Nuclear mRNA export

Effects of estradiol and progesterone on the reproduction of the freshwater crayfish Cherax albidus

In this study we have investigated the role of 17beta-estradiol and progesterone in the reproduction of the crayfish Cherax albidus by using vitellogenin (VTG) as a biomarker. Early-vitellogenic (EV), full-vitellogenic (FV), and non-vitellogenic (NV) females of Cherax albidus were treated with 17beta-estradiol, progesterone, or both for 4 weeks. Levels of VTG mRNA in the hepatopancreas were detected by RT-PCR. The PCR product was sequenced and showed 97% homology with Cherax quadricarinatus VTG. 17beta-estradiol was more effective than progesterone and 17beta-estradiol plus progesterone in increasing the vitellogenin transcript in the hepatopancreas of EV and FV females. On the contrary, progesterone was more effective than 17beta-estradiol and 17beta-estradiol plus progesterone in increasing the vitellogenin concentration in the hemolymph of EV and FV females. Hepatopancreas histology and fatty acid composition of females injected with hormones showed major modifications. No effects were registered in NV females. In conclusion, 17beta-estradiol and progesterone influence VTG synthesis, although our data indicate that they act through different pathways and are not effective until the proper hormonal environment is established, as demonstrated by their inefficacy in NV females.

[Understanding of molecular biology]

OBJECTIVES

To display theorical and methodological basis of the molecular biology. To point out its main medical applications.

DATA SOURCES

For this review, we analysed the English and French literature concerning the research and clinical aspects of the molecular biology, especially in anaesthesiology and intensive care, using the Medline database. The current textbooks were also used.

STUDY SELECTION

We selected: 1) the original articles corresponding to the main advances that resulted in the present state of this discipline; 2) the reviews; 3) some chapters of textbooks.

DATA EXTRACTION

In this review, we report: 1) the current knowledge concerning the conservation and the expression of the genome; 2) the principles of the most widely used experimental techniques; 3) the medical applications of this knowledge in anaesthesiology and intensive care; 4) the more recent developments of this research field.

DATA SYNTHESIS

Within medical biology, molecular biology essentially corresponds to the study of nucleic acids. In this review, the general principles governing the organization and expression of the genome are discussed. The expansion of molecular biology has been a consequence of the widespread use of enzymatic tools, of which bacterial restriction enzymes were the first. Numerous enzymes are now available, permitting DNA strands to be cut, linked, synthesized and sequenced. Several of the most representative molecular biology techniques are described. Some of them, such as PCR, are commonly used in clinical situations. Animal experimental models have also been generated by genome altering methods, in order to analyse the phenotypic consequences of these modifications. Recently, a viable mammal, deriving from a differentiated cell, has been cloned. Human embryonic totipotent stem cells are now available in cultures. These advances have important ethical implications whilst, at the same time, offering new opportunities for medical applications. The state of gene therapy and human genome sequencing programmes is discussed.

Somatic Mutations Within the Untranslated Regions of Rearranged Ig Genes in a Case of Classical Hodgkin’s Disease as a Potential Cause for the Absence of Ig in the Lymphoma Cells

Hodgkin–Reed-Sternberg (H-RS) cells are clonal B cells carrying Ig gene rearrangements. However, in situ hybridization methods failed to demonstrate Ig gene expression in H-RS cells of classical Hodgkin’s disease (HD). Because somatic mutations rendering potentially functional Ig gene rearrangements nonfunctional were detected in some cases of the disease, it was speculated that H-RS cells in classical HD may have lost the ability to express antigen receptor as a rule. Recently, we established a novel cell line (L1236) from H-RS cells of a patient with mixed cellularity subtype of HD. L1236 cells harbor a potentially functional VH1 and a potentially functional Vκ3 gene rearrangement. However, no antibody expression was detected. To show potential reasons for this lack of Ig expression, we analyzed the genomic organization of the Ig genes and their transcription in the primary and cultivated H-RS cells of this patient. The H-RS cells were found to have switched their isotype to IgG4, confirming their mature B-cell nature. By amplifying cDNA from L1236 cells as well as from frozen biopsy material transcripts of the Vκ3 and the VH1 gene rearrangement were detected for both sources of cDNA. However, Northern blot hybridization of L1236 RNA failed to demonstrate VH1 and Vκ3 transcripts, indicating only a low level of transcription. Sequence analysis of the promoter and leader regions of the VH1 gene rearrangement from L1236 cells as well as from lymphoma-affected tissue showed a somatic mutation in the conserved octamer motif of the promoter region. Somatic mutations were also detected within the 3′ splice site of the leader intron and adjacent nucleotides in the rearranged Vκ light chain gene, leading to aberrant splicing. These mutations might prevent the generation of adequate amounts of functional Ig gene transcripts as template for translation into protein. Thus, mutations in H-RS cells that prevent Ig gene expression might also be located outside the coding region of the Ig genes.

Somatic Mutations Within the Untranslated Regions of Rearranged Ig Genes in a Case of Classical Hodgkin’s Disease as a Potential Cause for the Absence of Ig in the Lymphoma Cells

Hodgkin–Reed-Sternberg (H-RS) cells are clonal B cells carrying Ig gene rearrangements. However, in situ hybridization methods failed to demonstrate Ig gene expression in H-RS cells of classical Hodgkin’s disease (HD). Because somatic mutations rendering potentially functional Ig gene rearrangements nonfunctional were detected in some cases of the disease, it was speculated that H-RS cells in classical HD may have lost the ability to express antigen receptor as a rule. Recently, we established a novel cell line (L1236) from H-RS cells of a patient with mixed cellularity subtype of HD. L1236 cells harbor a potentially functional VH1 and a potentially functional Vκ3 gene rearrangement. However, no antibody expression was detected. To show potential reasons for this lack of Ig expression, we analyzed the genomic organization of the Ig genes and their transcription in the primary and cultivated H-RS cells of this patient. The H-RS cells were found to have switched their isotype to IgG4, confirming their mature B-cell nature. By amplifying cDNA from L1236 cells as well as from frozen biopsy material transcripts of the Vκ3 and the VH1 gene rearrangement were detected for both sources of cDNA. However, Northern blot hybridization of L1236 RNA failed to demonstrate VH1 and Vκ3 transcripts, indicating only a low level of transcription. Sequence analysis of the promoter and leader regions of the VH1 gene rearrangement from L1236 cells as well as from lymphoma-affected tissue showed a somatic mutation in the conserved octamer motif of the promoter region. Somatic mutations were also detected within the 3′ splice site of the leader intron and adjacent nucleotides in the rearranged Vκ light chain gene, leading to aberrant splicing. These mutations might prevent the generation of adequate amounts of functional Ig gene transcripts as template for translation into protein. Thus, mutations in H-RS cells that prevent Ig gene expression might also be located outside the coding region of the Ig genes.

Nuclear history of a pre-mRNA determines the translational activity of cytoplasmic mRNA

The pathways of synthesis and maturation of pre-messenger RNA in the nucleus have a direct effect on the translational efficiency of mRNA in the cytoplasm. The transcription of intron-less mRNA in vivo directs this mRNA towards translational silencing. The presence of an intron at the 5' end of the transcript relieves this silencing, whereas an intron at the 3' end further represses translation. These regulatory events are strongly dependent on the transcription of pre-mRNA in the nucleus. The impact of nuclear history on regulatory events in the cytoplasm provides a novel mechanism for the control of gene expression.

