Preservation of forelimb function by UPF1 gene therapy in a rat model of TDP-43-induced motor paralysis

Nonsense-mediated mRNA decay (NMD) is an RNA surveillance mechanism that requires upframeshift protein 1 (UPF1). This study demonstrates that human UPF1 exerts protective effects in a rat paralysis model based on the amyotrophic lateral sclerosis (ALS)-associated protein, TDP-43 (transactive response DNA-binding protein 43 kDa). An adeno-associated virus vector (AAV9) was used to express TDP-43 throughout the spinal cord of rats, inducing reproducible limb paralysis, to recapitulate the paralysis in ALS. We selected UPF1 for therapeutic testing based on a genetic screen in yeast. The expression of human TDP-43 or human UPF1 in the spinal cord was titrated to less than twofold over the respective endogenous level. AAV9 human mycUPF1 clearly improved overall motor scores in rats also expressing TDP-43. The gene therapy effect of mycUPF1 was specific and reproducible compared with groups receiving either empty vector or green fluorescent protein vector controls. The gene therapy maintained forelimb motor function in rats that would otherwise become quadriplegic. This work helps validate UPF1 as a novel therapeutic for ALS and other TDP-43-related diseases and may implicate UPF1 and NMD involvement in the underlying disease mechanisms.

CBP80-promoted mRNP rearrangements during the pioneer round of translation, nonsense-mediated mRNA decay, and thereafter

In mammalian cells, two different messenger ribonucleoproteins (mRNPs) serve as templates for protein synthesis. Newly synthesized mRNPs bound by the cap-binding protein heterodimer CBP80-CBP20 (CBC) initially undergo a pioneer round of translation. One purpose of this round of translation is to ensure the quality of gene expression, as exemplified by nonsense-mediated messenger RNA (mRNA) decay (NMD). NMD largely functions to eliminate mRNAs that prematurely terminate translation, although NMD also contributes to proper gene control, and it targets CBC-bound mRNPs. CBC-bound mRNPs are remodeled to eukaryotic translation initiation factor (eIF)4E-bound mRNPs in steps that (1) are a consequence of the pioneer round of translation and (2) occur independently of translation. Rather than supporting NMD, eIF4E-bound mRNPs provide for the bulk of cellular protein synthesis and are the primary targets of mRNA decay mechanisms that conditionally regulate gene expression. Here, we overview cellular processes by which CBC-bound mRNPs are remodeled to eIF4E-bound mRNPs. We also describe the molecular movements of certain factors during NMD in view of the influential role of CBP80.

Evidence for a pioneer round of mRNA translation: mRNAs subject to nonsense-mediated decay in mammalian cells are bound by CBP80 and CBP20

Nonsense-mediated decay (NMD) eliminates mRNAs that prematurely terminate translation. We used antibody to the nuclear cap binding protein CBP80 or its cytoplasmic counterpart eIF4E to immunopurify RNP containing nonsense-free or nonsense-containing transcripts. Data indicate that NMD takes place in association with CBP80. We defined other components of NMD-susceptible mRNP as CBP20, PABP2, eIF4G, and the NMD factors Upf2 and Upf3. Consistent with the dependence of NMD on translation, the NMD of CBP80-bound mRNA is blocked by cycloheximide or suppressor tRNA. These findings provide evidence that translation can take place in association with CBP80. They also indicate that CBP80-bound mRNA undergoes a "pioneer" round of translation, before CBP80-CBP20 are replaced by eIF4E, and Upf2 and Upf3 proteins dissociate from upstream of exon-exon junctions.

Cloning of a novel phosphatidylinositol kinase-related kinase: characterization of the human SMG-1 RNA surveillance protein

We have cloned and characterized a new member of the phosphatidylinositol kinase (PIK)-related kinase family. This gene, which we term human SMG-1 (hSMG-1), is orthologous to Caenorhabditis elegans SMG-1, a protein that functions in nonsense-mediated mRNA decay (NMD). cDNA sequencing revealed that hSMG-1 encodes a protein of 3031 amino acids containing a conserved kinase domain, a C-terminal domain unique to the PIK-related kinases and an FKBP12-rapamycin binding-like domain similar to that found in the PIK-related kinase mTOR. Immunopurified FLAG-tagged hSMG-1 exhibits protein kinase activity as measured by autophosphorylation and phosphorylation of the generic PIK-related kinase substrate PHAS-1. hSMG-1 kinase activity is inhibited by high nanomolar concentrations of wortmannin (IC(50) = 105 nm) but is not inhibited by a FKBP12-rapamycin complex. Mutation of conserved residues within the kinase domain of hSMG-1 abolishes both autophosphorylation and substrate phosphorylation, demonstrating that hSMG-1 exhibits intrinsic protein kinase activity. hSMG-1 phosphorylates purified hUpf1 protein, a phosphoprotein that plays a critical role in NMD, at sites that are also phosphorylated in whole cells. Based on these data, we conclude that hSMG-1 is the human orthologue to C. elegans SMG-1. Our data indicate that hSMG-1 may function in NMD by directly phosphorylating hUpf1 protein at physiologically relevant sites.

Nonsense-mediated decay of mRNA for the selenoprotein phospholipid hydroperoxide glutathione peroxidase is detectable in cultured cells but masked or inhibited in rat tissues

Previous studies of mRNA for classical glutathione peroxidase 1 (GPx1) demonstrated that hepatocytes of rats fed a selenium-deficient diet have less cytoplasmic GPx1 mRNA than hepatocytes of rats fed a selenium-adequate diet. This is because GPx1 mRNA is degraded by the surveillance pathway called nonsense-mediated mRNA decay (NMD) when the selenocysteine codon is recognized as nonsense. Here, we examine the mechanism by which the abundance of phospholipid hydroperoxide glutathione peroxidase (PHGPx) mRNA, another selenocysteine-encoding mRNA, fails to decrease in the hepatocytes and testicular cells of rats fed a selenium-deficient diet. We demonstrate with cultured NIH3T3 fibroblasts or H35 hepatocytes transiently transfected with PHGPx gene variants under selenium-supplemented or selenium-deficient conditions that PHGPx mRNA is, in fact, a substrate for NMD when the selenocysteine codon is recognized as nonsense. We also demonstrate that the endogenous PHGPx mRNA of untransfected H35 cells is subject to NMD. The failure of previous reports to detect the NMD of PHGPx mRNA in cultured cells is likely attributable to the expression of PHGPx cDNA rather than the PHGPx gene. We conclude that 1) the sequence of the PHGPx gene is adequate to support the NMD of product mRNA, and 2) there is a mechanism in liver and testis but not cultured fibroblasts and hepatocytes that precludes or masks the NMD of PHGPx mRNA.

