An exon that prevents transport of a mature mRNA

Regulation of mRNA stability contributes to the function of innate lymphoid cells in various diseases

Innate lymphoid cells (ILCs) are important subsets of innate immune cells that regulate mucosal immunity. ILCs include natural killer cells, innate lymphoid cells-1 (ILC1s), ILC2s, and ILC3s, which have extremely important roles in the immune system. In this review, we summarize the regulation of mRNA stability mediated through various factors in ILCs (e.g., cytokines, RNA-binding proteins, non-coding RNAs) and their roles in mediating functions in different ILC subsets. In addition, we discuss potential therapeutic targets for diseases such as chronic obstructive pulmonary disease, cancer, and pulmonary fibrosis by regulation of mRNA stability in ILCs, which may provide novel directions for future clinical research.

Evolutionarily conserved autoregulation of alternative pre-mRNA splicing by ribosomal protein L10a

Alternative splicing of pre-mRNAs can regulate expression of protein-coding genes by generating unproductive mRNAs rapidly degraded by nonsense-mediated mRNA decay (NMD). Many of the genes directly regulated by alternative splicing coupled with NMD (AS-NMD) are related to RNA metabolism, but the repertoire of genes regulated by AS-NMD in vivo is to be determined. Here, we analyzed transcriptome data of wild-type and NMD-defective mutant strains of the nematode worm Caenorhabditis elegans and demonstrate that eight of the 82 cytoplasmic ribosomal protein (rp) genes generate unproductively spliced mRNAs. Knockdown of any of the eight rp genes exerted a dynamic and compensatory effect on alternative splicing of its own transcript and inverse effects on that of the other rp genes. A large subunit protein L10a, termed RPL-1 in nematodes, directly and specifically binds to an evolutionarily conserved 39-nt stretch termed L10ARE between the two alternative 5′ splice sites in its own pre-mRNA to switch the splice site choice. Furthermore, L10ARE-mediated splicing autoregulation of the L10a-coding gene is conserved in vertebrates. These results indicate that L10a is an evolutionarily conserved splicing regulator and that homeostasis of a subset of the rp genes are regulated at the level of pre-mRNA splicing in vivo.

Identification and characterization of alternative splicing in parasitic nematode transcriptomes

Background

Alternative splicing (AS) of mRNA is a vital mechanism for enhancing genomic complexity in eukaryotes. Spliced isoforms of the same gene can have diverse molecular and biological functions and are often differentially expressed across various tissues, times, and conditions. Thus, AS has important implications in the study of parasitic nematodes with complex life cycles. Transcriptomic datasets are available from many species, but data must be revisited with splice-aware assembly protocols to facilitate the study of AS in helminthes.

Methods

We sequenced cDNA from the model worm Caenorhabditis elegans using 454/Roche technology for use as an experimental dataset. Reads were assembled with Newbler software, invoking the cDNA option. Several combinations of parameters were tested and assembled transcripts were verified by comparison with previously reported C. elegans genes and transcript isoforms and with Illumina RNAseq data.

Results

Thoughtful adjustment of program parameters increased the percentage of assembled transcripts that matched known C. elegans sequences, decreased mis-assembly rates (i.e., cis- and trans-chimeras), and improved the coverage of the geneset. The optimized protocol was used to update de novo transcriptome assemblies from nine parasitic nematode species, including important pathogens of humans and domestic animals. Our assemblies indicated AS rates in the range of 20-30%, typically with 2-3 transcripts per AS locus, depending on the species. Transcript isoforms from the nine species were translated and searched for similarity to known proteins and functional domains. Some 21 InterPro domains, including several involved in nucleotide and chromatin binding, were statistically correlated with AS genetic loci. In most cases, the Roche/454 data explored in this study are the only sequences available from the species in question; however, the recently published genome of the human hookworm Necator americanus provided an additional opportunity to validate our results.

Conclusions

Our optimized assembly parameters facilitated the first survey of AS among parasitic nematodes. The nine transcriptome assemblies, their protein translations, and basic annotations are available from Nematode.net as a resource for the research community. These should be useful for studies of specific genes and gene families of interest as well as for curating draft genome assemblies as they become available.