PCF11 encodes a third protein component of yeast cleavage and polyadenylation factor I

Cleavage and polyadenylation factor I (CF I) is one of four factors required in vitro for yeast pre-mRNA 3'-end processing. Two protein components of this factor, encoded by genes RNA14 and RNA15, have already been identified. We describe here another gene, PCF11 (for protein 1 of CF I), that genetically interacts with RNA14 and RNA15 and which presumably codes for a third protein component of CF I. This gene was isolated in a two-hybrid screening designed to identify proteins interacting with Rna14 and Rna15. PCF11 is an essential gene encoding for a protein of 626 amino acids having an apparent molecular mass of 70 kDa. Thermosensitive mutations in PCF11 are synergistically lethal with thermosensitive alleles of RNA14 and RNA15. The Pcf11-2 thermosensitive strain shows a shortening of the poly(A) tails and a strong decrease in the steady-state level of actin transcripts after a shift to the nonpermissive temperature as do the thermosensitive alleles of RNA14 and RNA15. Extracts from the pcf11-1 and pcf11-2 thermosensitive strains and the wild-type strain, when Pcf11 is neutralized by specific antibodies, are deficient in cleavage and polyadenylation. Moreover, fractions obtained by anion-exchange chromatography of extracts from the wild-type strain contain both Pcf11 and Rna15 in the same fractions, as shown by immunoblotting with a Pcf11-specific antibody.

mRNA export correlates with activation of transcription in human subgroup C adenovirus-infected cells

To investigate the mechanisms by which viral mRNA species are distinguished from their cellular counterparts for export to the cytoplasm during the late phase of subgroup C adenovirus infection, we have examined the metabolism of several cellular and viral mRNAs in human cells productively infected by adenovirus type 5 (Ad5). Several cellular mRNAs that were refractory to, or could escape from, adenovirus-induced inhibition of export of mRNA from the nucleus have been identified. This group includes Hsp70 mRNAs synthesized upon heat shock of Ad5-infected 293 or HeLa cells during the late phase of infection. However, successful export in Ad5-infected cells is not a specific response to heat shock, for beta-tubulin and interferon-inducible mRNAs were also refractory to virus-induced export inhibition. The export of these cellular mRNAs, like that of viral late mRNAs, required the E1B 55-kDa protein. Export to the cytoplasm during the late phase of Ad5 infection of several cellular mRNAs, including members of the Hsp70 family whose export was inhibited under some, but not other, conditions, indicates that viral mRNA species cannot be selectively exported by virtue of specific sequence or structural features. Cellular and viral late mRNAs that can be exported from the nucleus to the cytoplasm were expressed from genes whose transcription was induced or activated during the late phase of Ad5 infection. Consistent with the possibility that successful export is governed by transcriptional activation in the late phase of adenovirus infection, newly synthesized viral early E1A mRNA was subject to export inhibition during the late phase of infection.

Coupling transcription to translation: a novel site for the regulation of eukaryotic gene expression

Recent experiments using Xenopus oocytes demonstrate that the history of a particular mRNA in the nucleus can influence the efficiency with which that mRNA will be utilized by the translational machinery. Individual promoter elements, specific protein-RNA interactions and the splicing process within the nucleus can all influence translational fate within the cytoplasm. Central to the regulatory mechanisms influencing the translation process is the packaging of mRNA by a highly conserved family of Y-box proteins. These Y-box proteins are found in cytoplasmic messenger ribonucleoprotein particles where they have a causal role in restricting the recruitment of mRNA to the translational machinery. Nuclear processes influence the packaging of mRNA by the Y-box proteins in the cytoplasm and in consequence mRNA translation. This functional coupling provides a novel site for the regulation of eukaryotic gene expression.

Nuclear retention of COL1A1 messenger RNA identifies null alleles causing mild osteogenesis imperfecta

Osteogenesis imperfecta (OI) is a heritable connective tissue disorder characterized by bone fragility. Most cases of severe OI result from mutations in the coding region of the COL1A1 or COL1A2 genes yielding an abnormal collagen alpha chain. In contrast, many patients with mild OI show evidence of a null allele due to a premature stop mutation in the mutant RNA transcript. We have previously described a null allele arising from a splice donor mutation where the transcript containing the included intron was sequestered in the nucleus. Here we demonstrate that transcripts from null alleles arising from premature stop mutations are also present in the nucleus and absent in the cytoplasm. Using reverse transcriptase-PCR and single-strand conformational polymorphism of COL1A1 mRNA from patients with mild OI, we describe three patients with distinct null producing mutations identified from the mutant transcript within the nuclear compartment. A fourth patient with a Gly--->Arg expressed point mutation exhibits the mutant transcript in both compartments. Defining the distribution of allelic variants of COL1A1 mRNA in the nuclear and cytoplasmic compartments gives further insight into cell biology of OI and provides a strategy for investigating potential causes of a null allele.

Nucleolar accumulation of poly (A)+ RNA in heat-shocked yeast cells: implication of nucleolar involvement in mRNA transport

Transport of mRNA from the nucleus to the cytoplasm plays an important role in gene expression in eukaryotic cells. In wild-type Schizosaccharomyces pombe cells poly(A)+ RNA is uniformly distributed throughout the nucleoplasm and cytoplasm. However, we found that a severe heat shock blocks mRNA transport in S. pombe, resulting in the accumulation of bulk poly(A)+ RNA, as well as a specific intron-less transcript, in the nucleoli. Pretreatment of cells with a mild heat shock, which induces heat shock proteins, before a severe heat shock protects the mRNA transport machinery and allows mRNA transport to proceed unimpeded. In heat-shocked S. pombe cells, the nucleolar region condensed into a few compact structures. Interestingly, poly(A)+ RNA accumulated predominantly in the condensed nucleolar regions of the heat-shocked cells. These data suggest that the yeast nucleolus may play a role in mRNA transport in addition to its roles in rRNA synthesis and preribosome assembly.

Effects of mutations in the Saccharomyces cerevisiae RNA14, RNA15, and PAP1 genes on polyadenylation in vivo

The RNA14 and RNA15 gene products have been implicated in a variety of cellular processes. Mutations in these genes lead to faster decay of some mRNAs and yield extracts that are deficient in cleavage and polyadenylation in vitro. These results suggest that the RNA14 and RNA15 gene products may be involved in both adenylation and deadenylation in vivo. To explore the roles of these gene products in vivo, we examined the site of adenylation and the rate of deadenylation for individual mRNAs in rna14 and rna15 mutant strains. We observed that the rates of deadenylation are not affected by lesions in either the RNA14 or the RNA15 gene. This result suggests that the proteins encoded by these genes are not involved in regulation of the deadenylation rate. In contrast, we observed that the site of adenylation for the ACT1 transcript can be altered in these mutants. Interestingly, we also observed that mutation of the poly(A) polymerase gene altered the site of ACT1 polyadenylation. These observations suggest that the RNA14, RNA15, and PAP1 proteins are involved in poly(A) site choice. This alteration in poly(A) site choice in the rna14 mutant can be corrected by the ssm4 suppressor, indicating that this suppression acts at the level of polyadenylation and not by slowing mRNA degradation.