Mammalian heat shock p70 and histone H4 transcripts, which derive from naturally intronless genes, are immune to nonsense-mediated decay

Nonsense-mediated decay (NMD), also called mRNA surveillance, is an evolutionarily conserved pathway that degrades mRNAs that prematurely terminate translation. To date, the pathway in mammalian cells has been shown to depend on the presence of a cis-acting destabilizing element that usually consists of an exon-exon junction generated by the process of pre-mRNA splicing. Whether or not mRNAs that derive from naturally intronless genes, that is, mRNAs not formed by the process of splicing, are also subject to NMD has yet to be investigated. The possibility of NMD is certainly reasonable considering that mRNAs of Saccharomyces cerevisiae are subject to NMD even though most derive from naturally intronless genes. In fact, mRNAs of S. cerevisiae generally harbor a loosely defined splicing-independent destabilizing element that has been proposed to function in NMD analogously to the spliced exon-exon junction of mammalian mRNAs. Here, we demonstrate that nonsense codons introduced into naturally intronless genes encoding mouse heat shock protein 70 or human histone H4 fail to elicit NMD. Failure is most likely because each mRNA lacks a cis-acting destabilizing element, because insertion of a spliceable intron a sufficient distance downstream of a nonsense codon within either gene is sufficient to elicit NMD.

Evidence that selenium deficiency results in the cytoplasmic decay of GPx1 mRNA dependent on pre-mRNA splicing proteins bound to the mRNA exon-exon junction

Studies of transcripts for the selenoprotein glutathione peroxidase 1 (GPx1) have provided remarkable evidence for the coupling of pre-mRNA splicing in the nucleus and mRNA translation in the cytoplasm. Such evidence derives from the initial finding that GPx1 mRNA is a natural substrate of nonsense-mediated decay. Here, recent work on GPx1 RNA metabolism is reviewed and future directions of study are defined.

Identification and characterization of human orthologues to Saccharomyces cerevisiae Upf2 protein and Upf3 protein (Caenorhabditis elegans SMG-4)

Nonsense-mediated mRNA decay (NMD), also called mRNA surveillance, is an important pathway used by all organisms that have been tested to degrade mRNAs that prematurely terminate translation and, as a consequence, eliminate the production of aberrant proteins that could be potentially harmful. In mammalian cells, NMD appears to involve splicing-dependent alterations to mRNA as well as ribosome-associated components of the translational apparatus. To date, human (h) Upf1 protein (p) (hUpf1p), a group 1 RNA helicase named after its Saccharomyces cerevisiae orthologue that functions in both translation termination and NMD, has been the only factor shown to be required for NMD in mammalian cells. Here, we describe human orthologues to S. cerevisiae Upf2p and S. cerevisiae Upf3p (Caenorhabditis elegans SMG-4) based on limited amino acid similarities. The existence of these orthologues provides evidence for a higher degree of evolutionary conservation of NMD than previously appreciated. Interestingly, human orthologues to S. cerevisiae Upf3p (C. elegans SMG-4) derive from two genes, one of which is X-linked and both of which generate multiple isoforms due to alternative pre-mRNA splicing. We demonstrate using immunoprecipitations of epitope-tagged proteins transiently produced in HeLa cells that hUpf2p interacts with hUpf1p, hUpf3p-X, and hUpf3p, and we define the domains required for the interactions. Furthermore, we find by using indirect immunofluorescence that hUpf1p is detected only in the cytoplasm, hUpf2p is detected primarily in the cytoplasm, and hUpf3p-X localizes primarily to nuclei. The finding that hUpf3p-X is a shuttling protein provides additional indication that NMD has both nuclear and cytoplasmic components.

Evidence that phosphorylation of human Upfl protein varies with intracellular location and is mediated by a wortmannin-sensitive and rapamycin-sensitive PI 3-kinase-related kinase signaling pathway

Human Upf1 protein (p), a group 1 RNA helicase, has recently been shown to function in nonsense-mediated mRNA decay (NMD) in mammalian cells. Here, we demonstrate that the estimated 3 x 10(6) copies of hUpf1 p per exponentially growing HeLa cell are essentially equally distributed among polysomal, subpolysomal, and ribosome-free fractions. We also demonstrate that hUpf1p binds RNA and is a phosphoprotein harboring phosphoserine and phosphothreonine. hUpf1p is phosphorylated to the highest extent when polysome-associated and to the lowest extent when ribosome free. We find that serum-induced phosphorylation of hUpf1p is inhibited by wortmannin at a concentration that selectively inhibits PI 3-kinase related kinases and, to a lesser extent, by rapamycin. These and other data suggest that phosphorylation is mediated by a wortmannin-sensitive and rapamycin-sensitive PI 3-kinase-related kinase signaling pathway. Comparisons are made of hUpf1p to Upf1p and SMG-2, which are the orthologs to hUpf1p in Saccharomyces cerevisiae and Caenorhabditis elegans, respectively.

The spliceosome deposits multiple proteins 20-24 nucleotides upstream of mRNA exon-exon junctions

Eukaryotic mRNAs exist in vivo as ribonucleoprotein particles (mRNPs). The protein components of mRNPs have important functions in mRNA metabolism, including effects on subcellular localization, translational efficiency and mRNA half-life. There is accumulating evidence that pre-mRNA splicing can alter mRNP structure and thereby affect downstream mRNA metabolism. Here, we report that the spliceosome stably deposits several proteins on mRNAs, probably as a single complex of approximately 335 kDa. This complex protects 8 nucleotides of mRNA from complete RNase digestion at a conserved position 20-24 nucleotides upstream of exon-exon junctions. Splicing-dependent RNase protection of this region was observed in both HeLa cell nuclear extracts and Xenopus laevis oocyte nuclei. Immunoprecipitations revealed that five components of the complex are the splicing-associated factors SRm160, DEK and RNPS1, the mRNA-associated shuttling protein Y14 and the mRNA export factor REF. Possible functions for this complex in nucleocytoplasmic transport of spliced mRNA, as well as the nonsense-mediated mRNA decay pathway, are discussed.

Nonsense-mediated decay of glutathione peroxidase 1 mRNA in the cytoplasm depends on intron position

mRNA for glutathione peroxidase 1 (GPx1) is subject to cytoplasmic nonsense-mediated decay (NMD) when the UGA selenocysteine (Sec) codon is recognized as nonsense. Here, we demonstrate by moving the sole intron of the GPx1 gene that either the Sec codon or a TAA codon in its place elicits NMD when located >/=59 bp but not </=43 bp upstream of the intron. Therefore, the exon-exon junction of GPx1 mRNA positions the boundary between nonsense codons that do and do not elicit NMD, as has been shown for the 3'-most junctions of mRNAs subject to nucleus-associated NMD. We also demonstrate by using a regulatable promoter to drive GPx1 gene expression that cytoplasmic NMD is characteristic of steady-state mRNA, in contrast to nucleus-associated NMD. These findings clarify the mechanistic relationship between cytoplasmic and nucleus-associated NMD and offer the first demonstration that nuclear introns can influence cytoplasmic NMD. Finally, by analyzing hybrid GPx1 genes, we disprove the idea that the cellular site of NMD is determined by the efficiency of translation initiation.

