Small nuclear RNA U2 is base-paired to heterogeneous nuclear RNA

The Emerging Role of Noncoding RNAs in Pediatric Inflammatory Bowel Disease

Prevalence of inflammatory bowel disease (IBD), a chronic inflammatory disorder of the gut, has been on the rise in recent years-not only in the adult population but also especially in pediatric patients. Despite the absence of curative treatments, current therapeutic options are able to achieve long-term remission in a significant proportion of cases. To this end, however, there is a need for biomarkers enabling accurate diagnosis, prognosis, and prediction of response to therapies to facilitate a more individualized approach to pediatric IBD patients. In recent years, evidence has continued to evolve concerning noncoding RNAs (ncRNAs) and their roles as integral factors in key immune-related cellular pathways. Specific deregulation patterns of ncRNAs have been linked to pathogenesis of various diseases, including pediatric IBD. In this article, we provide an overview of current knowledge on ncRNAs, their altered expression profiles in pediatric IBD patients, and how these are emerging as potentially valuable clinical biomarkers as we enter an era of personalized medicine.

The RNA Base-Pairing Problem and Base-Pairing Solutions

RNA molecules are folded into structures and complexes to perform a wide variety of functions. Determination of RNA structures and their interactions is a fundamental problem in RNA biology. Most RNA molecules in living cells are large and dynamic, posing unique challenges to structure analysis. Here we review progress in RNA structure analysis, focusing on methods that use the "cross-link, proximally ligate, and sequence" principle for high-throughput detection of base-pairing interactions in living cells. Beginning with a comparison of commonly used methods in structure determination and a brief historical account of psoralen cross-linking studies, we highlight the important features of cross-linking methods and new biological insights into RNA structures and interactions from recent studies. Further improvement of these cross-linking methods and application to previously intractable problems will shed new light on the mechanisms of the "modern RNA world."

Stoichiometries of U2AF35, U2AF65 and U2 snRNP reveal new early spliceosome assembly pathways

The selection of 3΄ splice sites (3΄ss) is an essential early step in mammalian RNA splicing reactions, but the processes involved are unknown. We have used single molecule methods to test whether the major components implicated in selection, the proteins U2AF35 and U2AF65 and the U2 snRNP, are able to recognize alternative candidate sites or are restricted to one pre-specified site. In the presence of adenosine triphosphate (ATP), all three components bind in a 1:1 stoichiometry with a 3΄ss. Pre-mRNA molecules with two alternative 3΄ss can be bound concurrently by two molecules of U2AF or two U2 snRNPs, so none of the components are restricted. However, concurrent occupancy inhibits splicing. Stoichiometric binding requires conditions consistent with coalescence of the 5΄ and 3΄ sites in a complex (I, initial), but if this cannot form the components show unrestricted and stochastic association. In the absence of ATP, when complex E forms, U2 snRNP association is unrestricted. However, if protein dephosphorylation is prevented, an I-like complex forms with stoichiometric association of U2 snRNPs and the U2 snRNA is base-paired to the pre-mRNA. Complex I differs from complex A in that the formation of complex A is associated with the loss of U2AF65 and 35.

Whole transcriptome analysis: what are we still missing?

New technologies such as tag-based sequencing and tiling arrays have provided unique insights into the transcriptional output of cells. Many new RNA classes have been uncovered in the past decade, despite limitations in current technologies. Even as the repertoire of known functional elements of the transcriptome increases and contemporary technologies become mainstream, inadequacies in conventional protocols for library preparation, sequencing and mapping continue to hamper revelation of the entire transcriptome of cells. In this article, we review current protocols and outline their deficiencies. We also provide our view on what we may be overlooking in the transcriptome, despite exhaustive investigations, and indicate future areas of technological development and research.

Three new small nucleolar RNAs that are psoralen cross-linked in vivo to unique regions of pre-rRNA

We have recently described three novel human small nucleolar RNA species with unique nucleotide sequences, which were named E1, E2, and E3. The present article describes specific psoralen photocross-linking in whole HeLa cells of E1, E2, and E3 RNAs to nucleolar pre-rRNA. These small RNAs were cross-linked to different sections of pre-rRNA. E1 RNA was cross-linked to two segments of nucleolar pre-rRNA; one was within residues 697 to 1163 of the 5' external transcribed spacer, and the other one was between nucleotides 664 and 1021 of the 18S rRNA sequence. E2 RNA was cross-linked to a region within residues 3282 to 3667 of the 28S rRNA sequence. E3 RNA was cross-linked to a sequence between positions 1021 and 1639 of the 18S rRNA sequence. Primer extension analysis located psoralen adducts in E1, E2, and E3 RNAs that were enriched in high-molecular-weight fractions of nucleolar RNA. Some of these psoralen adducts might be cross-links of E1, E2, and E3 RNAs to large nucleolar RNA. Antisense oligodeoxynucleotide-targeted RNase H digestion of nucleolar extracts revealed accessible segments in these three small RNAs. The accessible regions were within nucleotide positions 106 to 130 of E1 RNA, positions 24 to 48 and 42 to 66 of E2 RNA, and positions 7 to 16 and about 116 to 122 of E3 RNA. Some of the molecules of these small nucleolar RNAs sedimented as if associated with larger structures when both nondenatured RNA and a nucleolar extract were analyzed.

Three new small nucleolar RNAs that are psoralen cross-linked in vivo to unique regions of pre-rRNA

We have recently described three novel human small nucleolar RNA species with unique nucleotide sequences, which were named E1, E2, and E3. The present article describes specific psoralen photocross-linking in whole HeLa cells of E1, E2, and E3 RNAs to nucleolar pre-rRNA. These small RNAs were cross-linked to different sections of pre-rRNA. E1 RNA was cross-linked to two segments of nucleolar pre-rRNA; one was within residues 697 to 1163 of the 5' external transcribed spacer, and the other one was between nucleotides 664 and 1021 of the 18S rRNA sequence. E2 RNA was cross-linked to a region within residues 3282 to 3667 of the 28S rRNA sequence. E3 RNA was cross-linked to a sequence between positions 1021 and 1639 of the 18S rRNA sequence. Primer extension analysis located psoralen adducts in E1, E2, and E3 RNAs that were enriched in high-molecular-weight fractions of nucleolar RNA. Some of these psoralen adducts might be cross-links of E1, E2, and E3 RNAs to large nucleolar RNA. Antisense oligodeoxynucleotide-targeted RNase H digestion of nucleolar extracts revealed accessible segments in these three small RNAs. The accessible regions were within nucleotide positions 106 to 130 of E1 RNA, positions 24 to 48 and 42 to 66 of E2 RNA, and positions 7 to 16 and about 116 to 122 of E3 RNA. Some of the molecules of these small nucleolar RNAs sedimented as if associated with larger structures when both nondenatured RNA and a nucleolar extract were analyzed.

