation: the long and short of it

Cleavage and polyadenylation (C/P) of nascent transcripts is essential for maturation of the 3' ends of most eukaryotic mRNAs. Over the past three decades, biochemical studies have elucidated the machinery responsible for the seemingly simple C/P reaction. Recent genomic analyses have indicated that most eukaryotic genes have multiple cleavage and polyadenylation sites (pAs), leading to transcript isoforms with different coding potentials and/or variable 3' untranslated regions (UTRs). As such, alternative cleavage and polyadenylation (APA) is an important layer of gene regulation impacting mRNA metabolism. Here, we review our current understanding of APA and recent progress in this field.

Use of mutated self-cleaving 2A peptides as a molecular rheostat to direct simultaneous formation of membrane and secreted anti-HIV immunoglobulins

In nature, B cells produce surface immunoglobulin and secreted antibody from the same immunoglobulin gene via alternative splicing of the pre-messenger RNA. Here we present a novel system for genetically programming B cells to direct the simultaneous formation of membrane-bound and secreted immunoglobulins that we term a "Molecular Rheostat", based on the use of mutated "self-cleaving" 2A peptides. The Molecular Rheostat is designed so that the ratio of secreted to membrane-bound immunoglobulins can be controlled by selecting appropriate mutations in the 2A peptide. Lentiviral transgenesis of Molecular Rheostat constructs into B cell lines enables the simultaneous expression of functional b12-based IgM-like BCRs that signal to the cells and mediate the secretion of b12 IgG broadly neutralizing antibodies that can bind and neutralize HIV-1 pseudovirus. We show that these b12-based Molecular Rheostat constructs promote the maturation of EU12 B cells in an in vitro model of B lymphopoiesis. The Molecular Rheostat offers a novel tool for genetically manipulating B cell specificity for B-cell based gene therapy.

Dual suppression of hemangiogenesis and lymphangiogenesis by splice-shifting morpholinos targeting vascular endothelial growth factor receptor 2 (KDR)

The KDR gene, which participates in angiogenesis and lymphangiogenesis, produces two functionally distinct protein products, membrane-bound KDR (mbKDR) and its isoform, soluble KDR (sKDR). Since sKDR does not have a tyrosine kinase domain and does not dimerize, it is principally an antagonist of lymphangiogenesis by sequestering VEGF-C. Alternative polyadenylation of exon 30 or intron 13 leads to the production of mbKDR or sKDR, respectively, yet the regulatory mechanisms are unknown. Here we show that an antisense morpholino oligomer directed against the exon 13-intron 13 junction increases sKDR (suppressing lymphangiogenesis) and decreases mbKDR (inhibiting hemangiogenesis). The latent polyadenylation site in intron 13 of KDR is activated by blocking the upstream 5' splicing site with an antisense morpholino oligomer. Intravitreal morpholino injection suppressed laser choroidal neovascularization while increasing sKDR. In the mouse cornea, subconjunctival injection of the morpholino-inhibited corneal angiogenesis and lymphangiogenesis, and suppressed graft rejection after transplantation. Thus, this morpholino can be used for concurrent suppression of hemangiogenesis and lymphangiogenesis. This study offers new insight into the mechanisms and potential therapeutic modulation of alternative polyadenylation.

New insights into the enigma of immunoglobulin D

Immunoglobulin D (IgD) has remained a mysterious antibody class for almost half a century. IgD was initially thought to be a recently evolved Ig isotype expressed only by some mammalian species, but recent discoveries in fishes and amphibians demonstrate that IgD was present in the ancestor of all jawed vertebrates and has important immunological functions. The structure of IgD has been very dynamic throughout evolution. Mammals can express IgD through alternative splicing and class switch recombination. Active cell-dependent and T-cell-independent IgM-to-IgD class switching takes place in a unique subset of human B cells from the upper aerodigestive mucosa, which provides a layer of mucosal protection by interacting with many pathogens and their virulence factors. Circulating IgD can bind to myeloid cells such as basophils and induce antimicrobial, inflammatory, and B-cell-stimulating factors upon cross-linking, which contributes to not only immune surveillance but also inflammation and tissue damage when this pathway is overactivated under pathological conditions. Recent research shows that IgD is an important immunomodulator that orchestrates an ancestral surveillance system at the interface between immunity and inflammation.

B-cell display-based one-step method to generate chimeric human IgG monoclonal antibodies

The recent development of screening strategies based on the generation and display of large libraries of antibody fragments has allowed considerable advances for the in vitro isolation of monoclonal antibodies (mAbs). We previously developed a technology referred to as the ‘ADLib (Autonomously Diversifying Library) system’, which allows the rapid screening and isolation in vitro of antigen-specific monoclonal antibodies (mAbs) from libraries of immunoglobulin M (IgM) displayed by the chicken B-cell line DT40. Here, we report a novel application of the ADLib system to the production of chimeric human mAbs. We have designed gene knock-in constructs to generate DT40 strains that coexpress chimeric human IgG and chicken IgM via B-cell-specific RNA alternative splicing. We demonstrate that the application of the ADLib system to these strains allows the one-step selection of antigen-specific human chimeric IgG. In addition, the production of chimeric IgG can be selectively increased when we modulate RNA processing by overexpressing the polyadenylation factor CstF-64. This method provides a new way to efficiently design mAbs suitable for a wide range of purposes including antibody therapy.

RNA processing and export

Messenger RNAs undergo 5' capping, splicing, 3'-end processing, and export before translation in the cytoplasm. It has become clear that these mRNA processing events are tightly coupled and have a profound effect on the fate of the resulting transcript. This processing is represented by modifications of the pre-mRNA and loading of various protein factors. The sum of protein factors that stay with the mRNA as a result of processing is modified over the life of the transcript, conferring significant regulation to its expression.

Alternative splicing and polyadenylation contribute to the generation of hERG1 C-terminal isoforms

The human ether-a-go-go-related gene 1 (hERG1) encodes the pore-forming subunit of the rapidly activating delayed rectifier potassium channel. Several hERG1 isoforms with different N- and C-terminal ends have been identified. The hERG1a, hERG1b, and hERG1-3.1 isoforms contain the full-length C terminus, whereas the hERG1(USO) isoforms, hERG1a(USO) and hERG1b(USO), lack most of the C-terminal domain and contain a unique C-terminal end. The mechanisms underlying the generation of hERG1(USO) isoforms are not understood. We show that hERG1 isoforms with different C-terminal ends are generated by alternative splicing and polyadenylation of hERG1 pre-mRNA. We identified an intrinsically weak, noncanonical poly(A) signal, AGUAAA, within intron 9 of hERG1 that modulates the expression of hERG1a and hERG1a(USO). Replacing AGUAAA with the strong, canonical poly(A) signal AAUAAA resulted in the predominant production of hERG1a(USO) and a marked decrease in hERG1 current. In contrast, eliminating the intron 9 poly(A) signal or increasing the strength of 5' splice site led to the predominant production of hERG1a and a significant increase in hERG1 current. We found significant variation in the relative abundance of hERG1 C-terminal isoforms in different human tissues. Taken together, these findings suggest that post-transcriptional regulation of hERG1 pre-mRNA may represent a novel mechanism to modulate the expression and function of hERG1 channels.

