Histone mRNA degradation in vivo: the first detectable step occurs at or near the 3' terminus

Role of oligouridylation in normal metabolism and regulated degradation of mammalian histone mRNAs

Metazoan replication-dependent histone mRNAs are the only known cellular mRNAs that are not polyadenylated. Histone mRNAs are present in large amounts only in S-phase cells, and their levels are coordinately regulated with the rate of DNA replication. In mammals, the stemloop at the 3' end of histone mRNA is bound to stemloop binding protein, a protein required for both synthesis and degradation of histone mRNA, and an exonuclease, 3'hExo (ERI1). Histone mRNAs are rapidly degraded when DNA synthesis is inhibited in S-phase cells and at the end of S-phase. Upf1 is also required for rapid degradation of histone mRNA as is the S-phase checkpoint. We report that Smg1 is required for histone mRNA degradation when DNA replication is inhibited, suggesting it is the PI-like kinase that activates Upf1 for histone mRNA degradation. We also show that some mutant Upf1 proteins are recruited to histone mRNAs when DNA replication is inhibited and act as dominant negative factors in histone mRNA degradation. We report that the pathway of rapid histone mRNA degradation when DNA replication is inhibited in S-phase cells that are activating the S-phase checkpoint is similar to the pathway of rapid degradation of histone mRNA at the end of S-phase.This article is part of the theme issue '5' and 3' modifications controlling RNA degradation'.

TUT7 catalyzes the uridylation of the 3' end for rapid degradation of histone mRNA

The replication-dependent histone mRNAs end in a stem-loop instead of the poly(A) tail present at the 3' end of all other cellular mRNAs. Following processing, the 3' end of histone mRNAs is trimmed to 3 nucleotides (nt) after the stem-loop, and this length is maintained by addition of nontemplated uridines if the mRNA is further trimmed by 3'hExo. These mRNAs are tightly cell-cycle regulated, and a critical regulatory step is rapid degradation of the histone mRNAs when DNA replication is inhibited. An initial step in histone mRNA degradation is digestion 2-4 nt into the stem by 3'hExo and uridylation of this intermediate. The mRNA is then subsequently degraded by the exosome, with stalled intermediates being uridylated. The enzyme(s) responsible for oligouridylation of histone mRNAs have not been definitively identified. Using high-throughput sequencing of histone mRNAs and degradation intermediates, we find that knockdown of TUT7 reduces both the uridylation at the 3' end as well as uridylation of the major degradation intermediate in the stem. In contrast, knockdown of TUT4 did not alter the uridylation pattern at the 3' end and had a small effect on uridylation in the stem-loop during histone mRNA degradation. Knockdown of 3'hExo also altered the uridylation of histone mRNAs, suggesting that TUT7 and 3'hExo function together in trimming and uridylating histone mRNAs.

Degradation of oligouridylated histone mRNAs: see UUUUU and goodbye

During the cell cycle the expression of replication-dependent histones is tightly coupled to DNA synthesis. Histone messenger RNA (mRNA) levels strongly increase during early S-phase and rapidly decrease at the end of it. Here, we review the degradation of replication-dependent histone mRNAs, a paradigm of post-transcriptional gene regulation, in the context of processing, translation, and oligouridylation. Replication-dependent histone transcripts are characterized by the absence of introns and by the presence of a stem-loop structure at the 3' end of a very short 3' untranslated region (UTR). These features, together with a need for active translation, are a prerequisite for their rapid decay. The degradation is induced by 3' end additions of untemplated uridines, performed by terminal uridyl transferases. Such 3' oligouridylated transcripts are preferentially bound by the heteroheptameric LSM1-7 complex, which also interacts with the 3'→5' exonuclease ERI1 (also called 3'hExo). Presumably in cooperation with LSM1-7 and aided by the helicase UPF1, ERI1 degrades through the stem-loop of oligouridylated histone mRNAs in repeated rounds of partial degradation and reoligouridylation. Although histone mRNA decay is now known in some detail, important questions remain open: How is ceasing nuclear DNA replication relayed to the cytoplasmic histone mRNA degradation? Why is translation important for this process? Recent research on factors such as SLIP1, DBP5, eIF3, CTIF, CBP80/20, and ERI1 has provided new insights into the 3' end formation, the nuclear export, and the translation of histone mRNAs. We discuss how these results fit with the preparation of histone mRNAs for degradation, which starts as early as these transcripts are generated.

RNA decay via 3' uridylation

The post-transcriptional addition of non-templated nucleotides to the 3' ends of RNA molecules can have a profound impact on their stability and biological function. Evidence accumulated over the past few decades has identified roles for polyadenylation in RNA stabilisation, degradation and, in the case of eukaryotic mRNAs, translational competence. By contrast, the biological significance of RNA 3' modification by uridylation has only recently started to become apparent. The evolutionary origin of eukaryotic RNA terminal uridyltransferases can be traced to an ancestral poly(A) polymerase. Here we review what is currently known about the biological roles of these enzymes, the ways in which their activity is regulated and the consequences of this covalent modification for the target RNA molecule, with a focus on those instances where uridylation has been found to contribute to RNA degradation. Roles for uridylation have been identified in the turnover of mRNAs, pre-microRNAs, piwi-interacting RNAs and the products of microRNA-directed mRNA cleavage; many mature microRNAs are also modified by uridylation, though the consequences in this case are currently less well understood. In the case of piwi-interacting RNAs, modification of the 3'-terminal nucleotide by the HEN1 methyltransferase blocks uridylation and so stabilises the small RNA. The extent to which other uridylation-dependent mechanisms of RNA decay are similarly regulated awaits further investigation. This article is part of a Special Issue entitled: RNA Decay mechanisms.