Nucleolar accumulation of poly (A)+ RNA in heat-shocked yeast cells: implication of nucleolar involvement in mRNA transport

Transport of mRNA from the nucleus to the cytoplasm plays an important role in gene expression in eukaryotic cells. In wild-type Schizosaccharomyces pombe cells poly(A)+ RNA is uniformly distributed throughout the nucleoplasm and cytoplasm. However, we found that a severe heat shock blocks mRNA transport in S. pombe, resulting in the accumulation of bulk poly(A)+ RNA, as well as a specific intron-less transcript, in the nucleoli. Pretreatment of cells with a mild heat shock, which induces heat shock proteins, before a severe heat shock protects the mRNA transport machinery and allows mRNA transport to proceed unimpeded. In heat-shocked S. pombe cells, the nucleolar region condensed into a few compact structures. Interestingly, poly(A)+ RNA accumulated predominantly in the condensed nucleolar regions of the heat-shocked cells. These data suggest that the yeast nucleolus may play a role in mRNA transport in addition to its roles in rRNA synthesis and preribosome assembly.

Tissue distribution, hormone regulation and evidence for a human homologue of the estrogen-inducible Xenopus laevis vitellogenin mRNA binding protein

17 beta-estradiol induces the synthesis of massive amounts of the hepatic mRNA encoding the Xenopus laevis egg yolk precursor protein, vitellogenin. Vitellogenin mRNA exhibits a half life of approx. 500 h when 17 beta-estradiol is present, and 16 h after removal of 17 beta-estradiol from the culture medium. We recently reported that Xenopus liver contains a protein, which is induced by 17 beta-estradiol and binds with a high degree of specificity to a binding site in a segment of the 3'-untranslated region (3'-UTR) of vitellogenin mRNA implicated in 17 beta-estradiol stabilization of vitellogenin mRNA. To determine if this mRNA binding protein was specific to this system, or if it was present elsewhere, and regulated by other steroids, we examined the tissue distribution and androgen regulation of this protein. Substantial amounts of the vitellogenin 3'-UTR binding protein were found in several Xenopus tissues including testis, ovary and muscle. In the absence of hormone treatment, lung and intestine contained minimal levels of the mRNA binding protein. Testosterone administration induced the vitellogenin 3'-UTR RNA binding protein in several tissues. Additionally, we found a homologous mRNA binding protein in MCF-7, human breast cancer cells. Although the MCF-7 cell protein was not induced by 17 beta-estradiol, the MCF-7 cell mRNA binding protein appears to be closely related to the Xenopus protein since: (i) the human and Xenopus proteins elicit gel shifted bands with the same electrophoretic mobility using the vitellogenin mRNA 3'-UTR binding site; (ii) The human and Xenopus proteins exhibit similar binding specificity for the vitellogenin 3'-UTR RNA binding site; and (iii) RNA from MCF-7 cells is at least as effective as RNA from control male Xenopus liver in blocking the binding of the Xenopus and human proteins to the vitellogenin mRNA 3'-UTR binding site. Its broad tissue distribution and regulation by both 17 beta-estradiol and testosterone suggests that this mRNA binding protein may play a significant role in steroid hormone regulation of mRNA metabolism in many vertebrate cells.

A conditional allele of the novel repeat-containing yeast nucleoporin RAT7/NUP159 causes both rapid cessation of mRNA export and reversible clustering of nuclear pore complexes

In a screen for Saccharomyces cerevisiae genes required for nucleocytoplasmic transport of messenger RNA, we identified the RAT7 gene (ribonucleic acid trafficking), which encodes an essential protein of 1,460 amino acids. Rat7p is located at the nuclear rim in a punctate pattern characteristic of nucleoporins. Furthermore, the central third of Rat7p contains 22 XXFG and three XFXFG degenerate repeats that are similar to signature GLFG and XFXFG repeats present in a majority of yeast and some mammalian nucleoporins sequenced to date. Shift of a strain bearing the temperature-sensitive rat7-1 allele from 23 degrees C to 37 degrees C resulted in rapid (within 15 minutes) cessation of mRNA export, but did not cause concomitant cytoplasmic accumulation of a reporter protein bearing a nuclear localization signal. This suggests that Rat7p may play a direct role in nucleocytoplasmic export of RNA. Immunofluorescence and thin section electron microscopy revealed that in rat7-1 cells grown at 23 degrees C, the majority of nuclear pore complexes (NPCs) were clustered on one side of the nucleus. No ultrastructural abnormalities of the nuclear envelope were seen. Interestingly, shifting rat7-1 cells to 37 degrees C for 1 h caused the NPCs to disperse, restoring near wild-type NPC distribution. After this temperature shift, the mutant Rat7p was no longer detectable by immunofluorescence.

Transgenic targeting of neuroendocrine peptide genes in the hypothalamic-pituitary axis

A large number of neuroendocrine peptide genes have been tested for their ability to target expression to the hypothalamus and pituitary in transgenic mice. This has resulted in a number of powerful applications, for example, ablation or immortalization of specific cell types, and analysis of transcription regulatory sequences. The greatest amount of success in targeting cells of the neuroendocrine axis has been in the pituitary and has utilized regulatory sequences of genes that are normally expressed in pituitary. Greater difficulties have been encountered in directing expression to specific neurons in the hypothalamus. A primary goal of this review is to consider collectively the data obtained by a number of laboratories in order to draw conclusions about the general sequence requirements for achieving cell-specific expression. The data suggest that the mechanisms controlling cell-specific expression of neuropeptide genes in the hypothalamus are complex and involve multiple regulatory elements that may reside within the gene or many kilobases away from the promoter. These elements act positively and negatively in different cells to enhance or restrict expression, and may include sequences that shield a transgene from regulatory influences of other genes near the point of chromosomal insertion.

Diverse effects of the guanine nucleotide exchange factor RCC1 on RNA transport

Transport of RNAs within nuclei and through nuclear pore complexes (NPCs) are essential, but poorly understood, steps in gene expression. In experiments with mammalian cells, RCC1, the abundant nuclear guanine nucleotide exchange factor for the guanosine triphosphatase Ran/TC4, was shown to be required for nucleocytoplasmic transport of precursors of spliceosomal small nuclear RNAs (snRNAs), intranuclear transport of U3 snRNA, and processing of ribosomal RNAs, but not for export of transfer RNAs. It is proposed that guanosine triphosphate (GTP)-bound Ran/TC4 associates with ribonucleoprotein particles (RNPs) during intranuclear movement, and that GTP hydrolysis promotes deposition of RNPs at targeted sites such as NPCs or nucleoli.