Transcription elongation factor ELL2 directs immunoglobulin secretion in plasma cells by stimulating altered RNA processing

Immunoglobulin secretion is modulated by a competition between use of a weak promoter proximal poly(A) site and a non-consensus splice site in the last secretory-specific exon of the heavy chain pre-mRNA. RNA polymerase II transcription elongation factor ELL2, induced in plasma cells, enhanced both polyadenylation and exon skipping with the Igh gene and reporter constructs. Lowering ELL2 expression by hnRNP F transfection or siRNA reduced secretory-specific forms of IgH mRNA. ELL2 and polyadenylation factor CstF-64 co-tracked with RNA polymerase II across the Igh mu and gamma gene segments; association of both factors was blocked by ELL2 siRNA. Thus loading of ELL2 and CstF-64 on RNAP-II was linked, causative for enhanced proximal poly(A) site use and necessary for IgH mRNA processing.

Where do introns come from?

The systems for mRNA surveillance, capping, and cleavage/polyadenylation are proposed to play pivotal roles in the physical establishment and distribution of spliceosomal introns along a transcript.

Mechanisms controlling production of membrane and secreted immunoglobulin during B cell development

The immunoglobulin gene which encodes both membrane-associated and secreted proteins through alternative RNA processing reactions has been a model system used for over 25 yr to better understand the regulatory mechanisms governing alternative RNA processing. This gene contains competing cleavage-polyadenylation and RNA splicing reactions and the relative use of the two pathways is differentially regulated between B cells and plasma cells. General cleavage-polyadenylation and RNA splicing reactions are both altered during B cell maturation to affect immunoglobulin expression. However, the specific factors involved in this regulation have yet to be identified clearly. As transcriptional regulators stimulate the developmental RNA processing switch, microarray analysis is a promising approach to identify candidate regulators of this complex RNA processing mechanism.

Distance-dependent processing of adeno-associated virus type 5 RNA is controlled by 5' exon definition

Adeno-associated virus type 5 (AAV5) is unique among human AAV serotypes in that it uses a polyadenylation site [(pA)p] within the single small intron in the center of the genome. We previously reported that inhibition of polyadenylation at (pA)p, necessary for read-through of P41-generated capsid gene pre-mRNAs which are subsequently spliced, requires binding of U1 snRNP to the upstream donor. Inhibition was reduced as the distance between the cap site and the donor was increased (increasing the size of the 5' exon). Here, we have demonstrated that U1-70K is a key component of U1 snRNP that mediates inhibition of polyadenylation at (pA)p. Furthermore, introduction of a U-rich stretch, predicted to target TIA-1 and thus increase the affinity of U1 snRNP binding to the intervening donor site, significantly augmented inhibition of (pA)p, while depletion of TIA-1 by siRNA increased (pA)p read-through. Finally, artificially tethering the cap binding complex (CBC) components CBP80 and CBP20 upstream of the intron donor increased inhibition of polyadenylation at (pA)p. Our results suggest that interaction with the CBC strengthens U1 snRNP binding to the downstream intron donor in a manner inversely proportional to the size of the 5' exon, thus governing the competition between intron splicing and polyadenylation at (pA)p. This competition must be optimized to program both the levels of polyadenylation of P7- and P19-generated RNA at (pA)p required to produce proper levels of the essential Rep proteins and the splicing of P41-generated RNAs to produce the proper ratio of capsid proteins during AAV5 infection.

Multiple features contribute to the use of the immunoglobulin M secretion-specific poly(A) signal but are not required for developmental regulation

The secretory-specific poly(A) signal (mus) of the immunoglobulin mu gene plays a central role in regulating alternative RNA processing to produce RNAs that encode membrane-associated and secreted immunoglobulins. This poly(A) signal is in direct competition with a splice reaction, and regulation requires that these two reaction efficiencies be balanced. The mus poly(A) signal has several unique sequence features that may contribute to its strength and regulation. Site-directed mutations and small internal deletions made in the intact mu gene show that an extensive AU/A-rich sequence surrounding AAUAAA enhances signal use and that, of the two potential downstream GU-rich elements, both of which appear suboptimally located, only the proximal GU-rich sequence contributes substantially to use of this signal. A GU-rich sequence placed at a more standard location did not improve mus poly(A) signal use. All mu genes tested that contained modified mus poly(A) signals were developmentally regulated, indicating that the GU-rich sequences, the sequences between them previously identified as suboptimal U1A binding sites, and an upstream suboptimal U1A site do not contribute to mu mRNA processing regulation. Expression of wild-type and modified mu genes in HeLa cells overexpressing U1A also failed to demonstrate that U1A contributes to mus poly(A) signal regulation.

An RNA polymerase pause site is associated with the immunoglobulin mus poly(A) site

Immunoglobulin mu alternative RNA processing is regulated during B-cell maturation and requires balanced efficiencies of the competing splice (mum) and cleavage-polyadenylation (mus) reactions. When we deleted sequences 50 to 200 nucleotides beyond the mus poly(A) site, the mus/mum mRNA ratio decreased three- to eightfold in B, plasma, and nonlymphoid cells. The activity could not be localized to a smaller fragment but did function in heterologous contexts. Our data suggest that this region contains an RNA polymerase II pause site that enhances the use of the mus poly(A) site. First, known pause sites replaced the activity of the deleted fragment. Second, the mu fragment, when placed between tandem poly(A) sites, enhanced the use of the upstream poly(A) site. Finally, nuclear run-ons detected an increase in RNA polymerase loading just downstream from the mus poly(A) site, even when the poly(A) site was inactivated. When this mu fragment and another pause site were inserted 1 kb downstream from the mus poly(A) site, they no longer affected the mRNA expression ratio, suggesting that pause sites affect poly(A) site use over a limited distance. Fragments from the immunoglobulin A gene were also found to have RNA polymerase pause site activity.