Pre-mRNA splicing alters mRNP composition: evidence for stable association of proteins at exon-exon junctions

We provide direct evidence that pre-mRNA splicing alters mRNP protein composition. Using a novel in vitro cross-linking approach, we detected several proteins that associate with mRNA exon-exon junctions only as a consequence of splicing. Immunoprecipitation experiments suggested that these proteins are part of a tight complex around the junction. Two were identified as SRm160, a nuclear matrix-associated splicing coactivator, and hPrp8p, a core component of U5 snRNP and spliceosomes. Glycerol gradient fractionation showed that a subset of these proteins remain associated with mRNA after its release from the spliceosome. These results demonstrate that the spliceosome can leave behind signature proteins at exon-exon junctions. Such proteins could influence downstream metabolic events in vivo such as mRNA transport, translation, and nonsense-mediated decay.

At least one intron is required for the nonsense-mediated decay of triosephosphate isomerase mRNA: a possible link between nuclear splicing and cytoplasmic translation

Mammalian cells have established mechanisms to reduce the abundance of mRNAs that harbor a nonsense codon and prematurely terminate translation. In the case of the human triosephosphate isomerase (TPI gene), nonsense codons located less than 50 to 55 bp upstream of intron 6, the 3'-most intron, fail to mediate mRNA decay. With the aim of understanding the feature(s) of TPI intron 6 that confer function in positioning the boundary between nonsense codons that do and do not mediate decay, the effects of deleting or duplicating introns have been assessed. The results demonstrate that TPI intron 6 functions to position the boundary because it is the 3'-most intron. Since decay takes place after pre-mRNA splicing, it is conceivable that removal of the 3'-most intron from pre-mRNA "marks" the 3'-most exon-exon junction of product mRNA so that only nonsense codons located more than 50 to 55 nucleotides upstream of the "mark" mediate mRNA decay. Decay may be elicited by the failure of translating ribosomes to translate sufficiently close to the mark or, more likely, the scanning or looping out of some component(s) of the translation termination complex to the mark. In support of scanning, a nonsense codon does not elicit decay if some of the introns that normally reside downstream of the nonsense codon are deleted so the nonsense codon is located (i) too far away from a downstream intron, suggesting that all exon-exon junctions may be marked, and (ii) too far away from a downstream failsafe sequence that appears to function on behalf of intron 6, i.e., when intron 6 fails to leave a mark. Notably, the proposed scanning complex may have a greater unwinding capability than the complex that scans for a translation initiation codon since a hairpin structure strong enough to block translation initiation when inserted into the 5' untranslated region does not block nonsense-mediated decay when inserted into exon 6 between a nonsense codon residing in exon 6 and intron 6.

A mutated human homologue to yeast Upf1 protein has a dominant-negative effect on the decay of nonsense-containing mRNAs in mammalian cells

All eukaryotic cells analyzed have developed mechanisms to eliminate the production of mRNAs that prematurely terminate translation. The mechanisms are thought to exist to protect cells from the deleterious effects of in-frame nonsense codons that are generated by routine inefficiencies and inaccuracies in RNA metabolism such as pre-mRNA splicing. Depending on the particular mRNA and how it is produced, nonsense codons can mediate a reduction in mRNA abundance either (i) before its release from an association with nuclei into the cytoplasm, presumably but not certainly while the mRNA is being exported to the cytoplasm and translated by cytoplasmic ribosomes, or (ii) in the cytoplasm. Here, we provide evidence for a factor that functions to eliminate the production of nonsense-containing RNAs in mammalian cells. The factor, variously referred to as Rent1 (regulator of nonsense transcripts) or HUPF1 (human Upf1 protein), was identified by isolating cDNA for a human homologue to Saccharomyces cerevisiae Upf1p, which is a group I RNA helicase that functions in the nonsense-mediated decay of mRNA in yeast. Using monkey COS cells and human HeLa cells, we demonstrate that expression of human Upf1 protein harboring an arginine-to-cysteine mutation at residue 844 within the RNA helicase domain acts in a dominant-negative fashion to abrogate the decay of nonsense-containing mRNA that takes place (i) in association with nuclei or (ii) in the cytoplasm. These findings provide evidence that nonsense-mediated mRNA decay is related mechanistically in yeast and in mammalian cells, regardless of the cellular site of decay.

Intron function in the nonsense-mediated decay of beta-globin mRNA: indications that pre-mRNA splicing in the nucleus can influence mRNA translation in the cytoplasm

Generally, mRNAs that prematurely terminate translation are abnormally low in abundance. In the case of mammalian cells, nonsense codons most often mediate a reduction in the abundance of newly synthesized, nucleus-associated mRNA by a mechanism that is not well understood. With the aim of defining cis-acting sequences that are important to the reduction process, the effects of particular beta-globin gene rearrangements on the metabolism of beta-globin mRNAs harboring one of a series of nonsense codons have been assessed. Results indicate that nonsense codons located 54 bp or more upstream of the 3'-most intron, intron 2, reduce the abundance of nucleus-associated mRNA to 10-15% of normal without altering the level of either of the two introns within pre-mRNA. The level of cytoplasmic mRNA is also reduced to 10-15% of normal, indicating that decay does not take place once the mRNA is released from an association with nuclei into the cytoplasm. A nonsense codon within exon 2 that does not reduce mRNA abundance can be converted to the type that does by (1) inserting a sufficiently large in-frame sequence immediately upstream of intron 2 or (2) deleting and reinserting intron 2 a sufficient distance downstream of its usual position. These findings indicate that only those nonsense codons located more than 54 bp upstream of the 3'-most intron reduce beta-globin mRNA abundance, which is remarkably consistent with which nonsense codons within the triosephosphate isomerase (TPI) gene reduce TPI mRNA abundance. We propose that the 3'-most exon-exon junction of beta-globin mRNA and, possibly, most mRNAs is marked by the removal of the 3'-most intron during pre-mRNA splicing and that the "mark" accompanies mRNA during transport to the cytoplasm. When cytoplasmic ribosomes terminate translation more than 54 nt upstream of the mark during or immediately after transport, the mRNA is subjected to nonsense-mediated decay. The finding that deletion of beta-globin intron 2 does not appreciably alter the effect of any nonsense codon on beta-globin mRNA abundance suggests that another cis-acting sequence functions in nonsense-mediated decay comparably to intron 2, at least in the absence of intron 2, possibly as a fail-safe mechanism. The analysis of deletions and insertions indicates that this sequence resides within the coding region and can be functionally substituted by intron 2.

