Dynamics of the U1 Small Nuclear Ribonucleoprotein during Yeast Spliceosome Assembly*

(Received for publication, February 6, 1997, and in revised form, April 16, 1997)

Stephanie W. Ruby Dagger

From the Department of Cell Biology, University of New Mexico Health Sciences Center, Cancer Research and Treatment Center, Albuquerque, New Mexico 87131

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES


ABSTRACT

U1 small nuclear ribonucleoprotein (snRNP) may function during several steps of spliceosome assembly. Most spliceosome assembly assays, however, fail to detect the U1 snRNP. Here, I used a new native gel electrophoretic assay to find the yeast U1 snRNP in three pre-splicing complexes (delta , beta 1, alpha 2) formed in vitro. The order of complex formation is deduced to be delta  right-arrow beta 1 right-arrow alpha 2 right-arrow alpha 1 right-arrow beta 2, the active spliceosome. The delta  complex is formed when U1 snRNP binds to pre-mRNA in the absence of ATP. There are two forms of delta : a major one, delta un, unstable to competitor RNA; and a minor one, delta commit, committed to the splicing pathway. The other complexes are formed in the presence of ATP and contain the following snRNPs: beta 1, the pre-spliceosome, has both U1 and U2; alpha 2 has all five, however, U1 is reduced compared with the others; and alpha 1 and beta 2 have U2, U5, and U6. Prior work by others suggests that U1 is "handing off" the 5' splice site region to the U5 and U6 snRNPs before splicing begins. The reduced levels of U1 snRNP in the alpha 2 complex suggests that the handoff occurs during formation of this complex.


INTRODUCTION

The U1 small nuclear ribonucleoprotein (snRNP)1 is one of several components including the U2, U4, U5, and U6 snRNPs and several non-snRNP proteins that form the spliceosome on pre-mRNA (for review, see Refs. 1-7). U1 is the first snRNP to bind to pre-mRNA during spliceosome assembly as studied by in vitro assays. Subsequently the U2 snRNP binds and the pre-spliceosome is formed. Next the U4/U5/U6 tri-snRNP binds, and the spliceosome is created. Finally, the spliceosome is activated for splicing by at least one conformational change in which the U4 and U6 snRNAs dissociate from one another.

Although the order of binding of snRNPs and some non-snRNP proteins during spliceosome assembly is known, the presence and function of U1 snRNP in several of the spliceosome assembly intermediates are controversial. The U1 snRNP has been thought to function in recognizing the intron primarily during the early steps of spliceosome assembly. As the first snRNP to bind to the pre-mRNA, U1 has an important, hierarchic role in spliceosome assembly and in recognition of the splice sites in the yeast Saccharomyces cerevisiae. The nucleotides 3-8 at the 5' end of U1 snRNA base pair with the pre-mRNA 5' splice site region (8). This interaction probably occurs when U1 binds to pre-mRNA because mutations in the pre-mRNA 5' splice site decrease U1 snRNP binding and inhibit subsequent steps in spliceosome assembly (9, 10). RNase H degradation (9) or depletion (11) of the U1 snRNP prevents the other snRNPs from binding to the pre-mRNA as well.

In addition to base pairing with the 5' splice site, U1 snRNP interacts directly or indirectly with several other spliceosomal components. A protein bridge may span the 5' splice site and branchpoint region (12, 13) and contribute to U1 snRNP binding to the pre-mRNA (9, 14). U1 snRNP may also associate directly with the U2 snRNP as a U1/U2 snRNP complex can be induced in Hela cell extracts by an RNA complementary to the 5' end of U1 snRNA (15). Finally, U1 snRNP may interact with additional spliceosomal components during the late steps of spliceosome assembly as suggested by the finding that a 2'-O-methyl oligoribonucleotide complementary to U5 snRNA can induce the formation of a U1/U4/U5 snRNP complex in Hela cell extracts (16). Most of these interactions are probably important for spliceosome assembly but not for splicing catalysis because once a yeast spliceosome is formed on the pre-mRNA, it can lose U1 snRNA and still catalyze splicing (17).

These interactions suggest that the U1 snRNP is present in several intermediates in spliceosome assembly. At least in HeLa cell splicing extracts, this is the case. When pre-mRNA is added to HeLa cell extracts, the pre-splicing complexes E, A, and B form in that order as precursors to the active spliceosome, complex C (18-22). The U1 snRNP can be detected in all four complexes when purified by affinity chromatography. However, it is found predominantly in E, and its concentration decreases relative to the U2 and U4/U5/U6 snRNPs as these snRNPs bind during formation of the A and B complexes, respectively (20). These and other studies (23, 24) have proposed that the association of the U1 snRNP with the spliceosome changes sometime before splicing is catalyzed. In fact, U1 is supplanted by the U5 and U6 snRNAs at the pre-mRNA 5' splice site before catalysis (for review, see Refs. 5 and 6). Recently, it has been suggested that the base pairing between U1 and pre-mRNA is disrupted even earlier, before U2 snRNP binds (25, 26).

Although the U1 snRNP has been thought to participate in several steps of spliceosome formation in yeast, its presence in most of the yeast pre-splicing complexes formed in vitro has not been shown. Pre-splicing complexes III, I, and II, as detected initially by one-gel electrophoretic assay (27, 28), and complexes B, A2-1, and A2-2, as identified by a different gel assay (29), form in that order and contain the U2, U2/U4/U5/U6, and U2/U5/U6 snRNPs, respectively. U1 snRNP binding to the pre-mRNA during the first step of yeast spliceosome assembly was discovered subsequently by affinity chromatography (9) and by gel-electrophoresis (11). All gel electrophoretic assays, however, have failed to find U1 snRNA in pre-splicing complexes formed after this first assembly step (11, 18, 27, 29), although the U1 snRNP-specific 70K protein was found in pre-splicing complexes formed in HeLa extracts and resolved by gel electrophoresis (30).

To detect the U1 snRNP during yeast spliceosome assembly in vitro, I developed a new native gel electrophoretic assay. I found U1 snRNA in three pre-splicing complexes (delta , beta 1, and alpha 2). One of these complexes, beta 1 (the pre-spliceosome), contains both U1 and U2 snRNAs as had been proposed by previous studies (9, 11). The alpha 2 complex contains the U2, U4, U5, and U6 snRNAs, as well as reduced amounts of U1. This reduction in the amount of U1 suggests that the association of U1 with pre-mRNA or other spliceosomal components that makes this snRNP stable in the pre-spliceosome is disrupted about the time the alpha 2 complex is formed. This change in U1 may indicate the "handing off" of the 5' splice site region from the U1 to the U5 and U6 snRNPs.


EXPERIMENTAL PROCEDURES

In Vitro Splicing Assays and Native Gel Electrophoresis

Plasmid for in vitro synthesis of Sp6-Wt (31) actin pre-mRNA was as described. The plasmid was cut with HpaII restriction endonuclease (New England Biolabs Inc.) for synthesizing the transcripts used in the native gel electrophoretic assays. Uncapped, radiolabeled pre-mRNAs for splicing and spliceosome assembly assays were synthesized in vitro with SP6 polymerase (Promega) and [32P]UTP (Amersham Corp.) as described previously (31). For Northern blot analyses, the pre-mRNA was synthesized with very low or no specific activity as described previously (29).