Downstream sequence elements with different affinities for the hnRNP H/H' protein influence the processing efficiency of mammalian polyadenylation signals

Auxiliary factors likely play an important role in determining the polyadenylation efficiency of mammalian pre-mRNAs. We previously identified an auxiliary factor, hnRNP H/H', which stimulates 3'-end processing through an interaction with sequences downstream of the core elements of the SV40 late polyadenylation signal. Using in vitro reconstitution assays we have demonstrated that hnRNP H/H' can stimulate processing of two additional model polyadenylation signals by binding at similar relative downstream locations but with significantly different affinities. A short tract of G residues was determined to be a common property of all three hnRNP H/H' binding sites. A survey of mammalian polyadenylation signals identified potential G-rich hnRNP H/H' binding sites at similar downstream locations in approximately 34% of these signals. All of the novel G-rich elements tested were found to bind hnRNP H/H' protein and the processing of selected signals identified in the survey was stimulated by the protein both in vivo and in vitro. Downstream G-rich tracts, therefore, are a common auxiliary element in mammalian polyadenylation signals. Sequences capable of binding hnRNP H protein with varying affinities may play a role in determining the processing efficiency of a significant number of mammalian polyadenylation signals.

Regulation of nuclear poly(A) addition controls the expression of immunoglobulin M secretory mRNA

B-cell differentiation is accompanied by a dramatic increase in cytoplasmic accumulation and stability of the IgM heavy chain (mu) secretory mRNA. Despite considerable effort, the mechanism is unknown. We have identified three short motifs upstream of the secretory poly(A) site, which, when mutated in the mu heavy chain gene, significantly increase the accumulation of the secretory form of poly(A)(+) mRNA relative to the membrane form and regulate the expression of the secretory poly(A) site in a developmental manner. We show that these motifs bind U1A and inhibit polyadenylation in vitro and in vivo. Overexpression of U1A in vivo results in the selective inhibition of the secretory form. Thus, this novel mechanism selectively controls post-cleavage expression of the mu secretory mRNA. We present evidence that this mechanism is used to regulate alternative expression of other genes.

Complex protein interactions within the human polyadenylation machinery identify a novel component

Polyadenylation of mRNA precursors is a two-step reaction requiring multiple protein factors. Cleavage stimulation factor (CstF) is a heterotrimer necessary for the first step, endonucleolytic cleavage, and it plays an important role in determining the efficiency of polyadenylation. Although a considerable amount is known about the RNA binding properties of CstF, the protein-protein interactions required for its assembly and function are poorly understood. We therefore first identified regions of the CstF subunits, CstF-77, CstF-64, and CstF-50, required for interaction with each other. Unexpectedly, small regions of two of the subunits participate in multiple interactions. In CstF-77, a proline-rich domain is necessary not only for binding both other subunits but also for self-association, an interaction consistent with genetic studies in Drosophila. In CstF-64, a small region, highly conserved in metazoa, is responsible for interactions with two proteins, CstF-77 and symplekin, a nuclear protein of previously unknown function. Intriguingly, symplekin has significant similarity to a yeast protein, PTA1, that is a component of the yeast polyadenylation machinery. We show that multiple factors, including CstF, cleavage-polyadenylation specificity factor, and symplekin, can be isolated from cells as part of a large complex. These and other data suggest that symplekin may function in assembly of the polyadenylation machinery.

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.

Auxiliary downstream elements are required for efficient polyadenylation of mammalian pre-mRNAs

We have previously identified a G-rich sequence (GRS) as an auxiliary downstream element (AUX DSE) which influences the processing efficiency of the SV40 late polyadenylation signal. We have now determined that sequences downstream of the core U-rich element (URE) form a fundamental part of mammalian polyadenylation signals. These novel AUX DSEs all influenced the efficiency of 3'-end processing in vitro by stabilizing the assembly of CstF on the core downstream URE. Three possible mechanisms by which AUX DSEs mediate efficient in vitro 3'-end processing have been explored. First, AUX DSEs can promote processing efficiency by maintaining the core elements in an unstructured domain which allows the general polyadenylation factors to efficiently assemble on the RNA substrate. Second, AUX DSEs can enhance processing by forming a stable structure which helps focus binding of CstF to the core downstream URE. Finally, the GRS element, but not the binding site for the bacteriophage R17 coat protein, can substitute for the auxiliary downstream region of the adenovirus L3 polyadenylation signal. This suggests that AUX DSE binding proteins may play an active role in stimulating 3'-end processing by stabilizing the association of CstF with the RNA substrate. AUX DSEs, therefore, serve as a integral part of the polyadenylation signal and can affect signal strength and possibly regulation.

Characterization of the gene for the membrane and secretory form of the IgM heavy-chain constant region gene (C mu) of the cow (Bos taurus)

Our present understanding of the evolution of immunoglobulins is derived from a few vertebrate species. In order to obtain additional information on the development of the humoral immune system, we cloned and determined the nucleotide sequence of the bovine cDNA and genomic IgM heavy-chain constant region gene (C mu). The gene contains four constant region domain-encoding exons (CH1 to CH4) and two exons encoding the transmembrane domain (TM1, TM2), expressed in the membrane-bound receptor form of the IgM. The sequence of a cDNA clone encoding the 3' portion of the membrane form of the mu-chain revealed that the TM1 exon is spliced to the CH4 exon, as occurs in other mammals. Comparison of deduced amino acid sequence data from different vertebrates revealed a high similarity to sheep C mu (88%) and a lower degree of similarity to pig (62%), rat (62%), rabbit (58%) human (56%), hamster (55%), mouse (54%), chicken (28%) and horned shark (22%) C mu.

A nonimmunoglobulin transgene and the endogenous immunoglobulin mu gene are coordinately regulated by alternative RNA processing during B-cell maturation

The immunoglobulin (Ig) genes have been extensively studied as model systems for developmentally regulated alternative RNA processing. Transcripts from these genes are alternatively processed at their 3' ends to yield a transcript that is either cleaved and polyadenylated at a site within an intron or spliced to remove the poly(A) site and subsequently cleaved and polyadenylated at a downstream site. Results obtained from expressing modified genes in established tissue culture cell lines that represent different stages of B-lymphocyte maturation have suggested that the only requirement for regulation is that a pre-mRNA contain competing cleavage-polyadenylation and splice reactions whose efficiencies are balanced. Since several non-Ig genes modified to have an Ig gene-like structure are regulated in cell lines, Ig-specific sequences are not essential for this control. This strongly implies that changes in the amounts or activities of general RNA processing components mediate the processing regulation. Despite numerous studies in cell lines, this model of Ig gene regulation has never been tested in vivo during normal lymphocyte maturation. We have now introduced a non-Ig gene with an Ig gene-like structure into the mouse germ line and demonstrate that RNA from the transgene is alternatively processed and regulated in murine splenic B cells. This establishes that the balance and arrangement of competing cleavage-polyadenylation reactions are sufficient for RNA processing regulation during normal B-lymphocyte development. These experiments also validate the use of tissue culture cell lines for studies of Ig processing regulation. This is the first transgenic mouse produced to test a specific model for regulated mRNA processing.