Nuclear export pathways of tRNA and 40 S ribosomes include both common and specific intermediates

Different classes of RNAs are exported from Xenopus laevis oocyte nuclei by facilitated pathways. We have performed kinetic competition analyses to investigate the relationship between the export pathways of microinjected tRNA and ribosomal subunits. Saturating concentrations of ribosomal subunits do not compete tRNA export. Thus, the saturable factor in the ribosomal subunit export pathway is not limiting for tRNA export. The co-microinjection of ribosomal subunits did, however, stimulate the rate of tRNA export. Co-injected mRNA also stimulated tRNA export. tRNA export itself displays positive cooperative export kinetics that are abrogated by saturating concentrations of rRNA. These results are consistent with the existence of common high affinity RNA-binding sites that can be titrated with tRNA, rRNA or ribosomal subunits, and mRNA. Furthermore, high concentrations of tRNA are also shown to have moderate inhibitory effects on 40 S subunit export, indicating a lower affinity common intermediate also shared by mRNA.

The metabolism of small cellular RNA species during productive subgroup C adenovirus infection

During the late phase of subgroup C adenovirus infection, export of cellular mRNA from the nucleus to the cytoplasm is inhibited. In one approach to investigate the mechanism whereby viral late mRNAs are selected for export, we have examined the metabolism of small cellular RNA species transcribed by all three RNA polymerases during the late phase of Ad5 infection. No changes in the quantities of [3H]uridine-labeled 5S rRNA or tRNAs entering the cytoplasm were observed in infected cells. Adenovirus type 5 infection reduced the nuclear and cytoplasmic populations of the newly synthesized, snRNP-associated snRNAs U1, U2, U4, U5, and U6. Transcription of a representative snRNA, U1 RNA, was not inhibited, indicating that the post-transcriptional metabolism of snRNAs was perturbed during the late phase of infection. The increased cytoplasmic concentration of newly synthesized U1 RNA in Ad5- compared to mock-infected cells, and the greater reduction of the snRNP-associated compared to the total U1 RNA population, indicated that snRNP assembly in the cytoplasm was impaired. As adenovirus infection does not perturb export from the nucleus of small cellular mRNAs transcribed by RNA polymerases II and III, viral mRNA must be distinguished for selective export at a nuclear step upstream of translocation to the cytoplasm via nuclear pore complexes.

Nup145p is required for nuclear export of mRNA and binds homopolymeric RNA in vitro via a novel conserved motif

An essential yeast protein, Nup145p, is identified via its genetic interaction with the nucleoporin Nsp1p. Nup145p contains GLFG repeats and localizes to nuclear pores. Depletion of Nup145p in vivo leads rapidly to nuclear retention of polyadenylated RNAs and more slowly to cytoplasmic accumulation of a nuclear reporter protein. A stretch of 140 amino acids within Nup145p is conserved in two other yeast nucleoporins, Nup116p and Nup100p, and in an uncharacterized C. elegans protein. Genetic experiments in yeast reveal that the three copies of the motif carry out an essential, redundant function. Fragments of Nup145p and Nup116p including this motif bind specifically to homopolymeric RNAs in vitro. Nup145p, Nup116p, and Nup100p thus represent a novel class of nucleoporins involved in nucleocytoplasmic transport.

Nuclear pore complex ion channels (review)

It is currently thought that nuclear pore complexes (NPCs) primarily govern nucleocytoplasmic interactions via selective recognition and active transport of macromolecules. However, in various nuclear preparations, patch-clamp and fluorescence, luminiscence and ion microscopy support classical microelectrode measurements indicating that monoatomic ion flow across the nuclear envelope (NE) is strictly regulated. Gating of large conductance nuclear envelope ion channels (NICs) somewhat resembles that of gap junctional channels. In other respects, NICs are distinct in that they require cytosolic factors, are blocked by wheat germ agglutinin and are blocked and/or modified by antibodies to epitopes of NPC glycoproteins. Therefore, NIC activity, recorded as electrical current/conductance is likely to be intrinsic to NPCs. This observation suggests a potential use for the patch-clamp technique in establishing the mechanisms underlying nuclear pore gating in response to cytosolic and nucleosolic factors such as transcription and growth factors, oncogene and proto-oncogene products and receptors for retinoids, steroids and thyroid hormone. NIC activity may also be useful in evaluating the mechanisms of nuclear import of foreign nucleic acid material such as that contained in virons and viroids. Finally, in consideration to the electrophysiological data accumulated so far, the study of nuclear pore ion channel activity may help our understanding of other important issues such as cell suicide, programmed cell death or apoptosis.

An amino-terminal tetrapeptide specifies cotranslational degradation of beta-tubulin but not alpha-tubulin mRNAs

The steady-state level of alpha- and beta-tubulin synthesis is autoregulated by a posttranscriptional mechanism that selectively alters alpha- and beta-tubulin mRNA levels in response to changes in the unassembled tubulin subunit concentration. For beta-tubulin mRNAs, previous efforts have shown that this is the result of a selective mRNA degradation mechanism which involves cotranslational recognition of the nascent amino-terminal beta-tubulin tetrapeptide as it emerges from the ribosome. Site-directed mutagenesis is now used to determine that the minimal sequence requirement for conferring the full range of beta-tubulin autoregulation is the amino-terminal tetrapeptide MR(E/D)I. Although tubulin-dependent changes in alpha-tubulin mRNA levels are shown to result from changes in cytoplasmic mRNA stability, transfection of wild-type and mutated alpha-tubulin genes reveals that alpha- and beta-tubulin mRNA degradation is not mediated through a common pathway. Not only does the amino-terminal alpha-tubulin tetrapeptide MREC fail to confer regulated mRNA degradation, neither wild-type alpha-tubulin transgenes nor an alpha-tubulin gene mutated to encode an amino-terminal MREI yields mRNAs that are autoregulated. Further, although slowing ribosome transit accelerates the autoregulated degradation of endogenous alpha- and beta-tubulin mRNAs, degradation of alpha-tubulin transgene mRNAs is not enhanced, and in one case, the mRNA is actually stabilized. We conclude that, despite similarities, alpha- and beta-tubulin mRNA destabilization pathways utilize divergent determinants to link RNA instability to tubulin subunit concentrations.

Nucleocytoplasmic transport

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An amino-terminal tetrapeptide specifies cotranslational degradation of beta-tubulin but not alpha-tubulin mRNAs

The steady-state level of alpha- and beta-tubulin synthesis is autoregulated by a posttranscriptional mechanism that selectively alters alpha- and beta-tubulin mRNA levels in response to changes in the unassembled tubulin subunit concentration. For beta-tubulin mRNAs, previous efforts have shown that this is the result of a selective mRNA degradation mechanism which involves cotranslational recognition of the nascent amino-terminal beta-tubulin tetrapeptide as it emerges from the ribosome. Site-directed mutagenesis is now used to determine that the minimal sequence requirement for conferring the full range of beta-tubulin autoregulation is the amino-terminal tetrapeptide MR(E/D)I. Although tubulin-dependent changes in alpha-tubulin mRNA levels are shown to result from changes in cytoplasmic mRNA stability, transfection of wild-type and mutated alpha-tubulin genes reveals that alpha- and beta-tubulin mRNA degradation is not mediated through a common pathway. Not only does the amino-terminal alpha-tubulin tetrapeptide MREC fail to confer regulated mRNA degradation, neither wild-type alpha-tubulin transgenes nor an alpha-tubulin gene mutated to encode an amino-terminal MREI yields mRNAs that are autoregulated. Further, although slowing ribosome transit accelerates the autoregulated degradation of endogenous alpha- and beta-tubulin mRNAs, degradation of alpha-tubulin transgene mRNAs is not enhanced, and in one case, the mRNA is actually stabilized. We conclude that, despite similarities, alpha- and beta-tubulin mRNA destabilization pathways utilize divergent determinants to link RNA instability to tubulin subunit concentrations.

