Group II Introns: Structure and Catalytic Versatility of Large Natural Ribozymes

Lehmann, Karola; Schmidt, Udo

doi:10.1080/713609236

Cited by 153 publications

(138 citation statements)

References 303 publications

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“…The first step of splicing in this reaction apparently proceeds through hydrolysis rather than branching; however, catalysis of the first step of splicing through hydrolysis is widely observed in group II introns as a physiological alternative to branching both in vitro and in vivo (29,30). Indeed, under the conditions used in our catalytic assays, hydrolysis is the dominant or even the sole reaction pathway for a number of well-studied introns that can efficiently perform branching in the presence of higher salt concentrations (1,2). Recently, it has been shown that the spliceosomal active site can also catalyze hydrolytic reactions at splice sites by cleavage of the 2nd exon from lariat intermediates or spliced mRNAs (31).…”

Section: Discussionmentioning

confidence: 99%

Protein-free small nuclear RNAs catalyze a two-step splicing reaction

Valadkhan

Mohammadi

Jaladat

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

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Pre-mRNA splicing is a crucial step in eukaryotic gene expression and is carried out by a highly complex ribonucleoprotein assembly, the spliceosome. Many fundamental aspects of spliceosomal function, including the identity of catalytic domains, remain unknown. We show that a base-paired complex of U6 and U2 small nuclear RNAs, in the absence of the Ϸ200 other spliceosomal components, performs a two-step reaction with two short RNA oligonucleotides as substrates that results in the formation of a linear RNA product containing portions of both oligonucleotides. This reaction, which is chemically identical to splicing, is dependent on and occurs in proximity of sequences known to be critical for splicing in vivo. These results prove that the complex formed by U6 and U2 RNAs is a ribozyme and can potentially carry out RNA-based catalysis in the spliceosome.catalysis ͉ ribozymes ͉ snRNAs ͉ spliceosome ͉ U6 E xtensive mechanistic and structural similarities between spliceosomal small nuclear RNAs (snRNAs) and self-splicing group II introns (1, 2) have led to the hypothesis that the snRNAs are evolutionary descendents of group II-like introns and thus could similarly have a catalytic role in the spliceosome (3-5). However, because of the extreme complexity of the spliceosome (6-9), a dynamic cellular machine composed of more than 200 different proteins in addition to the snRNAs (U1, U2, U4, U5, and U6), it has not been possible to determine whether the snRNAs can indeed catalyze the splicing reaction without the help of spliceosomal proteins.In activated spliceosomes, U6 and U2, which are the only snRNAs required for both steps of splicing, form an extensively base-paired complex (7, 10, 11) (Fig. 1A). Considerable data support the functional importance of both the secondary and tertiary structure of the U6/U2 complex (10-13). Furthermore, an evolutionarily invariant region in U6, the ACAGAGA box ( Fig. 1 A), is in close proximity to the splice sites during splicing catalysis (14-18), and mutagenesis studies have shown that this domain plays a crucial role in catalysis of the splicing reaction (7,10,11). Two other conserved regions, the AGC triad and an asymmetric bulge in the intramolecular stemloop of U6 (ISL), are also thought to play important roles in spliceosomal catalysis (11). Recent structural studies indicate that sequences equivalent to these three regions form the active site of group II introns (19). In both systems, the ACAGAGA sequence and its equivalent in group II introns seem to be positioned in close proximity to a conserved asymmetric loop in the middle of the ISL or domain V, the corresponding stemloop in group II introns (19,20).Previously we provided evidence that in vitro-transcribed, protein-free RNAs containing the conserved central domains of human U6 and U2 could form a base-paired complex in vitro that was similar to the complex formed in activated spliceosomes (13) (Fig. 1 A). In addition, this in vitro-assembled, protein-free U6/U2 complex could catalyze a number of branching-like react...

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Section: Discussionmentioning

confidence: 99%

Protein-free small nuclear RNAs catalyze a two-step splicing reaction

Valadkhan

Mohammadi

Jaladat

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

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“…[1] Some group II introns also encode for a maturase protein, enabling these RNAs to act as mobile genetic elements. [1] Although their direct occurrence is nowadays confined to a limited range of organisms, these catalytic RNAs may have played an important role in evolution. Taking into account related nuclear introns and transposable LINE elements, as much as one third of the human DNA may have evolved from ancestral group II introns.…”