Uncoupling two functions of the U1 small nuclear ribonucleoprotein particle during in vitro splicing

To probe functions of the U1 small nuclear ribonucleoprotein particle (snRNP) during in vitro splicing, we have used unusual splicing substrates which replace the 5' splice site region of an adenovirus substrate with spliced leader (SL) RNA sequences from Leptomonas collosoma or Caenorhabditis elegans. In agreement with previous results (J.P. Bruzik and J.A. Steitz, Cell 62:889-899, 1990), we find that oligonucleotide-targeted RNase H destruction of the 5' end of U1 snRNA inhibits the splicing of a standard adenovirus splicing substrate but not of the SL RNA-containing substrates. However, use of an antisense 2'-O-methyl oligoribonucleotide that disrupts the first stem of U1 snRNA as well as stably sequestering positions of U1 snRNA involved in 5' and 3' splice site recognition inhibits the splicing of both the SL constructs and the standard adenovirus substrate. The 2'-O-methyl oligoribonucleotide is no more effective than RNase H pretreatment in preventing pairing of U1 with the 5' splice site, as assessed by inhibition of psoralen cross-link formation between the SL RNA-containing substrate and U1. The 2'-O-methyl oligoribonucleotide does not alter the protein composition of the U1 monoparticle or deplete the system of essential splicing factors. Native gel analysis indicates that the 2'-O-methyl oligoribonucleotide inhibits splicing by diminishing the formation of splicing complexes. One interpretation of these results is that removal of the 5' end of U1 inhibits base pairing in a different way than sequestering the same sequence with a complementary oligoribonucleotide. Alternatively, our data may indicate that two elements near the 5' end of U1 RNA normally act during spliceosome assembly; the extreme 5' end base pairs with the 5' splice site, while the sequence or structural integrity of stem I is essential for some additional function. It follows that different introns may differ in their use of the repertoire of U1 snRNP functions.

Uncoupling two functions of the U1 small nuclear ribonucleoprotein particle during in vitro splicing

To probe functions of the U1 small nuclear ribonucleoprotein particle (snRNP) during in vitro splicing, we have used unusual splicing substrates which replace the 5' splice site region of an adenovirus substrate with spliced leader (SL) RNA sequences from Leptomonas collosoma or Caenorhabditis elegans. In agreement with previous results (J.P. Bruzik and J.A. Steitz, Cell 62:889-899, 1990), we find that oligonucleotide-targeted RNase H destruction of the 5' end of U1 snRNA inhibits the splicing of a standard adenovirus splicing substrate but not of the SL RNA-containing substrates. However, use of an antisense 2'-O-methyl oligoribonucleotide that disrupts the first stem of U1 snRNA as well as stably sequestering positions of U1 snRNA involved in 5' and 3' splice site recognition inhibits the splicing of both the SL constructs and the standard adenovirus substrate. The 2'-O-methyl oligoribonucleotide is no more effective than RNase H pretreatment in preventing pairing of U1 with the 5' splice site, as assessed by inhibition of psoralen cross-link formation between the SL RNA-containing substrate and U1. The 2'-O-methyl oligoribonucleotide does not alter the protein composition of the U1 monoparticle or deplete the system of essential splicing factors. Native gel analysis indicates that the 2'-O-methyl oligoribonucleotide inhibits splicing by diminishing the formation of splicing complexes. One interpretation of these results is that removal of the 5' end of U1 inhibits base pairing in a different way than sequestering the same sequence with a complementary oligoribonucleotide. Alternatively, our data may indicate that two elements near the 5' end of U1 RNA normally act during spliceosome assembly; the extreme 5' end base pairs with the 5' splice site, while the sequence or structural integrity of stem I is essential for some additional function. It follows that different introns may differ in their use of the repertoire of U1 snRNP functions.

U2 small nuclear RNA 3' end formation is directed by a critical internal structure distinct from the processing site

Mature U2 small nuclear RNA is generated by the removal of 11 to 12 nucleotides from the 3' end of the primary transcript. This pre-U2 RNA processing reaction takes place in the cytoplasm. In this study, the sequences and/or structures of pre-U2 RNA that are important for 3' processing have been examined in an in vitro system. The 7-methylguanosine cap, stem-loops I and II, the lariat branch site recognition sequence, the conserved Sm domain, and several other regions throughout the 5' end of U2 RNA have no apparent role in the 3' processing reaction. In fact, deletion of the entire first 104 nucleotides resulted in mini-pre-U2 RNAs which were efficiently processed. Similarly, deletion of the top two-thirds of stem-loop III or mutation of nucleotides in the loop of stem-loop IV had little effect on 3' processing. Most surprisingly, the precursor's 11- to 12-nucleotide 3' extension itself was of relatively little importance, since this sequence could be replaced with completely different sequences with only a minor effect on the 3' processing reaction. In contrast, we have defined a critical structure consisting of the bottom of stem III and the stem of stem-loop IV that is essential for 3' processing of pre-U2 RNA. Compensatory mutations which restore base pairing in this region resulted in normal 3' processing. Thus, although the U2 RNA processing activity recognizes the bottom of stem III and stem IV, the sequence of this critical region is much less important than its structure. These results, together with the surprising observation that the reaction is relatively indifferent to the sequence of the 11- to 12-nucleotide 3' extension itself, point to a 3' processing reaction of pre-U2 RNA that has sequence and structure requirements significantly different from those previously identified for pre-mRNA 3' processing.

U2 small nuclear RNA 3' end formation is directed by a critical internal structure distinct from the processing site

Mature U2 small nuclear RNA is generated by the removal of 11 to 12 nucleotides from the 3' end of the primary transcript. This pre-U2 RNA processing reaction takes place in the cytoplasm. In this study, the sequences and/or structures of pre-U2 RNA that are important for 3' processing have been examined in an in vitro system. The 7-methylguanosine cap, stem-loops I and II, the lariat branch site recognition sequence, the conserved Sm domain, and several other regions throughout the 5' end of U2 RNA have no apparent role in the 3' processing reaction. In fact, deletion of the entire first 104 nucleotides resulted in mini-pre-U2 RNAs which were efficiently processed. Similarly, deletion of the top two-thirds of stem-loop III or mutation of nucleotides in the loop of stem-loop IV had little effect on 3' processing. Most surprisingly, the precursor's 11- to 12-nucleotide 3' extension itself was of relatively little importance, since this sequence could be replaced with completely different sequences with only a minor effect on the 3' processing reaction. In contrast, we have defined a critical structure consisting of the bottom of stem III and the stem of stem-loop IV that is essential for 3' processing of pre-U2 RNA. Compensatory mutations which restore base pairing in this region resulted in normal 3' processing. Thus, although the U2 RNA processing activity recognizes the bottom of stem III and stem IV, the sequence of this critical region is much less important than its structure. These results, together with the surprising observation that the reaction is relatively indifferent to the sequence of the 11- to 12-nucleotide 3' extension itself, point to a 3' processing reaction of pre-U2 RNA that has sequence and structure requirements significantly different from those previously identified for pre-mRNA 3' processing.