A novel mechanism for B cell repertoire maturation based on response by B cell precursors to pre-B receptor assembly

The expression of different sets of immunoglobulin specificities by fetal and adult B lymphocytes is a long-standing puzzle in immunology. Recently it has become clear that production of immunoglobulin mu heavy chain and subsequent assembly with a surrogate light chain to form the pre-B cell receptor complex is critical for development of B cells. Here we show that instead of promoting pre-B cell progression as in adult bone marrow, this complex inhibits pre-B cell growth in fetal liver. Curiously, we identify a fetal-associated VH11 mu heavy chain that allows continued pre-B proliferation in fetal liver. Interestingly, this heavy chain does not associate efficiently with a surrogate light chain, providing a previously unrecognized mechanism for skewing the expression of distinctive VH genes toward fetal through early neonatal life.

Intronic polyadenylation in the human glycinamide ribonucleotide formyltransferase gene

The mouse glycinamide ribonucleotide formyltransferase (GART) locus is known to produce two functional proteins, one by recognition and use of an intronic polyadenylation site and the other by downstream splicing. We now report a similar intronic polyadenylation mechanism for the human GART locus. The human GART gene has two potential polyadenylation signals within the identically located intron as that involved in intronic polyadenylation in the mouse gene. Each of the potential polyadenylation signals in the human gene was followed by an extensive polyT rich tract, but only the downstream signal was preceded by a GT tract. Only the downstream signal was utilized. The polyT rich tract which followed the functional polyadenylation site in the human GART gene was virtually identical in sequence to a similarly placed region in the mouse gene. An exact inverted complement to the polyT rich stretch following the active polyadenylation signal was found in the upstream intron of the human gene, suggesting that a hairpin loop may be involved in this intronic polyadenylation.

The murine IgM secretory poly(A) site contains dual upstream and downstream elements which affect polyadenylation

Regulation of polyadenylation efficiency at the secretory poly(A) site plays an essential role in gene expression at the immunoglobulin (IgM) locus. At this poly(A) site the consensus AAUAAA hexanucleotide sequence is embedded in an extended AU-rich region and there are two downstream GU-rich regions which are suboptimally placed. As these sequences are involved in formation of the polyadenylation pre-initiation complex, we examined their function in vivo and in vitro . We show that the upstream AU-rich region can function in the absence of the consensus hexanucleotide sequence both in vivo and in vitro and that both GU-rich regions are necessary for full polyadenylation activity in vivo and for formation of polyadenylation-specific complexes in vitro . Sequence comparisons reveal that: (i) the dual structure is distinct for the IgM secretory poly(A) site compared with other immunoglobulin isotype secretory poly(A) sites; (ii) the presence of an AU-rich region close to the consensus hexanucleotide is evolutionarily conserved for IgM secretory poly(A) sites. We propose that the dual structure of the IgM secretory poly(A) site provides a flexibility to accommodate changes in polyadenylation complex components during regulation of polyadenylation efficiency.

A novel chimeric Ig heavy chain from a teleost fish shares similarities to IgD

IgD is considered to be a recently evolved Ig, being previously found only in primates and rodents. Here we describe, from a teleost fish (the channel catfish, Ictalurus punctatus), a novel complex chimeric Ig heavy chain, homologous, in part, to the heavy chain (delta) of IgD. In addition to alternative secretory or membrane-associated C termini, this chimeric molecule contains a rearranged variable domain, the first constant domain of mu, and seven constant domains encoded by a delta gene homolog. Identification of the catfish gene as delta is based on the following properties: sequence relatedness to mammalian delta; a location within the IgH locus that is immediately downstream of the mu gene; separate terminal exons for the secretory and membrane forms; coexpression with the complete mu chain in some but not all B cells. These results (i) suggest that IgD is an ancient immunoglobulin that was present in vertebrates ancestral to both the mammals and the ray-finned fishes, and (ii) raise the possibility that this Ig isotype may have served an as yet unidentified important function early in the evolution of the immune system.

Alternative processing of the sarco/endoplasmic reticulum Ca(2+)-ATPase transcripts during muscle differentiation is a specifically regulated process

Expression of the muscle-specific 2a isoform of the sarco/endoplasmic reticulum Ca(2+)-ATPase (SERCA2) requires activation of an otherwise inefficient splice process at the 3'-end of the primary gene transcript. We provide evidence that SERCA2 splicing is a specifically regulated process, rather than the result of an increase in general splice efficiency or a decrease in polyadenylation efficiency at the 5'-most polyadenylation site. This is indicated by the fact that changes in general splice and polyadenylation efficiency, as observed during B-cell maturation, did not affect SERCA2 splicing. Furthermore, expression and overexpression studies did not support the hypothesis that changes in the level of the alternative splice factor ASF/SF2 or other arginine and serine rich proteins are sufficient to obtain the regulation of muscle- and neuronal-specific splicing.

Characterization of a second secreted IgE isoform and identification of an asymmetric pathway of IgE assembly

A number of alternatively spliced epsilon transcripts have been detected in IgE-producing B cells, in addition to the mRNAs encoding the classical membrane and secreted IgE heavy (H) chains. In a recent study, we examined the protein products of three of these alternatively spliced isoforms and found that they are intracellularly retained and degraded because of their inability to assemble into complete IgE molecules. We have now similarly examined a more recently described epsilon mRNA species that is generated by splicing between a donor splice site immediately upstream of the stop codon in the H-chain constant region exon 4 (CH4) and an acceptor site located in the 3' part of the second membrane exon. We show that this isoform is efficiently secreted by both plasma cells and B lymphocytes and therefore represents a second secreted IgE isoform (epsilon S2). The epsilon S2 H chain is only six amino acids longer than the classical secreted Ig H chain (epsilon S1) and contains a C-terminal cysteine, which is a characteristic sequence feature of mu and alpha H chains. However, unlike IgM and IgA, the epsilon S2 C-terminal cysteine (Cys-554) does not induce polymerization of H2L2 molecules (where L is light chain), but rather creates a disulfide bond between the two H chains that increases the rate of association into covalently bound H2L2 monomers. This C-terminal cysteine also does not function as an intracellular retention element because the epsilon S2 isoform was secreted in amounts equal to that of the epsilon S1, both in B lymphocytes and in plasma cells. The epsilon S2 H chains secreted by B lymphocytes differed from the epsilon S1 H chains in the extent of glycosylation. Interestingly, a difference in glycosylation between B-lymphocytes and plasma cells was also noted for both isoforms. The presence of the Cys-554 also allowed the identification of a distinctive asymmetric pathway of IgE assembly, common to both types of epsilon H chains.