Selenium deficiency reduces the abundance of mRNA for Se-dependent glutathione peroxidase 1 by a UGA-dependent mechanism likely to be nonsense codon-mediated decay of cytoplasmic mRNA

The mammalian mRNA for selenium-dependent glutathione peroxidase 1 (Se-GPx1) contains a UGA codon that is recognized as a codon for the nonstandard amino acid selenocysteine (Sec). Inadequate concentrations of selenium (Se) result in a decrease in Se-GPx1 mRNA abundance by an uncharacterized mechanism that may be dependent on translation, independent of translation, or both. In this study, we have begun to elucidate this mechanism. We demonstrate using hepatocytes from rats fed either a Se-supplemented or Se-deficient diet for 9 to 13 weeks that Se deprivation results in an approximately 50-fold reduction in Se-GPx1 activity and an approximately 20-fold reduction in Se-GPx1 mRNA abundance. Reverse transcription-PCR analyses of nuclear and cytoplasmic fractions revealed that Se deprivation has no effect on the levels of either nuclear pre-mRNA or nuclear mRNA but reduces the level of cytoplasmic mRNA. The regulation of Se-GPx1 gene expression by Se was recapitulated in transient transfections of NIH 3T3 cells, and experiments were extended to examine the consequences of converting the Sec codon (TGA) to either a termination codon (TAA) or a cysteine codon (TGC). Regardless of the type of codon, an alteration in the Se concentration was of no consequence to the ratio of nuclear Se-GPx1 mRNA to nuclear Se-GPx1 pre-mRNA. The ratio of cytoplasmic Se-GPx1 mRNA to nuclear Se-GPx1 mRNA from the wild-type (TGA-containing) allele was reduced twofold when cells were deprived of Se for 48 h after transfection, which has been shown to be the extent of the reduction for the endogenous Se-GPx1 mRNA of cultured cells incubated as long as 20 days in Se-deficient medium. In contrast to the TGA allele, Se had no effect on expression of either the TAA allele or the TGC allele. Under Se-deficient conditions, the TAA and TGC alleles generated, respectively, 1.7-fold-less and 3-fold-more cytoplasmic Se-GPx1 mRNA relative to the amount of nuclear Se-GPx1 mRNA than the TGA allele. These results indicate that (i) under conditions of Se deprivation, the Sec codon reduces the abundance of cytoplasmic Se-GPx1 mRNA by a translation-dependent mechanism and (ii) there is no additional mechanism by which Se regulates Se-GPx1 mRNA production. These data suggest that the inefficient incorporation of Sec at the UGA codon during mRNA translation augments the nonsense-codon-mediated decay of cytoplasmic Se-GPx1 mRNA.

Evidence that translation reinitiation abrogates nonsense-mediated mRNA decay in mammalian cells

Nonsense codons upstream of and including position 192 of the human gene for triosephosphate isomerase (TPI) have been found to reduce the abundance of TPI mRNA to approximately 25% of normal. The reduction is due to the decay of newly synthesized TPI mRNA that co-purifies with nuclei. TPI mRNA that co-purifies with cytoplasm is immune to nonsense-mediated decay. Until now, a nonsense codon at position 23 has been the 5'-most nonsense codon that has been analyzed. Here, we provide evidence that a nonsense codon at position 1, 2 or 10 reduces the abundance of nucleus-associated TPI mRNA to an average of only 84% of normal because translation reinitiates at the methionine codon at position 14. First, converting codon 14 to one for valine increased the effectiveness with which an upstream nonsense codon reduces mRNA abundance. Second, when TPI gene sequences, including codon 14, were fused upstream of and in-frame to the translational reading frame of an Escherichia coli chloramphenicol acetyl transferase (CAT) gene that lacked an initiation codon, a nonsense codon at TPI position 1 or 2 allowed for the production of TPI-CAT that was an estimated 14 amino acids smaller than TPI-CAT produced by a nonsense-free gene, whereas a nonsense codon at TPI position 23 precluded the production of TPI-CAT. These and related findings lend credence to the concept that the nonsense-mediated reduction in the half-life of nucleus-associated TPI mRNA involves cytoplasmic ribosomes.

Evidence that the decay of nucleus-associated nonsense mRNA for human triosephosphate isomerase involves nonsense codon recognition after splicing

For most of the mammalian mRNAs that have been shown to be reduced in abundance by a nonsense or a frameshift mutation that generates a nonsense codon, reduction takes place while the mRNA is nucleus-associated rather than after the mRNA has been exported to the cytoplasm (reviewed in Maquat LE, 1995, RNA 1:453-465). A variety of mechanisms have been put forth to explain how a nonsense codon could affect the abundance of nuclear mRNA. Some mechanisms have implicated nonsense codon recognition in the nucleus prior to splicing. Among the best-studied nonsense transcripts that manifest nonsense-mediated alterations in nucleus-associated metabolism are those that derive from human alleles for the glycolytic enzyme triosephosphate isomerase (TPI). Nonsense codons within TPI transcripts have been shown to reduce the half-life of completely spliced TPI (mRNA that co-purifies with nuclei (Belgrader P et al., 1994, Mol Cell Biol 14:8219-8228). However, whether or not nonsense codon recognition within TPI transcripts takes place prior to or after splicing remained unresolved. To address this issue, codons that span two exons, i.e., are disrupted by an intron prior to pre-mRNA splicing, were converted to nonsense. If nonsense codon recognition were to precede splicing, then the disrupting intron would be expected to preclude nonsense codon recognition by preventing the physical juxtapositioning of the codon nucleotides. In the absence of nonsense codon recognition, there would be no nonsense-mediated reduction in TPI mRNA abundance. The results of northern (RNA) blot hybridization demonstrated that the two nonsense codons of this type that were studied reduced the level of total, nuclear and cytoplasmic TPI mRNA to an average of 12% of normal, consistent with each nonsense codon being competent to mediate nuclear mRNA degradation. The possibility that the nonsense codons reduced TPI mRNA abundance by altering TPI mRNA abundance or splicing was eliminated by using RT-PCR to demonstrate that the level of each intron within pre-mRNA was essentially unaffected and cDNA sequencing to demonstrate that splice site choice was unaltered. Furthermore, missense codons that harbored some of the nonsense codon changes were found to have little effect on mRNA abundance. These findings, plus the previous finding that a suppressor tRNA abrogates the decay of TPI mRNA brought about by a nonsense codon residing within a single exon (Belgrader P, Cheng J, Maquat LE, 1993, Proc Natl Acad Sci USA 90:482-486), argue strongly that nonsense codon recognition in the nonsense-mediated decay of TPI mRNA takes place after splicing.

Cytoplasmic mRNA for human triosephosphate isomerase is immune to nonsense-mediated decay despite forming polysomes

Nonsense codons between position 14 within the first exon and position 193 within the penultimate exon of the human gene for triosephosphate isomerase reduce mRNA abundance to 25% of normal. The reduction in abundance is due to the decay of newly synthesized mRNA that copurifies with nuclei. TPI mRNA that copurifies with cytoplasm is immune to decay. We show here that immunity is not due to the failure of nonsense-containing mRNA to form polysomes. This finding indicates that cytoplasmic mRNA, in contrast to nucleus-associated mRNA, may have lost one or more factors that are required for nonsense-mediated decay or gained one or more factors that confer immunity to nonsense-mediated decay.