mRNAs containing the histone 3' stem-loop are degraded primarily by decapping mediated by oligouridylation of the 3' end

Metazoan replication-dependent histone mRNAs are only present in S-phase, due partly to changes in their stability. These mRNAs end in a unique stem-loop (SL) that is required for both translation and cell-cycle regulation. Previous studies showed that histone mRNA degradation occurs through both 5'→3' and 3'→5' processes, but the relative contributions are not known. The 3' end of histone mRNA is oligouridylated during its degradation, although it is not known whether this is an essential step. We introduced firefly luciferase reporter mRNAs containing the histone 3' UTR SL (Luc-SL) and either a normal or hDcp2-resistant cap into S-phase HeLa cells. Both mRNAs were translated, and translation initially protected the mRNAs from degradation, but there was a lag of ∼40 min with the uncleavable cap compared to ∼8 min for the normal cap before rapid decay. Knockdown of hDcp2 resulted in a similar longer lag for Luc-SL containing a normal cap, indicating that 5'→3' decay is important in this system. Inhibition of DNA replication with hydroxyurea accelerated the degradation of Luc-SL. Knockdown of terminal uridyltransferase (TUTase) 4 but not TUTase 3 slowed the decay process, but TUTase 4 knockdown had no effect on destabilization of the mRNA by hydroxyurea. Both Luc-SL and its 5' decay intermediates were oligouridylated. Preventing oligouridylation by 3'-deoxyadenosine (cordycepin) addition to the mRNA slowed degradation, in the presence or absence of hydroxyurea, suggesting oligouridylation initiates degradation. The spectrum of oligouridylated fragments suggests the 3'→5' degradation machinery stalls during initial degradation, whereupon reuridylation occurs.

Control of protein expression through mRNA stability in calcium signalling

Specific sequences (cis-acting elements) in the 3'-untranslated region (UTR) of RNA, together with stabilizing and destabilizing proteins (trans-acting factors), determine the mRNA stability, and consequently, the level of expression of several proteins. Such interactions were discovered initially for short-lived mRNAs encoding cytokines and early genes like c-jun and c-myc. However, they may also determine the fate of more stable mRNAs in a tissue and disease-dependent manner. The interactions between the cis-acting elements and the trans-acting factors may also be modulated by Ca(2+) either directly or via a control of the phosphorylation status of the trans-acting factors. We focus initially on the basic concepts in mRNA stability with the trans-acting factors AUF1 (destabilizing) and HuR (stabilizing). Sarco/endoplasmic reticulum Ca(2+) pumps, SERCA2a (cardiac and slow twitch muscles) and SERCA2b (most cells including smooth muscle cells), are pivotal in Ca(2+) mobilization during signal transduction. SERCA2a and SERCA2b proteins are encoded by relatively stable mRNAs that contain cis-acting stability determinants in their 3'-regions. We present several pathways where 3'-UTR mediated mRNA decay is key to Ca(2+) signalling: SERCA2a and beta-adrenergic receptors in heart failure, renin-angiotensin system, and parathyroid hormones. Other examples discussed include cytokines vascular endothelial growth factor, endothelin and endothelial nitric oxide synthase. Roles of Ca(2+) and Ca(2+)-binding proteins in mRNA stability are also discussed. We anticipate that these novel modes of control of protein expression will form an emerging area of research that may explore the central role of Ca(2+) in cell function during development and in disease.

Metazoan replication-dependent histone mRNAs: a distinct set of RNA polymerase II transcripts

Metazoan replication-dependent histone mRNAs are the only eukaryotic mRNAs that lack polyA tails. The genes for the five histone proteins have remained physically linked during evolution. Expression of histone mRNAs and histone proteins requires a unique set of factors, and may be coordinated by association of the histone genes with Cajal bodies. Recently several novel factors, including components of the U7 snRNP, as well as proteins involved in regulation of histone gene expression, have been described.

A 3' exonuclease that specifically interacts with the 3' end of histone mRNA

Metazoan histone mRNAs end in a highly conserved stem-loop structure followed by ACCCA. Previous studies have suggested that the stem-loop binding protein (SLBP) is the only protein binding this region. Using RNA affinity purification, we identified a second protein, designated 3'hExo, that contains a SAP and a 3' exonuclease domain and binds the same sequence. Strikingly, 3'hExo can bind the stem-loop region both separately and simultaneously with SLBP. Binding of 3'hExo requires the terminal ACCCA, whereas binding of SLBP requires the 5' side of the stem-loop region. Recombinant 3'hExo degrades RNA substrates in a 3'-5' direction and has the highest activity toward the wild-type histone mRNA. Binding of SLBP to the stem-loop at the 3' end of RNA prevents its degradation by 3'hExo. These features make 3'hExo a primary candidate for the exonuclease that initiates rapid decay of histone mRNA upon completion and/or inhibition of DNA replication.