Regulation of herpes simplex virus poly (A) site usage and the action of immediate-early protein IE63 in the early-late switch

The essential herpes simplex virus type 1 (HSV-1) immediate-early IE63 (ICP27) is pleiotropic in function, promoting the switch from the early to late phase of virus gene expression, and has effects on the posttranscriptional processes of mRNA splicing and 3' processing. We have investigated the role of IE63 in the regulation of viral mRNA 3' processing and of late gene expression. Our in vitro 3' processing studies demonstrated that HSV-1 infection induces an activity, which requires IE63 gene expression, responsible for an observed increase in 3' processing of selected HSV-1 poly(A) sites. Processing efficiencies at the poly(A) sites of two late genes, UL38 and UL44, shown to be inherently weak processing sites, were increased by the IE63-induced activity. In contrast, 3' processing at the poly(A) sites of selected immediate-early and early genes, stronger processing sites, was unaffected by IE63 expression. UV cross-linking experiments demonstrated that HSV infection caused enhanced binding of protein factors, including the 64-kDa component of cleavage stimulation factor (CstF), to poly(A) site RNAs from virus genes of all temporal classes and that this enhanced binding required expression of IE63. By immunofluorescence, the homogeneous pattern of the 64-kDa CstF protein distribution became slightly clumped with infection, whereas the splicing small nuclear ribonucleoprotein particles were recognized into a highly punctate distribution away from the sites of virus transcription. This effect could create an increase in the relative concentration of 3' processing factors available to pre-mRNAs. Western blot (immunoblot) analysis showed that IE63 was required for expression of several true late genes and for the efficient and timely expression of the UL29 and UL42 early genes, integral components on the viral DNA synthesis machinery. Our data are consistent with two effects of IE63 on late gene regulation: firstly, a stimulation of pre-mRNA 3' processing and, secondly, as a requirement for expression of functions necessary for viral DNA synthesis.

Regulation of poly(A) site use during mouse B-cell development involves a change in the binding of a general polyadenylation factor in a B-cell stage-specific manner

During the development of mouse B cells there is a regulated shift from the production of membrane to the secretion-specific forms of immunoglobulin (Ig) mRNA, which predominate in the late-stage or plasma B cells. By DNA transfection experiments we have previously shown that there is an increase in polyadenylation efficiency accompanying the shift to secretion-specific forms of Ig mRNA (C. R. Lassman, S. Matis, B. L. Hall, D. L. Toppmeyer, and C. Milcarek, J. Immunol. 148:1251-1260, 1992). When we look in vitro at nuclear extracts prepared from early or memory versus late-stage or plasma B cells, we see cell stage-specific differences in the proteins which are UV cross-linked to the input RNAs. We have characterized one of these proteins as the 64-kDa subunit of the general polyadenylation factor cleavage-stimulatory factor (CstF) by immunoprecipitation of UV-cross-linked material. The amount of 64-kDa protein and its mobility on two-dimensional gels do not vary between the B-cell stages. However, the activity of binding of the protein to both Ig and non-Ig substrates increases four- to eightfold in the late-stage or plasma cell lines relative to the binding seen in the early or memory B-cell lines. Therefore, the binding activity of a constitutive factor required for polyadenylation is altered in a B-cell-specific fashion. The increased binding of the 64-kDa protein may lead to a generalized increase in polyadenylation efficiency in plasma cells versus early or memory B cells which may be responsible for the increased use of the secretory poly(A) site seen in vivo.

Identification of an activity in B-cell extracts that selectively impairs the formation of an immunoglobulin mu s poly(A) site processing complex

The immunoglobulin mu heavy-chain transcription unit is differentially expressed during B-cell development, producing mRNAs that encode secreted (mu s) and membrane-bound (mu m) forms of the heavy-chain polypeptide. Whereas the mu s mRNA and the mu m mRNA are produced in approximately equal abundance in B cells, an increase in the utilization of the mu s poly(A) site contributes to the production of the mu s mRNA as the predominant form in a plasma cell. Previous experiments have demonstrated a correlation between the formation of a stable complex on a poly(A) site and the relative function of the poly(A) site. We have thus investigated the parameters determining the interaction of these factors with the immunoglobulin poly(A) sites. Assays of complex formation involving the two immunoglobulin poly(A) sites by using HeLa cell activities revealed the formation of stable complexes with no apparent difference between the mu s site and the mu m site. In contrast, the mu s-specific complex was markedly less stable when a B-cell extract was used. Fractionation of B-cell extracts has revealed an activity that specifically destabilizes the mu s polyadenylation complex, suggesting that the function of this poly(A) site may be regulated by both positive- and negative-acting factors.

Regulated immunoglobulin (Ig) RNA processing does not require specific cis-acting sequences: non-Ig RNA can be alternatively processed in B cells and plasma cells

Alternative RNA processing of the heavy-chain immunoglobulin mu gene is regulated during B-cell maturation and requires competition between splice and cleavage-polyadenylation reactions that have balanced efficiencies. Studies with modified mu genes have failed to identify gene-specific sequences required for regulation. Thus, the only important feature for regulation may be the balanced competing splice and cleavage-polyadenylation reactions themselves. If this is so, then alternative RNA processing from any gene with similar competitive RNA processing pathways should also be regulated when expression is compared between B cells and plasma cells. To test this prediction, two nonimmunoglobulin genes engineered to have competing splice and cleavage-polyadenylation reactions were expressed in B cells and plasma cells. The ratios of alternative RNAs produced from both genes are different in the two cell types; like the mu gene, relatively more spliced RNA is produced in B cells than in plasma cells. Also, in a survey of mu gene expression in nine non-B-cell lines, only a T-cell line had an expression pattern similar to that of B cells; the expression patterns of all other lines resembled that of the plasma cells. Therefore, regulated mu RNA processing must be mediated by changes in general processing factors whose activity or abundance is regulated, most likely, in B cells.