Whole cell splicing extract was made from strain EJ101 as described previously (31). A typical splicing reaction contained 0.4 nM radiolabeled pre-mRNA, 60 mM KPO4 (pH 7.4), 3 mM MgCl2, 2 mM ATP, 3% PEG8000 and 40% extract in 20 mM Hepes-K+ (pH 7.8 at 0 °C), 0.2 mM EDTA, 50 mM KCl, 0.5 mM dithiothreitol, and 20% glycerol. A 10-µl splicing reaction with radiolabeled pre-mRNA was incubated at 23 °C and then quenched by adding it to 10 µl of ice-cold 50 mM Hepes-K+ (pH 7.4), 2 mM (CH3COO)2Mg (R buffer; see Ref. 11) with 2 µg/µl carrier RNA. Carrier RNA was prepared from mouse intestine as described (32). The sample was incubated on ice for 10 min, and then 5 µl of loading buffer (200 mM Tris-phosphate (pH 8.0 at 0 °C), 50% (v/v) glycerol, 0.1% xylene cyanol, and 0.1% bromphenol blue) were added. The samples were fractionated on a 3.2% polyacrylamide gel (50:1, acrylamide:bisacrylamide) in TPM8 buffer (48 mM Tris-phosphate (pH 8.0 at 0 °C), 1.5 mM (CH3COO)2Mg)) at 4 °C for 16-20 h at 5.5-6.7 V/cm. The gel was placed on 3MM Whatman paper, and the complexes were visualized by autoradiography with film or a Molecular Dynamics PhosphorImager.

The previously described prp6-1 mutant (33) was used for mutant extract. A UV-induced, temperature-resistant revertant of this prp6-1 mutant (prp6-1R1), was isolated and used for wild-type extract, as shown in Fig. 5.


Fig. 5. Pre-splicing complex formation with wild-type and mutant prp6 splicing extracts. A, splicing reactions with mutant prp6 extract but without splicing substrate were incubated for 2 min at the indicated temperatures. Radiolabeled actin pre-mRNA was then added. At 15 and 30 min, samples were removed, fractionated by native gel electrophoresis, and visualized by autoradiography as shown here. The bands formed by the pre-mRNA are indicated as delta , beta , and alpha . B, splicing reactions with non-radiolabeled pre-mRNA and either wild-type or mutant prp6 extract were incubated at 30 °C as described in panel A. Samples were removed at 2, 10, and 20 min after pre-mRNA addition and assayed by native gel electrophoresis. The RNAs in the gel were transferred to a membrane, hybridized sequentially with the U snRNA probes indicated, and visualized by autoradiography. The pre-splicing complexes (delta , beta 1, beta 2, and alpha ) are indicated. The symbol, U4/U5/U6*, indicates the tri-snRNP that is formed in wild-type but not mutant prp6 extract at 30 °C.
[View Larger Version of this Image (31K GIF file)]

Northern Blot Analyses

Ten-µl splicing reactions containing 4 nM pre-mRNA were run on native gels as described above. After electrophoresis, the gel was placed on 3MM Whatman paper and soaked in two changes of a 5-fold volume of 1 × TBE (8 mM Tris-borate (pH 8), 2 mM EDTA) with 8 M urea for 15 min each; this denaturation is essential for efficient transfer of the snRNAs in the next step. The RNAs in the gel were electrophoretically transferred to Gene Screen (New England Nuclear) in 0.25 × TBE at 120 V for 1 h at 4 °C in an apparatus described by Church and Gilbert (34). The wet membrane was then irradiated with three germicidal bulbs (General Electric, G15T8) at a distance of 35 cm for 15 min. The membrane was next simmered for 10 min in about 500 ml of boiling 0.1 × SSCP (120 mM NaCl, 15 mM Na citrate, and 20 mM NaPO4 (pH 7.0)) with 0.1% SDS in the microwave and then shaken for 10 min at room temperature. After prehybridization in hybridization buffer (50% formamide, 5 × SSCP, 0.1% SDS, 3 × Denhardt's solution, and 100 µg/ml sonicated, denatured salmon sperm DNA) at 42 °C for at least 30 min, the radiolabeled probe was added in 15-20 mls of fresh hybridization buffer and incubated with the membrane overnight. The blot was washed three times at 23 °C for 10 min each in 3 × SSCP with 0.1% SDS, once for 10 min at 55 °C, and once in 0.1 × SSCP with 0.1% SDS for 10 min at 55 °C. The hybridization was detected by autoradiography with either film or a Molecular Dynamics PhosphorImager.

For radiolabeled snRNA probes, the DNA fragments encoding the snRNAs on plasmids pT7-U1 and pT7-U2 (from D. McPheeters, Case Western Reserve University, Cleveland, OH), pT7-U4 and pT7-U6 (from P. Fabrizio, Phillips University Marburg, Marburg, Germany), and pT7-U5 (from L. Krinke) encoding the snRNAs were amplified by the polymerase chain reaction (35). The sizes of amplified fragments are the following: U1, 575 bp; U2, ~1200 bp; U4, 170 bp; U5, 180 bp; and U6, 115 bp. The amplified DNAs were then radiolabeled by random oligodeoxynucleotide-primed extension (36).

Deoxyoligonucleotide-directed RNase H Degradation of snRNAs in Splicing Extracts

Deoxyoligonucleotides for targeted degradation of the U1 (oSR19), U2 (oSR20-also called SRU2), and U6 (d1) were as described (9, 37). For the experiment shown in Fig. 7, A and B, the deoxyoligonucleotide oSR20 was added to a concentration of 1.3 µM in splicing extract with 1.6 mM MgCl2 and 2 mM dithiothreitol. After incubating the extract for 30 min at 30 °C, water was added to bring the extract to 40% of the volume, and KPO4 (pH 7.6), MgCl2, ATP, and PEG8000 were added to final concentrations of 60, 3, and 2 mM and 3%, respectively. This brought the calculated concentration of the deoxoligonucleotide oSR20 to 600 nM for the splicing reactions incubated in Step 1. After addition of an equal volume of splicing reaction with active extract in Step 3, the final calculated concentration of oSR20 was 300 nM. The conditions for inactivating the U1 and U6 snRNAs in extracts were as described (9, 37).


Fig. 7.

Commitment and stability of the delta  complex. A, a flow scheme for determining if pre-mRNA in the delta  complex can be chased into the spliceosome. The scheme corresponds to the reactions shown in lanes 6, 7, and 8 in panel B. Step 1, radiolabeled pre-mRNA was incubated for 10 min at 23 °C in a splicing reaction with ATP and with the U2 snRNA inactivated by deoxyoligonucleotide-directed RNase H degradation. Step 2, a 25-fold excess of cold pre-mRNA was added to the reaction that was then incubated for 1 min at 23 °C. Step 3, an equal volume of a splicing reaction made with active whole cell extract and ATP was added to the reaction. After 15 and 30 min, samples were removed and assayed by native gel electrophoresis. B, autoradiogram of the native gel electrophoretic assay. The samples are from the following reactions: lane 1, radiolabeled pre-mRNA was incubated in Step1 only; lane 2, radiolabeled pre-mRNA was incubated in Step1 and Step3 but with no ATP in Step 3; lane 3, radiolabeled pre-mRNA was incubated in Step1 and Step 3; lane 4, 25-fold molar excess cold pre-mRNA was incubated in the splicing reaction in Step 1 and radiolabeled pre-mRNA and active splicing extract and ATP were added in Step 3; lane 5, radiolabeled pre-mRNA was added in Step 1, excess cold pre-mRNA was added in Step 2, and carrier RNA was added before active extract to quench the reaction; lanes 6, 7 and 8 are as diagrammed in panel A; lanes and 10, radiolabeled pre-mRNA was added in Step 1, and active extract and ATP were added in Step 3; lane 11, "0" time point, radiolabeled pre-mRNA was added to the splicing reaction after the reaction had been stopped for native gel electrophoresis; and lanes 12 and 13, radiolabeled pre-mRNA was added to active splicing extract with ATP (Step 3 only), and samples were removed at 15 and 30 min, respectively. C, samples designated pre show splicing extract with ATP and the U2 snRNA inactivated by deoxyoligonucleotide-directed RNase H degradation were incubated first for 10 min with 0, 1-, 5-, or 10-fold molar amounts of cold pre-mRNA, and then for 10 min with radiolabeled pre-mRNA, after which the samples were assayed by native gel electrophoresis and visualized by autoradiography. Samples designated post show radiolabeled pre-mRNA was incubated in extract first for 10 min and then for 10 min after the indicated amounts of cold pre-mRNA were added.