Inactivation of gene expression in plants as a consequence of specific sequence duplication

Numerous examples now exist in plants where the insertion of multiple copies of a transgene leads to loss of expression of some or all copies of the transgene. Where the transgene contains sequences homologous to an endogenous gene, expression of both transgene and endogenous gene is sometimes found to be impaired. Several examples of these phenomena displaying different features are reviewed. Possible explanations for the observed phenomena are outlined, drawing on known cellular processes in Drosophila, fungi, and mammals as well as plants. It is hypothesized that duplicated sequences can, under certain circumstances, become involved in cycles of hybrid chromatin formation or other processes that generate the potential for modification of inherited chromatin structure and cytosine methylation patterns. These epigenetic changes could lead to altered transcription rates or altered efficiencies of mRNA maturation and export from the nucleus. Where the loss of gene expression is posttranscriptional, antisense RNA could be formed on accumulated, inefficiently processed RNAs by an RNA-dependent RNA polymerase or from a chromosomal promoter and cause the observed loss of homologous mRNAs and possibly the modification of homologous genes. It is suggested that the mechanisms evolved to help silence the many copies of transposable elements in plants. Multicopy genes that are part of the normal gene catalog of a plant species must have evolved to avoid these silencing mechanisms or their consequences.

mRNA nuclear export

The export of mRNA from the nucleus to the cytoplasm is an essential step in the expression of genetic information in eukaryotes. It is an energy-dependent process and involves transport across the nuclear pores. It requires both cis-acting ribonucleoprotein particle signals and specific trans-acting factors. Although much remains to be learned, recent information has begun to define this pathway at both the cellular and biochemical levels and indicates that it is used as a key regulatory step by several viruses.

Nuclear export of different classes of RNA is mediated by specific factors

Various classes of RNA are exported from the nucleus to the cytoplasm, including transcripts of RNA polymerase I (large ribosomal RNAs), II (U-rich small nuclear RNAs [U snRNAs], mRNAs), and III (tRNAs, 5S RNA). Here, evidence is presented that some steps in the export of various classes of nuclear RNA are mediated by specific rather than common factors. Using microinjection into Xenopus oocytes, it is shown that a tRNA, a U snRNA, and an mRNA competitively inhibit their own export at concentrations at which they have no effect on the export of heterologous RNAs. While the export of both U snRNAs and mRNAs is enhanced by their 7-methyl guanosine cap structures, factors recognizing this structure are found to be limiting in concentration only in the case of U snRNAs. In addition to the specific factors, evidence for steps in the export process that may be common to at least some classes of RNA are provided by experiments in which synthetic homopolymeric RNAs are used as inhibitors.

Influenza virus NS1 protein inhibits pre-mRNA splicing and blocks mRNA nucleocytoplasmic transport

The influenza virus RNA segment 8 encodes two proteins, NS1 and NS2, by differential splicing. The collinear transcript acts as mRNA for NS1 protein, while the spliced mRNA encodes NS2 protein. The splicing of NS1 mRNA was studied in cells transfected with a recombinant plasmid that has the cDNA of RNA segment 8 cloned under the SV40 late promoter and polyadenylation signals. As described for influenza virus-infected cells, NS1 mRNA was poorly spliced to yield NS2 mRNA. However, inactivation of the NS1 gene, but not the NS2 gene, led to a substantial increase in the splicing efficiency, as shown by the relative accumulations of NS1 and NS2 mRNAs. This effect was not specific for NS1 mRNA, since the splicing of the endogenous SV40 early transcript was altered in such a way that t-Ag mRNA was almost eliminated. These changes in the splicing pattern coincided with a strong inhibition of the mRNA nucleocytoplasmic transport. Both NS1 and NS2 mRNAs were retained in the nucleus of cells expressing NS1 protein, but no effect was observed when only NS2 protein was expressed. Furthermore, other mRNAs tested, such as T-Ag mRNA and the non-spliceable nucleoprotein transcript, were also retained in the nucleus upon expression of NS1 protein, suggesting that it induced a generalized block of mRNA export from the nucleus.

Elevated levels of cyclin D1 protein in response to increased expression of eukaryotic initiation factor 4E

Cyclin D1 is a G1-specific cyclin that has been linked to lymphoid, parathyroid, and breast tumors. Recent studies suggested that high protein levels of cyclin D1 are not always produced when cyclin D1 mRNA is overexpressed in transfected cells, suggesting that posttranscriptional events may be important in cyclin D1 regulation. The mRNA cap-binding protein (eukaryotic initiation factor 4E [eIF-4E]) is a potential regulatory of several posttranscriptional events, and it can itself induce neoplastic transformation. Consequently, we examined eIF-4E as a potential regulator of cyclin D1. Overexpression of cyclin D1 mRNA in NIH 3T3 cells did not increase cyclin D1 protein. In contrast, overexpression of eIF-4E markedly increased the amount of cyclin D1 protein in NIH 3T3 cells. This increase was specific to cyclin D1 in comparison with the retinoblastoma gene product, c-Myc, actin, and eukaryotic initiation factor 2 alpha. We also examined cyclin D1 protein in cells expressing an estrogen receptor-Myc fusion protein because we previously found that eIF-4E increases after induction of c-myc function. In these cells, increased levels of eIF-4E protein were closely followed by increases in levels of cyclin D1 protein, but the level of cyclin D1 mRNA was not increased. We conclude that increases in cyclin D1 levels may result from increased expression of eIF-4E, and this regulation may be one determinant of cyclin D1 levels in the cell.

Elevated levels of cyclin D1 protein in response to increased expression of eukaryotic initiation factor 4E

Cyclin D1 is a G1-specific cyclin that has been linked to lymphoid, parathyroid, and breast tumors. Recent studies suggested that high protein levels of cyclin D1 are not always produced when cyclin D1 mRNA is overexpressed in transfected cells, suggesting that posttranscriptional events may be important in cyclin D1 regulation. The mRNA cap-binding protein (eukaryotic initiation factor 4E [eIF-4E]) is a potential regulatory of several posttranscriptional events, and it can itself induce neoplastic transformation. Consequently, we examined eIF-4E as a potential regulator of cyclin D1. Overexpression of cyclin D1 mRNA in NIH 3T3 cells did not increase cyclin D1 protein. In contrast, overexpression of eIF-4E markedly increased the amount of cyclin D1 protein in NIH 3T3 cells. This increase was specific to cyclin D1 in comparison with the retinoblastoma gene product, c-Myc, actin, and eukaryotic initiation factor 2 alpha. We also examined cyclin D1 protein in cells expressing an estrogen receptor-Myc fusion protein because we previously found that eIF-4E increases after induction of c-myc function. In these cells, increased levels of eIF-4E protein were closely followed by increases in levels of cyclin D1 protein, but the level of cyclin D1 mRNA was not increased. We conclude that increases in cyclin D1 levels may result from increased expression of eIF-4E, and this regulation may be one determinant of cyclin D1 levels in the cell.