Analysis of the function, expression, and subcellular distribution of human tristetraprolin

OBJECTIVE

The zinc-finger protein tristetraprolin (TTP) has been demonstrated to regulate tumor necrosis factor alpha (TNFalpha) messenger RNA (mRNA) instability in murine macrophages. We sought to develop a model system to characterize the effects of human TTP (hTTP) on TNFalpha 3'-untranslated region (3'-UTR)-mediated expression. We also generated a specific polyclonal antibody against hTTP that enabled the examination of the subcellular distribution of hTTP and its RNA binding in vivo.

METHODS

Transfection of reporter gene constructs were used to functionally characterize the role of hTTP in regulating TNFalpha expression in a 3'-UTR-dependent manner. An immunoprecipitation reverse transcription-polymerase chain reaction technique, immunoblotting, immunocytochemistry, and sucrose density fractionation were used to identify and localize hTTP.

RESULTS

We found that hTTP interacted with human TNFalpha mRNA in the cytoplasm. The presence of the TNFalpha 3'-UTR was sufficient to confer binding by TTP in vivo. This interaction resulted in reduced luciferase reporter gene activity in a TNFalpha 3'-UTR adenine-uridine-rich element (ARE)-dependent manner. Immunoblotting and immunocytochemistry indicated that endogenous and transfected hTTP localized to the cytoplasm. Results of sucrose density fractionation studies were consistent with a polysomal location of hTTP. In rheumatoid synovium, hTTP expression was restricted to cells in the synovial lining layers.

CONCLUSION

Through the development of an antiserum specific for hTTP, we have been able to demonstrate that hTTP binds specifically to the TNFalpha 3'-UTR and reduces reporter gene expression in an ARE-specific manner. These studies establish that hTTP is likely to function in a similar, if not identical manner, in the posttranscriptional regulation of TNFalpha. Understanding the posttranscriptional regulation of TNFalpha biosynthesis is important for the development of novel treatment strategies in rheumatoid arthritis.

Regulation of c-myc mRNA decay in vitro by a phorbol ester-inducible, ribosome-associated component in differentiating megakaryoblasts

The K562 leukemia cell line is bipotential for erythroid and megakaryoblastic differentiation. The phorbol ester 12-O-tetradecanoylphorbol-13-acetate (TPA) activates a genetic program of gene expression in these cells leading to their differentiation into megakaryoblasts, a platelet precursor. Thus, K562 cells offer a means to examine early changes in gene expression necessary for megakaryoblastic commitment and differentiation. An essential requirement for differentiation of many hematopoietic cell types is the down-regulation of c-myc expression, because its constitutive expression blocks differentiation. TPA-induced differentiation of K562 cells causes rapid down-regulation of c-myc expression, due in part to an mRNA decay rate that is 4-fold faster compared with dividing cells. A cell-free mRNA decay system reconstitutes TPA-induced destabilization of c-myc mRNA, but it requires at least two components for reconstitution. One component fractionates to the post-ribosomal supernatant from either untreated or treated cells. This component is sensitive to cycloheximide and micrococcal nuclease. The other component is polysome-associated and is induced or activated by TPA. Although in dividing cells c-myc mRNA decays via a sequential pathway involving removal of the poly(A) tract followed by degradation of the mRNA body, TPA activates a deadenylation-independent pathway. The cell-free mRNA decay system reconstitutes this alternate decay pathway as well.

The virion host shutoff function of herpes simplex virus degrades the 5' end of a target mRNA before the 3' end

During lytic infections, the virion host shutoff (vhs) function of herpes simplex virus (HSV) disaggregates host polysomes and induces rapid turnover of both cellular and viral mRNAs. To examine the steps in vhs-induced mRNA degradation, an RNase protection assay was used to compare the relative decay rates of sequences from the 5' and 3' ends of a selected target mRNA. In cells infected with wild-type HSV-1, sequences at the 5' end of the HSV-1 thymidine kinase mRNA were degraded more rapidly than those at the 3' end of the transcript. In contrast, in cells infected with a vhs mutant, the decay rates of sequences at the 5' and 3' termini of the transcript were much slower and were essentially indistinguishable from each other. Vhs-induced degradation of the transcribed portion of the mRNA was not preceded by detectable shortening of the poly(A) tail in vivo; nor was a poly(A) tail required to make an RNA a target for the vhs activity in vitro. The results suggest that degradation of sequences at or near the 5' end of an mRNA is an early step in vhs-induced decay.

Evidence for a 3'-5' decay pathway for c-myc mRNA in mammalian cells

Many mRNAs in mammalian cells decay via a sequential pathway involving rapid conversion of polyadenylated molecules to a poly(A)-deficient state followed by rapid degradation of the poly(A)-deficient molecules. However, the rapidity of this latter step(s) has precluded further analyses of the decay pathways involved. Decay intermediates derived from degradation of poly(A)-deficient molecules could offer clues regarding decay pathways, but these intermediates have not been readily detected. Cell-free mRNA decay systems have proven useful in analyses of decay pathways because decay intermediates are rather stable in vitro. Cell-free systems indicate that many mRNAs decay by a sequential 3'-5' pathway because 3'-terminal decay intermediates form following deadenylation. However, if 3'-terminal, in vitro decay intermediates reflect a biologically significant aspect of mRNA turnover, then similar intermediates should be present in cells. Here, I have compared the in vivo and in vitro decay of mRNA encoded by the c-myc proto-oncogene. Its decay both in vivo and in vitro occurs by rapid removal of the poly(A) tract and generation of a 3'-terminal decay intermediate. These data strongly suggest that a 3'-5' pathway contributes to turnover of c-myc mRNA in cells. It is likely that 3'-5' decay represents a major turnover pathway in mammalian cells.