Visualization and genetic analysis of alternative splicing regulation in vivo using fluorescence reporters in transgenic Caenorhabditis elegans

Transgenic multicolor fluorescence reporters enable the visualization of alternative splicing patterns at a single-cell resolution in living organisms and facilitate further genetic analyses to identify cis-elements and trans-acting factors involved in splicing regulation. In this paper, we describe a method of generating fluorescence alternative splicing reporters for the nematode Caenorhabditis elegans. We describe strategies for designing minigene reporters and methods for constructing them; DNA fragments ('modules', such as promoter/3' cassettes, a genomic fragment of interest and a fluorescent protein cassette) that exist in separate vectors are assembled using site-directed recombination. We also describe strategies and methods for mutant screening and single-nucleotide polymorphism mapping using fluorescence reporters. This is the first detailed description of the design and construction of fluorescence alternative splicing reporters for C. elegans and their use in subsequent genetic analyses. It takes 2-4 months to construct minigenes and generate extrachromosomal lines for visualizing spatiotemporal distribution of alternative splicing events in vivo. Identification of regulators by integration of transgenes, mutant screening and mapping of the responsible genes takes a further 6-12 months. The fluorescence-reporter construction described here can also be applied to the vertebrate cell culture system.

Communication with the exon-junction complex and activation of nonsense-mediated decay by human Upf proteins occur in the cytoplasm

The nonsense-mediated mRNA decay (NMD) pathway rids eukaryotic cells of mRNAs with premature termination codons. There is contradictory evidence as to whether mammalian NMD is a nuclear or a cytoplasmic process. Here, we show evidence that NMD in human cells occurs primarily, if not entirely, in the cytoplasm. Polypeptides designed to inhibit interactions between NMD factors specifically impede NMD when exogenously expressed in the cytoplasm. However, restricting the polypeptides to the nucleus strongly impairs their NMD-inhibitory function, even for those intended to inhibit interactions between the exon-junction complex (EJC) and hUpf3 proteins, which localize primarily in the nucleus. NMD substrates classified based on cell fractionation assays as "nucleus associated" or "cytoplasmic" are all inhibited in the same manner. Furthermore, retention of the NMD factor hUpf1 in the nucleus strongly impairs NMD. These observations suggest that the hUpf complex communicates with the EJC and triggers NMD in the cytoplasm.

U2AF binding selects for the high conservation of the C. elegans 3' splice site

Caenorhabditis elegans is unusual among animals in having a highly conserved octamer sequence at the 3' splice site: UUUU CAG/R. This sequence can bind to the essential heterodimeric splicing factor U2AF, with U2AF65 contacting the U tract and U2AF35 contacting the splice site itself (AG/R). Here we demonstrate a strong correspondence between binding to U2AF of RNA oligonucleotides with variant octamer sequences and the frequency with which such variations occur in splice sites. C. elegans U2AF has a strong preference for the octamer sequence and exerts much of the pressure for 3' splice sites to have the precise UUUUCAG/R sequence. At two positions the splice site has a very strong preference for U even though alternative bases can also bind tightly to U2AF, suggesting that evolution can select against sequences that may have a relatively modest reduction in binding. Although pyrimidines are frequently present at the first base in the exon, U2AF has a very strong bias against them, arguing there is a mechanism to compensate for weakened U2AF binding at this position. Finally, the C in the consensus sequence must remain adjacent to the AG/R rather than to the stretch of U's, suggesting this C is recognized by U2AF35.