PUB1 is a major nuclear and cytoplasmic polyadenylated RNA-binding protein in Saccharomyces cerevisiae

Proteins that directly associate with nuclear polyadenylated RNAs, or heterogeneous nuclear RNA-binding proteins (hnRNPs), and those that associate with cytoplasmic mRNAs, or mRNA-binding proteins (mRNPs), play important roles in regulating gene expression at the posttranscriptional level. Previous work with a variety of eukaryotic cells has demonstrated that hnRNPs are localized predominantly within the nucleus whereas mRNPs are cytoplasmic. While studying proteins associated with polyadenylated RNAs in Saccharomyces cerevisiae, we discovered an abundant polyuridylate-binding protein, PUB1, which appears to be both an hnRNP and an mRNP. PUB1 and PAB1, the polyadenylate tail-binding protein, are the two major proteins cross-linked by UV light to polyadenylated RNAs in vivo. The deduced primary structure of PUB1 indicates that it is a member of the ribonucleoprotein consensus sequence family of RNA-binding proteins and is structurally related to the human hnRNP M proteins. Even though the PUB1 protein is a major cellular polyadenylated RNA-binding protein, it is nonessential for cell growth. Indirect cellular immunofluorescence combined with digital image processing allowed a detailed comparison of the intracellular distributions of PUB1 and PAB1. While PAB1 is predominantly, and relatively uniformly, distributed within the cytoplasm, PUB1 is localized in a nonuniform pattern throughout both the nucleus and the cytoplasm. The cytoplasmic distribution of PUB1 is considerably more discontinuous than that of PAB1. Furthermore, sucrose gradient sedimentation analysis demonstrates that PAB1 cofractionates with polyribosomes whereas PUB1 does not. These results suggest that PUB1 is both an hnRNP and an mRNP and that it may be stably bound to a translationally inactive subpopulation of mRNAs within the cytoplasm.

PUB1 is a major nuclear and cytoplasmic polyadenylated RNA-binding protein in Saccharomyces cerevisiae

Proteins that directly associate with nuclear polyadenylated RNAs, or heterogeneous nuclear RNA-binding proteins (hnRNPs), and those that associate with cytoplasmic mRNAs, or mRNA-binding proteins (mRNPs), play important roles in regulating gene expression at the posttranscriptional level. Previous work with a variety of eukaryotic cells has demonstrated that hnRNPs are localized predominantly within the nucleus whereas mRNPs are cytoplasmic. While studying proteins associated with polyadenylated RNAs in Saccharomyces cerevisiae, we discovered an abundant polyuridylate-binding protein, PUB1, which appears to be both an hnRNP and an mRNP. PUB1 and PAB1, the polyadenylate tail-binding protein, are the two major proteins cross-linked by UV light to polyadenylated RNAs in vivo. The deduced primary structure of PUB1 indicates that it is a member of the ribonucleoprotein consensus sequence family of RNA-binding proteins and is structurally related to the human hnRNP M proteins. Even though the PUB1 protein is a major cellular polyadenylated RNA-binding protein, it is nonessential for cell growth. Indirect cellular immunofluorescence combined with digital image processing allowed a detailed comparison of the intracellular distributions of PUB1 and PAB1. While PAB1 is predominantly, and relatively uniformly, distributed within the cytoplasm, PUB1 is localized in a nonuniform pattern throughout both the nucleus and the cytoplasm. The cytoplasmic distribution of PUB1 is considerably more discontinuous than that of PAB1. Furthermore, sucrose gradient sedimentation analysis demonstrates that PAB1 cofractionates with polyribosomes whereas PUB1 does not. These results suggest that PUB1 is both an hnRNP and an mRNP and that it may be stably bound to a translationally inactive subpopulation of mRNAs within the cytoplasm.

Multiple cis-acting signals for export of pre-U1 snRNA from the nucleus

We have identified cis-acting sequences that promote nuclear export of pre-U1 RNA injected into Xenopus oocyte nuclei. At least three elements, the 5' m7G cap, the 3'-terminal stem-loop structure, and sequences in the 5'-terminal 124 nucleotides, contribute to efficient export of this RNA. Both the 5' and 3' export signals can function separately and do so independently of the cap structure. Experiments using hybrid RNAs indicate that the 5' and 3' export sequences of U1 RNA are sufficient to direct export of the heterologous, otherwise nonexportable, U6 RNA. The absence of comparable export signals in U6 RNA appears to be responsible for its retention in the nucleus. Stability of the pre-snRNAs in the nucleus depends on the presence of both a 5' cap structure and a 3' base-paired stem. The 5' m7G cap is neither sufficient nor necessary for nuclear export. The m7G cap by itself did not promote export of U6 RNA or nonspecific small RNAs. Moreover, substitution of this cap with either an AppG cap or gamma-mppG cap did not eliminate export of either full-length or a "minimal" U1 RNA (lacking most of the internal U1 RNA sequences), but it reduced the rate of export by about two to threefold. However, in the absence of the 3' stem-loop, substitution of the m7G cap led to a greater decrease in export rate, underscoring the cooperative action of the three different export elements of pre-U1 RNA. The m7G cap analog, m7GpppG, selectively destabilized pre-U1 RNA within the nucleus. Thus, nuclear components that recognize the 5' m7G cap may be important for both the stability and the export of pre-U1 RNA.

Architecture of the Xenopus nuclear pore complex revealed by three-dimensional cryo-electron microscopy

The nuclear pore complex spans the nuclear envelope and functions as a macromolecular transporter in the ATP-dependent process of nucleocytoplasmic transport. In this report, we present three dimensional (3D) structures for both membrane-associated and detergent-extracted Xenopus NPCs, imaged in frozen buffers by cryo-electron microscopy. A comparison of the differing configurations present in the 3D maps suggests that the spokes may possess an intrinsic conformational flexibility. When combined with recent data from a 3D map of negatively stained NPCs (Hinshaw, J. E., B. O. Carragher, and R. A. Milligan. 1992. Cell. 69:1133-1141), these observations suggest a minimal domain model for the spoke-ring complex which may account for the observed plasticity of this assembly. Moreover, lumenal domains in adjacent spokes are interconnected by radial arm dimers, forming a lumenal ring that may be responsible for anchoring the NPC within the nuclear envelope pore. Importantly, the NPC transporter is visualized as a centrally tapered cylinder that spans the entire width of the NPC, in a direction normal to the nuclear envelope. The central positioning, tripartite structure, and hollow nature of the transporter suggests that it may form a macromolecular transport channel, with a globular gating domain at each end. Finally, the packing of the transporter within the spokes creates a set of eight internal channels that may be responsible, in part, for the diffusion of ions and small molecules across the nuclear envelope.