The search for trans-acting factors controlling messenger RNA decay

Control of mRNA turnover is an integral component of regulated gene expression. Individual mRNAs display a wide range of stabilities, which in many cases have been linked to discrete sequence elements. The most extensively characterized determinants of rapid constitutive mRNA turnover in mammalian systems are A + U-rich elements (AREs), first identified in the 3' untranslated regions of many cytokine/lymphokine and protooncogene mRNAs. In this article, we describe recent advances in the characterization of ARE-directed mRNA turnover, including links to deadenylation kinetics and functional heterogeneity among AREs from different mRNAs. We then describe strategies employed in the search for trans-acting factors interacting with these elements. Using such techniques, an ARE-binding activity capable of accelerating c-myc mRNA turnover in vitro was identified, and named AUF1. Subsequent cloning and characterization revealed that AUF1 exists as a family of four proteins formed by alternative splicing of a common pre-mRNA and appears to function as part of a multisubunit trans-acting complex to promote ARE-directed mRNA turnover. Investigations using several systems have demonstrated that AUF1 expression and/or activity correlate with rapid decay of ARE-containing mRNAs, and that both expression and activity of AUF1 are regulated by developmental and signal transduction mechanisms.

Assays for analyzing exonucleases in vitro

Ribonucleases play essential roles in cell growth, differentiation, and the response to stress. This article deals with exoribonucleases, enzymes that degrade RNAs beginning at either the 5' or 3' end and proceed down the length of the RNA. The preparation of a crude extract of a mammalian 3'-to-5' exonuclease is described. Assay conditions for both 5'-to-3' and 3'-to-5' exonucleases are given. One of these is a yeast enzyme that is known to be involved in mRNA decay. Others are vertebrate exonucleases that are presumed to have a role in mRNA stability but have not yet been proven to do so.

The c-myc coding region determinant-binding protein: a member of a family of KH domain RNA-binding proteins

The half-life of c- myc mRNA is regulated when cells change their growth rates or differentiate. Two regions within c- myc mRNA determine its short half-life. One is in the 3'-untranslated region, the other is in the coding region. A cytoplasmic protein, the coding region determinant-binding protein (CRD-BP), binds in vitro to the c- myc coding region instability determinant. We have proposed that the CRD-BP, when bound to the mRNA, shields the mRNA from endonucleolytic attack and thereby prolongs the mRNA half-life. Here we report the cloning and further characterization of the mouse CRD-BP, a 577 amino acid protein containing four hnRNP K-homology domains, two RNP domains, an RGG RNA-binding domain and nuclear import and export signals. The CRD-BP is closely related to the chicken beta-actin zipcode-binding protein and is similar to three other proteins, one of which is overexpressed in some human cancers. Recombinant mouse CRD-BP binds specifically to c- myc CRD RNA in vitro and reacts with antibody against human CRD-BP. Most of the CRD-BP in the cell is cytoplasmic and co-sediments with ribosomal subunits.

Regulation of p56(lck) messenger turnover upon T cell activation: involvement of the 3' untranslated region in stability as determined in cell-free extracts

Full activation of T lymphocytes transiently downregulates the steady state level of the tyrosine kinase p56(lck) mRNA. Here, we show that a decrease in messenger stability is involved in this downmodulation followed thereafter by a rapid and marked increase in mRNA half-life. In order to facilitate the study of p56(lck) messenger stability, an in vitro mRNA decay assay was developed and used to determine whether the 451 nucleotide long 3' untranslated region (3'UTR) of the messenger is implicated in the regulation of mRNA stability. Indeed, deletion of most of the 3'UTR led to a substantial increase in transcript half-life whereas deletion of a limited 3' portion did not, thus showing that the 146 nucleotides located in 5' of the 3'UTR contain destabilizing elements. Furthermore, the stability of both truncated transcripts was still modulated upon activation, thereby suggesting that the activation-responsive elements are located in a region distinct from the 3'UTR.

Two types of polyadenated mRNAs are synthesized from Drosophila replication-dependent histone genes

The polyadenylation of replication-dependent histone H2B, H3 and H4 mRNAs in Drosophila melanogaster was analysed. Two types of mRNAs, containing a poly(A) tail, can be detected in addition to non-polyadenylated messengers, which represent the majority of replication-dependent histone mRNAs. Firstly, conventional polyadenylation signals, localized downstream from the stem-loop region, are used to produce polyadenylated mRNAs. The messengers of this type, generated from the D. melanogaster H2B gene, are preferentially synthesized in the testis of the fly. Secondly, a distinct type of polyadenylated histone mRNA has been identified. This mRNA, which is present in many different tissues and constitutes a minor part of the total histone mRNA pool, contains a short poly(A) tail, added to the end of the 3' terminal stem-loop structure, which is in most cases lacking several nucleotides from its 3' end. The sites of polyadenylation within the stem-loop are not preceded by a normal polyadenylation signal. The possible functions of the polyadenylated histone transcripts are discussed.