[View Larger Version of this Image (34K GIF file)]


RESULTS

Detection of U1 snRNA in Pre-splicing Complexes

As the U1 snRNA is not found in most pre-splicing complexes resolved by native gel electrophoresis, I specifically sought electrophoretic conditions that would retain the U1 snRNP in pre-splicing complexes. Among the gel buffer components tested, magnesium ion had the most significant effect on U1 snRNP retention (Fig. 1). U1 snRNA, as detected by Northern blot hybridization, is present with pre-mRNA in two bands, delta  and beta 1, in a gel run with or without magnesium acetate, but there is an average of 16-fold more U1 in the delta  band (n = 4, standard deviation = 1.9) with magnesium ion than without it. Additional assays revealed that the amount of U1 in the delta  band is proportional to the magnesium ion concentration in the buffer up to 1.5 mM (data not shown). In a gel with or without magnesium ion, "free" U1 snRNP not bound to the added pre-mRNA migrates as two diffuse bands (designated by asterisks in Fig. 1). There is less free U1 snRNP with than without magnesium, and yet equivalent amounts of free U1 snRNP are detected in splicing reactions without added pre-mRNA. This suggests that most U1 snRNP bound to added pre-mRNA dissociates during electrophoresis without magnesium. The beta 1 band migrates near the slower form of free U1 snRNP; however, it is distinct from free U1 snRNP as it is sharp and its formation depends on the presence of added pre-mRNA. That there is more delta  band and less free U1 snRNP in gels with magnesium ion than without it suggests that magnesium ion stabilizes U1 snRNP bound to pre-mRNA. I included 1.5 mM magnesium acetate in all subsequent assays.


Fig. 1. Pre-splicing complexes separated by electrophoresis in native gels with and without magnesium acetate and analyzed by Northern blot hybridizations with a U1-specific probe. Samples were removed from a splicing reaction at 5, 15, and 30 min after the addition of an actin pre-mRNA of very low specific activity (+ pre-mRNA) or no pre-mRNA (-pre-mRNA). Each sample was divided in two and run on a native polyacrylamide gel either with (+Mg2+) or without magnesium acetate (-Mg2+) in the gel buffer. The RNAs were transferred to a membrane and hybridized with a U1 snRNA-specific probe. The complexes containing U1 snRNA were visualized by autoradiography as shown here: delta  and beta 1 denote pre-splicing complexes, and the asterisks indicate endogenous complexes containing U1 snRNA.
[View Larger Version of this Image (50K GIF file)]

To begin to determine the order of formation of the pre-splicing complexes, I assayed their kinetics of formation in splicing reactions at the normal 23 or at 15 °C, which slows the splicing reaction (Fig. 2). Radiolabeled pre-mRNA was added to splicing reactions with or without added ATP, and at various times thereafter, samples were removed and analyzed by native gel electrophoresis. In the absence of added ATP at either temperature, there are two major bands, a rapidly migrating band that forms nonspecifically on any RNA and the delta  band. The delta  band forms quickly at 23 °C with the maximum amount appearing by 2-5 min. Later, there are low amounts of a slowly migrating smear that consists of two nearly unresolved bands (beta  and alpha ); their formation without added ATP is due to the low levels of ATP endogenous to the splicing extract (see below; also see Ref. 38). In the presence of added ATP at 23 °C, the delta  band accumulates first with maximal amounts reached at 2-5 min and then declines after 10 min. The beta -alpha band reaches maximal amounts at about 10 min. The reactions incubated at 15 °C form most of the bands more slowly than at 23 °C, allowing additional kinetic differentiation. In particular, the delta  band now appears first in the presence of added ATP, followed by the more slowly migrating beta  band. Little alpha  band accumulates at these early times. The simplest interpretation of the temporal relationship of the formation of these bands is that one or more complexes in the delta  band is the precursor of the complexes in the beta  and alpha  bands. The beta  and alpha  bands migrate close to one another and do not resolve well when formed on the amount, specific activity, and type of radiolabeled actin pre-mRNA used here. Subsequent experiments described below show that these two bands can be resolved.


Fig. 2. Kinetics of spliceosome assembly in the presence and absence of added ATP. Splicing reactions with or without added ATP were initiated by the addition of a radiolabeled pre-mRNA and incubated at either 15 or 23 °C. Samples were removed at the times indicated (0, 0.5, 1, 2, 5, 10, 20, and 30 min) and separated by native gel electrophoresis. The pre-mRNA-dependent (delta , beta , and alpha ) and the nonspecific (ns) bands were visualized by autoradiography as shown here.
[View Larger Version of this Image (56K GIF file)]

If the delta  band represents the first pre-splicing complex to form, then its formation should depend on the U1 but not the U2 snRNP (9, 11). I therefore analyzed its formation with radiolabeled pre-mRNA in splicing extracts in which either the U1 or U2 snRNA was inactivated by deoxyoligonucleotide-directed RNase H degradation (Fig. 3). The reaction with inactivated U1 snRNA forms no detectable pre-mRNA-specific bands (Fig. 3A). The reaction with inactivated U2 snRNA forms the delta  band in the presence or absence of ATP but is unable to form additional complexes. Additionally, extracts pre-incubated with the control deoxyoligonucleotide do not form the beta  and alpha  bands unless ATP is added subsequently for the assay as the pre-incubation step depletes the endogenous levels of ATP (39). U2 snRNA in the gel was detected by Northern blot analysis with a U2-specific probe after sufficient time had elapsed for the radiolabel in the pre-mRNA to decay. As previously reported for the conditions used in this study (9, 40), greater than 97% of U2 snRNA was destroyed when targeted for degradation (Fig. 3B, lanes 9-12). This destruction, however, has no effect on the formation or migration of the delta  band even though free U2 snRNP normally migrates close to the delta  complex. Furthermore, the delta  band has the same mobility when formed in extracts with either wild-type U2 snRNP or a smaller, but functional, U2 snRNP (41) despite the fact that the small U2 snRNP migrates nearly twice as far as wild-type U2 snRNP in the gel (data not shown). Thus, the formation and migration of the delta  band requires U1 but not U2 snRNP while the formation of the alpha  and beta  bands requires ATP and both U1 and U2 snRNPs. The properties of the delta  band (that it contains U1 snRNA, forms in the absence of ATP and U2 snRNP, and forms first in the presence of ATP), as well as additional properties described below, indicate that the delta  band contains a pre-splicing complex that I have called the delta  complex.