A new interaction between the mouse 5' external transcribed spacer of pre-rRNA and U3 snRNA detected by psoralen crosslinking

The first cleavage in mammalian pre-rRNA processing occurs within the 5' external transcribed spacer (ETS). We have recently shown that the U3 snRNP is required for this cleavage reaction, binds to the rRNA precursor, and remains complexed with the downstream processing product after the reaction has been completed (1). Using psoralen crosslinking in mouse cell extract we have detected a new interaction between U3 RNA and the mouse ETS processing substrate and its processed product. The crosslinked sites on both U3 and ETS RNAs have been mapped by RNase H cleavage and primer extension analyses. The crosslinked sites in U3 RNA map to C5, U6, and U8. U8 lies within and C5 and U6 are adjacent to an evolutionarily conserved U3 sequence termed box A'. In the ETS the crosslinked sites are U1012 and U1013, 362 nucleotides downstream from the processing site. Although the crosslinked site is dispensable for the primary processing reaction in vitro, a short conserved sequence just 3' to the cleavage site (nucleotides 650-668) is absolutely required for crosslink formation. We conclude that the interaction between U3 RNA and the 5' ETS detected by psoralen crosslinking may play a role in subsequent step(s) of pre-rRNA processing.

U3 small nuclear RNA can be psoralen-cross-linked in vivo to the 5' external transcribed spacer of pre-ribosomal-RNA

U3 small nuclear RNA is hydrogen-bonded to high molecular weight nucleolar RNA and can be isolated from greater than 60S pre-ribosomal ribonucleoprotein particles, suggesting that it is involved in processing of ribosomal RNA precursors (pre-rRNA) or in ribosome biogenesis. Here we have used in vivo psoralen cross-linking to identify the region of pre-rRNA interacting with U3 RNA. Quantitative hybridization selection/depletion experiments with clones of rRNA-encoding DNA (rDNA) and cross-linked nuclear RNA showed that all of the cross-linked U3 RNA was associated with a region that includes the external transcribed spacer (ETS) at the 5' end of the human rRNA precursor. To further identify the site of interaction within the approximately 3.7-kilobase ETS, Southern blots of rDNA clones were sandwich-hybridized with cross-linked RNA and then probed for cross-linked U3 RNA. These experiments showed that U3 RNA was cross-linked to a 258-base sequence between nucleotides +438 and +695, just downstream of the ETS early cleavage site (+414). The localization of U3 to this region of the rRNA precursor was not expected from previous models for a base-paired U3-rRNA interaction and suggests that U3 plays a role in the initial pre-rRNA processing event.

In-vivo secondary structure analysis of the small nuclear RNA U1 using psoralen cross-linking

Intramolecular base-pairing interactions have been probed in the small nuclear RNA U1 in vivo. HeLa cells were treated with the psoralen derivative aminomethyltrioxsalen, and cross-linking was carried out by irradiating the intact cells with light of 365 nm wavelength. Cross-linking resulted in a discrete shift in electrophoretic mobility of approximately 65 to 70% of the U1. This intramolecularly cross-linked U1 RNA, termed XU1, was purified and shown to co-migrate with uncross-linked U1 upon photo-reversal of psoralen cross-links with light of 254 nm wavelength. XU1 was also generated by the in-vitro cross-linking of deproteinized U1, suggesting that the secondary structure of U1 RNA in solution is similar to that of U1 ribonucleoprotein in the cell. A sequencing analysis was developed, based on partial enzymatic and alkaline cleavage of psoralen-treated RNA, to identify the position of psoralen cross-links and to distinguish between psoralen monoadducts and diadducts (cross-links). Sequencing of 3' and 5' end-labeled XU1 provided direct evidence for the presence of a unique intramolecular cross-link in XU1, located on uridine 116 (U116). This result is consistent with several secondary-structure models for U1 in which U116 is located in a base-paired stem. The proximity of uridine 96 (U96) to U116 on the opposite side of the base-paired stem suggested that U116 was cross-linked to U96. An additional U1 species having an electrophoretic mobility between those of U1 and XU1 was also generated by psoralen treatment. Analysis of this U1 species, termed U1M, revealed a psoralen monoadduct on U96. Further longwave (365 nm) irradiation of purified U1M resulted in its conversion to XU1 by completion of the U96-U116 cross-link. This suggested that cross-linking at the U96-U116 site occurred as a two-step process in which the psoralen first reacted with U96 and then with U116. Sequencing analysis also identified a psoralen monoadduct on uridine 45 (U45) of XU1. Efficient psoralen-adduct formation, which resulted in cross-linking at the U96-U116 site and monoaddition on U45, suggests that these regions are relatively accessible in the native U1 small nuclear ribonucleoprotein particle in vivo.

The effects of covalent additions of a psoralen on transcription by E. coli RNA polymerase

Synthetic DNA substrates containing a site-specifically engineered psoralen monoadduct or diadduct were used to characterize the response of the E. coli RNA polymerase elongation complex to these lesions. The psoralen derivative HMT (4'-hydroxymethyl-4,5', 8-trimethylpsoralen) was site specifically placed into two synthetic double-stranded DNA fragments each of which contained an E. coli RNA polymerase promoter at one end. The HMT molecule was attached to the middle of the DNA fragments as either a furan-side monoadduct or an interstrand diadduct. Transcription off the HMT crosslinked DNA templates showed that E. coli RNA polymerase terminated at the HMT diadduct site, i. e., one nucleotide before the modified thymidine residue on the template strand. The furan-side monoadduct when on the template strand also blocked transcription by the polymerase. However, no effect on transcription was observed when the monoadduct was located on the non-template strand.

The role of small nuclear ribonucleoprotein particles in pre-mRNA splicing

A small set of distinctive short RNA molecules are found in the nuclei of all higher eukaryotic cells and yeast, in protein complexes known as 'small nuclear ribonucleoprotein particles', or snRNPs. Recent work has confirmed early suggestions that these particles form part of the machinery by which primary RNA transcripts are processed to their mature, functional form. In particular, snRNPs have been shown to be an integral part of the 'spliceosome', a multi-component complex involved in the removal of intron sequences from the coding regions of messenger RNA precursors.

A procedure for Northern blot analysis of native RNA

We describe a modification of the Northern technique that allows the detection of RNA either native and/or containing hidden breaks. We found that the highest sensitivity of the hybridization signals was obtained after denaturation of the RNA in the gel prior to its transfer onto a nylon membrane (GeneScreen) followed by uv irradiation. The sensitivity of the method using native RNA was found to be equivalent to that obtained with denatured RNA.

U1, U2, and U6 small nuclear ribonucleoproteins (snRNPs) are associated with large nuclear RNP particles containing transcripts of an amplified gene in vivo

Nuclear ribonucleoprotein (RNP) complexes that contain intact transcripts of the amplified gene for CAD, the multifunctional protein that initiates UMP synthesis in Syrian hamster cells, have been released from nuclei of Syrian hamster cells as large particulate structures that sediment at the 200S region in a sucrose gradient. By the technique of RNA hybridization, we have shown that U1, U2, and U6 small nuclear RNAs (snRNAs) cosediment with the large RNP particles in the sucrose gradients. Autoimmune sera from systemic lupus erythematosus and mixed connective tissue disease patients, characterized as anti-(U1)RNP, have further been shown to immunoprecipitate CAD RNA along with U1 and U2 snRNAs from the fractionated nuclear 200S RNP particles. We conclude that U1, U2, and U6 snRNPs are integral constituents of the 200S RNP particles. The requirement of snRNPs for RNA processing that evidently occurs on RNP particles has been recently demonstrated. Our results thus suggest that the 200S RNPs are structurally and functionally close to the native particles on which RNA processing occurs.