In vivo generation of 3' and 5' truncated species in the process of c-myc mRNA decay

It has been demonstrated that the half-life of c-myc mRNA is modulated in response to physiological agents. The elucidation of the decay process and the identification of the critical steps in the in vivo c-myc mRNA degradation pathway can be approached by following the fate of c-myc mRNA under the influence of such factors. IFN-alpha was the factor used to modulate c-myc mRNA half-life in HeLa 1C5 cells, a stable clone derived from HeLa cells. This cell line carries multiple copies of the c-myc gene, under the control of the dexamethasone inducible mouse mammary tumor virus-long terminal repeat (MMTV-LTR). Exposure of HeLa 1C5 cells to IFN-alpha resulted in a further 2-fold increase over the dexamethasone-induced c-myc mRNA. However, the c-myc mRNA in IFN-alpha treated cells was less stable than that in the control cells. RNase H mapping of the 3' untranslated region of c-myc mRNA revealed, in addition to the full length mRNA, three smaller fragments. These fragments were proven to be truncated, non-adenylated c-myc mRNA species generated in vivo. Exposure of HeLa 1C5 cells to Interferon-alpha before induction with dexamethasone resulted in the enhanced presence of these intermediates. RNase H analysis of c-myc mRNA after actinomycin D chase revealed that deadenylation led to the formation of a relatively more stable oligoadenylated c-myc mRNA population which did not appear to be precursor to the truncated intermediates. The detection of truncated 3' end c-myc mRNA adenylated fragments as well, implies that the c-myc mRNA degradation process may follow an alternative pathway possibly involving endonucleolytic cleavage.

mRNA stability in mammalian cells

This review concerns how cytoplasmic mRNA half-lives are regulated and how mRNA decay rates influence gene expression. mRNA stability influences gene expression in virtually all organisms, from bacteria to mammals, and the abundance of a particular mRNA can fluctuate manyfold following a change in the mRNA half-life, without any change in transcription. The processes that regulate mRNA half-lives can, in turn, affect how cells grow, differentiate, and respond to their environment. Three major questions are addressed. Which sequences in mRNAs determine their half-lives? Which enzymes degrade mRNAs? Which (trans-acting) factors regulate mRNA stability, and how do they function? The following specific topics are discussed: techniques for measuring eukaryotic mRNA stability and for calculating decay constants, mRNA decay pathways, mRNases, proteins that bind to sequences shared among many mRNAs [like poly(A)- and AU-rich-binding proteins] and proteins that bind to specific mRNAs (like the c-myc coding-region determinant-binding protein), how environmental factors like hormones and growth factors affect mRNA stability, and how translation and mRNA stability are linked. Some perspectives and predictions for future research directions are summarized at the end.

mRNA stability in mammalian cells

This review concerns how cytoplasmic mRNA half-lives are regulated and how mRNA decay rates influence gene expression. mRNA stability influences gene expression in virtually all organisms, from bacteria to mammals, and the abundance of a particular mRNA can fluctuate manyfold following a change in the mRNA half-life, without any change in transcription. The processes that regulate mRNA half-lives can, in turn, affect how cells grow, differentiate, and respond to their environment. Three major questions are addressed. Which sequences in mRNAs determine their half-lives? Which enzymes degrade mRNAs? Which (trans-acting) factors regulate mRNA stability, and how do they function? The following specific topics are discussed: techniques for measuring eukaryotic mRNA stability and for calculating decay constants, mRNA decay pathways, mRNases, proteins that bind to sequences shared among many mRNAs [like poly(A)- and AU-rich-binding proteins] and proteins that bind to specific mRNAs (like the c-myc coding-region determinant-binding protein), how environmental factors like hormones and growth factors affect mRNA stability, and how translation and mRNA stability are linked. Some perspectives and predictions for future research directions are summarized at the end.

Mechanisms of mRNA degradation in eukaryotes

Recent experiments have identified distinct mechanisms of eukaryotic RNA turnover. In one mechanism, deadenylation triggers decapping, exposing the messenger RNA to 5' to 3' degradation. This pathway may act at different rates on the majority of messenger RNAs. There are also degradation mechanisms, such as endonucleolytic cleavage, limited to messenger RNAs containing specific sequence elements.

Protection of mRNA against nucleases in cytoplasmic extracts of mouse sarcoma ascites cells

The mRNA present in extracts of mouse sarcoma 180 (S-180) ascites cells is relatively resistant to degradation when compared to added tracer ribosomal RNA. Deproteinized mRNA added to the extract is about as resistant as the endogenous mRNA, an indication that the protection is not due to any protein present in the endogenous mRNP structure. A major determinant of protection lies at the 5' end of RNA chains, where the presence of a triphosphate or a cap enhances the stability of mRNA transcripts. Addition of poly(A) to a capped transcript had little effect on stability. Stabilization by the cap structure is apparently not due to association of transcripts with a cap-binding protein. The discrimination in RNA decay rates appears to be based on interaction of the different RNA species with an exonuclease, which represents the predominant ribonuclease activity in the extract. Other major cytoplasmic nucleases are suppressed by an RNase inhibitor that is present in excess.