Fig. 3. Pre-splicing complex formation in splicing extracts inactivated by deoxyoligonucleotide-directed RNase H degradation of U1 or U2 snRNA. Splicing extract was incubated with a control deoxyoligonucleotide or with a deoxyoligonucleotide complementary to either the U1 or U2 snRNA. The extracts were then incubated with radiolabeled actin pre-mRNA and with or without ATP. Samples were removed at 10 and 20 min after pre-mRNA addition and assayed by native gel electrophoresis. A, the pre-spliceosome complexes (delta , beta 1, beta 2, and alpha ) formed on radiolabeled pre-mRNA were visualized by autoradiography. B, the RNAs in the gel in panel A were transferred to a membrane. After sufficient time for the radiolabel in the pre-mRNA to decay, the RNAs were hybridized with a probe specific for the U2 snRNA. The position of the endogenous U2 snRNP is indicated (U2).
[View Larger Version of this Image (59K GIF file)]

To identify additional pre-splicing complexes that contain U1 snRNP, a splicing reaction was incubated either with or without non-radiolabeled pre-mRNA, fractionated by native gel electrophoresis, and analyzed by Northern blot hybridization with the snRNA-specific probes (Fig. 4). This experiment resolved three slowly migrating complexes in addition to the delta  complex. They are distinguished by their mobilities, kinetics of formation, and snRNA content, and are called beta 1, alpha , and beta 2. The delta  and beta  complexes as detected with the U1 probe appear early in the splicing reaction. Of note is that both U1 and U2 snRNAs are present in the beta  complex at the early times (Fig. 4, lanes 1 and 6). At 30 min, however, U2, U5, and U6 snRNAs accrue, and U1 snRNA remains the same (lane 3) or decreases (data not shown). Furthermore, only pre-mRNA can be isolated from the beta  complex at early times in splicing reactions, whereas pre-mRNA and intermediates can be isolated from the beta complex at late times (data not shown). These results suggest that there are two co-migrating beta  complexes that are kinetically distinguishable: beta 1, which forms early in the splicing reaction and contains U1 and U2 snRNPs, and beta 2, which forms later, contains U2, U5 and U6 snRNPs, and is the active spliceosome.


Fig. 4. Northern analysis of pre-splicing and endogenous snRNP complexes. A, splicing reactions with ATP were incubated either with (+pre-mRNA) or without (-pre-mRNA) non-radiolabeled splicing substrate. Samples were removed at 5, 15, or 30 min from the start of the reactions and fractionated by native gel electrophoresis. The RNAs were transferred to a membrane and hybridized sequentially with a probe for the U1, U2, U4, U5, or U6 snRNA. The complexes containing U snRNAs were visualized by autoradiography as shown here: delta , beta , and alpha  denote pre-splicing complexes; and the asterisks indicate endogenous snRNP complexes.
[View Larger Version of this Image (54K GIF file)]

A third band formed on the pre-mRNA in the presence of ATP is also apparent in this assay (Fig. 4). The alpha  band, as seen most clearly with the U4 snRNA probe, is identified by having 1) a slower migration than the beta  complexes, 2) a slower rate of formation than the beta 1 complex, and 3) the U4 as well as the U2, U5, and U6 snRNAs. A very small amount of U1 snRNA may also be present in this band. The alpha  band is more readily identified by Northern blot hybridizations in part because the splicing reactions usually have 10-fold more pre-mRNA than those with radiolabeled pre-mRNA. Subsequent assays described below identified two complexes in this band.

To confirm the nature and composition of the beta 1 complex, I assayed its formation in a splicing extract in which the Prp6 protein was inactivated. The Prp6 protein is required for the U4/U5/U6 tri-snRNP to form and to be incorporated into the developing spliceosome (42). Active splicing extract made from a temperature-sensitive prp6-1 mutant grown at the permissive temperature has been shown to be temperature sensitive in vitro due to the mutant prp6 protein (33). The prp6-1 mutant extract is active for splicing in vitro at or below 26 °C but inactive at 30 °C, whereas the wild-type extract is active at all the temperatures tested (data not shown). When splicing reactions with mutant extract and radiolabeled pre-mRNA are analyzed by native gel electrophoresis, however, the reactions incubated at 23 °C look similar to those at 30 °C in that most of the radiolabeled pre-mRNA is in the beta  band (Fig. 5A). However, a defect in complex formation due to inactivation of the mutant prp6 protein at 30 °C is detected by Northern blot analyses (Fig. 5B). A wild-type reaction incubated at 30 °C forms all three bands (delta , beta , and alpha ) with the U2, U4, U5, and U6 snRNAs accumulating in the alpha  band by 20 min. Again, a small amount of U1 snRNA may be present in the alpha  band. The U2, U5, and U6 snRNAs also accumulate in the beta  band at 20 min. In contrast, a splicing reaction with mutant prp6 extract incubated at 30 °C accumulates U1 and U2 but not U5 and U6 snRNAs in the beta  band. Furthermore, little or no U2, U4, U5, or U6 is present in the alpha  band at 20 min. Additionally, little or no tri-snRNP can be seen in the 30 °C reactions with mutant prp6 extract even in the absence of added pre-mRNA (Fig. 5B, lane 7, in U4, U5, and U6 panels), whereas this extract can form the tri-snRNP at 23 °C (data not shown). These results indicate that the reactions with the mutant prp6 extract at 30 °C form no tri-snRNP, alpha  band, or beta 2 complex. They do, however, accumulate the U1 and U2 snRNAs in the beta  band, consistent with the properties of the beta 1 complex. Additionally, the results show that beta 1 is formed before the alpha  and beta 2 complexes.

Inactivation of U6 snRNA by deoxyoligonucleotide-directed RNase H degradation has also been shown to prevent the U4, U5, and U6 snRNPs from forming the tri-snRNP and binding to the pre-spliceosome (37). I found that both control and U6-inactivated extracts form delta  and beta 1 complexes with beta 1 containing both U1 and U2 snRNAs. The alpha  and beta 2 complexes form only when U6 snRNA is intact (data not shown).

Given these data on the kinetics of formation, snRNA and pre-mRNA content, and formation of the pre-splicing complexes in inactivated extracts, I deduced the order of formation and composition of the delta , beta 1, and beta 2 complexes to be as follows; first delta  (with U1 snRNA), then beta 1 (with U1 and U2 snRNAs), and eventually beta 2 (with U2, U5, and U6 snRNAs). The identities of complexes in the alpha  band and their relationships to the other complexes were revealed in the experiments described below.

U1 snRNA in a Late Pre-splicing Complex

I next asked if U1 snRNA could be detected in any additional pre-splicing complexes. Two different approaches were used to increase the amounts of late-forming complexes.

In one approach, EDTA was added to the splicing reactions. Previously, Cheng and Abelson (29) added EDTA to splicing reactions to identify and distinguish in their native gel electrophoretic assay two complexes (A1 and A2-1) that form late in the assembly pathway. They showed that 5 mM EDTA in the yeast splicing reaction induces accumulation of A1 complex in particular and almost completely inhibits splicing. Complex A2-1 contains the U2, U4, U5, and U6 snRNAs and is most likely the precursor to complex A1, which contains the U2, U5, and U6 snRNAs. The A1 complex is the immediate precursor of the active spliceosome, designated A2-2 in the gel system of Cheng and Abelson (29). I assayed the effects of 5 mM EDTA on pre-splicing complex formation by my native gel electrophoretic assay and Northern blot hybridizations (Fig. 6).