Antibodies against small nuclear ribonucleoproteins immunoprecipitate complexes containing ts110 Moloney murine sarcoma virus genomic and messenger RNAs

Small nuclear ribonucleoproteins (snRNPs) are believed to play a role in processing premessenger RNAs. In this study, snRNPs were immunoprecipitated from extracts of cells infected with ts110 Moloney murine sarcoma virus (ts110 MoMuSV). Both the unspliced 4.0 kb and the spliced 3.5-kb ts110 MoMuSV specific RNA species were found in the immunoprecipitates obtained with monoclonal antibody anti-Sm and polyclonal anti-Sm, anti-(U1) RNP and anti-La sera. Although only a portion of the total ts110 RNAs was present in these immunoprecipitates, immune recognition by the anti-snRNPs was specific and not due to contaminating anti-RNA (at least for the anti-Sm sera) or, to anti-viral protein activities. Genomic 8.3-kb RNA and subgenomic 3.0-kb spliced env mRNA from Moloney murine leukemia virus (MoMuLV) infected cells as well as the cellular actin mRNA were also detected in immunoprecipitates obtained with the same antisera. The fact that pre-mRNAs and mature mRNAs of different origin can be recovered from immunoprecipitates formed with anti-snRNP sera establishes their tight association and confirms the role of snRNPs in mRNA processing.

Antibodies to hnRNP core proteins inhibit in vitro splicing of human beta-globin pre-mRNA

In vitro splicing of human beta-globin pre-mRNA can be fully inhibited by treatment of the splicing extract with polyclonal antibodies against hnRNP core proteins prior to the addition of pre-mRNA. Inhibition of the first step in the splicing pathway, cleavage at the 5' splice site and lariat formation, requires more antibodies than inhibition of the second step, cleavage at the 3' splice site and exon ligation. The anti-hnRNP antibodies can also inhibit the splicing reaction after the formation of the active nucleoprotein splicing complex which is known to occur during the initial lag period. Thus, hnRNP core proteins appear to be present in the complex that performs pre-mRNA splicing.

Specific and stable intron-factor interactions are established early during in vitro pre-mRNA splicing

Biochemical components (splicing factors) interact with specific intron regions during pre-mRNA splicing in vitro. The pre-mRNA specifically associates with factors at both the branch point and the 5' splice site and these RNA-factor interactions are maintained in the intron-containing RNA processing products. The first detectable event, the ATP-dependent association of a factor (or factors) with the branch point, is mediated by at least one factor containing an essential nucleic acid component. Mutant RNA substrates that lack either the 5' splice site or the vast majority of exon sequences can still associate with the branch point binding factor(s). However, this branch point-factor interaction does not occur with a mutant RNA substrate that contains the branch point but that lacks the 3' splice site consensus sequence. These results suggest that selection of the 3' splice site accompanied by the association of a factor with the branch point may be the initial step in mammalian pre-mRNA splicing.

U2 as well as U1 small nuclear ribonucleoproteins are involved in premessenger RNA splicing

Two different experimental approaches have provided evidence that both U2 and U1 snRNPs function in pre-mRNA splicing. When the U2 snRNPs in a nuclear extract are selectively degraded using ribonuclease H and either of two deoxyoligonucleotides complementary to U2 RNA, splicing activity is abolished. Mixing an extract in which U2 has been degraded with one in which U1 has been degraded recovers activity. Use of anti-(U2)RNP autoantibodies demonstrates that U2 snRNPs associate with the precursor RNA during in vitro splicing. At 60 min, but not at 0 min, into the reaction intron fragments that include the branch-point sequence are immunoprecipitated by anti-(U2)RNP. At all times, U1 snRNPs bind the 5' splice site of the pre-mRNA. Possible interactions of the U2 snRNP with the U1 snRNP and with the pre-mRNA during splicing are considered.

Multiple factors including the small nuclear ribonucleoproteins U1 and U2 are necessary for pre-mRNA splicing in vitro

We have identified six distinct factors necessary for pre-mRNA splicing in vitro by selective inactivation and complementation studies, and by fractionation procedures. Splicing factor 1 (SF1) is sensitive to micrococcal nuclease, and appears to consist of at least U1 and U2 snRNPs, since splicing is inhibited when the 5' termini of U1 and U2 snRNAs are removed by site-directed cleavage with RNAase H. SF2 is a micrococcal nuclease-resistant factor present in the nuclear extract but absent from an S100 extract. SF3 is a factor that can be preferentially inactivated by moderate heat treatment. Two additional factors (SF4A and SF4B) were identified by fractionation of the nuclear extract using spermine-agarose and CM-sepharose chromatography. SF1, SF2, and SF4B appear to be required for cleavage of the pre-mRNA at the 5' splice site and lariat formation, whereas SF3 and SF4A are only required for cleavage at the 3' splice site and exon ligation.

Intron splicing: a conserved internal signal in introns of Drosophila pre-mRNAs

The introns of Drosophila pre-mRNAs have been analysed for conserved internal sequence elements near the 3' intron boundary similar to the T-A-C-T-A-A-C in yeast introns and the C/T-T-A/G-A-C/T in introns of other organisms. Such conserved internal elements are the 3' splice signals recognized in intron splicing. In the lariat splicing mechanism, the G at the 5' end of an intron joins covalently to the last A of a 3' splice signal to form a branch point in a splicing intermediate. Analysis of 39 published sequences of Drosophila introns reveals that potential 3' splice signals with the consensus C/T-T-A/G-A-C/T are present in 18 cases. In 17 of the remaining cases signals are present which vary from this consensus just in the middle or last position. In Drosophila introns the 3' splice signal is usually located in a discrete region between 18 and 35 nucleotides upstream from the 3' splice point. We note that the Drosophila small nuclear U2-RNA has sequences complementary to C-T-G-A-T, one variant of the signal, and to C-A-G, one variant of the 3' terminus of an intron. We also note that the absence of any A-G between -3 and -19 from the 3' splice point may be an essential feature of a strong 3' boundary.