A human histone H2B.1 variant gene, located on chromosome 1, utilizes alternative 3' end processing

A variant human H2B histone gene (GL105), previously shown to encode a 2300 nt replication independent mRNA, has been cloned. We demonstrate this gene expresses alternative mRNAs regulated differentially during the HeLa S3 cell cycle. The H2B-Gl105 gene encodes both a 500 nt cell cycle dependent mRNA and a 2300 nt constitutively expressed mRNA. The 3' end of the cell cycle regulated mRNA terminates immediately following the region of hyphenated dyad symmetry typical of most histone mRNAs, whereas the constitutively expressed mRNA has a 1798 nt non-translated trailer that contains the same region of hyphenated dyad symmetry but is polyadenylated. The cap site for the H2B-GL105 mRNAs is located 42 nt upstream of the protein coding region. The H2B-GL105 histone gene was localized to chromosome region 1q21-1q23 by chromosomal in situ hybridization and by analysis of rodent-human somatic cell hybrids using an H2B-GL105 specific probe. The H2B-GL105 gene is paired with a functional H2A histone gene and this H2A/H2B gene pair is separated by a bidirectionally transcribed intergenic promoter region containing consensus TATA and CCAAT boxes and an OTF-1 element. These results demonstrate that cell cycle regulated and constitutively expressed histone mRNAs can be encoded by the same gene, and indicate that alternative 3' end processing may be an important mechanism for regulation of histone mRNA. Such control further increases the versatility by which cells can modulate the synthesis of replication-dependent as well as variant histone proteins during the cell cycle and at the onset of differentiation.

Degradation products of the mRNA encoding the small subunit of ribulose-1,5-bisphosphate carboxylase in soybean and transgenic petunia

The degradation of a soybean ribulose-1,5-bisphosphate carboxylase small subunit RNA, SRS4, was investigated in soybean seedlings and in petunia plants transformed with an SRS4 gene construct. Polyacrylamide RNA gel blot, primer extension, and S1 nuclease analyses were used to identify and map fragments of the SRS4 mRNA generated in vivo. We showed that SRS4 mRNA is degraded to a characteristic set of fragments in soybean and transgenic petunia and that degradation is not dependent on position of insertion of the gene construct within the genome, on the expression level of the SRS4 mRNA, or on the rbcS promoter. Degradation products lacked poly(A) tails and fractionated with poly(A)-depleted RNA on oligo(dT)-sepharose columns. These products pelleted with polysomes and were released from polysomes prepared with EDTA. Sequences at the 5' end of the SRS4 mRNA were more stable than those at the 3' end of the mRNA. Three models for SRS4 mRNA degradation involving endonucleolytic and exonucleolytic degradation were presented to explain the origin of the 5' proximal fragments.

A plant histone gene promoter can direct both replication-dependent and -independent gene expression in transgenic plants

Chimeric genes containing the beta-glucuronidase (GUS) gene under the control of different Arabidopsis histone H3 and H4 promoters were found to be highly expressed in transient expression experiments using tobacco protoplasts. The activity of one of these promoters, H4A748, was further analyzed. The kinetics of H4A748-GUS activity are very similar to these of a CaMV 35S-GUS constitutive gene during protoplast culture. No increase in H4A748-GUS activity was found after 24 h of protoplast culture when DNA synthesis starts, nor was the GUS activity affected when an inhibitor of DNA synthesis was included in the culture medium. This failure to detect any replication-dependent activity is most likely to be due to the fact that transient transcription of the introduced construct is restricted to the first 24 h following transfection. Stable integration of the H4A748-GUS gene into tobacco plants showed that the histone promoter could confer increased expression in meristematic tissues but it is also expressed to significant levels in non-proliferating tissues. Protoplasts prepared from these transgenic tobacco plants were cultivated under different conditions that affect DNA synthesis. Analysis of H4A748-GUS activity revealed (i) the existence of a basal replication-independent activity and (ii) a replication-dependent activity induced in parallel with DNA synthesis. These results show that the histone H4 promoter is able to direct both replication-dependent and -independent gene expression.

In vivo analysis of plant RNA structure: soybean 18S ribosomal and ribulose-1,5-bisphosphate carboxylase small subunit RNAs

A method to investigate the structure of RNA molecules within intact plant tissues has been developed. The RNA structures are analyzed using dimethyl sulfate (DMS), which modifies substituents of adenine and cytosine residues within single-stranded regions of RNA molecules. Reactive sites are identified by primer extension analysis. Using this procedure, an analysis of the secondary structure of the cytoplasmic 18S ribosomal RNA in soybean seedling leaves has been completed. DMS modification data are in good agreement with the phylogenetic structure predicted for soybean 18S rRNA. However, there are a few notable exceptions where residues thought to be involved in double-stranded regions in all 18S rRNAs are strongly modified in soybean leaf samples. These data taken together with the phylogenetic structure suggest that alternate structures may exist in vivo. The further applicability of this technique is demonstrated by comparing the modification pattern obtained in vivo to that obtained in vitro for a particular mRNA molecule encoding the small subunit of ribulose-1,5-bisphosphate carboxylase. The results obtained are compared to a predicted minimum energy secondary structure. The data indicate that the conformation of RNA molecules within the cell may not be reflected in a structural analysis of purified mRNA molecules.