When cells stop making sense: effects of nonsense codons on RNA metabolism in vertebrate cells

It appears that no organism is immune to the effects of nonsense codons on mRNA abundance. The study of how nonsense codons alter RNA metabolism is still at an early stage, and our current understanding derives more from incidental vignettes than from experimental undertakings that address molecular mechanisms. Challenges for the future include identifying the gene products and RNA sequences that function in nonsense mediated RNA loss, resolving the cause and consequences of there apparently being more than one cellular site and mechanism for nonsense-mediated RNA loss, and understanding how these sites and mechanisms are related to both constitutive and specialized pathways of pre-mRNA processing and mRNA decay.

Lack of an effect of the efficiency of RNA 3'-end formation on the efficiency of removal of either the final or the penultimate intron in intact cells

Evidence exists from studies using intact cells that intron removal can be influenced by the reactivity of upstream and downstream splice sites and that cleavage and polyadenylation can be influenced by the reactivity of upstream splice sites. These results indicate that sequences within 3'-terminal introns can function in the removal of upstream introns as well as the formation of RNA 3' ends. Evidence from studies using intact cells for an influence of RNA 3'-end formation on intron removal is lacking. We report here that mutations within polyadenylation sequences that either decrease or increase the efficiency of RNA 3'-end formation have no effect on the efficiencies with which either the 3'-terminal or the penultimate intron is removed by splicing. Northern (RNA) blot hybridization, RNase mapping, and an assay that couples reverse transcription and PCR were used to analyze the effects of deletions and a substitution of the polyadenylation sequences within the human gene for triosephosphate isomerase (TPI). TPI pre-mRNA harbors six introns that are constitutively removed by splicing. Relative to normal levels, each of the deletions was found to reduce the nuclear and cytoplasmic levels of TPI mRNA, increase the nuclear level of unprocessed RNA 3' ends, and decrease the nuclear level of processed RNA 3' ends. The simplest interpretation of these data indicates that (i) the rate of 3'-end formation normally limits the amount of mRNA produced and (ii) the deletions decrease and the substitution increases the efficiency of RNA 3'-end formation. While each of the deletions and the substitution altered the absolute levels of intron 6-containing, intron 5-containing, intron 6-free, and intron 5-free RNAs, in no case was there an abnormal ratio of intron-containing to intron-free RNA for either intron. Therefore, at least for TPI RNA, while the efficiency of removal of the 3'-terminal intron influences the efficiency of removal of either the 3'-end formation, the efficiency of RNA 3'-end formation does not influence the efficiency of removal of either the 3'-terminal or penultimate intron. The dependence of TPI RNA 3'-end formation on splicing may reflect the suboptimal strengths of the corresponding regulatory sequences and may function to ensure that TPI pre-mRNA is not released from the chromatin template until it has formed a complex with spliceosomes. If so, then the independence of TPI RNA splicing on 3'-end formation may be rationalized by the lack of a comparable function.

Mammalian nonsense codons can be cis effectors of nuclear mRNA half-life

Frameshift and nonsense mutations within the gene for human triosephosphate isomerase (TPI) that generate a nonsense codon within the first three-fourths of the protein coding region have been found to reduce the abundance of the product mRNA that copurifies with nuclei. The cellular process and location of the nonsense codon-mediated reduction have proven difficult to elucidate for technical reasons. We show here, using electron microscopy to judge the purity of isolated nuclei, that the previously established reduction to 25% of the normal mRNA level is evident for nuclei that are free of detectable cytoplasmic contamination. Therefore, the reduction is likely to be characteristic of bona fide nuclear RNA. Fully spliced nuclear mRNA is identified by Northern (RNA) blot hybridization and a reverse transcription-PCR assay as the species that undergoes decay in experiments that used the human c-fos promoter to elicit a burst and subsequent shutoff of TPI gene transcription upon the addition of serum to serum-deprived cells. Finally, the finding that deletion of a 5' splice site of the TPI gene results predominantly but not exclusively in the removal by splicing (i.e., skipping) of the upstream exon as a part of the flanking introns has been used to demonstrate that decay is specific to those mRNA products that maintain the nonsense codon. This result, together with our previous results that implicate translation by ribosomes and charged tRNAs in the decay mechanism, indicate that nonsense codon recognition takes place after splicing and triggers decay solely in cis. The possibility that decay takes place during the process of mRNA export from the nucleus to the cytoplasm is discussed.

Nonsense but not missense mutations can decrease the abundance of nuclear mRNA for the mouse major urinary protein, while both types of mutations can facilitate exon skipping

In an effort to understand the mechanisms by which nonsense codons affect RNA metabolism in mammalian cells, nonsense mutations were generated within the gene for the secretory major urinary protein (MUP) of mice. The translation of MUP mRNA normally begins within exon 1 and terminates within exon 6, the penultimate exon. Through the use of Northern (RNA) blot hybridization and assays that couple reverse transcription and PCR, a nonsense mutation within codon 50 of exon 2 or codon 143 of exon 5 was found to reduce the abundance of fully spliced, nuclear MUP mRNA to 10 to 20% of normal without an additional reduction in the abundance of cytoplasmic mRNA. In contrast, a nonsense mutation within codon 172 of exon 5 was found to have no effects on the abundance of MUP mRNA. These findings suggest that a boundary between nonsense mutations that do and do not reduce the abundance of nuclear mRNA exists within the exon preceding the exon that harbors the normal site of translation termination. In this way, the boundary is analogous to the boundary that exists within the penultimate exon of the human gene for the cytosolic enzyme triosephosphate isomerase. Assays for exon skipping, i.e., the removal of an exon as a part of the flanking introns during the process of splicing, reveal that 0.1, 2.0, and 0.1% of MUP mRNA normally lack exon 5, exon 6, and exons 5 plus 6, respectively. Relative to normal, the two nonsense mutations within exon 5 increase the abundance of RNA lacking exon 5 on average 20-fold and increase the abundance of RNA lacking exons 5 plus 6 on average 5-fold. Since only one of these nonsense mutations also reduces the abundance of fully spliced nuclear mRNA to 10 to 20% of normal, the two mechanisms by which a nonsense mutation can alter nuclear RNA metabolism must be distinct. The analysis of missense mutations within codons 143 and 172, some of which retain the nonsense mutation, indicates that the reduction in the abundance of fully spliced nuclear mRNA is dependent upon the premature termination of MUP mRNA translation, whereas skipping is attributable to nonsense mutation-mediated changes in exon 5 structure rather than to the premature termination of translation. The increase in exon 5 skipping by either the nonsense or missense mutations within codon 172 correlates with a decrease in the complementarity of exon 5 to U1 snRNA. This suggests that a 5' splice site may extend as far as 12 nucleotides into the upstream exon, which is, to our knowledge, the largest extension.