Localization and structure of snRNPs during mitosis. Immunofluorescent and biochemical studies

The distribution of U snRNAs during mitosis was studied by indirect immunofluorescence microscopy with snRNA cap-specific anti-m3G antibodies. Whereas the snRNAs are strictly nuclear at late prophase, they become distributed in the cell plasm at metaphase and anaphase. They re-enter the newly formed nuclei of the two daughter cells at early telophase, producing speckled nuclear fluorescent patterns typical of interphase cells. While the snRNAs become concentrated at the rim of the condensing chromosomes and at interchromosomal regions at late prophase, essentially no association of the snRNAs was observed with the condensed chromosomes during metaphase and anaphase. Independent immunofluorescent studies with anti-(U1)RNP autoantibodies, which react specifically with proteins unique to the U1 snRNP species, showed the same distribution of snRNP antigens during mitosis as was observed with the snRNA-specific anti-m3G antibody. Immunoprecipitation studies with anti-(U1)RNP and anti-Sm autoantibodies, as well as protein analysis of snRNPs isolated from extracts of mitotic cells, demonstrate that the snRNAs remain associated in a specific manner with the same set of proteins during interphase and mitosis. The concept that the overall structure of the snRNPs is maintained during mitosis also applies to the coexistence of the snRNAs U4 and U6 in a single ribonucleoprotein complex. Particle sedimentation studies in sucrose gradients reveal that most of the snRNPs present in sonicates of mitotic cells do not sediment as free RNP particles, but remain associated with high molecular weight (HMW) structures other than chromatin, most probably with hnRNA/RNP.

Ribonucleoprotein organization of eukaryotic RNA. XXXII. U2 small nuclear RNA precursors and their accurate 3' processing in vitro as ribonucleoprotein particles

Biosynthetic precursors of U2 small nuclear RNA have been identified in cultured human cells by hybrid-selection of pulse-labeled RNA with cloned U2 DNA. These precursor molecules are one to approximately 16 nucleotides longer than mature U2 RNA and contain 2,2,7-trimethylguanosine "caps". The U2 RNA precursors are associated with proteins that react with a monoclonal antibody for antigens characteristic of small nuclear ribonucleoprotein particles. Like previously described precursors of U1 and U4 small nuclear RNAs, the pre-U2 RNAs are recovered in cytoplasmic fractions, although it is not known if this is their location in vivo. The precursors are processed to mature-size U2 RNA when cytoplasmic extracts are incubated in vitro at 37 degrees C. Mg2+ is required but ATP is not. The ribonucleoprotein structure of the pre-U2 RNA is maintained during the processing reaction in vitro, as are the 2,2,7-trimethylguanosine caps. The ribonucleoprotein organization is of major importance, as exogenous, protein-free U2 RNA precursors are degraded rapidly in the in vitro system. Two lines of evidence indicate that the conversion of U2 precursors to mature-size U2 RNA involves a 3' processing reaction. First, the reaction is unaffected by a large excess of mature U2 small nuclear RNP, whose 5' trimethylguanosine caps would be expected to compete for a 5' processing activity. Second, when pre-U2 RNA precursors are first stoichiometrically decorated with an antibody specific for 2,2,7-trimethylguanosine, the extent of subsequent processing in vitro is unaffected. These results provide the first demonstration of a eukaryotic RNA processing reaction in vitro occurring within a ribonucleoprotein particle.

Biosynthesis and cytoplasmic distribution of small poly(A)-containing B2 RNA

Previously, we described a small polyadenylated RNA predominantly located in cytoplasm and hybridizing with the ubiquitous B2 sequence of the mouse genome (Kramerov, D.A., Lekakh, I.V., Samarina, O.P. and Ryskov, A.P. (1982) Nucleic Acids Res. 10, 7477-7491). This 180-300 nucleotide long RNA was designated B2 RNA. Here, we demonstrate that B2 RNA is complementary to just one of the strands of cloned B2 sequence. The synthesis of B2 is rather resistant to ultraviolet irradiation of Ehrlich ascites carcinoma cells. The treatment of the cells with alpha-amanitin at a concentration completely blocking the formation of small nuclear RNAs U1, U2 and U3 does not interfere with the B2 RNA synthesis. These results suggest that B2 RNA formation is directly transcribed with the aid of RNA polymerase III, rather than being formed in the course of the processing of large RNA molecules which are known to contain a lot of B2 sequences. We also surprisingly found that the synthesis of up to 50% of long poly(A) +RNA in Ehrlich carcinoma cells is rather resistant to alpha-amanitin. The possible role of genetic elements including B2 sequences able to promote large RNA-polymerase III transcripts is discussed. B2 RNA in the cytoplasm is incorporated into the ribonucleoprotein particles, both small (12-18 S) and heavy. The latter probably correspond to informosomes. After deproteinization of heavy particles, a major part of B2 RNA still cosediments with mRNA and is split from it only after denaturation. We suggest that the B2 RNA of heavy ribonucleoproteins is associated with mRNA by short complementary stretches. About half of the B2 RNA is recovered in the cytoskeletal fraction. The possible role of B2 RNA in mRNA transport or in translation regulation is discussed.

The small nuclear RNAs of Drosophila

We have investigated the sequences of the major small nuclear RNAs of Drosophila cultured cells, with the objective of elucidating phylogenetically conserved primary and secondary structures by comparison of the data with previously determined sequences of these RNAs in vertebrate species. Our results reveal striking degrees of conservation between each Drosophila RNA and its vertebrate cognate, and also demonstrate blocks of homology among the Drosophila small nuclear RNAs, as previously described for vertebrates. The most conserved features include the 5' terminal region of U1 RNA, though to function in pre-mRNA splicing, most of the regions of U4 RNA recently implicated in 3' processing of pre-mRNA, and the major snRNP protein binding site ("domain A") that is also shared by vertebrate U1, U2, U4 and U5 RNAs. Several other conserved features have been revealed, suggesting additional regions of functional significance in these RNAs and also providing further insights into the evolutionary history of the small nuclear RNAs.

Transcription-dependent localization of U1 and U2 small nuclear ribonucleoproteins at major sites of gene activity in polytene chromosomes

The location and dynamics of small nuclear ribonucleoproteins (snRNPs) were studied in salivary gland polytene chromosomes of Chironomus tentans by immunofluorescence with specific snRNP antibodies. Monoclonal antibody against the snRNP Sm antigens reacted at all sites of transcription (puffs and Balbiani rings). The amount of snRNP immunofluorescence was strictly dependent on transcription, increasing in parallel with gene activation and decreasing upon repression. Identical patterns of localization and transcriptional dependence were observed with antibodies specific for U1 or U2 snRNPs. These latter results show that the involvement of U1 and U2 snRNPs in transcription-related processes involves a high proportion, rather than small subsets, of active gene loci. In addition, the colocalization of U1 and U2 snRNPs at loci known to contain only one messenger RNA transcription unit (e.g. Balbiani ring 2) raises the possibility that both of these snRNPs interact with the same transcript. Finally, the lack of immunofluorescence at repressed loci indicates that snRNPs are not structural components of the chromatin (DNP) fiber, and also shows that unused snRNPs are not stored in chromatin. These latter points, and the growing evidence for the involvement of U1 snRNP in splicing, suggest that nascent pre-mRNA is the major chromosomal binding site for snRNPs.