UAP56 levels affect viability and mRNA export in Caenorhabditis elegans

Expression of a gfp transgene in the intestines of living Caenorhabditis elegans has been measured following depletion by RNAi of a variety of known splicing factors and mRNA export proteins. Reduction of most splicing factors showed only a small effect on expression of the transgene in the animal injected with dsRNA, although most of these RNAi's resulted in embryonic lethality in their offspring. In contrast, RNAi of nxf-1, the worm homolog of mammalian NXF1/TAP, a key component of the mRNA export machinery, resulted in dramatic suppression of GFP expression in the injected animals. When we tested other proteins previously reported to be involved in marking mRNAs for export, we obtained widely divergent results. Whereas RNAi of the worm REF/Aly homologs had no obvious effect, either in the injected animals or their offspring, RNAi of UAP56, reported to be the partner of REF/Aly, resulted in strong suppression of GFP expression due to nuclear retention of its mRNA. Overexpression of UAP56 also resulted in rapid loss of GFP expression and lethality at all stages of development. We conclude that UAP56 plays a key role in mRNA export in C. elegans, but that REF/Aly may not. It also appears that some RNA processing factors are required for viability (e.g., U2AF, PUF60, SRp54, SAP49, PRP8, U1-70K), whereas others are not (e.g., U2A', CstF50).

mRNA surveillance: the perfect persist

In eukaryotes, an elaborate set of mechanisms has evolved to ensure that the multistep process of gene expression is accurately executed and adapted to cellular needs. The mRNA surveillance pathway works in this context by assessing the quality of mRNAs to ensure that they are suitable for translation. mRNA surveillance facilitates the detection and destruction of mRNAs that contain premature termination codons by a process called nonsense-mediated decay. Moreover, recent studies have shown that a distinct mRNA surveillance process, called nonstop decay, is responsible for depleting mRNAs that lack in-frame termination codons. mRNA surveillance thereby prevents the synthesis of truncated and otherwise aberrant proteins, which can have dominant-negative and other deleterious effects.

The human papillomavirus type 31 late 3' untranslated region contains a complex bipartite negative regulatory element

The papillomavirus life cycle is tightly linked to epithelial cell differentiation. Production of virus capsid proteins is restricted to the most terminally differentiated keratinocytes in the upper layers of the epithelium. However, mRNAs encoding the capsid proteins can be detected in less-differentiated cells, suggesting that late gene expression is controlled posttranscriptionally. Short sequence elements (less than 80 nucleotides in length) that inhibit gene expression in undifferentiated epithelial cells have been identified in the late 3' untranslated regions (UTRs) of several papillomaviruses, including the high-risk mucosal type human papillomavirus type 16 (HPV-16). Here we show that closely related high-risk mucosal type HPV-31 also contains elements that can act to repress gene expression in undifferentiated epithelial cells. However, the HPV-31 negative regulatory element is surprisingly complex, comprising a major inhibitory element of approximately 130 nucleotides upstream of the late polyadenylation site and a minor element of approximately 110 nucleotides mapping downstream. The first 60 nucleotides of the major element have 68% identity to the negative regulatory element of HPV-16, and these elements bind the same cellular proteins, CstF-64, U2AF(65), and HuR. The minor inhibitory element binds some cellular proteins in common with the major inhibitory element, though it also binds certain proteins that do not bind the upstream element.

Identification of new poly(A) polymerase-inhibitory proteins capable of regulating pre-mRNA polyadenylation

The 3' ends of nearly all eukaryotic pre-mRNAs undergo cleavage and polyadenylation, thereby acquiring a poly(A) tail added by the enzyme poly(A) polymerase (PAP). Two well-characterized examples of regulated poly(A) tail addition in the nucleus consist of spliceosomal proteins, either the U1A or U170K proteins, binding to the pre-mRNA and inhibiting PAP via their PAP regulatory domains (PRDs). These two proteins are the only known examples of this type of gene regulation. On the basis of sequence comparisons, it was predicted that many other proteins, including some members of the SR family of splicing proteins, contain functional PRDs. Here we demonstrate that the putative PRDs found in the SR domains of the SR proteins SRP75 and U2AF65, via fusion to a heterologous MS2 RNA binding protein, specifically and efficiently inhibit PAP in vitro and pre-mRNA polyadenylation in vitro and in vivo. A similar region from the SR domain of SRP40 does not exhibit these activities, indicating that this is not a general property of SR domains. We find that the polyadenylation- and PAP-inhibitory activity of a given polypeptide can be accurately predicted based on sequence similarity to known PRDs and can be measured even if the polypeptides' RNA target is unknown. Our results also indicate that PRDs function as part of a network of interactions within the pre-mRNA processing complex and suggest that this type of regulation will be more widespread than previously thought.