Fig. 6. Northern blot analysis of spliceosome assembly in the absence or presence of added EDTA. Either 1 nM pre-mRNA of a very low specific activity or no pre-mRNA was added to initiate reactions in splicing extracts containing either no or 5 mM EDTA. Samples were removed at 0, 2, 20, and 40 min and fractionated by native gel electrophoresis. The RNAs in the gel were transferred to a membrane and hybridized sequentially with the U snRNA probes indicated. Complexes with U snRNAs were visualized by autoradiography. Only the beta 1, beta 1*, beta 2, alpha 1, and alpha 2 pre-splicing complexes are shown here. The complexes as detected in lanes 6-8 of the U2 panel are individually labeled in the lower right boxed inset for ease of reference. U1/U5* and U4/U5/U6* denote endogenous snRNP complexes.
[View Larger Version of this Image (73K GIF file)]

Six complexes are distinguishable in the reaction with 5 mM EDTA: delta , three beta  complexes (beta 1, and beta 1*, and beta 2), and two alpha  complexes (alpha 1 and alpha 2). Three complexes that hybridize with the U1 probe form within 2 min after addition of pre-mRNA, delta , beta 1, and beta 1*. The beta 1 complex is so designated in this reaction because it forms early, contains the U1 and U2 snRNAs, and migrates in the same position as the beta 1 complex in reactions with no EDTA. A novel beta 1* complex also contains U1 and U2 snRNAs and appears early but only in the presence of EDTA, and it migrates more slowly than beta 1. The alpha 2 complex, as most clearly seen with the U4 probe, contains U2, U4, U5, and U6 snRNAs like the A2-1 complex of Cheng and Abelson (29). Notably, a distinguishable, but small amount of U1 snRNA compared with the other snRNAs is also present in the alpha 2 complex. Finally, two complexes containing the U2, U5, and U6 snRNAs accumulate late in the splicing reaction. The most abundant of these two probably corresponds to the A1 complex of Cheng and Abelson (29) as it accumulates in the presence of 5 mM EDTA and contains the U2, U5, and U6 snRNAs, and hence, I have called it alpha 1. The second, more rapidly migrating and less abundant complex migrates the same as the beta 2 complex in the reaction without EDTA and is most likely the active spliceosome. Neither U1 or U4 snRNA is detected in the spliceosome. Consistent with the low levels of beta 2 in this reaction, splicing was greatly inhibited by 5 mM EDTA (data not shown). When compared for their kinetics of formation, snRNA content, and response to EDTA, the alpha 2 and alpha 1 complexes are analogous to the A2-1 and A1 complexes, respectively, of Cheng and Abelson (29). This comparison, as well as the snRNA composition of the complexes, suggests that the order of formation of the late pre-splicing complexes detected in this gel assay is beta 1 right-arrow alpha 2 right-arrow alpha 1 right-arrow beta 2.

An endogenous U1-U5 bi-snRNP complex can also be observed in the presence or absence of EDTA in the splicing reaction (Fig. 6). The presence of this complex varies among extract preparations.

Because the amount of delta  complex is dependent on magnesium ion in this gel assay, the addition of EDTA to the splicing reaction might destabilize U1 snRNP in the complexes. I therefore used a second approach to determine if U1 is in the alpha 1 complex. Previously Cheng and Abelson (29) showed that inactivation of a temperature-sensitive, mutant prp2 protein in vitro results in accumulation of the A1 complex. I found that inactivation of the prp2 protein caused the U2, U5, and U6 snRNAs, but not the U1 and U4 snRNAs to accumulate in the alpha  band, and prevented beta 2 complex formation (data not shown). These results again indicate that U1 snRNA is not in the alpha 1 complex. They also suggest that the alpha 2 complex is normally short lived as this complex, like the A2-1 complex (43), is not readily detected.

Functional Analysis of the delta  Complex

The delta  complex has several of the properties of the commitment complex (CC) (11, 44): 1) it contains U1 snRNA and 2) forms on pre-mRNA in the absence of ATP and the U2, U4, U5, and U6 snRNPs. CC was originally defined in yeast splicing extracts as a complex that is formed in the absence of ATP and, once formed, is stable in the presence of excess competitor pre-mRNA and can be chased into an active spliceosome in the presence of competitor and ATP (44). To test if the delta  complex is the functional equivalent of CC, I determined if the delta  complex could be chased into an active spliceosome in the presence of excess competitor pre-mRNA. Radiolabeled pre-mRNA was incubated in extract in the absence of ATP and an intact U2 snRNP (Fig. 7A, Step 1). After 10 min of incubation, a 25-fold molar excess of cold pre-mRNA was added (Fig. 7A, Step 2). One min later, additional extract and ATP were added and incubated for an additional 15 or 30 min (Fig. 7A, Step 3). Samples were removed at the various steps and assayed by native gel electrophoresis. When a 25-fold excess cold competitor pre-mRNA is added at Step 2, only a small fraction of the pre-mRNA in the delta  complex is subsequently chased into the other complexes during the incubation in Step 3 (Fig. 7B, lanes 6-8). That these complexes are formed from the Step 1 delta  complex is indicated by the datum that the 25-fold excess of cold competitor RNA is sufficient to block any pre-splicing complex formation if it is added in Step 1 before the radiolabeled pre-mRNA is added (lane 4). In contrast, the delta  complex formed in Step 1 is stable in the extract in the absence of ATP and competitor RNA during the Step 3 incubation (Fig. 7B, compare lanes 6-8 with lanes 1-2). When ATP and complete extract are subsequently added in Step 3, the pre-mRNA can efficiently form additional complexes (lane 3). Thus, like the commitment complexes described by Rosbash and coworkers (10, 11, 44), some of the pre-mRNA in the delta  complex is committed to the splicing pathway. Unlike the CC, however, a significant amount of pre-mRNA in the delta  complex cannot be chased into the spliceosome by this assay.

One possible explanation for the fraction of unchaseable pre-mRNA in the delta  complex is that some of the delta  complex is not stable in the presence of excess cold competitor pre-mRNA. I, therefore, assayed the stability of the delta  complex in the presence of competitor pre-mRNA. To measure the levels pre-mRNA in the delta  complex only, I used splicing extract in which the U2 snRNP had been inactivated by deoxyoligonucleotide-directed RNase H degradation. If the delta complex is formed first on the radiolabeled pre-mRNA, subsequent incubation with even an equal molar amount of cold pre-mRNA is sufficient to reduce the amount of radiolabeled pre-mRNA in the delta  complex, with increasing reductions occurring with increasing amounts of cold competitor pre-mRNA (Fig. 7C). In contrast, at least a 10-fold excess of cold competitor pre-mRNA is required to block formation of the delta  complex on radiolabeled pre-mRNA added after the cold competitor. Although this is the same extract used in the experiments in Fig. 7, B and C, I have found the same results with other extracts. Thus most of the radiolabeled pre-mRNA that cannot be chased into the spliceosome can be accounted for by being in a delta  complex that is unstable in the presence of the excess cold competitor.


DISCUSSION

Detection of U1 snRNA in Three Pre-splicing Complexes

Although it has been proposed that the U1 snRNP has several functions in spliceosome assembly and in splice site recognition and selection, most spliceosome assembly assays have failed to detect the U1 snRNP. Here I used a new native gel electrophoretic assay to detect the yeast U1 snRNA in three pre-splicing complexes (delta , beta 1, alpha 2) formed in an in vitro splicing reaction. I determined the most probable order of formation of the complexes to be delta right-arrow beta 1 right-arrow alpha 2 right-arrow alpha 1 right-arrow beta 2, where beta 2 is the active spliceosome. Unlike all previous electrophoretic gel assays, this new assay has detected the U1 snRNA together with other snRNAs in two complexes: 1) with U2 snRNA in the beta 1 complex and 2) with U2, U4, U5, and U6 snRNAs in the alpha 2 complex. Although U1 is in the alpha 2 complex, little of it is present compared with the other four snRNAs in the complex and to the levels of both U1 and U2 in beta 1. This reduction of U1 snRNA in alpha 2 precedes the complete loss of U1 and U4 that occurs subsequently in the transition from alpha 2 to alpha 1. Both alpha 1 and the active spliceosome as isolated by this gel electrophoretic assay contain the U2, U5, and U6 snRNAs.