Estrogen-induced ribonuclease activity in Xenopus liver

Estrogen administration to male Xenopus causes the cytoplasmic destabilization of the hepatic serum protein coding mRNAs, most notably, albumin, yet has little effect on mRNAs encoding intracellular proteins such as ferritin. This report describes an estrogen-inducible ribonuclease activity found in liver polysomes that degrades albumin mRNA 4 times faster in vitro than it degrades ferritin mRNA. This differential rate of degradation was observed upon incubation of polysome extract with free liver RNA, isolated liver mRNPs, or transcripts from plasmid vectors. A cleavage fragment consisting of a doublet of approximately 194 nucleotides in length was consistently observed upon digestion of transcripts for the full length or 5' half of albumin mRNA. The generation of this cleavage fragment was used as an assay to study properties of the polysome nuclease activity. The 194 doublet is produced by the action of a Mg(2+)-independent endonuclease. This distinguishes the Xenopus liver enzyme from the enzymes that degrade histone or c-myc mRNA in vitro. It is inactivated by 400 mM NaCl or heating at 90 degrees C, but not by placental ribonuclease inhibitor or N-ethylmaleimide. Finally, the polysomal nuclease activity does not degrade double-stranded RNA. We believe the estrogen-induced nuclease activity contains an enzyme(s) that may mediate hormone-regulated changes in mRNA stability in this tissue.

S. pombe pac1+, whose overexpression inhibits sexual development, encodes a ribonuclease III-like RNase

The Schizosaccharomyces pombe pac1 gene is a multicopy suppressor of the pat1 temperature-sensitive mutation, which directs uncontrolled meiosis at the restrictive temperature. Overexpression of the pac1 gene had no apparent effect on vegetative growth but inhibited mating and sporulation in wild type S. pombe cells. In such cells, expression of certain genes required for mating or meiosis was inhibited. The pac1 gene is essential for vegetative cell growth. The deduced pac1 gene product has 363 amino acids. Its C-terminal 230 residues revealed 25% amino acid identity with ribonuclease III, an enzyme that digests double-stranded RNA and is involved in processing ribosomal RNA precursors and certain mRNAs in Escherichia coli. The pac1 gene product could degrade double-stranded RNA in vitro. These observations establish the presence of a RNase III homolog in eukaryotic cells. The pac1 gene product probably inhibits mating and meiosis by degrading a specific mRNA(s) required for sexual development. It is likely that mRNA processing is involved in the regulation of sexual development in fission yeast.

Role of messenger RNA subcellular localization in the posttranscriptional regulation of human histone gene expression

Histone mRNAs are naturally localized on non-membrane-bound polysomes and selectively destabilized during inhibition of DNA replication. Targeting histone mRNA to membrane-bound polysomes, by incorporating sequences coding for a signal peptide into the message, results in the stabilization of the histone fusion mRNA when DNA synthesis is interrupted (Zambetti et al.: Proceedings of the National Academy of Sciences of the United States of America 84:2683-2687, 1987). A single nucleotide substitution that abolishes the synthesis of the signal peptide results in the localization of the histone fusion mRNA on non-membrane-bound polysomes to the same extent as endogenous histone mRNA and fully restores the coupling of histone fusion mRNA stability to DNA replication. Signal peptide-histone fusion mRNAs containing two point mutations that result in the incorporation of two positively charged amino acids into the hydrophobic domain of the signal peptide are partially retained on non-membrane-bound polysomes and are partially destabilized during inhibition of DNA synthesis. These data indicate that the degree to which the signal peptide-histone fusion mRNAs are associated with non-membrane-bound polysomes is correlated with the extent to which the mRNAs are degraded during inhibition of DNA synthesis. These results suggest that the subcellular location of histone mRNA plays an important role in the posttranscriptional regulation of histone gene expression.

Modifications in molecular mechanisms associated with control of cell cycle regulated human histone gene expression during differentiation

Histone proteins are preferentially synthesized during the S-phase of the cell cycle, and the temporal and functional coupling of histone gene expression with DNA replication is mediated at both the transcriptional and posttranscriptional levels. The genes are transcribed throughout the cell cycle, and a 3-5-fold enhancement in the rate of transcription occurs during the first 2 h following initiation of DNA synthesis. Control of histone mRNA stability also accounts for some of the 20-100fold increase in cellular histone mRNA levels during S-phase and for the rapid and selective degradation of the mRNAs at the natural completion of DNA replication or when DNA synthesis is inhibited. Two segments of the proximal promoter, designated Sites I and II, influence the specificity and rate of histone gene transcription. Occupancy of Sites I and II during all periods of the cell cycle by three transacting factors (HiNF-A, HiNF-C, and HiNF-D) suggests that these protein-DNA interactions are responsible for the constitutive transcription of histone genes. Binding of HiNF-D in Site II is selectively lost, whereas occupancy of Site I by HiNF-A and -C persists when histone gene transcription is down regulated when cells terminally differentiate. These results are consistent with a primary role for interactions of HiNF-D with a proximal promoter element in rendering cell growth regulated human histone genes transcribable in proliferating cells.