Regulation of nuclear gamma interferon gene expression by interleukin 12 (IL-12) and IL-2 represents a novel form of posttranscriptional control

Posttranscriptional control of gamma interferon (IFN-gamma) gene expression has not been extensively studied and is poorly understood. Our work describes a posttranscriptional mechanism that modulates IFN-gamma mRNA expression in stimulated natural killer (NK) cells through nuclear retention of the IFN-gamma mRNA. This is evidenced by the elevated and sustained nuclear accumulation of both precursor and processed IFN-gamma mRNAs in NK cells stimulated with interleukin-12 (IL-12). The elevated nuclear mRNA accumulation persists long after transcriptional activity has subsided and the rate of cytoplasmic IFN-gamma mRNA accumulation has dropped. The IL-12-induced nuclear retention of the IFN-gamma mRNA prevails until a secondary cytokine stimulus is received. The secondary stimulus, which is initiated by IL-2, mediates transcription-independent movement of the nuclear IFN-gamma mRNA. Concurrent with the nucleocytoplasmic movement of the IFN-gamma mRNA, we have observed increases in the amount of processed nuclear IFN-gamma mRNA that are greater than that seen for the unprocessed IFN-gamma mRNA. The increase in processed IFN-gamma mRNA appears to be due to increased mRNA stability which then promotes increased nucleocytoplasmic shuttling of the mature IFN-gamma mRNA. These data support a model whereby mobilization of nuclear IFN-gamma mRNA stores allows NK cells to rapidly and robustly respond to secondary cytokine activators in a transcription-independent manner, thus shortening the time for overall cellular response to inflammatory signals.

Characterization of U2AF(6), a splicing factor related to U2AF(35)

The essential splicing factor U2AF (U2 auxiliary factor) is a heterodimer composed of 65-kDa (U2AF(65)) and 35-kDa (U2AF(35)) subunits. U2AF(35) has multiple functions in pre-mRNA splicing. First, U2AF(35) has been shown to function by directly interacting with the AG at the 3' splice site. Second, U2AF(35) is thought to play a role in the recruitment of U2AF(65) by serine-arginine-rich (SR) proteins in enhancer-dependent splicing. It has been proposed that the physical interaction between the arginine-serine-rich (RS) domain of U2AF(35) and SR proteins is important for this activity. However, other data suggest that this may not be the case. Here, we report the identification of a mammalian gene that encodes a 26-kDa protein bearing strong sequence similarity to U2AF(35), designated U2AF(26). The N-terminal 187 amino acids of U2AF(35) and U2AF(26) are nearly identical. However, the C-terminal domain of U2AF(26) lacks many characteristics of the U2AF(35) RS domain and, therefore, might be incapable of interacting with SR proteins. We show that U2AF(26) can associate with U2AF(65) and can functionally substitute for U2AF(35) in both constitutive and enhancer-dependent splicing, demonstrating that the RS domain of the small U2AF subunit is not required for splicing enhancer function. Finally, we show that U2AF(26) functions by enhancing the binding of U2AF(65) to weak 3' splice sites. These studies identify U2AF(26) as a mammalian splicing factor and demonstrate that distinct U2AF complexes can participate in pre-mRNA splicing. Based on its sequence and functional similarity to U2AF(35), U2AF(26) may play a role in regulating alternative splicing.

Stop making nonSense: the C. elegans smg genes

Cells monitor the quality of their mRNAs and degrade any transcripts that are poorly or incompletely translated. In the nematode Caenorhabditis elegans, degradation by the mRNA surveillance pathway depends on seven smg genes. Three of these genes also have a role in a second mRNA degradation pathway called RNA interference (RNAi), which is triggered by double-stranded RNA (dsRNA). Here I describe what is known about the smg genes and their potential functions in these two mRNA degradation pathways.