Regulated immunoglobulin (Ig) RNA processing does not require specific cis-acting sequences: non-Ig RNA can be alternatively processed in B cells and plasma cells

Alternative RNA processing of the heavy-chain immunoglobulin mu gene is regulated during B-cell maturation and requires competition between splice and cleavage-polyadenylation reactions that have balanced efficiencies. Studies with modified mu genes have failed to identify gene-specific sequences required for regulation. Thus, the only important feature for regulation may be the balanced competing splice and cleavage-polyadenylation reactions themselves. If this is so, then alternative RNA processing from any gene with similar competitive RNA processing pathways should also be regulated when expression is compared between B cells and plasma cells. To test this prediction, two nonimmunoglobulin genes engineered to have competing splice and cleavage-polyadenylation reactions were expressed in B cells and plasma cells. The ratios of alternative RNAs produced from both genes are different in the two cell types; like the mu gene, relatively more spliced RNA is produced in B cells than in plasma cells. Also, in a survey of mu gene expression in nine non-B-cell lines, only a T-cell line had an expression pattern similar to that of B cells; the expression patterns of all other lines resembled that of the plasma cells. Therefore, regulated mu RNA processing must be mediated by changes in general processing factors whose activity or abundance is regulated, most likely, in B cells.

Alternative promoter usage and splicing options result in the differential expression of mRNAs encoding four isoforms of chicken VBP, a member of the PAR subfamily of bZIP transcription factors

We previously isolated a set of overlapping cDNA clones that encoded a unique open reading frame for the chicken VBP transcription factor. We now report the isolation of a cDNA clone that encodes a complete open reading frame for a VBP isoform that differs from the previously reported sequence at both the amino-terminal and carboxyl-terminal ends. An analysis of the VBP gene revealed that the two different amino-terminal sequences map to alternative first exons and that the two different carboxyl-terminal sequences reflect an optional splicing event which can occur only on transcripts that are polyadenylated at the more distal of two polyadenylation sites. An RT-PCR analysis further revealed that a total of four VBP isoforms are encoded by the combinatorial use of these two splicing options. The mRNAs for these four isoforms are differentially expressed in different tissues and cell types. We provide evidence that one function of the amino-terminal domains is to impose cell type specificity on a core transactivation domain that is present in all four isoforms. Since it is known that VBP can heterodimerize with other members of the PAR subfamily of bZIP factors, our evidence for four VBP isoforms greatly expands the number of complexes that may be used to effect transcriptional regulation through PAR-factor binding sites.

Regulation of splicing is responsible for the expression of the muscle-specific 2a isoform of the sarco/endoplasmic-reticulum Ca(2+)-ATPase

Tissue-specific alternative processing of sarco/endoplasmic reticulum Ca(2+)-ATPase 2 (SERCA2) transcripts generates functionally different Ca2+ pump isoforms in muscle compared with non-muscle tissues. In non-muscle cells, the SERCA2 pre-mRNA can be polyadenylated at a site located between the donor and acceptor splice site of an intron which is only removed in muscle tissues. To define the cis-active elements involved in differential processing, we constructed a minigene (pCM beta SERCA2) containing the 3' end of the SERCA2 gene. When stably transfected into a myogenic cell line, minigene transcripts were differentially processed depending on the differentiation state of the cells. This proves that the essential elements required for regulated processing are present in the construct. Furthermore, co-transfection of the pCM beta SERCA2 minigene and a myogenin expression vector in a fibroblast cell line induced muscle-specific splicing of transcripts from pCM beta SERCA2. This shows that trans-acting factor(s) responsible for muscle-specific processing can be induced by one of the important regulatory genes of muscle differentiation. Inactivation of the non-muscle poly(A) site did not induce splicing in non-muscle cells. This excludes a simple competition model between splicing and polyadenylation, but it is consistent with splicing being very inefficient in non-muscle cells. Moreover, splicing could be induced in non-muscle cells by optimizing the muscle-specific donor splice site and/or by shortening the intron length. We therefore propose that expression of the muscle-specific SERCA2a isoform is the result of activation of an otherwise inefficient splicing process.

Sequence elements upstream of the 3' cleavage site confer substrate strength to the adenovirus L1 and L3 polyadenylation sites

The adenovirus major late transcription unit is a well-characterized transcription unit which relies heavily on alternative pre-mRNA processing to generate distinct populations of mRNA during the early and late stages of viral infection. In the early stage of infection, two major late transcription unit mRNA transcripts are generated through use of the first (L1) of five available poly(A) sites (L1 through L5). This contrasts with the late stage of infection when as many as 45 distinct mRNAs are generated, with each of the five poly(A) sites being used. In previous work characterizing elements involved in alternative poly(A) site use, we showed that the L1 poly(A) site is processed less efficiently than the L3 poly(A) site both in vitro and in vivo. Because of the dramatic difference in processing efficiency and the role processing efficiency plays in production of steady-state levels of mRNA, we have identified the sequence elements that account for the differences in L1 and L3 poly(A) site processing efficiency. We have found that the element most likely to be responsible for poly(A) site strength, the GU/U-rich downstream element, plays a minor role in the different processing efficiencies observed for the L1 and L3 poly(A) sites. The sequence element most responsible for inefficient processing of the L1 poly(A) site includes the L1 AAUAAA consensus sequence and those sequences which immediately surround the consensus hexanucleotide. This region of the L1 poly(A) site contributes to an inability to form a stable processing complex with the downstream GU/U-rich element. In contrast to the L1 element, the L3 poly(A) site has a consensus hexanucleotide and surrounding sequences which can form a stable processing complex in cooperation with the downstream GU/U-rich element. The L3 poly(A) site is also aided by the presence of sequences upstream of the hexanucleotide which facilitate processing efficiency. The sequence UUCUUUUU, present in the L3 upstream region, is shown to enhance processing efficiency as well as stable complex formation (shown by increased binding of the 64-kDa cleavage stimulatory factor subunit) and acts as a binding site for heterogeneous nuclear ribonucleoprotein C proteins.