As U1 snRNA is found in three pre-splicing complexes, the gel conditions used in this study most likely preserve several U1 interactions with other spliceosomal components. This gel assay will be useful for studying factors that affect these interactions during spliceosome assembly.

There Are Two Forms of delta  Complex, One of Which Is Committed to the Splicing Pathway

A small fraction of the delta  complex is probably the functional equivalent of the previously identified yeast commitment (11) and mammalian E (45) complexes. Like the CC and E complexes, the delta  complex is formed in the absence of ATP. It is the first splicing-specific complex formed in the presence of ATP (Fig. 2). Its formation depends on the 5' end of U1 snRNP but not on other snRNPs (Figs. 3 and 5). Also, the delta  complex (33) like CC (13, 46) forms in the absence of active Prp9 or Prp11 protein, each of which is required for pre-spliceosome assembly. Additionally, the effects of some mutations in both actin and RP51 pre-mRNAs on delta  complex formation2 are similar to those previously reported for CC formation (11) and for U1 snRNP binding to pre-mRNA (9), 5' splice site mutations reduce the total amount of delta  complex as well as inhibit formation of other pre-splicing complexes. Finally, some, but not all of the pre-mRNA in the delta  complex is refractory to excess competitor pre-mRNA and can be chased into succeeding assembly intermediates (Fig. 7).

A substantial fraction of delta  complex represents a new complex that contains U1 snRNP and pre-mRNA but is not committed to splicing (Fig. 7). The failure to chase most of the pre-mRNA in the delta  complex into subsequent steps in the splicing pathway is probably due to the instability of this fraction in the presence of excess competitor pre-mRNA (Fig. 7C). Thus, there are two forms of delta complex: 1) one scarce form, delta commit, which is stable to exogenous competitor pre-mRNA and can be chased into subsequent steps of the splicing pathway; and 2) another, abundant form, delta un ("un" for unstable and uncommitted), which apparently dissociates in the presence of competitor.

There are several possibilities to consider regarding the relationship between delta un and delta commit. The 5' pre-mRNA cap and the nuclear cap binding complex may be pertinent to this relationship because the cap and complex help to stabilize interactions between the U1 snRNP and pre-mRNA (47, 48). Furthermore, an uncapped pre-mRNA of the RP51 gene is not as efficiently chased as the capped form from the commitment complex to the spliceosome in vitro in the presence of competitor RNA (49). However, the uncapped actin pre-mRNA used here in this study is spliced with equal efficiency as the capped form in vitro (31, 50). Thus, delta un may be a precursor of the pre-spliceosome or a precursor to delta commit. Alternatively, delta un may not be involved in splicing. Finally, I cannot exclude the possibility that there are more than two complexes in the delta  band. Two forms of commitment complex formed on RP51 pre-mRNA migrate as two distinct bands, CC1 and CC2, in another gel assay system (11). Clearly, additional experiments are necessary to understand the parameters affecting the formation and stabilities of delta un and delta commit, the significance of these two complexes, and their relationship to each other and to the previously characterized commitment complexes, CC1 and CC2.

The Yeast Pre-spliceosome Identified as the beta 1 Complex Contains the U1 and U2 snRNPs

The yeast pre-spliceosome has been thought to contain the U1 as well as the U2 snRNP; however, previous gel electrophoretic assays have not found U1 snRNA in the B or III complex analogue of the pre-spliceosome (11, 27, 29). beta 1, the second complex formed during spliceosome formation in this study, contains both the U1 and U2 snRNAs and most probably represents the pre-spliceosome. Like the mammalian A and yeast B and III complexes, beta 1 arises early during an in vitro splicing reaction and requires ATP and the U1 and U2 snRNPs for its formation (Figs. 1, 2, 3, 4). It does not require a functional U4/U5/U6 tri-snRNP (Fig. 5). Furthermore, anti-Prp4 antibody that inhibits the U4/U5/U6 in yeast splicing extracts still allows formation of beta 1 (33) and B complexes (51). Finally, the Prp5, Prp9, and Prp11 proteins are necessary for beta 1 formation (33). The mammalian homologs of the Prp9 and Prp11 proteins are also required for pre-spliceosome formation in HeLa cell splicing extracts (52-54). Therefore, although I have not shown that pre-mRNA in the beta 1 complex can be chased into an active spliceosome, the kinetics and other properties of its formation strongly suggest that the beta 1 complex is the pre-spliceosome.

Recently, it has been proposed that disruption of base pairing between the U1 snRNA and 5' splice site of the pre-mRNA occurs after U1 snRNP binds to the pre-mRNA and before U2 snRNP binds during pre-spliceosome formation (25, 26). In support of this idea are the observations that less U1 than U2 snRNA is present in the mammalian pre-spliceosome (complex A) (20) and that U2 snRNP can bind to one mutant pre-mRNA without U1 snRNP and ATP in yeast splicing reactions (25). I have not observed any changes at this step of spliceosome assembly as evidence of this proposed alteration; in the absence of competitor pre-mRNA, the delta  complex is stable. Furthermore, there are only low levels of U1 snRNA in the delta  complex run in a gel without magnesium ion but higher levels of U1 snRNA in the pre-spliceosome (beta 1 complex) (Fig. 1). This suggests that the U1 and U2 snRNPs stabilize each other in the pre-spliceosome.

I have also detected a second complex, beta 1*, that, like beta 1, contains pre-mRNA, and the U1 and U2 snRNAs. beta 1* appears early in splicing reactions with added EDTA and does not accumulate at later times. As its mobility is different than the beta 1 complex formed in either the presence or absence of added EDTA, beta 1* is most likely a novel complex. beta 1* may be an assembly intermediate that, in the absence of added EDTA, co-migrates with beta 1 or is short-lived. If it is an intermediate, then its existence may mean that additional non-snRNP factors bind to the pre-spliceosome or the conformation of the pre-spliceosome changes in preparation for the binding of the U4/U5/U6 tri-snRNP. Alternatively, it may be an aberrant complex formed as a result of the EDTA.

The Association of the U1 snRNP with the Developing Spliceosome Changes during or Shortly after the U4/U5/U6 Tri-snRNP Binds to the Pre-spliceosome

In the native gel electrophoretic assay described here, little alpha  band is present in splicing reactions with radiolabeled actin pre-mRNA, and the alpha  band migrates close to the beta  complexes. The alpha  band becomes apparent when more pre-mRNA is used in the reaction and it is assayed by Northern blot analyses. This band may have two complexes: 1) the alpha 2 complex that contains U2, U4, U5, and U6 snRNAs as well as a small amount of U1 snRNA (Fig. 4-6); and 2) the alpha 1 complex that contains the U2, U5, and U6 snRNAs. Both of these complexes require a functional U4/U5/U6 tri-snRNP to form. Furthermore, splicing reactions blocked with anti-prp4 antibody that prevents the tri-snRNP from binding to pre-mRNA can only form the delta  and beta 1 complex (33). These two complexes are distinguished by their behavior in reactions with 5 mM EDTA (Fig. 6). In the presence of 5 mM EDTA, the alpha 1 complex migrates slightly faster than alpha 2 and slower than beta 2. They can also be differentiated under other experimental conditions. In the presence of low concentrations of added ATP, alpha 2 accumulates and little alpha 1 forms; and in heat-inactivated mutant prp2 extracts, mostly alpha 1 accumulates.2 Given the known order of snRNP binding to the pre-mRNA during spliceosome assembly (for reviews, see Refs. 1, 2, 7, and 55), the simplest interpretation of the data is that alpha 2 is formed from the pre-spliceosome and that alpha 1 is formed from alpha 2.