Introns are cis effectors of the nonsense-codon-mediated reduction in nuclear mRNA abundance

The translation of human triosephosphate isomerase (TPI) mRNA normally terminates at codon 249 within exon 7, the final exon. Frameshift and nonsense mutations of the type that cause translation to terminate prematurely at or upstream of codon 189 within exon 6 reduce the level of nuclear TPI mRNA to 20 to 30% of normal by a mechanism that is not a function of the distance of the nonsense codon from either the translation initiation or termination codon. In contrast, frameshift and nonsense mutations of another type that cause translation to terminate prematurely at or downstream of codon 208, also within exon 6, have no effect on the level of nuclear TPI mRNA. In this work, quantitations of RNA that derived from TPI alleles in which nonsense codons had been generated between codons 189 and 208 revealed that the boundary between the two types of nonsense codons resides between codons 192 and 195. The analysis of TPI gene insertions and deletions indicated that the positional feature differentiating the two types of nonsense codons is the distance of the nonsense codon upstream of intron 6. For example, the movement of intron 6 to a position downstream of its normal location resulted in a concomitant downstream movement of the boundary between the two types of nonsense codons. The analysis of intron 6 mutations indicated that the intron 6 effect is stipulated by the 88 nucleotides residing between the 5' and 3' splice sites. Since the deletion of intron 6 resulted in only partial abrogation of the nonsense codon-mediated reduction in the level of TPI mRNA, other sequences within TPI pre-mRNA must function in the effect. One of these sequences may be intron 2, since the deletion of intron 2 also resulted in partial abrogation of the effect. In experiments that switched introns 2 and 6, the replacement of intron 6 with intron 2 was of no consequence to the effect of a nonsense codon within either exon 1 or exon 6. In contrast, the replacement of intron 2 with intron 6 was inconsequential to the effect of a nonsense codon in exon 6 but resulted in partial abrogation of a nonsense codon in exon 1.

Upstream introns influence the efficiency of final intron removal and RNA 3'-end formation

For all intron-containing pre-mRNAs of higher eukaryotes that have been examined using either living cells or cell-free extracts, a functional 3' splice site within the 3'-terminal intron is required for efficient RNA 3'-end formation. The mechanism by which intron sequences facilitate RNA 3'-end formation, which is achieved by endonucleolytic cleavage and polyadenylation, is not understood. We report here that in intact cells the efficiency of RNA 3'-end formation correlates with the efficiency of final intron removal, even when the intron is normally a 5'-terminal or internal intron. Therefore, the influence of the 3'-terminal intron on 3'-end formation is likely to be attributable to the determinants of splicing efficiency, which include but are not limited to the 3' splice site. Quantitative RNase mapping and methods that couple reverse transcription and the polymerase chain reaction were used to assess the consequence to RNA 3'-end formation of intron deletions within the human gene for triosephosphate isomerase (TPI). Results indicate that the formation of TPI RNA 3' ends requires TPI gene introns in addition to the last intron, intron 6, to proceed efficiently. These additional TPI gene introns are also required for the efficient removal of intron 6. When introns 1 and 5 were engineered to be the final intron, they were found, as was intron 6, to function in RNA 3'-end formation with an efficiency that correlated with their efficiency of removal. The simultaneous deletion of the 5' and 3' splice sites of intron 6 reduced the efficiencies of both RNA 3'-end formation and the removal of intron 5, which constituted the 3'-most functional intron. Deletion of only the 3' splice site of intron 6 precluded RNA 3'-end formation but had no effect on the efficiency of intron 5 removal. Deletion of only the 5' splice site of intron 6, which resulted in exon 6 skipping (i.e., the removal of intron 5, exon 6, and intron 6 as a single unit), had no effect on the efficiencies of either RNA 3'-end formation or the removal of intron 5-exon 6-intron 6. These results indicate that sequences within the 3'-terminal intron are functionally coupled to both RNA 3'-end formation and removal of the penultimate intron via a network of interactions that form across the last two exons and, most likely, between RNA processing factors.

Sequences within the last intron function in RNA 3'-end formation in cultured cells

In cultured cells, little if any mRNA accumulates from an intronless version of the human gene for triosephosphate isomerase (TPI), a gene that normally contains six introns. By deleting introns either individually or in combinations, it was demonstrated by Northern (RNA) blot hybridization that while the deletion of a greater number of introns generally results in a lower level of product mRNA, not all introns contribute equally to mRNA formation. For example, intron 1 appeared to be dispensable, at least when the remaining introns are present, but deletion of the last intron, intron 6, reduced the level of product mRNA to 51% of normal. To determine how intron 6 contributes to mRNA formation, partial deletions of intron 6 were constructed and analyzed. Deletion of the lariat and acceptor splice sites or the donor, lariat, and acceptor splice sites, each of which precluded removal of the intron 6 sequences that remained, reduced the level of product mRNA to < 1 or 27% of normal, respectively. As measured by RNase mapping and cDNA sequencing, the decrease in mRNA abundance that was attributable to the complete and partial intron 6 deletions was accompanied by an increase in the abundance of pre-mRNA that lacked a mature 3' end, i.e., that was neither cleaved nor polyadenylated. We infer from these and other data that sequences within the final intron facilitate proper 3'-end formation, possibly through an association with the components of a productive spliceosome.

Human triosephosphate isomerase deficiency resulting from mutation of Phe-240

Triosephosphate isomerase (TPI; D-glyceraldehyde-3-phosphate ketolisomerase [E.C.5.3.1.1]) deficiency is an autosomal recessive disorder that typically results in chronic, nonspherocytic hemolytic anemia and in neuromuscular impairment. The molecular basis of this disease was analyzed for one Hungarian family and for two Australian families by localizing the defects in TPI cDNA and by determining how each defect affects TPI gene expression. The Hungarian family is noteworthy in having the first reported case of an individual, A. Jó., who harbors two defective TPI alleles but who does not manifest neuromuscular disabilities. This family was characterized by two mutations that have never been described. One is a missense mutation within codon 240 (TTC [Phe]-->CTC [Leu]), which creates a thermolabile protein, as indicated by the results of enzyme activity assays using cell extracts. This substitution, which changes a phylogenetically conserved amino acid, may affect enzyme activity by disrupting intersubunit contacts or substrate binding, as deduced from enzyme structural studies. The other mutation has yet to be localized but reduces the abundance of TPI mRNA 10-20-fold. Each of the Australian families was characterized by a previously described mutation within codon 104 (GAG [Glu]-->GAC [Asp]), which also results in thermolabile protein.

Nonsense codons can reduce the abundance of nuclear mRNA without affecting the abundance of pre-mRNA or the half-life of cytoplasmic mRNA

The abundance of the mRNA for human triosephosphate isomerase (TPI) is decreased to approximately 20% of normal by frameshift and nonsense mutations that cause translation to terminate at a nonsense codon within the first three-fourths of the reading frame. Results of previous studies inhibiting RNA synthesis with actinomycin D suggested that the decrease is not attributable to an increased rate of cytoplasmic mRNA decay. However, the step in TPI RNA metabolism that is altered was not defined, and the use of actinomycin D, in affecting all polymerase II-transcribed genes, could result in artifactual conclusions. In data presented here, the nonsense codon-mediated reduction in the level of TPI mRNA is shown to be characteristic of both nuclear and cytoplasmic fractions of the cell, indicating that the altered metabolic step is nucleus associated. Neither aberrancies in gene transcription nor aberrancies in RNA splicing appear to contribute to the reduction since there were no accompanying changes in the amount of nuclear run-on transcription, the level of any of the six introns in TPI pre-mRNA, or the size of processed mRNA in the nucleus. Deletion of all splice sites that reside downstream of a nonsense codon does not abrogate the reduction, indicating that the reduction takes place independently of the splicing of a downstream intron. Experiments that placed TPI gene expression under the control of the human c-fos promoter, which can be transiently activated by the addition of serum to serum-deprived cells, verified that there is no detectable effect of a nonsense codon on the turnover of cytoplasmic mRNA.