Sequence elements upstream of the 3' cleavage site confer substrate strength to the adenovirus L1 and L3 polyadenylation sites

The adenovirus major late transcription unit is a well-characterized transcription unit which relies heavily on alternative pre-mRNA processing to generate distinct populations of mRNA during the early and late stages of viral infection. In the early stage of infection, two major late transcription unit mRNA transcripts are generated through use of the first (L1) of five available poly(A) sites (L1 through L5). This contrasts with the late stage of infection when as many as 45 distinct mRNAs are generated, with each of the five poly(A) sites being used. In previous work characterizing elements involved in alternative poly(A) site use, we showed that the L1 poly(A) site is processed less efficiently than the L3 poly(A) site both in vitro and in vivo. Because of the dramatic difference in processing efficiency and the role processing efficiency plays in production of steady-state levels of mRNA, we have identified the sequence elements that account for the differences in L1 and L3 poly(A) site processing efficiency. We have found that the element most likely to be responsible for poly(A) site strength, the GU/U-rich downstream element, plays a minor role in the different processing efficiencies observed for the L1 and L3 poly(A) sites. The sequence element most responsible for inefficient processing of the L1 poly(A) site includes the L1 AAUAAA consensus sequence and those sequences which immediately surround the consensus hexanucleotide. This region of the L1 poly(A) site contributes to an inability to form a stable processing complex with the downstream GU/U-rich element. In contrast to the L1 element, the L3 poly(A) site has a consensus hexanucleotide and surrounding sequences which can form a stable processing complex in cooperation with the downstream GU/U-rich element. The L3 poly(A) site is also aided by the presence of sequences upstream of the hexanucleotide which facilitate processing efficiency. The sequence UUCUUUUU, present in the L3 upstream region, is shown to enhance processing efficiency as well as stable complex formation (shown by increased binding of the 64-kDa cleavage stimulatory factor subunit) and acts as a binding site for heterogeneous nuclear ribonucleoprotein C proteins.

Alternative promoter usage of the Fos-responsive gene Fit-1 generates mRNA isoforms coding for either secreted or membrane-bound proteins related to the IL-1 receptor

Fit-1 has been identified previously as a Fos-responsive gene of rat fibroblasts. Here we show that Fit-1 is directly regulated by the estrogen-inducible transcription factor Fos-ER and that it belongs to the family of delayed early genes. Two different mRNA isoforms are expressed from the Fit-1 gene. The Fit-1M mRNA isolated from spleen codes for a membrane-bound protein which is most closely related in its extracellular, transmembrane and intracellular domains to the type I interleukin-1 (IL-1) receptor. The Fit-1S mRNA of fibroblasts directs, instead, the synthesis of a secreted protein consisting of only the extracellular domain. Analysis of the exon-intron structure of the Fit-1 gene indicated that the Fit-1S and Fit-1M mRNAs are transcribed from two different promoters and that the sequence differences at their 3' ends result from alternative 3' processing. Northern blot analysis with specific 5' and 3' probes directly demonstrated tight coupling between alternative promoter usage and 3' processing of the Fit-1 transcripts. The orthologous gene of the mouse (known as T1 or ST2) is expressed during ontogeny first in the fetal liver of the embryo and then in lung and hematopoietic tissues of the adult. The mRNA coding for the membrane-bound protein is more abundantly expressed in all of these tissues, while the transcript for the secreted form predominates in fibroblasts and mammary epithelial cells. Differential regulation of two distinct promoters is thus used to determine the ratio between secreted and membrane-bound forms of Fit-1 (T1/ST2) which may modulate signaling in response to IL-1.

Exon size affects competition between splicing and cleavage-polyadenylation in the immunoglobulin mu gene

The alternative RNA processing of microseconds and microns mRNAs from a single primary transcript depends on competition between a cleavage-polyadenylation reaction to produce microseconds mRNA and a splicing reaction to produce microns mRNA. The ratio of microseconds to microns mRNA is regulated during B-cell maturation; relatively more spliced microns mRNA is made in B cells than in plasma cells. The balance between the efficiencies of splicing and cleavage-polyadenylation is critical to the regulation. The mu gene can be modified to either reduce or improve the efficiency of each reaction and thus alter the ratio of the two RNAs produced. However, as long as neither reaction is so strong that it totally dominates, expression of the modified mu genes is regulated in B cells and plasma cells. The current experiments reveal a relationship between the C mu 4 exon size and the microseconds/microns expression ratio. The shorter the distance between the C mu 4 5' splice site and the nearest upstream 3' splice site, the more spliced microns mRNA was produced. Conversely, when this exon was expanded, more microseconds mRNA was produced. Expression from these mu genes with altered exon sizes were regulated between B cells and plasma cells. Since RNA processing in the mu gene can be considered a competition between defining the C mu 4 exon as an internal exon (in microns mRNA) versus a terminal exon (in microseconds mRNA), exon size may affect the competition among factors interacting with this exon.

Sex-lethal autoregulation requires multiple cis-acting elements upstream and downstream of the male exon and appears to depend largely on controlling the use of the male exon 5' splice site

The on/off state of the binary switch gene Sex-lethal (Sxl), which controls somatic sexual development in Drosophila melanogaster, is regulated at the level of alternative splicing. In males, in which the gene is off, the default splicing machinery produces nonfunctional mRNAs; in females, in which the gene is on, the autoregulatory activity of the Sxl proteins directs the splicing machinery to produce functional mRNAs. We have used germ line transformation to analyze the mechanism of default and regulated splicing. Our results demonstrate that a blockage mechanism is employed in Sxl autoregulation. However, in contrast to transformer, in which Sxl appears to function by preventing the interaction of splicing factors with the default 3' splice site, a different strategy is used in autoregulation. (i) Multiple cis-acting elements, both upstream and downstream of the male exon, are required. (ii) These cis-acting elements are distant from the splice sites they regulate, suggesting that the Sxl protein cannot function in autoregulation by directly competing with splicing factors for interaction with the regulated splice sites. (iii) The 5' splice site of the male exon appears to be dominant in regulation while the 3' splice site plays a subordinate role.

Exon size affects competition between splicing and cleavage-polyadenylation in the immunoglobulin mu gene

The alternative RNA processing of microseconds and microns mRNAs from a single primary transcript depends on competition between a cleavage-polyadenylation reaction to produce microseconds mRNA and a splicing reaction to produce microns mRNA. The ratio of microseconds to microns mRNA is regulated during B-cell maturation; relatively more spliced microns mRNA is made in B cells than in plasma cells. The balance between the efficiencies of splicing and cleavage-polyadenylation is critical to the regulation. The mu gene can be modified to either reduce or improve the efficiency of each reaction and thus alter the ratio of the two RNAs produced. However, as long as neither reaction is so strong that it totally dominates, expression of the modified mu genes is regulated in B cells and plasma cells. The current experiments reveal a relationship between the C mu 4 exon size and the microseconds/microns expression ratio. The shorter the distance between the C mu 4 5' splice site and the nearest upstream 3' splice site, the more spliced microns mRNA was produced. Conversely, when this exon was expanded, more microseconds mRNA was produced. Expression from these mu genes with altered exon sizes were regulated between B cells and plasma cells. Since RNA processing in the mu gene can be considered a competition between defining the C mu 4 exon as an internal exon (in microns mRNA) versus a terminal exon (in microseconds mRNA), exon size may affect the competition among factors interacting with this exon.