The comparison of alpha 2 and alpha 1 with the previously described A2-1 and A1 complexes (29, 38) is also consistent with this interpretation. A2-1 and alpha 2 are formed after the pre-spliceosome, contain the U2, U4, U5, and U6 snRNAs, and appear to be short lived but accumulate in the presence of low ATP. A1 and alpha 1 contain the U2, U5, and U6 snRNAS and accumulate in reactions with 5 mM EDTA or inactivated Prp2 protein. The similarities of the alpha 2 and alpha 1 complexes to the A2-1 and A1 complexes suggests that alpha 2 and alpha 1 are intermediates in the spliceosome assembly pathway. However, that they are intermediates and equivalent to the A2-1 and A1 complexes remains to be shown.

The presence of the U1 snRNP with the other snRNPs in the the alpha 2 complex is supported by recent evidence that U1 and U5 snRNPs associate with each other in a complex. Recently, Ast and Weiner induced the formation of a U1/U4/U5 complex in HeLa extracts (16) as well as found that the U1 and U5 snRNAs can be cross-linked in a splicing related complex (56). Here I have observed that the U1 and U5 snRNPs co-migrate in a complex in the absence of added pre-mRNA although the function, signficance, and origin of this complex has yet to be determined.

The amount of U1 snRNA is reduced relative to the other snRNAs in the alpha 2 complex. This reduction suggests that the U1 snRNP dissociates from the alpha 2 complex during gel electrophoresis or during spliceosome assembly about the time alpha 2 is formed. A decrease in the levels of U1 relative to U2 in the transition from the pre-spliceosome to complex B in HeLa extracts has also been observed (57). Because studies in HeLa cell extracts have detected some U1 snRNP in late assembly intermediates (20, 23, 30, 57) as well as the formation of a U1/U4/U5 snRNP complex (16), I favor the first explanation that the loss of U1 is due to its instability in the alpha 2 complex during gel electrophoresis. This instability may be due to a disruption of the base pairing between U1 snRNA and pre-mRNA or of the U1 snRNP interactions with other spliceosomal components that make this snRNP stable to electrophoresis in the pre-spliceosome.

Genetic experiments in yeast have predicted a loss of base pairing between the pre-mRNA and U1 snRNA and the formation of base pairs between the 5' splice site and the U5 and U6 snRNAs sometime in the splicing pathway (for reviews, see Refs. 3 and 5). Subsequently, in vitro assays revealed that U5 and U6 snRNAs can be cross-linked to the 5' splice site region in a spliceosome formed in either yeast or HeLa cell extracts (for review, see Ref. 6) Furthermore, the U1 and U5 interact with the 5' splice site region during spliceosome assembly, whereas U5 and U6 associate with this region during splicing catalysis. These data support the notion that the U1 snRNP is "handing off" the 5' splice site region to U5 and U6 snRNPs. The low level of U1 snRNA in the alpha 2 complex that I observe suggests that the handoff occurs when the U4/U5/U6 tri-snRNP binds the pre-spliceosome or shortly thereafter.

A Model for Spliceosome Assembly

A working model of yeast spliceosome assembly showing the U1 snRNP in several pre-splicing complexes is shown in Fig. 8. Although numerous non-snRNP proteins are required at several steps in the assembly pathway (for reviews, see Refs. 1, 55, 58, and 59), these are not included here.


Fig. 8. A working model of spliceosome assembly.
[View Larger Version of this Image (14K GIF file)]

The U1 snRNP binds to the pre-mRNA in the absence of ATP to form the delta  complex. The folding of the pre-mRNA designates the dependence of U1 snRNP binding to the pre-mRNA on both the 5' splice site and branch point regions of the pre-mRNA (9, 14). Some of this complex delta commit is committed to subsequent steps in the splicing pathway. The uncommitted complex, delta un, may be a precursor of either delta commit or the pre-spliceosome, or not in the pathway.

The U2 snRNP binds to delta commit in a reaction requiring ATP, and the pre-spliceosome with the U1 and U2 snRNPs is formed. The U4/U5/U6 tri-snRNP binds to the pre-spliceosome, and the alpha 2 complex with all five snRNPs is created. The relative positions of the snRNPs are arbitrarily drawn. During this time or shortly thereafter, the association of the U1 snRNP with the developing spliceosome changes, depicted as a change in shading and positioning of the U1 snRNP. In the transition from the alpha 2 to the alpha 1 complex, the association of U1 and U4 with the complex becomes tenuous as these snRNPs are not detected in the alpha 1 complex. These two snRNPs may dissociate from the complex during assembly or electrophoresis. Finally, the active spliceosome containing the U2, U5, and U6 snRNAs is formed in the transition from the alpha 1 to the beta 2 complex.


FOOTNOTES

*   This work was supported by National Science Foundation Grant MCB9104862 and by the Dedicated Health Research Funds of the University of New Mexico School of Medicine.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
Dagger    To whom correspondence should be addressed: Dept. of Cell Biology, UNM Health Sciences Center, Cancer Research and Treatment Center, 900 Camino de Salud, N. E., Albuquerque, NM 87131. Tel.: 505-272-5830; Fax: 505-272-8199; E-mail: sruby{at}medusa.unm.edu.
1   The abbreviations used are: snRNP, small nuclear ribonucleoprotein; PEG, polyethylene glycol; snRNA, small nuclear RNA; bp, base pair(s); CC, commitment complex.
2   S. Ruby, unpublished data.

ACKNOWLEDGEMENTS

I thank J. Banroques, P. Fabrizio, L. Krinke, R-J. Lin, D. McPheeters, M. Robinson, U. Vijayraghavan, and T. Wilkie for antibodies, plasmids, prp2 splicing extracts, and carrier RNA samples. I thank M. Ares, J. Staley, J. Summers, and J. Warner for comments on the manuscript. I thank J. Abelson for support during the initial development of the native gel assay and J. Sampson for suggestions.