Intron splicing: a conserved internal signal in introns of animal pre-mRNAs

Splicing of introns of yeast pre-mRNAs requires an internal conserved sequence T-A-C-T-A-A-C that is located 20-55 nucleotides from the 3' intron boundary. Sequences differing only in certain positions from this yeast signal have now been identified in the corresponding internal region of pre-mRNA introns of a variety of animal genes. A computer program that searches for homologues to a consensus structure and calculates the accuracy of match of each homologue is used to locate these sequences. We list here the signals found by this search in introns of sea urchin, mouse, rat, and human genes and give the consensus for each species. We also give the consensus found for Drosophila and chicken and duck signals. We then discuss the accumulating evidence that these internal signals are required for splicing in animals. It is also noted that a single-stranded region of small nuclear RNA U2 contains sequences complementary both to the proposed mammalian internal signal and to the neighboring CT-A-G at the 3' intron boundary. A role for U2 ribonucleoprotein in intron splicing is thus suggested.

Interactions of U1 RNP with heterogeneous nuclear RNA in rat Novikoff hepatoma nuclei

The nature of the association of U1 RNA with rapidly sedimenting RNP structures in rat hepatoma nuclei was investigated. The effects of salt and proteinase K treatment on the stability of this 'bound' form of U1 RNA were studied using sucrose density gradient analyses. Quantitation of the amount of U1 RNA remaining associated with large structures after treatment was used to assess the relative contribution of protein-protein (and protein-RNA) versus RNA-RNA interactions. Forty-eight percent of the total nuclear U1 RNA released by sonication was found in a 'bound' form when the sonicate was centrifuged through gradients containing 50 mM NaCl. Fifty percent of this 'bound' U1 RNA remained associated with rapidly sedimenting RNPs when the NaCl concentration was raised to 500 mM. To assess the contribution of protein independent interactions, large RNPs were completely deproteinized and their RNA moieties were then recentrifuged on gradients. By this analysis, 27% of the U1 RNA originally 'bound' to hnRNPs was associated with rapidly sedimenting (greater than 30 S) RNA (at 50 mM NaCl) suggesting their association by RNA-RNA hydrogen bonds. When the concentration of NaCl was 500 mM, 31% of the U1 RNA was associated with large RNA. Hence, approximately 30% of the U1 RNA molecules originally 'bound' (or about 15% of the total nuclear U1 RNA) were found to be associated by RNA-RNA hydrogen bonds while the remainder of the binding of U1 RNP to hnRNP was by protein-protein and/or protein-RNA interactions.

Precursors of U4 small nuclear RNA

The processing and ribonucleoprotein assembly of U4 small nuclear RNA has been investigated in HeLa cells. After a 45-min pulse label with [3H]uridine, a set of apparently cytoplasmic RNAs was observed migrating just behind the gel electrophoretic position of mature U4 RNA. These molecules were estimated to be one to at least seven nucleotides longer than mature U4 RNA. They reacted with Sm autoimmune patient sera and a monoclonal Sm antibody, indicating their association with proteins characteristic of small nuclear ribonucleoprotein complexes. The same set of RNAs was identified by hybrid selection of pulse-labeled RNA with cloned U4 DNA, confirming that these are U4 RNA sequences. No larger nuclear precursors of these RNAs were detected. Pulse-chase experiments revealed a progressive decrease in the radioactivity of the U4 precursor RNAs coincident with an accumulation of labeled mature U4 RNA, confirming a precursor-product relationship.

Interstrand duplexes in Friend erythroleukemia nuclear RNA. The interaction of non-polyadenylated nuclear RNA with polyadenylated nuclear RNA and with small nuclear RNAs

Intermolecular duplexes among large nuclear RNAs, and between small nuclear RNA and heterogeneous nuclear RNA, were studied after isolation by a procedure that yielded protein-free RNA without the use of phenol or high salt. The bulk of the pulse-labeled RNA had a sedimentation coefficient greater than 45 S. After heating in 50% (v/v) formamide, it sedimented between the 18 S and 28 S regions of the sucrose gradient. Proof of the existence of interstrand duplexes prior to deproteinization was obtained by the introduction of interstrand cross-links using 4'-aminomethyl-4,5',8-trimethylpsoralen and u.v. irradiation. Thermal denaturation did not reduce the sedimentation coefficient of pulse-labeled RNA obtained from nuclei treated with this reagent and u.v. irradiated. Interstrand duplexes were observed among the non-polyadenylated RNA species as well as between polyadenylated and non-polyadenylated RNAs. beta-Globin mRNA but not beta-globin pre-mRNA also contained interstrand duplex regions. In this study, we were able to identify two distinct classes of polyadenylated nuclear RNA, which were differentiated with respect to whether or not they were associated with other RNA molecules. The first class was composed of poly(A)+ molecules that were free of interactions with other RNAs. beta-Globin pre-mRNA belongs to this class. The second class included poly(A)+ molecules that contained interstrand duplexes. beta-Globin mRNA is involved in this kind of interaction. In addition, hybrids between small nuclear RNAs and heterogeneous nuclear RNA were isolated. These hybrids were formed with all the U-rich species, 4.5 S, 4.5 SI and a novel species designated W. Approximately equal numbers of hybrids were formed by species U1a, U1b, U2, U6 and W; however, species U4 and U5 were significantly under-represented. Most of these hybrids were found to be associated stably with non-polyadenylated RNA. These observations demonstrated for the first time that small nuclear RNA-heterogeneous nuclear RNA hybrids can be isolated without crosslinking, and that proteins are not necessary to stabilize the complexes. However, not all molecules of a given small nuclear RNA species are involved in the formation of these hybrids. The distribution of a given small nuclear RNA species between the free and bound state does not reflect the stability of the complex in vitro but rather the abundance of complementary sequences in the heterogeneous nuclear RNA.(ABSTRACT TRUNCATED AT 400 WORDS)

Ribonucleoprotein organization of eukaryotic RNA. XXX. Evidence that U1 small nuclear RNA is a ribonucleoprotein when base-paired with pre-messenger RNA in vivo

U1 small nuclear RNA is thought to be involved in messenger RNA splicing by binding to complementary sequences in pre-mRNA. We have investigated intermolecular base-pairing between pre-mRNA (hnRNA) and U1 small nuclear RNA by psoralen crosslinking in situ, with emphasis on ribonucleoprotein structure. HeLa cells were pulse-labeled with [3H]uridine under conditions in which hnRNA is preferentially labeled. Isolated nuclei were treated with aminomethyltrioxsalen , which produces interstrand crosslinks at sites of base-pairing between hnRNA and U1 RNA. hnRNA-ribonucleoprotein (hnRNP) particles were isolated in sucrose gradients containing 50% formamide, to dissociate non-crosslinked U1 RNA, and then analyzed by immunoaffinity chromatography using a human autoantibody that is specific for the ribonucleoprotein form of U1 RNA (anti-U1 RNP). After psoralen crosslinking, pulse-labeled hnRNA in hnRNP particles reproducibly bound to anti-U1 RNP. The amount of hnRNA bound to anti-U1 RNP was reduced 80 to 85% when psoralen crosslinking of nuclei was omitted, or if the crosslinks between U1 RNA and hnRNA were photo-reversed prior to immunoaffinity chromatography. Analysis of the proteins bound to anti-U1 RNP after crosslink reversal revealed polypeptides having molecular weights similar to those previously described for U1 RNP. These proteins did not bind to control, non-immune human immunoglobulin G. These results indicate that the subset of nuclear U1 RNA that is base-paired with hnRNA at a given time in the cell is a ribonucleoprotein. This raises the possibility that these proteins, as well as U1 RNA itself, may participate in pre-mRNA splice site recognition by U1 RNP.