Sex-lethal autoregulation requires multiple cis-acting elements upstream and downstream of the male exon and appears to depend largely on controlling the use of the male exon 5' splice site

The on/off state of the binary switch gene Sex-lethal (Sxl), which controls somatic sexual development in Drosophila melanogaster, is regulated at the level of alternative splicing. In males, in which the gene is off, the default splicing machinery produces nonfunctional mRNAs; in females, in which the gene is on, the autoregulatory activity of the Sxl proteins directs the splicing machinery to produce functional mRNAs. We have used germ line transformation to analyze the mechanism of default and regulated splicing. Our results demonstrate that a blockage mechanism is employed in Sxl autoregulation. However, in contrast to transformer, in which Sxl appears to function by preventing the interaction of splicing factors with the default 3' splice site, a different strategy is used in autoregulation. (i) Multiple cis-acting elements, both upstream and downstream of the male exon, are required. (ii) These cis-acting elements are distant from the splice sites they regulate, suggesting that the Sxl protein cannot function in autoregulation by directly competing with splicing factors for interaction with the regulated splice sites. (iii) The 5' splice site of the male exon appears to be dominant in regulation while the 3' splice site plays a subordinate role.

Polyadenylation site selection cannot occur in vivo after excision of the 3'-terminal intron

Splicing of 3'-terminal introns and polyadenylation of pre-mRNAs can be coupled in an appropriate cell-free system. However, definitive evidence has been lacking as to whether these events are coupled in vivo and whether the order of these two processing events is obligatory. Here, we investigated these questions by examining the in vivo processing of transcripts that differ solely by the precise insertion of an intron within the first of two polyadenylation signals. Quantitative S1 nuclease mapping and PCR techniques were utilized to analyze the processed RNAs that accumulated in monkey cells transfected with plasmids encoding these transcripts. We found that, whereas all of the primary transcripts that lacked the inserted intron were processed via utilization of the 5'-proximal polyadenylation signal, none of the transcripts initially disrupted in this signal were processed this way even though the disrupting intron had been properly excised and excision sometimes preceded polyadenylation. In addition, deletion of the second polyadenylation signal resulted in failure of spliced transcripts to accumulate. We conclude that selection of, but not necessarily cleavage at the polyadenylation site precedes excision of the 3'-terminal intron in vivo; although coupling exists during selection of the sites to be used for polyadenylation and excision of the 3'-terminal intron, the actual order of the subsequent enzymatic reactions is probably simply a reflection of their relative kinetics.

Alternative poly(A) site utilization during adenovirus infection coincides with a decrease in the activity of a poly(A) site processing factor

The recognition and processing of a pre-mRNA to create a poly(A) addition site, a necessary step in mRNA biogenesis, can also be a regulatory event in instances in which the frequency of use of a poly(A) site varies. One such case is found during the course of an adenovirus infection. Five poly(A) sites are utilized within the major late transcription unit to produce more than 20 distinct mRNAs during the late phase of infection. The proximal half of the major late transcription unit is also expressed during the early phase of a viral infection. During this early phase of expression, the L1 poly(A) site is used three times more frequently than the L3 poly(A) site. In contrast, the L3 site is used three times more frequently than the L1 site during the late phase of infection. Recent experiments have suggested that the recognition of the poly(A) site GU-rich downstream element by the CF1 processing factor may be a rate-determining step in poly(A) site selection. We demonstrate that the interaction of CF1 with the L1 poly(A) site is less stable than the interaction of CF1 with the L3 poly(A) site. We also find that there is a substantial decrease in the level of CF1 activity when an adenovirus infection proceeds to the late phase. We suggest that this reduction in CF1 activity, coupled with the relative instability of the interaction with the L1 poly(A) site, contributes to the reduced use of the L1 poly(A) site during the late stage of an adenovirus infection.

Regulated splicing of the Drosophila sex-lethal male exon involves a blockage mechanism

In Drosophila melanogaster, sex determination in somatic cells is controlled by a cascade of genes whose expression is regulated by alternative splicing [B. S. Baker, Nature (London) 340:521-524, 1989; J. Hodgkin, Cell 56:905-906, 1989]. The master switch gene in this hierarchy is Sex-lethal. Sex-lethal is turned on only in females, and an autoregulatory feedback loop which controls alternative splicing maintains this state (L. R. Bell, J. I. Horabin, P. Schedl, and T. W. Cline, Cell 65:229-239, 1991; L. N. Keyes, T. W. Cline, and P. Schedl, Cell 68:933-943, 1992). Sex-lethal also promotes female differentiation by controlling the splicing of RNA from the next gene in the hierarchy, transformer. Sosnowski et al. (B. A. Sosnowski, J. M. Belote, and M. McKeown, Cell 58:449-459, 1989) have shown that the mechanism for generating female transformer transcripts is not through the activation of the alternative splice site but by the blockage of the default splice site. We have tested whether an activation or a blockage mechanism is involved in Sex-lethal autoregulation. The male exon of Sex-lethal with flanking splice sites was placed into the introns of heterologous genes. Our results support the blockage mechanism. The poly(U) run at the male exon 3' splice site is required for sex-specific splicing. However, unlike transformer, default splicing to the male exon is sensitive to the sequence context within which the exon resides. This and the observation that the splice signals at the exon are suboptimal are discussed with regard to alternate splicing.

Alternative poly(A) site utilization during adenovirus infection coincides with a decrease in the activity of a poly(A) site processing factor

The recognition and processing of a pre-mRNA to create a poly(A) addition site, a necessary step in mRNA biogenesis, can also be a regulatory event in instances in which the frequency of use of a poly(A) site varies. One such case is found during the course of an adenovirus infection. Five poly(A) sites are utilized within the major late transcription unit to produce more than 20 distinct mRNAs during the late phase of infection. The proximal half of the major late transcription unit is also expressed during the early phase of a viral infection. During this early phase of expression, the L1 poly(A) site is used three times more frequently than the L3 poly(A) site. In contrast, the L3 site is used three times more frequently than the L1 site during the late phase of infection. Recent experiments have suggested that the recognition of the poly(A) site GU-rich downstream element by the CF1 processing factor may be a rate-determining step in poly(A) site selection. We demonstrate that the interaction of CF1 with the L1 poly(A) site is less stable than the interaction of CF1 with the L3 poly(A) site. We also find that there is a substantial decrease in the level of CF1 activity when an adenovirus infection proceeds to the late phase. We suggest that this reduction in CF1 activity, coupled with the relative instability of the interaction with the L1 poly(A) site, contributes to the reduced use of the L1 poly(A) site during the late stage of an adenovirus infection.