REFERENCES

  1. Guthrie, C. (1991) Science 253, 157-163 [Medline] [Order article via Infotrieve]
  2. Moore, M. J., Query, C. C., and Sharp, P. A. (1993) in The RNA World (Gesteland, R. F., and Atkins, J. F., eds), pp. 303-358, Cold Spring Harbor Laboratory, Cold Spring Harbor, NY
  3. Newman, A. J. (1994) Curr. Opin. Genet. & Dev. 4, 298-304 [Medline] [Order article via Infotrieve]
  4. Madhani, H. D., and Guthrie, C. (1994) Annu. Rev. Genet. 28, 1-26 [CrossRef][Medline] [Order article via Infotrieve]
  5. Newman, A. (1994) Curr. Biol. 4, 462-464 [Medline] [Order article via Infotrieve]
  6. Ares, M., and Weiser, B. (1995) Prog. Nucleic Acid Res. Mol. Biol. 50, 131-159 [Medline] [Order article via Infotrieve]
  7. Kramer, A. (1996) Annu. Rev. Biochem. 65, 367-409 [CrossRef][Medline] [Order article via Infotrieve]
  8. Siliciano, P. G., and Guthrie, C. (1988) Genes & Dev. 2, 1258-1267 [Abstract]
  9. Ruby, S. W., and Abelson, J. (1988) Science 242, 1028-1035 [Medline] [Order article via Infotrieve]
  10. Seraphin, B., and Rosbash, M. (1988) EMBO J. 7, 2533-2538 [Abstract]
  11. Seraphin, B., and Rosbash, M. (1989) Cell 59, 349-358 [Medline] [Order article via Infotrieve]
  12. Wu, J. Y., and Maniatis, T. (1993) Cell 75, 1061-1070 [Medline] [Order article via Infotrieve]
  13. Abovich, N., Liao, X. C., and Rosbash, M. (1994) Genes & Dev. 8, 843-854 [Abstract]
  14. Rosbash, M., and Seraphin, B. (1991) Trends Biochem. Sci. 16, 187-190 [CrossRef][Medline] [Order article via Infotrieve]
  15. Daugeron, M.-C., Tazi, J., Jeanteur, P., Brunel, C., and Cathala, G. (1992) Nucleic Acids Res. 20, 3625-3630 [Abstract]
  16. Ast, G., and Weiner, A. M. (1996) Science 272, 881-884 [Abstract]
  17. Yean, S.-L., and Lin, R.-J. (1996) Gene Expr. 5, 301-313 [Medline] [Order article via Infotrieve]
  18. Konarska, M. M., and Sharp, P. A. (1986) Cell 46, 845-855 [Medline] [Order article via Infotrieve]
  19. Reed, R. (1990) Proc. Natl. Acad. Sci. U. S. A. 87, 8031-8035 [Abstract]
  20. Bennett, M., Michaud, S., Kingston, J., and Reed, R. (1992) Genes & Dev. 6, 1986-2000 [Abstract]
  21. Jamison, S. F., Crow, A., and Garcia-Blanco, M. A. (1992) Mol. Cell. Biol. 12, 4279-4287 [Abstract]
  22. Furman, E., and Glitz, D. G. (1995) J. Biol. Chem. 270, 15515-15522 [Abstract/Free Full Text]
  23. Bindereif, A., and Green, M. R. (1987) EMBO J. 6, 2415-2424 [Abstract]
  24. Konforti, B. B., Koziolkiewicz, M. J., and Konarska, M. M. (1993) Cell 75, 863-873 [Medline] [Order article via Infotrieve]
  25. Liao, X. C., Colot, H. V., Wang, Y., and Rosbash, M. (1992) Nucleic Acids Res. 20, 4237-4245 [Abstract]
  26. Champion-Arnaud, P., Gonzani, O., Palandjian, L., and Reed, R. (1995) Mol. Cell. Biol. 15, 5750-5756 [Abstract]
  27. Pikielny, C. W., Rymond, B. C., and Rosbash, M. (1986) Nature 324, 341-345 [Medline] [Order article via Infotrieve]
  28. Pikielny, C. W., and Rosbash, M. (1986) Cell 45, 869-877 [Medline] [Order article via Infotrieve]
  29. Cheng, S.-C., and Abelson, J. (1987) Genes & Dev. 1, 1014-1027 [Abstract]
  30. Zillmann, M., Zapp, M. L., and Berget, S. M. (1988) Mol. Cell. Biol. 8, 814-821 [Medline] [Order article via Infotrieve]
  31. Lin, R. J., Newman, A. J., Cheng, S.-C., and Abelson, J. (1985) J. Biol. Chem. 260, 14780-14792 [Abstract/Free Full Text]
  32. Auffray, C., and Rougeon, F. (1980) Eur. J. Biochem. 107, 303-324 [Abstract]
  33. Ruby, S. W., Chang, T. H., and Abelson, J. (1993) Genes & Dev. 7, 1909-1925 [Abstract]
  34. Church, G. M., and Gilbert, W. (1984) Proc. Natl. Acad. Sci. U. S. A. 81, 1991-1995 [Abstract]
  35. Sambrook, J., Fritsch, E. F., and Maniatis, T. (1989) Molecular Cloning: A laboratory Manual, 2nd Ed., Cold Spring Harbor Laboratory, Cold Spring Harbor, NY
  36. Feinberg, A. P., and Vogelstein, B. (1983) Anal. Biochem. 132, 6-13 [Medline] [Order article via Infotrieve]
  37. Fabrizio, P., McPheeters, D. S., and Abelson, J. (1989) Genes & Dev. 3, 2137-2150 [Abstract]
  38. Tarn, W., Lee, K., and Cheng, S. (1993) Proc. Natl. Acad. Sci. U. S. A. 90, 10821-10825 [Abstract]
  39. Horowitz, D., and Abelson, J. (1993) Genes & Dev. 7, 320-329 [Abstract]
  40. Kretzner, L., Rymond, B. C., and Rosbash, M. (1987) Cell 50, 593-602 [Medline] [Order article via Infotrieve]
  41. Shuster, E. O., and Guthrie, C. (1988) Cell 55, 41-48 [Medline] [Order article via Infotrieve]
  42. Galisson, F., and Legrain, P. (1993) Nucleic Acids Res. 21, 1555-1562 [Abstract]
  43. Wiest, D. K., O'Day, C. L., and Abelson, J. (1996) J. Biol. Chem. 271, 33268-33276 [Abstract/Free Full Text]
  44. Legrain, P., Seraphin, B., and Rosbash, M. (1988) Mol. Cell. Biol. 8, 3755-3760 [Medline] [Order article via Infotrieve]
  45. Michaud, S., and Reed, R. (1991) Genes & Dev. 5, 2534-2546 [Abstract]
  46. Abovich, N., Legrain, P., and Rosbash, M. (1990) Mol. Cell. Biol. 10, 6417-6425 [Medline] [Order article via Infotrieve]
  47. Lewis, J. D., Izaurralde, E., Jarmolowski, A., Mcguigan, C., and Mattaj, I. W. (1996) Genes & Dev. 10, 1683-1698 [Abstract]
  48. Lewis, J., Gorlich, D., and Mattaj, I. W. (1996) Nucleic Acids Res. 24, 3332-3336 [Abstract/Free Full Text]
  49. Colot, H. V., Stutz, F., and Rosbash, M. (1996) Genes & Dev. 10, 1699-1708 [Abstract]
  50. Schwer, B., and Schuman, S. (1996) RNA 2, 574-583 [Abstract]
  51. Banroques, J., and Abelson, J. N. (1989) Mol. Cell. Biol. 9, 3710-3719 [Medline] [Order article via Infotrieve]
  52. Brosi, R., Groning, K., Behrens, S.-E., Luhrmann, R., and Kramer, A. (1993) Science 262, 102-105 [Medline] [Order article via Infotrieve]
  53. Bennett, M., and Reed, R. (1993) Science 262, 105-108 [Medline] [Order article via Infotrieve]
  54. Behrens, S., Galisson, F., Legrain, P., and Luhrmann, R. (1993) Proc. Natl. Acad. Sci. U. S. A. 90, 8229-8233 [Abstract/Free Full Text]
  55. Ruby, S. W., and Abelson, J. (1991) Trends Genet. 7, 79-85 [Medline] [Order article via Infotrieve]
  56. Ast, G., and Weiner, A. (1997) RNA 3, 371-381 [Abstract]
  57. Michaud, S., and Reed, R. (1993) Genes & Dev. 7, 1008-1020 [Abstract]
  58. Rymond, B. C., and Rosbash, M. (1992) in The Molecular and Cellular Biology of the Yeast Saccharomyces (Jones, E. W., Pringle, J. R., and Broach, J. R., eds), Vol. 2, pp. 143-192, Cold Spring Harbor Laboratory, Cold Spring Harbor, NY
  59. Hodges, P. E., and Beggs, J. D. (1994) Curr. Biol. 4, 264-267 [Medline] [Order article via Infotrieve]

©1997 by The American Society for Biochemistry and Molecular Biology, Inc.