Evidence to implicate translation by ribosomes in the mechanism by which nonsense codons reduce the nuclear level of human triosephosphate isomerase mRNA

The abundance of the mRNA for human triosephosphate isomerase (TPI) is decreased to 20-30% of normal by frameshift and nonsense mutations that prematurely terminate translation within the first three-quarters of the reading frame. The decrease has been shown to be attributable to a reduced level of TPI mRNA that copurifies with nuclei. Given that the translational reading frame of an mRNA is assessed in the cytoplasm during protein synthesis, cytoplasmic and nuclear RNA processes may be linked. Alternatively, a nuclear mechanism may exist whereby in-frame nonsense codons can be identified. To differentiate between these two possibilities, two distinct modulators of protein synthesis have been tested for the ability to influence the nonsense-codon-mediated reduction in the mRNA level. (i) A suppressor tRNA, which acts in trans to suppress an amber nonsense codon within TPI mRNA, and (ii) a hairpin structure in the 5' untranslated region of TPI mRNA, which acts exclusively in cis to inhibit initiation of TPI mRNA translation, were found, individually, and to a greater extent, together, to abrogate the decrease in mRNA. These results show that tRNA and ribosomes coordinately mediate the effect of a nonsense codon on the level of newly synthesized TPI mRNA. We suggest that the premature termination of TPI mRNA translation in the cytoplasm can reduce the level of TPI mRNA that fractionates with nuclei.

Human beta-globin mRNAs that harbor a nonsense codon are degraded in murine erythroid tissues to intermediates lacking regions of exon I or exons I and II that have a cap-like structure at the 5′ termini

Previous studies have demonstrated that nonsense codons within beta zero-thalassemic or in vitro-mutagenized human beta-globin transgenes result in the production of mRNAs that are degraded abnormally rapidly in the cytoplasm of murine erythroid cells. As a consequence, three RNA degradative intermediates are formed that lack sequences from either exon I or exons I and II. We show here that the intermediates, like the full-length mRNA from which they derive and the endogenous murine beta maj-globin mRNA, bind to the anticap monoclonal antibody H-20 in a way that is competed by the cap analogue m7G and eliminated by prior exposure to tobacco acid pyrophosphatase. Furthermore, the intermediates, like the two full-length mRNAs, are resistant to a 5'----3' exonuclease activity isolated from HeLa cell nuclei that degrades uncapped but not capped ribopolymers. Based on these observations, the intermediates appear to possess a structure that is indistinguishable from the cap at the 5' end of mRNA, i.e. a methylated nucleoside that is linked to the RNA by a 5'-5' phosphodiester bond. Detection of the intermediates during murine development was concomitant with detection of full-length thalassemic mRNA. Intermediate production appears to be influenced by RNA structure as indicated by the products that derive from a beta zero-thalassemic beta-globin transgene harboring a structural alteration (a 4 bp deletion) that was larger than any of those previously studied.

Nonsense codons in human beta-globin mRNA result in the production of mRNA degradation products

Human beta zero-thalassemic beta-globin genes harboring either a frameshift or a nonsense mutation that results in the premature termination of beta-globin mRNA translation have been previously introduced into the germ line of mice (S.-K. Lim, J.J. Mullins, C.-M. Chen, K. Gross, and L.E. Maquat, EMBO J. 8:2613-2619, 1989). Each transgene produces properly processed albeit abnormally unstable mRNA as well as several smaller RNAs in erythroid cells. These smaller RNAs are detected only in the cytoplasm and, relative to mRNA, are longer-lived and are missing sequences from either exon I or exons I and II. In this communication, we show by using genetics and S1 nuclease transcript mapping that the premature termination of beta-globin mRNA translation is mechanistically required for the abnormal RNA metabolism. We also provide evidence that generation of the smaller RNAs is a cytoplasmic process: the 5' ends of intron 1-containing pre-mRNAs were normal, the rates of removal of introns 1 and 2 were normal, and studies inhibiting RNA synthesis with actinomycin D demonstrated a precursor-product relationship between full-length mRNA and the smaller RNAs. In vivo, about 50% of the full-length species that undergo decay are degraded to the smaller RNAs and the rest are degraded to undetectable products. Exposure of erythroid cells that expressed a normal human beta-globin transgene to either cycloheximide or puromycin did not result in the generation of the smaller RNAs. Therefore, a drug-induced reduction in cellular protein synthesis does not reproduce this aspect of cytoplasmic mRNA metabolism. These data suggest that the premature termination of beta-globin mRNA translation in either exon I or exon II results in the cytoplasmic generation of discrete mRNA degradation products that are missing sequences from exon I or exons I and II. Since these degradation products appear to be the same for all nonsense codons tested, there is no correlation between the position of translation termination and the sites of nucleolytic cleavage.

Nuclear mRNA export

Nuclear mRNA export through the nuclear pore complex has been proposed to be a unidirectional, signal-mediated and energy-dependent process. Evidence exists that this process can be influenced by many factors including other steps in the pathway of cytoplasmic mRNA formation, sequences of the RNA substrate that are either transcribed or added co- or post-transcriptionally, and extracellular effectors.

Modulation of human triosephosphate isomerase gene transcription by serum

We have monitored the level of mRNA encoding the glycolytic and gluconeogenic enzyme trisephosphate isomerase (TPI) during the growth arrest of cells by serum deprivation and the subsequent growth activation of cells by serum addition. This analysis has demonstrated that the steady state level of TPI mRNA changes 5-20-fold, depending upon the cell type, during the transversal of cells from a proliferative to a nonproliferative state and vice versa. These changes are largely attributable to changes in the rate of TPI gene transcription rather than to alterations in post-transcriptional processes as determined by nuclear run-on measurements. Following serum stimulation, the increase in TPI gene expression is maximal at or around the onset of DNA synthesis. We have also quantitated TPI mRNA throughout the cell cycle following cell synchronization with aphidicolin. Our results indicate that the steady state level of TPI mRNA is relatively constant throughout the division cycle of proliferating cells. Thus, while TPI gene expression is modulated during the traversal of cells to and from a nonproliferative state, it is not significantly modulated during the cycle of events that is characteristic of continuously proliferating cells.