NAB2: a yeast nuclear polyadenylated RNA-binding protein essential for cell viability

A variety of nuclear ribonucleoproteins are believed to associate directly with nascent RNA polymerase II transcripts and remain associated during subsequent nuclear RNA processing reactions, including pre-mRNA polyadenylation and splicing as well as nucleocytoplasmic mRNA transport. To investigate the functions of these proteins by using a combined biochemical and genetic approach, we have isolated nuclear polyadenylated RNA-binding (NAB) proteins from Saccharomyces cerevisiae. Living yeast cells were irradiated with UV light to covalently cross-link proteins intimately associated with RNA in vivo. Polyadenylated RNAs were then selectively purified, and the covalent RNA-protein complexes were used to elicit antibodies in mice. Both monoclonal and polyclonal antibodies which detect a variety of NAB proteins were prepared. Here we characterize one of these proteins, NAB2. NAB2 is one of the major proteins associated with nuclear polyadenylated RNA in vivo, as detected by UV light-induced cross-linking. Cellular immunofluorescence, using both monoclonal and polyclonal antibodies, demonstrates that the NAB2 protein is localized within the nucleus. The deduced primary structure of NAB2 indicates that it is composed of at least two distinct types of RNA-binding motifs: (i) an RGG box recently described in a variety of heterogeneous nuclear RNA-, pre-rRNA-, mRNA-, and small nucleolar RNA-binding proteins and (ii) CCCH motif repeats related to the zinc-binding motifs of the largest subunit of RNA polymerases I, II, and III. In vitro RNA homopolymer/single-stranded DNA binding studies indicate that although both the RGG box and CCCH motifs bind poly(G), poly(U), and single-stranded DNA, the CCCH motifs also bind to poly(A). NAB2 is located on chromosome VII within a cluster of ribonucleoprotein genes, and its expression is essential for cell growth.

NAB2: a yeast nuclear polyadenylated RNA-binding protein essential for cell viability

A variety of nuclear ribonucleoproteins are believed to associate directly with nascent RNA polymerase II transcripts and remain associated during subsequent nuclear RNA processing reactions, including pre-mRNA polyadenylation and splicing as well as nucleocytoplasmic mRNA transport. To investigate the functions of these proteins by using a combined biochemical and genetic approach, we have isolated nuclear polyadenylated RNA-binding (NAB) proteins from Saccharomyces cerevisiae. Living yeast cells were irradiated with UV light to covalently cross-link proteins intimately associated with RNA in vivo. Polyadenylated RNAs were then selectively purified, and the covalent RNA-protein complexes were used to elicit antibodies in mice. Both monoclonal and polyclonal antibodies which detect a variety of NAB proteins were prepared. Here we characterize one of these proteins, NAB2. NAB2 is one of the major proteins associated with nuclear polyadenylated RNA in vivo, as detected by UV light-induced cross-linking. Cellular immunofluorescence, using both monoclonal and polyclonal antibodies, demonstrates that the NAB2 protein is localized within the nucleus. The deduced primary structure of NAB2 indicates that it is composed of at least two distinct types of RNA-binding motifs: (i) an RGG box recently described in a variety of heterogeneous nuclear RNA-, pre-rRNA-, mRNA-, and small nucleolar RNA-binding proteins and (ii) CCCH motif repeats related to the zinc-binding motifs of the largest subunit of RNA polymerases I, II, and III. In vitro RNA homopolymer/single-stranded DNA binding studies indicate that although both the RGG box and CCCH motifs bind poly(G), poly(U), and single-stranded DNA, the CCCH motifs also bind to poly(A). NAB2 is located on chromosome VII within a cluster of ribonucleoprotein genes, and its expression is essential for cell growth.

A three-dimensional view of precursor messenger RNA metabolism within the mammalian nucleus

A quantitative three-dimensional analysis of nuclear components involved in precursor messenger RNA metabolism was performed with a combination of fluorescence hybridization, immunofluorescence, and digital imaging microscopy. Polyadenylate [poly(A)] RNA-rich transcript domains were discrete, internal nuclear regions that formed a ventrally positioned horizontal array in monolayer cells. A dimmer, sometimes strand-like, poly(A) RNA signal was dispersed throughout the nucleoplasm. Spliceosome assembly factor SC-35 localized within the center of individual domains. These data support a nuclear model in which there is a specific topological arrangement of noncontiguous centers involved in precursor messenger RNA metabolism, from which RNA transport toward the nuclear envelope radiates.

An essential yeast gene with homology to the exonuclease-encoding XRN1/KEM1 gene also encodes a protein with exoribonuclease activity

An essential gene, designated HKE1/RAT1, has been isolated from the yeast Saccharomyces cerevisiae and characterized. The gene encodes a protein of 116 kDa (p116) and has significant homology to another yeast gene (XRN1/KEM1) encoding a related protein (p175) with 5'-->3' exonuclease activity as well as activities involving chromosomal DNA pairing and mechanics. Preliminary analysis of an hke1ts mutant reveals a precipitous decline in the translation of mRNA at the nonpermissive temperature. Sporulation of heterozygous HKE1/hke1::URA3 diploids reveals that this gene, unlike the highly related XRN1/KEM1 gene, is essential for cell viability. Overexpression of the homologous gene product, p175, failed to rescue cells lacking a functional p116. In vitro studies demonstrate that p116 is a protein with 5'-->3' exoribonuclease activity, a major activity of the related p175. An immunoreactive RNase activity of 116 kDa is abolished with antiserum against p116. Both the level of this protein and the RNase activity correlate with HKE1 gene dosage. The RNase activity purifies coincidentally with a previously described 116-kDa RNase having 5'-->3' exoribonuclease activity.

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.

An essential yeast gene with homology to the exonuclease-encoding XRN1/KEM1 gene also encodes a protein with exoribonuclease activity

An essential gene, designated HKE1/RAT1, has been isolated from the yeast Saccharomyces cerevisiae and characterized. The gene encodes a protein of 116 kDa (p116) and has significant homology to another yeast gene (XRN1/KEM1) encoding a related protein (p175) with 5'-->3' exonuclease activity as well as activities involving chromosomal DNA pairing and mechanics. Preliminary analysis of an hke1ts mutant reveals a precipitous decline in the translation of mRNA at the nonpermissive temperature. Sporulation of heterozygous HKE1/hke1::URA3 diploids reveals that this gene, unlike the highly related XRN1/KEM1 gene, is essential for cell viability. Overexpression of the homologous gene product, p175, failed to rescue cells lacking a functional p116. In vitro studies demonstrate that p116 is a protein with 5'-->3' exoribonuclease activity, a major activity of the related p175. An immunoreactive RNase activity of 116 kDa is abolished with antiserum against p116. Both the level of this protein and the RNase activity correlate with HKE1 gene dosage. The RNase activity purifies coincidentally with a previously described 116-kDa RNase having 5'-->3' exoribonuclease activity.