Intracellular site of U1 small nuclear RNA processing and ribonucleoprotein assembly

We have investigated the intracellular site and posttranscriptional immediacy of U1 small nuclear RNA processing and ribonucleoprotein (RNP) assembly in HeLa cells. After 30 or 45 min of labeling with [3H]uridine, a large amount of U1-related RNA radioactivity in the cytoplasm was found by using either hypotonic or isotonic homogenization buffers. The pulse-labeled cytoplasmic U1 RNA was resolved as a ladder of closely spaced bands running just behind mature-size U1 (165 nucleotides) on RNA sequencing gels, corresponding to a series of molecules between one and at least eight nucleotides longer than mature U1. They were further identified as U1 RNA sequences by gel blot hybridization with cloned U1 DNA. The ladder of cytoplasmic U1 RNA bands reacted with both RNP and Sm autoimmune sera and with a monoclonal Sm antibody, indicating a cytoplasmic assembly of these U1 RNA-related molecules into complexes containing the same antigens as nuclear U1 RNP particles. The cytoplasmic molecules behave as precursors to mature nuclear U1 RNA in both pulse-chase and continuous labeling experiments. While not excluding earlier or subsequent nuclear stages, these results suggest that the cytoplasm is a site of significant U1 RNA processing and RNP assembly. This raises the possibility that nuclear-transcribed eucaryotic RNAs are always processed in the cell compartment other than that in which they ultimately function, which suggests a set of precise signals regulating RNA and ribonucleoprotein traffic between nucleus and cytoplasm.

Interaction of snRNAs with rapidly sedimenting nuclear sub-structures (hnRNPs) from HeLa cells

We have shown previously (Liautard et al., 1982, J. Mol. Biol., 162, 623-643) that digestion with micrococcal nuclease under drastic conditions of a pure U1 snRNP, as well as a mixture containing U2, U1, U4, U5 and U6 snRNPs, gives rise to resistant RNA fragments derived from all but U6 snRNAs. As an attempt to elucidate the way in which snRNPs are attached to their native structure, the same approach was applied to hnRNP which are known to contain snRNP (Guimont-Ducamp et al., 1977, Biochimie, 59, 755-758). Micrococcal nuclease digestion of hnRNPs yielded a population of 15-50 nucleotides long resistant fragments of snRNAs. Sequence analyses showed that all fragments previously identified in core snRNPs were also present. Only U2 and U5 snRNAs were further protected as a result of their association with the hnRNP complex (from the cap to nucleotide 32 for U2 and from nucleotide 22 to nucleotide 70 for U5). No additional protected fragment derived from U1, U4 and U6 snRNAs was found. This finding confirms that the 5' terminal region of U1 snRNP remains available for base-pairing interaction with the premessenger RNA, as predicted by the model of Lerner et al. (Nature, 1980, 283, 220-224).

Synthesis and assembly of human small nuclear ribonucleoproteins generated by cell-free translation

Cell-free translation of human poly(A)+ RNA was carried out to generate and analyze the protein constituents of small nuclear ribonucleoprotein (snRNP) particles. The snRNP proteins were identified by immunoprecipitation with sera from patients with systemic lupus erythematosus. Size fractionation of mRNA prior to translation revealed that these snBNP proteins are all encoded by separate messages. One of the proteins (the A protein, molecular weight 32,000) was seen to lose antigenicity upon RNase treatment either when extracted from cells or when generated in vitro. RNase treatment of immunoprecipitated snRNPs released the A protein in an electrophoretically pure form. Analysis of snRNPs translated in vitro revealed the presence of unassembled and assembled particles as determined by sucrose density gradient sedimentation. Post-translational assembly of snRNPs involving both RNA-protein binding (as revealed by A protein antigenicity) and associations of other snRNP proteins occurred in the in vitro system employed here. In addition, the presence of unassembled snRNP proteins permitted the determination of the precise antigen peptides recognized by Sm and RNP autoimmune sera. It was observed that Sm sera are capable of recognizing each of the eight snRNP proteins, whereas RNP sera recognize only two of the eight.

Associations of small nuclear RNAs in human cells

Several observations have been made about the associations of small nuclear RNAs (snRNAs) in human cells. When nuclear RNA was extracted with phenol and chloroform under standard nondenaturing conditions, the proportion of the nuclear snRNA content that cosedimented with high molecular weight RNA was very low. These results do not support the proposal that it is a large percentage of the cellular snRNA content that is involved in relatively stable base-paired interactions with heterogeneous nuclear RNA at any given time. The various small nuclear ribonucleoprotein particles (snRNPs), in which the snRNAs are found in the cell, appear to differ substantially in their sedimentation rates under conditions of physiological ionic strength. Using anti-RNP and anti-Sm antibodies to analyze various subcellular fractions, we found that most, if not all, of the U1 snRNA cellular content is associated with the polypeptide(s) bearing the RNP determinant (in interphase and mitotic cells) and with the polypeptide(s) carrying the Sm determinant (in mitotic cells).

Molecular cloning and characterization of a gene for rat U2 small nuclear RNA

Six phage clones that contain sequences hybridizable with the small nuclear RNA U2 were isolated from a rat gene library. Of these clones, one which includes a candidate for a functional U2 RNA gene was selected and characterized. The sequence within the clone which hybridizes with rat U2 RNA was completely co-linear with that of the RNA. A T-A-T-A box was not found in the region of more than 400 base-pairs which lies upstream of the gene. However, several block homologies were found with the upstream sequences of a rat U1 RNA gene candidate cloned in our laboratory. An "identifier sequence", which was reported to be an element of gene regulation related to differentiation, was found downstream of the coding region at the same distance and with the same orientation as the identifier sequence located downstream of the U1 RNA gene candidate. We detected a presumed U2 RNA precursor elongated by about 11 nucleotides at the 3' end by S1 nuclease mapping using a fragment from the clone. A potential termination signal for transcription was found within the elongated region of the presumed precursor. Southern blot analysis suggests that families of U2 RNA genes that have conserved flanking sequences are present in the genomes of rat, mouse, man, calf and chicken.