Functional selection of splicing enhancers that stimulate trans-splicing in vitro

The role of exonic sequences in naturally occurring trans-splicing has not been explored in detail. Here, we have identified trans-splicing enhancers through the use of an iterative selection scheme. Several classes of enhancer sequences were identified that led to dramatic increases in trans-splicing efficiency. Two sequence families were investigated in detail. These include motifs containing the element (G/C)GAC(G/C) and also 5' splice site-like sequences. Distinct elements were tested for their ability to function as splicing enhancers and in competition experiments. In addition, discrete trans-acting factors were identified. This work demonstrates that splicing enhancers are able to effect a large increase in trans-splicing efficiency and that the process of exon definition is able to positively enhance trans-splicing even though the reaction itself is independent of the need for the 5' end of U1 snRNA. Due to the presence of internal introns in messages that are trans-spliced, the natural arrangement of 5' splice sites downstream of trans-splicing acceptors may lead to a general promotion of this unusual reaction.

3' splice site recognition in nematode trans-splicing involves enhancer-dependent recruitment of U2 snRNP

Trans-splicing requires that 5' and 3' splice sites be independently recognized. Here, we have used mutational analyses and a sensitive nuclease protection assay to determine the mechanism of trans-3' splice site recognition in vitro. Efficient recognition of the 3' splice site is dependent upon both the sequence of the 3' splice site itself and enhancer elements located in the 3' exon. We show that the presence of three distinct classes of enhancers results in increased binding of U2 snRNP to the branchpoint region. Several lines of evidence strongly suggest that the increased binding of U2 snRNP is mediated by U2AF. These results expand the roles of enhancers in constitutive splicing and provide direct support for the recruitment model of enhancer function.

Nucleocytoplasmic shuttling of heterodimeric splicing factor U2AF

The U2 small nuclear ribonucleoprotein auxiliary factor (U2AF) is a heterodimeric splicing factor composed of 65-kDa (U2AF(65)) and 35-kDa (U2AF(35)) subunits. The large subunit of U2AF recognizes the intronic polypyrimidine tract, a sequence located adjacent to the 3' splice site that serves as an important signal for both constitutive and regulated pre-mRNA splicing. The small subunit U2AF(35) interacts with the 3' splice site dinucleotide AG and is essential for regulated splicing. Like several other proteins involved in constitutive and regulated splicing, both U2AF(65) and U2AF(35) contain an arginine/serine-rich (RS) domain. In the present study we determined the role of RS domains in the subcellular localization of U2AF. Both U2AF(65) and U2AF(35) are shown to shuttle continuously between the nucleus and the cytoplasm by a mechanism that involves carrier receptors and is independent from binding to mRNA. The RS domain on either U2AF(65) or U2AF(35) acts as a nuclear localization signal and is sufficient to target a heterologous protein to the nuclear speckles. Furthermore, the results suggest that the presence of an RS domain in either U2AF subunit is sufficient to trigger the nucleocytoplasmic import of the heterodimeric complex. Shuttling of U2AF between nucleus and cytoplasm possibly represents a means to control the availability of this factor to initiate spliceosome assembly and therefore contribute to regulate splicing.

An allele associated with a non-detectable amount of alpha s2 casein in goat milk

The goat CSN1S2 locus is characterized by the presence of three alleles, A, B and C, all associated with about 2.5 g/l of protein per allele. The SDS-PAGE analysis of 441 individual milk samples obtained from goats belonging to a population reared in Southern Italy showed that the milk produced by three goats did not apparently contain alpha s2-casein, whereas milk produced by 37 goats showed a less intense electrophoretic band of this casein fraction (about 50%). These results can be explained by hypothesizing the presence of another allele at this locus, CSN1S2o, associated with a 'null' content of alpha s2-casein. Southern blot, PCR and PCR-RFLP analyses of the DNA region containing the CSN1S2 gene of individuals producing milk with and without alpha s2-casein did not show differences between the two groups. As a consequence, goats producing milk without alpha s2-casein carry an apparently intact gene. The first results obtained by sequencing part of the CSN1S2o allele revealed a G-->A transition at nucleotide 80 of the 11th exon which creates a stop codon and could be responsible for the absence of the alpha s2-casein in goat milk. This mutation eliminates a NcoI restriction site. A test based on this polymorphism has been established in order to identify carriers of the CSN1S2o allele.