Section: Introductionmentioning

confidence: 99%

“…[2] In addition, based on reaction pathway and sequence similarity, a common ancestry with the eukaryotic spliceosomal machinery has been proposed. [1] The spliceosome is a multicomponent RNA-protein complex that occurs in higher eukaryotes and consists of five highly structured snRNAs (U1, U2, U4, U5 and U6) and numerous proteins, the latter ones presumably having structural roles. [3,4] Here, splicing occurs through the assembly of the snRNAs at pre-mRNA splice sites thereby exhibiting a mechanism that is very similar to the one found for group II introns.…”

Section: Introductionmentioning

confidence: 99%

Solution Structure of Domain 6 from a Self‐Splicing Group II Intron Ribozyme: A Mg²⁺ Binding Site is Located Close to the Stacked Branch Adenosine

et al. 2007

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Group II intron self-splicing is essential for correct expression of organellar genes in plants, fungi, and yeast, as well as of bacterial genes. Self-excision of these autocatalytic introns from the primary RNA transcript is achieved in a two-step mechanism apparently analogous to the one of the eukaryotic spliceosome. The 2'-OH of a conserved adenosine (the branch point) located within domain 6 (D6) acts as the nucleophile in the first step of splicing. Despite the biological importance of group II introns, little is known about their structural organization and usage of metal ions in catalysis. Here we report the first solution structure of a catalytically active D6 construct encompassing the branch point and the neighboring helical regions from the mitochondrial yeast intron ai5 . The branch adenosine is the single unpaired nucleotide, and, in contrast to the spliceosomal branch site, resides within the helix being partially stacked between the two flanking GU wobble pairs. We identified a novel prominent Mg2+ binding site in the major groove of the branch site. Importantly, Mg2+ addition does not impair stacking of the branch-adenosine, but in contrast rather strengthens the interaction with the flanking uridines, as shown by NMR-and fluorescence studies. This means, that domain 6 presents the branch adenosine in a stacked fashion to the core of group II introns upon folding to the active conformation.

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“…the 2'-OH of a conserved adenosine, of these selfsplicing ribozymes, which exhibit a pathway strongly resembling the one of the 3 spliceosomal machinery. [18][19][20] Like all large ribozymes investigated to date, group II introns are obligate metalloribozymes that require Mg 2+ for folding and catalysis. [21][22][23][24][25][26][27] A recent crystal structure of a group IIC intron from Oceanobacillus iheyensis depicts the global architecture although domain 6 is disordered in the crystal.…”

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confidence: 99%

Metal ion-N7 coordination in a ribozyme branch domain by NMR

Erat¹,

Kovacs²,

Sigel³

2010

Journal of Inorganic Biochemistry

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The N7 of purine nucleotides presents one of the most dominant metal ion binding sites in nucleic acids. However, the interactions between kinetically labile metal ions like Mg2+ and these nitrogen atoms are inherently difficult to observe in large RNAs. Rather than using the insensitive direct N-15 detection, here we have used (2)J-H-1,N-15]-HSQC (Heteronuclear Single Quantum Coherence) NMR experiments as a fast and efficient method to specifically observe and characterize such interactions within larger RNA constructs. Using the 27 nucleotides long branch domain of the yeast-mitochondrial group II intron ribozyme Sc.ai5 gamma as an example, we show that direct N7 coordination of a Mg2+ ion takes place in a tetraloop nucleotide. A second Mg2+ ion, located in the major groove at the catalytic branch site, coordinates mainly in an outer-sphere fashion to the highly conserved flanking GU wobble pairs but not to N7 of the sandwiched branch adenosine. (C)

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Group II Introns: Structure and Catalytic Versatility of Large Natural Ribozymes

Cited by 153 publications

References 303 publications

Protein-free small nuclear RNAs catalyze a two-step splicing reaction

Protein-free small nuclear RNAs catalyze a two-step splicing reaction

Solution Structure of Domain 6 from a Self‐Splicing Group II Intron Ribozyme: A Mg²⁺ Binding Site is Located Close to the Stacked Branch Adenosine

Metal ion-N7 coordination in a ribozyme branch domain by NMR

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Group II Introns: Structure and Catalytic Versatility of Large Natural Ribozymes

Cited by 153 publications

References 303 publications

Protein-free small nuclear RNAs catalyze a two-step splicing reaction

Protein-free small nuclear RNAs catalyze a two-step splicing reaction

Solution Structure of Domain 6 from a Self‐Splicing Group II Intron Ribozyme: A Mg2+ Binding Site is Located Close to the Stacked Branch Adenosine

Metal ion-N7 coordination in a ribozyme branch domain by NMR

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Solution Structure of Domain 6 from a Self‐Splicing Group II Intron Ribozyme: A Mg²⁺ Binding Site is Located Close to the Stacked Branch Adenosine