Small nuclear RNA transcription and ribonucleoprotein assembly in early Xenopus development

The Xenopus egg and embryo, throughout the transcriptionally inactive early cleavage period, were found to contain a store of approximately 8 X 10(8) molecules of the small nuclear RNA (snRNA) U1, sufficient for 4,000-8,000 nuclei. In addition, when transcription is activated at the twelfth cleavage (4,000 cell-stage), the snRNAs U1, U2, U4, U5, and U6 are major RNA polymerase II products. From the twelfth cleavage to gastrulation, U1 RNA increases sevenfold in 4 h, paralleling a similar increase in nuclear number. This level of snRNA transcription is much greater than that typical of somatic cells, implying a higher rate of U1 transcription or a greater number of U1 genes active in the embryo. The Xenopus egg also contains snRNP proteins, since it has the capacity to package exogenously added snRNA into immunoprecipitable snRNP particles, which resemble endogenous particles in both sedimentation coefficient and T1 RNase digestibility. SnRNP proteins may recognize conserved secondary structure of U1 snRNA since efficient packaging of both mouse and Drosophila U1 RNAs, differing 30% in sequence, occurs. The Xenopus egg and embryo can be used to pose a number of interesting questions about the transcription, assembly, and function of snRNA.

Heat shock alters nuclear ribonucleoprotein assembly in Drosophila cells

Heterogeneous nuclear RNA is normally complexed with a specific set of proteins, forming ribonucleoprotein particles termed hnRNP. These particles are likely to be involved in mRNA processing. We have found that the structure of hnRNP is profoundly altered during the heat shock response in Drosophila cultured cells. Although hnRNA continues to be synthesized at a near-normal rate during heat shock, its assembly into hnRNP is incomplete, as evidenced by a greatly decreased protein content of the particles in Cs2SO4 density gradients. RNA-protein cross-linking conducted in vivo (Mayrand and Pederson, Proc. Natl. Acad. Sci. U.S.A. 78:2208-2212, 1981) also reveals that hnRNA made during heat shock is complexed with greatly reduced amounts of protein. The block of hnRNP assembly occurs immediately upon heat shock, even before the onset of heat shock protein synthesis. Additional experiments reveal that hnRNP assembled normally at 25 degrees C subsequently disassembles during heat shock. The capacity for normal hnRNP assembly is gradually restored after heat-shocked cells are returned to 25 degrees C. Heat-shocked mammalian cells also show a similar block in hnRNP assembly. We suggest that incomplete assembly of hnRNP during heat shock leads to abortive processing of most mRNA precursors and favors the processing or export (or both) of others whose pathway of nuclear maturation is less dependent on, or even independent of, normal hnRNP particle structure. This hypothesis is compatible with a large number of previous observations.

[Do repetitive DNA sequences have a biological function?]

By DNA reassociation kinetics it is known that the eucaryotic genome consists of non-repetitive DNA, middle-repetitive DNA and highly repetitive DNA. Whereas the majority of protein-coding genes is located on non-repetitive DNA, repetitive DNA forms a constitutive part of eucaryotic DNA and its amount in most cases equals or even substantially exceeds that of non-repetitive DNA. During the past years a large body of data on repetitive DNA has accumulated and these have prompted speculations ranging from specific roles in the regulation of gene expression to that of a selfish entity with inconsequential functions. The following article summarizes recent findings on structural, transcriptional and evolutionary aspects and, although by no means being proven, some possible biological functions are discussed.

Structure of nuclear ribonucleoprotein: heterogeneous nuclear RNA is complexed with a major sextet of proteins in vivo

Mouse erythroleukemia cells were pulse-labeled with [3H]uridine and irradiated with 254-nm light to produce covalent crosslinks between RNA and proteins in close proximity to one another in vivo. Nuclear ribonucleoprotein particles containing heterogeneous nuclear RNA were isolated and digested with nucleases, and the resulting proteins were subjected to gel electrophoresis. Proteins carrying covalently crosslinked [3H]uridine nucleotides were identified by fluorography. The results demonstrate that heterogeneous nuclear RNA is complexed in vivo with a set of six major proteins having molecular weights between 32,500 and 41,500. Analysis of chromatin fractions indicates that nascent heterogeneous nuclear RNA chains assemble with these six proteins as a very early post-transcriptional event. These data, and other results [Nevins, J. R. & Darnell, J. E. (1981) Cell 15, 1477-1493], lead us to propose the usual order of post-transcriptional events to be: heterogeneous nuclear RNA-ribonucleoprotein particle assembly leads to poly(A) addition leads to splicing.

Heat shock alters nuclear ribonucleoprotein assembly in Drosophila cells

Heterogeneous nuclear RNA is normally complexed with a specific set of proteins, forming ribonucleoprotein particles termed hnRNP. These particles are likely to be involved in mRNA processing. We have found that the structure of hnRNP is profoundly altered during the heat shock response in Drosophila cultured cells. Although hnRNA continues to be synthesized at a near-normal rate during heat shock, its assembly into hnRNP is incomplete, as evidenced by a greatly decreased protein content of the particles in Cs2SO4 density gradients. RNA-protein cross-linking conducted in vivo (Mayrand and Pederson, Proc. Natl. Acad. Sci. U.S.A. 78:2208-2212, 1981) also reveals that hnRNA made during heat shock is complexed with greatly reduced amounts of protein. The block of hnRNP assembly occurs immediately upon heat shock, even before the onset of heat shock protein synthesis. Additional experiments reveal that hnRNP assembled normally at 25 degrees C subsequently disassembles during heat shock. The capacity for normal hnRNP assembly is gradually restored after heat-shocked cells are returned to 25 degrees C. Heat-shocked mammalian cells also show a similar block in hnRNP assembly. We suggest that incomplete assembly of hnRNP during heat shock leads to abortive processing of most mRNA precursors and favors the processing or export (or both) of others whose pathway of nuclear maturation is less dependent on, or even independent of, normal hnRNP particle structure. This hypothesis is compatible with a large number of previous observations.

Purification of snRNPs U1, U2, U4, U5 and U6 with 2,2,7-trimethylguanosine-specific antibody and definition of their constituent proteins reacting with anti-Sm and anti-(U1)RNP antisera

Small nuclear ribonucleoprotein particles (snRNPs) of the U-snRNP class from Ehrlich ascites tumor cells were purified in a one-step procedure by affinity chromatography with antibodies specific for 2,2,7-trimethylguanosine (m23.2.7G), which is part of the 5'-terminal cap structure of snRNAs U1-U5. Antibody-bound snRNPs are desorbed from the affinity column by elution with excess nucleoside m23.2.7G; this guarantees maintenance of their native structure. The snRNPs U1, U2, U4, U5 and U6 can be recovered quantitatively from nuclear extracts by this procedure. Co-isolation of U6 snRNP must be due to interactions between this and other snRNPs, as anti-m23.2.7G antibodies do not react with deproteinized U6 snRNA. We have so far defined nine proteins of approximate mol. wts. 10 000, 12 000, 13 000, 16 000, 21 000, 28 000, 32 000, 34 000 and 75 000. Purified snRNPs react with anti-(U1)RNP and with anti-Sm antisera from patients with mixed connective tissue disease and from MRL/l mice. As determined by the protein blotting technique, six of the snRNP polypeptides, characterized by apparent mol. wts. 13 000, 16 000, 21 000, 28 000, 34 000 and 75 000, bear antigenic determinants for one or the other of the above autoantibody classes. This suggests strongly that the U-snRNPs produced by the procedure described here are indeed representative of the snRNPs in the cell. With highly purified snRNPs available, investigation of possible enzymic functions of the particles may now be undertaken.