Caspase-2 pre-mRNA alternative splicing: Identification of an intronic element containing a decoy 3' acceptor site

We have established a model system using the caspase-2 pre-mRNA and initiated a study on the role of alternative splicing in regulation of programmed cell death. A caspase-2 minigene construct has been made that can be alternatively spliced in transfected cells and in nuclear extracts. Using this system, we have identified a 100-nt region in downstream intron 9 that inhibits the inclusion of the 61-bp alternative exon. This element (In100) can facilitate exon skipping in the context of competing 3' or 5' splice sites, but not in single-intron splicing units. The In100 element is also active in certain heterologous pre-mRNAs, although in a highly context-dependent manner. Interestingly, we found that In100 contains a sequence that highly resembles a bona fide 3' splice site. We provide evidence that this sequence acts as a "decoy" acceptor site that engages in U2 snRNP-dependent but nonproductive splicing complexes with the 5' splice site of exon 9, hence conferring competitive advantage to the exon-skipping splicing event (E8-E10). These results reveal a mechanism of action for a negative intronic regulatory element and uncover a role for U2 snRNP in the regulation of alternative splicing.

Caspase-2 pre-mRNA alternative splicing: Identification of an intronic element containing a decoy 3' acceptor site

We have established a model system using the caspase-2 pre-mRNA and initiated a study on the role of alternative splicing in regulation of programmed cell death. A caspase-2 minigene construct has been made that can be alternatively spliced in transfected cells and in nuclear extracts. Using this system, we have identified a 100-nt region in downstream intron 9 that inhibits the inclusion of the 61-bp alternative exon. This element (In100) can facilitate exon skipping in the context of competing 3' or 5' splice sites, but not in single-intron splicing units. The In100 element is also active in certain heterologous pre-mRNAs, although in a highly context-dependent manner. Interestingly, we found that In100 contains a sequence that highly resembles a bona fide 3' splice site. We provide evidence that this sequence acts as a "decoy" acceptor site that engages in U2 snRNP-dependent but nonproductive splicing complexes with the 5' splice site of exon 9, hence conferring competitive advantage to the exon-skipping splicing event (E8-E10). These results reveal a mechanism of action for a negative intronic regulatory element and uncover a role for U2 snRNP in the regulation of alternative splicing.

Nuclear export of heat shock and non-heat-shock mRNA occurs via similar pathways

Several studies of the yeast Saccharomyces cerevisiae support differential regulation of heat shock mRNA (hs mRNA) and non-hs mRNA nuclear export during stress. These include the finding that hs mRNA export at 42 degrees C is inhibited in the absence of the nucleoporinlike protein Rip1p (also called Nup42p) (C. A. Saavedra, C. M. Hammell, C. V. Heath, and C. N. Cole, Genes Dev. 11:2845-2856, 1997; F. Stutz, J. Kantor, D. Zhang, T. McCarthy, M. Neville, and M. Rosbash, Genes Dev. 11:2857-2868, 1997). However, the results reported in this paper provide little evidence for selective non-hs mRNA retention or selective hs mRNA export under heat shock conditions. First, we do not detect a block to non-hs mRNA export at 42 degrees C in a wild-type strain. Second, hs mRNA export appears to be mediated by the Ran system and several other factors previously reported to be important for general mRNA export. Third, the export of non-hs mRNA as well as hs mRNA is inhibited in the absence of Rip1p at 42 degrees C. As a corollary, we find no evidence for cis-acting hs mRNA sequences that promote transport during heat shock. Taken together, our data suggest that a shift to 42 degrees C in the absence of Rip1p impacts a late stage of transport affecting most if not all mRNA.