Analysis of the multiple 5' and 3' termini of poly(A)+ and poly(A)-deficient thymidylate synthase mRNA in growth-stimulated mouse fibroblasts

Thymidylate synthase (TS) mRNA content increases about 20-fold when growth-stimulated mouse cells progress from the G0/G1 phase into the S phase of the cell cycle. Previous studies, using a cell line in which the TS gene is amplified (LU3-7), indicated that transcriptional initiation as well as polyadenylation of the mRNA occur at several locations in unsynchronized cells. In the present study, we have used S1 nuclease protection assays to analyze the possible significance of the multiple transcriptional initiation and polyadenylation sites. We found that the same pattern of 5' and 3' termini were detected with RNA isolated from the overproducing cells as with RNA isolated from the parental mouse 3T6 cell line, demonstrating that the heterogeneous termini are not a consequence of gene amplification. There was no change in the pattern of 5' or 3' termini with either cell line during the progression from G1 phase through S phase in serum-stimulated cells. Therefore, the increase in TS mRNA content is not the result of differential utilization of the various transcriptional initiation or polyadenylation sites. Analyses of poly(A)- deficient cytoplasmic TS RNA showed that the 5' termini were the same as those found in poly(A) + mRNA. However, the 3' termini were extremely heterogeneous in length. Although some of the poly(A)- deficient RNA extended beyond the normal site of polyadenylation, most of it was shorter than full-length TS mRNA.

A model for the structure and functions of iron-responsive elements

Most eukaryotic cells express two proteins, whose biosynthetic rates are determined by the intracellular iron status. The genes for both these proteins, ferritin and the transferrin receptor (TfR), are regulated at the post-transcriptional level, but by entirely different mechanisms. Ferritin mRNA levels are not affected by acute changes in iron availability. Ferritin biosynthesis is regulated translationally via a defined element contained within the 5' untranslated region (UTR) of the ferritin mRNA. This element has been highly conserved during evolution and has been termed an iron-responsive element (IRE). In contrast to ferritin, the regulation of TfR biosynthesis is mirrored by equivalent changes in TfR mRNA levels. The genetic information for this regulation is mostly located in the region of the gene encoding the 3' UTR of the TfR mRNA. Five elements that closely resemble the ferritin IRE are contained within the region which is critical for TfR regulation. The IRE is suggested to function by forming a specific stem-loop structure that interacts with a transacting factor in an iron-dependent fashion. We present a model that accommodates the mediation of distinct post-transcriptional regulatory phenomena via IREs.

Kinetics of accumulation and depletion of soluble newly synthesized histone in the reciprocal regulation of histone and DNA synthesis

Procedures are presented which permit the identification and analysis of cellular histone that is not bound to chromatin. This histone, called soluble histone, could be distinguished from that bound to chromatin by the state of H4 modification and the lack of H2A ubiquitination. Changes in the levels of newly synthesized soluble histone were analyzed with respect to the balance between histone and DNA synthesis in hamster ovary cells. Pulse-chase protocols suggested that the chase of newly synthesized histone from the soluble fraction into chromatin may have two kinetic components with half-depletion times of about 1 and 40 min. When protein synthesis was inhibited, the pulse-chase kinetics of newly synthesized histone from the solubl fraction into chromatin were not significantly altered from those of the control. However, in contrast to the control, when protein synthesis was inhibited, DNA synthesis was also inhibited with kinetics similar to those of the chase of newly synthesized histone from the soluble fraction. There was a rapid decrease in the rate of DNA synthesis with a half-deceleration time of 1 min down to about 30% of the control rate, followed by a slower decrease with an approximate half-deceleration time of 40 min. When DNA synthesis was inhibited, newly synthesized histone accumulated in the soluble fraction, but H2A and H2B continued to complex with chromatin at a significant rate. Soluble histone in G1 cells showed the same differential partitioning of H4/H3 and H2A/H2B between the soluble and chromatin-bound fractions as was found in cycling cells with inhibited DNA synthesis. These results support a unified model of reciprocal regulatory mechanisms between histone and DNA synthesis in the assembly of chromatin.

Correlation between tubulin mRNA stability and poly(A) length over the cell cycle of Physarum polycephalum

During the cell cycle of the Physarum polycephalum plasmodium, levels of alpha-tubulin mRNA rise exponentially in G2 phase, reach a peak at metaphase 40-fold above basal levels, and then fall exponentially to basal levels after mitosis. We show that post-mitotic alpha-tubulin mRNA carries poly(A) tracts of less than 30 residues. By contrast, when levels of alpha-tubulin mRNA rise during G2 phase, the mRNA has a poly(A) tract of approximately 80 bases. The length of the poly(A) tract of any mRNA encoding actin is relatively constant at fewer than 30 bases through the cycle. We have estimated the apparent rate of synthesis of alpha-tubulin mRNA at different stages of the cell cycle by short-term labeling in vivo. Transcription of alpha-tubulin mRNA continues even after mitosis, though the rate may be diminished relative to that in late G2 phase. So, the post-mitotic molecular half-life of alpha-tubulin mRNA must be less than the 19 minute half-life by which the levels of this species fall. The fact that the apparent rate of alpha-tubulin mRNA synthesis is not vastly greater in early G2 phase than in post-mitotic plasmodia is consistent with an S-phase destabilization of alpha-tubulin mRNA molecules. Thus, the poly(A) tail is shorter when the alpha-tubulin mRNA is less stable.