Minimal sequence and factor requirements for the initiation of transcription from an atypical, TATATAA box-containing housekeeping promoter

We have established the minimal sequence and factor requirements for both constitutive and viral-induced transcription from an atypical, TATATAA box-containing human housekeeping promoter. Utilizing a transient cotransfection protocol, we have found that efficient transactivation of triosephosphate isomerase (TPI) gene transcription by the immediate early proteins of adenovirus and pseudorabies virus is dependent upon the same assembly of sequence elements that collectively confer minimal TPI promoter function in the absence of viral protein. These elements span TPI promoter positions -65 and -6 (where +1 is the transcription initiation site) and include not only a TFIID-responsive TATATAA box (-27 to -21) but a single GC box (-53 to -48) that binds Spl, and a novel cap proximal element (-18 to -6) that binds a 110-kDa nuclear factor that is present in HeLa cells. We demonstrate that these elements function in an interdependent fashion; deleting either GC box 1 or the cap proximal element completely or nearly abolished both basal transcription and viral transactivation. Therefore, these elements and their cognate factors represent the basal transcription initiation complex through which the immediate early protein of adenovirus or pseudorabies virus mediates the stimulation of TPI gene transcription. We discuss the implications of these data for both constitutive and viral-induced transcription.

Novel metabolism of several beta zero-thalassemic beta-globin mRNAs in the erythroid tissues of transgenic mice

Mice that are transgenic for human beta zero-thalassemic beta-globin alleles were generated in order to study how beta zero-thalassemic mutations affect beta-globin RNA metabolism in erythroid tissues. Three thalassemic alleles were studied, each of which harbors either a frameshift or a nonsense mutation. These mutations result in the premature termination of beta-globin mRNA translation and an abnormally low level of beta-globin mRNA in the peripheral blood of thalassemic patients. Comparative studies of mice that express any of the beta zero-thalassemic transgenes with mice that express a normal human beta-globin transgene demonstrated that all three thalassemic mRNAs are metabolized in erythroid tissues abnormally. RNA blotting and S1 nuclease transcript mapping revealed for each thalassemic transgene that (i) the full-length mRNA is abnormally short-lived and (ii) in addition to full-length mRNA, three more stable yet smaller RNAs are present. These smaller RNAs are polyadenylated and lack the mRNA 5' end.

Transcriptional regulatory sequences of the housekeeping gene for human triosephosphate isomerase

To examine the functional organization of the human triosephosphate isomerase (TPI) promoter, deletion, insertion, and linker scanning mutations were introduced into the TPI promoter of hybrid TPI/beta-globin genes. These genes were transiently expressed in mouse L and human HeLa cells, and the effect of each mutation on the frequency and position of transcription initiation was assayed by S1 nuclease transcript mapping. Multiple positive regulatory elements reside between positions -595 and +1 in L cells and -920 and -7 in HeLa cells and coordinately promote maximum hybrid gene transcription. These elements include an array of GC boxes (positions -126 to -48) that variably conform to the consensus Sp1-binding site, and a canonical TATA box (positions -27 to -21) that is essential for detectable levels of transcription. In an additive yet position-dependent fashion, the GC boxes function in cis to the TATA box to control both the frequency and position of transcription initiation. Additional positive elements reside upstream of position -131 and are required for full promoter function. Also, an inhibitory element(s) residing between position -7200 and either -2800 in L cells or -920 in HeLa cells reduces transcription approximately 7-fold relative to the level of transcription achieved with the maximally active promoter.

Premature translation termination mediates triosephosphate isomerase mRNA degradation

We characterized an anemia-inducing mutation in the human gene for triosephosphate isomerase (TPI) that resulted in the production of prematurely terminated protein and mRNA with a reduced cytoplasmic half-life. The mutation converted a CGA arginine codon to a TGA nonsense codon and generated a protein of 188 amino acids, instead of the usual 248 amino acids. To determine how mRNA primary structure and translation influence mRNA stability, in vitro-mutagenized TPI alleles were introduced into cultured L cells and analyzed for their effect on TPI RNA metabolism. Results indicated that mRNA stability is decreased by all nonsense and frameshift mutations. To determine the relative contribution of the changes in mRNA structure and translation to the altered half-life, the effects of individual mutations were compared with the effects of second-site reversions that restored translation termination to normal. All mutations that resulted in premature translation termination reduced the mRNA half-life solely or mainly by altering the length of the mRNA that was translated. The only mutation that altered translation termination and that reduced the mRNA half-life mainly by affecting the mRNA structure was an insertion that shifted termination to a position downstream of the normal stop codon.

Human triose-phosphate isomerase deficiency: a single amino acid substitution results in a thermolabile enzyme

Triose-phosphate isomerase (TPI; D-glyceraldehyde-3-phosphate ketol-isomerase, EC 5.3.1.1) deficiency is a recessive disorder that results in hemolytic anemia and neuromuscular dysfunction. To determine the molecular basis of this disorder, a TPI allele from two unrelated patients homozygous for TPI deficiency was compared with an allele from a normal individual. Each disease-associated sequence harbors a G X C----C X G transversion in the codon for amino acid-104 and specifies a structurally altered protein in which a glutamate residue is replaced by an aspartate residue. The importance of glutamate-104 to enzyme structure and function is implicated by its conservation in the TPI protein of all species that have been characterized to date. The glutamate-to-aspartate substitution results in a thermolabile enzyme as demonstrated by assays of TPI activity in cultured fibroblasts of each patient and cultured Chinese hamster ovary (CHO) cells that were stably transformed with the mutant alleles. Although this substitution conserves the overall charge of amino acid-104, the x-ray crystal structure of chicken TPI indicates that the loss of a side-chain methylene group (-CH2CH2COO- ---- -CH2COO-) is sufficient to disrupt the counterbalancing of charges that normally exists within a hydrophobic pocket of the native enzyme.

Localization of DNA sequences involved in dexamethasone-dependent expression of the rat alpha 1-acid glycoprotein gene

Synthesis of rat alpha 1-acid glycoprotein (AGP), one of the major inflammation-induced plasma proteins, is positively regulated by dexamethasone. To define the dexamethasone-responsive genetic element, we isolated and tested AGP gene sequences for the ability to confer glucocorticoid induction to the bacterial chloramphenicol acetyltransferase (CAT) gene in L cells. A 141-base-pair region of the AGP gene, including 120 base pairs of DNA upstream from the start site of transcription and 21 base pairs of the 5' untranslated region, was sufficient for maximal CAT gene induction by dexamethasone. To localize more precisely the AGP glucocorticoid-responsive element, parts of this 141-base-pair region were inserted 5' to either an AGP promoter-CAT gene or a human triosephosphate isomerase promoter-CAT gene, both of which lacked a response to the steroid. The AGP gene region between 120 and 42 base pairs upstream from the start site of transcription was found to mediate maximal dexamethasone induction of CAT enzyme levels. This result was unexpected because this region does not contain sequence homologies to known glucocorticoid receptor-binding sites and those AGP gene regions that lay further upstream and were homologous to other glucocorticoid receptor-binding sites were inactive in the CAT assay. The fact that the AGP gene region mediating dexamethasone regulation was distinct from the transcribed region indicates that glucocorticoids increase AGP gene expression primarily at the transcriptional rather than the posttranscriptional level.