The human papillomavirus type 16 negative regulatory RNA element interacts with three proteins that act at different posttranscriptional levels

In human papillomaviruses, expression of the late genes L1 and L2, encoding the capsid proteins, is restricted to the upper layers of the infected epithelium. A 79-nt GU-rich negative regulatory element (NRE) located at the 3' untranslated region of the human papillomavirus 16 L1 gene was identified previously as key to the posttranscriptional control of late gene expression. Here, we demonstrate that in epithelial cells, the NRE can directly bind the U2 auxiliary splicing factor 65-kDa subunit, the cleavage stimulation factor 64-kDa subunit, and the Elav-like HuR protein. On induction of epithelial cell differentiation, levels of the U2 auxiliary splicing factor 65-kDa subunit decrease, levels of the cleavage stimulation factor 64-kDa subunit increase, and the levels of HuR remain unchanged, although redistribution of the HuR from the nucleus to the cytoplasm is observed. Late gene transcripts, which appear to be fully processed, are detected in undifferentiated W12 cells, but are confined in the nucleus. We propose that repression of late gene expression in basal epithelial cells may be caused by nuclear retention or cytoplasmic instability of NRE-containing late gene transcripts.

Functional characterization of five eIF4E isoforms in Caenorhabditis elegans

Recognition of the 5'-cap structure of mRNA by eIF4E is a critical step in the recruitment of most mRNAs to the ribosome. In Caenorhabditis elegans, approximately 70% of mRNAs contain an unusual 2,2,7-trimethylguanosine cap structure as a result of trans-splicing onto the 5' end of the pre-mRNA. The characterization of three eIF4E isoforms in C. elegans (IFE-1, IFE-2, and IFE-3) was reported previously. The present study describes two more eIF4E isoforms expressed in C. elegans, IFE-4 and IFE-5. We analyzed the requirement of each isoform for viability by RNA interference. IFE-3, the most closely related to mammalian eIF4E-1, binds only 7-methylguanosine caps and is essential for viability. In contrast, three closely related isoforms (IFE-1, IFE-2, and IFE-5) bind 2,2, 7-trimethylguanosine caps and are partially redundant, but at least one functional isoform is required for viability. IFE-4, which binds only 7-methylguanosine caps, is most closely related to an unusual eIF4E isoform found in plants (nCBP) and mammals (4E-HP) and is not essential for viability in any combination of IFE knockout. ife-2, ife-3, ife-4, and ife-5 mRNAs are themselves trans-spliced to SL1 spliced leaders. ife-1 mRNA is trans-spliced to an SL2 leader, indicating that its gene resides in a downstream position of an operon.

Both subunits of U2AF recognize the 3' splice site in Caenorhabditis elegans

Introns are defined by sequences that bind components of the splicing machinery. The branchpoint consensus, polypyrimidine (poly(Y)) tract, and AG at the splice boundary comprise the mammalian 3' splice site. Although the AG is crucial for the recognition of introns with relatively short poly(Y) tracts, which are termed 'AG-dependent introns', the molecule responsible for AG recognition has never been identified. A key player in 3' splice site definition is the essential heterodimeric splicing factor U2AF, which facilitates the interaction of the U2 small nuclear ribonucleoprotein particle with the branch point. The U2AF subunit with a relative molecular mass (Mr 65K) of 65,000 (U2AF65) binds to the poly(Y) tract, whereas the role of the 35K subunit (U2AF35) has not been clearly defined. It is not required for splicing in vitro but it plays a critical role in vivo. Caenorhabditis elegans introns have a highly conserved U4CAG/ R at their 3' splice sites instead of branch-point and poly(Y) consensus sequences. Nevertheless, C. elegans has U2AF, 12). Here we show that both U2AF subunits crosslink to the 3' splice site. Our results suggest that the U2AF65-U2AF35 complex identifies the U4CAG/R, with U2AF35 being responsible for recognition of the canonical AG.