Cell-to-cell movement of plant viruses. Insights from amino acid sequence comparisons of movement proteins and from analogies with cellular transport systems

Cell-to-cell movement is a crucial step in plant virus infection. In many viruses, the movement function is secured by specific virus-encoded proteins. Amino acid sequence comparisons of these proteins revealed a vast superfamily containing a conserved sequence motif that may comprise a hydrophobic interaction domain. This superfamily combines proteins of viruses belonging to all principal groups of positive-strand RNA viruses, as well as single-stranded DNA containing geminiviruses, double-stranded DNA-containing pararetroviruses (caulimoviruses and badnaviruses), and tospoviruses that have negative-strand RNA genomes with two ambisense segments. In several groups of positive-strand RNA viruses, the movement function is provided by the proteins encoded by the so-called triple gene block including two putative small membrane-associated proteins and a putative RNA helicase. A distinct type of movement proteins with very high content of proline is found in tymoviruses. It is concluded that classification of movement proteins based on comparison of their amino acid sequences does not correlate with the type of genome nucleic acid or with grouping of viruses based on phylogenetic analysis of replicative proteins or with the virus host range. Recombination between unrelated or distantly related viruses could have played a major role in the evolution of the movement function. Limited sequence similarities were observed between i) movement proteins of dianthoviruses and the MIP family of cellular integral membrane proteins, and ii) between movement proteins of bromoviruses and cucumoviruses and M1 protein of influenza viruses which is involved in nuclear export of viral ribonucleoproteins. It is hypothesized that all movement proteins of plant viruses may mediate hydrophobic interactions between viral and cellular macromolecules.

Map of cis-acting sequences that determine alternative pre-mRNA processing in the E3 complex transcription unit of adenovirus

The E3 complex transcription unit of adenovirus encodes four major mRNAs (a, c, f, and h) and two minor (d and e) mRNAs with overlapping exons, alternative splice sites, and two polyadenylation sites, termed E3A (upstream) and E3B (downstream). mRNAs a and d use the E3A polyadenylation site, and mRNAs c, e, f, and h use the E3B site. We have analyzed virus mutants with deletions throughout the E3 region in order to identify cis-acting sequences that function in E3 pre-mRNA processing. The results presented in this report as well as previous results are summarized as follows. (i) Deletions in the first (5') intron at nucleotides (nt) 372 to 768 in E3 had no effect unless they removed the consensus sequence for the nt 372 5' splice site; however, the overall pattern of E3 mRNAs did not change significantly. (ii) Deletions in region I (nt 1441 to 2044) eliminated mRNAs a and c and resulted in corresponding increases in mRNAs f and h; we propose that region I contains sequences that suppress splicing. (iii) Mutations in region II (nt 2161 to 2243) resulted in nearly exclusive synthesis of mRNA f; this phenotype is understood and is discussed. (iv) Changing the AUUAAA component of the E3A poly(A) addition signal to AAUAAA resulted in increased mRNA a levels, suggesting that the E3A poly(A) addition signal is intrinsically inefficient. (v) Deletions in region III (nt 2488 to 3002) decreased mRNA a levels about two- to threefold and specifically increased mRNA f levels; we suggest that region III facilitates use of the E3A polyadenylation site. (vi) Deletions in region IV (nt 2904 to 3251) increased mRNA a levels about two- to threefold; we suggest that region IV may contain sequences that facilitate use of the E3B polyadenylation site. A map of sequences that determine alternative pre-mRNA processing in region E3 is now nearly complete.

A cap binding protein that may mediate nuclear export of RNA polymerase II-transcribed RNAs

It has previously been shown that efficient export of U1 snRNA or of microinjected, in vitro synthesized, RNA transcripts from the nucleus of Xenopus oocytes is facilitated by their monomethyl guanosine cap structures. Nuclear exit of these transcripts could be competitively inhibited by microinjection of an excess of a cap analog, the dinucleotide m7GpppG (Hamm, J., and I. W. Mattaj. 1990. Cell. 63:109-118). We have now analyzed the ability of several other related cap analogs to inhibit the export of U1 snRNA from the nucleus. The results define the recognition specificity of a factor(s) involved in RNA transport, and indicate that the cap binding activity (CBA) involved in RNA export is different from cap binding proteins (CBPs) involved in the initiation of translation. A CBP, whose specificity for different analogs correlates with the ability of the analogs to inhibit U1 snRNA export, is identified in nuclear extracts prepared from HeLa cells. We propose that this protein may have a role in the export of capped RNAs from the nucleus.

RNA nucleocytoplasmic transport

The transport of RNAs from the nucleus to the cytoplasm is an obligatory step in gene expression and may also be a target for regulation. The cellular machinery has the capacity to export a myriad of RNA transcripts, which differ significantly in sequence and structure. Recent work is providing the first glimpses into how RNA export occurs.

Molecular trafficking across the nuclear pore complex

The nuclear pore complex is the gateway for protein and RNA transport between the cytoplasm and nucleus. Recent work has characterized signals and components involved in nuclear import of macromolecules and has described mechanisms for transport regulation. Advances in understanding the structure of the pore complex are starting to provide a framework for interpreting the biochemistry of nuclear import. Information on the export of RNA from the nucleus is only beginning to emerge.

Isolation and characterization of RAT1: an essential gene of Saccharomyces cerevisiae required for the efficient nucleocytoplasmic trafficking of mRNA

We have combined techniques of genetics and histochemistry to identify genes required for the nucleocytoplasmic export of mRNA in the budding yeast Saccharomyces cerevisiae. We adapted in situ hybridization using a digoxigenin-labeled oligo(dT)50 probe to localize poly(A)+ RNA in fixed yeast cells and used yeast strains carrying the rna1-1 mutation to develop an assay. The rna1-1 mutation is the only previously described mutation that causes defects in mRNA export. As visualized with this RNA localization assay, rna1-1 strains accumulated poly(A)+ RNA at the nuclear periphery at the nonpermissive temperature. This was in contrast to the RNA localization pattern of wild-type cells or rna1-1 cells grown at permissive temperature. Wild-type cells showed bright uniform cytoplasmic staining with little detectable RNA in the nuclei. We used this RNA localization assay to screen a bank of temperature-sensitive yeast strains for mutants with inducible defects in mRNA trafficking. Strains identified in this manner are designated RAT mutants for ribonucleic acid trafficking. The rat1-1 allele conferred temperature-sensitive accumulation of poly(A)+ RNA in one to several intranuclear spots that appear to lie at the nuclear periphery. RNA processing was unaffected in rat1-1 strains, except for an inducible defect in trimming the 5' end of the 5.8S rRNA. The wild-type RAT1 gene was cloned by complementation; it encodes an essential 116-kD protein with regions of homology to the protein encoded by SEP1 (also known as DST2, XRN1, KEM1, and RAR5). Sep1p is a nucleic acid binding protein, a 5'----3' exonuclease, and catalyzes DNA strand transfer reactions in vitro. We discuss the possible significance of the Rat1p/Sep1p homology for RNA trafficking. We also discuss the potential of this RNA localization assay to identify genes involved in nuclear structure and RNA metabolism.

RNA processing

Significant progress has been made over the last year in our understanding of the roles that RNA-binding proteins play in pre-mRNA splicing, the components of the spliceosome and how these components relate to the mechanism of splicing. Of particular importance has been the sequence analysis of the first mammalian splicing factors and structural determination of an RNA-binding domain.