Functionally distinct nucleic acid binding sites for a group I intron encoded RNA maturase/DNA homing endonuclease

A large number of group I introns encode a family of homologous proteins that either promote intron splicing (maturases) or are site-specific DNA endonucleases that function in intron mobility (a process called "homing"). Genetic studies have shown that some of these proteins have both activities, yet how a single protein carries out both functions remains obscure. The similarity between respective DNA-binding sites and the RNA structure near the 5' and 3' splice sites has fueled speculation that such proteins may use analogous interactions to perform both functions. The Aspergillus nidulans mitochondrial COB group I intron encodes a bi-functional protein, I-AniI, that has both RNA maturase and site-specific DNA endonuclease activities in vitro. Here, we show that I-AniI shows distinctive features of the endonuclease family to which it belongs, including highly specific, tight binding and sequential DNA strand cleavage. Competition experiments demonstrate that I-AniI binds the COB intron RNA even in saturating concentrations of its DNA target site substrate, suggesting that the protein has a separate binding site for RNA. In addition, we provide evidence that two different DNA-binding site mutants of I-AniI have little effect on the protein's RNA maturation activity. Since RNA splicing is likely a secondary adaptation of the protein, these observations support a model in which homing endonucleases may have developed maturase function by utilizing a hitherto "non-functional" protein surface.     

A C-terminal fragment of an intron-encoded maturase is sufficient for promoting group I intron splicing

Group I introns often encode proteins that catalyze site-specific DNA hydrolysis. Some of these proteins have acquired the ability to promote splicing of their cognate intron, but whether these two activities reside in different regions of the protein remains obscure. A crystal structure of I-AniI, a dual function intron-encoded protein, has shown that the protein has two pseudo-symmetric domains of equal size. Each domain contacts its DNA substrate on either side of two cleavage sites. As a first step to identify the RNA binding surface, the N- and C-terminal domains of I-AniI were separately expressed and tested for promoting the splicing of the mitochondrial (mt) COB pre-RNA. The N-terminal protein showed no splicing activation or RNA binding, suggesting that this domain plays a minimal role in activity or is improperly folded. Remarkably, the 16-kDa C-terminal half facilitates intron splicing with a rate similar to that of the full-length protein. Both the C-terminal fragment and full-length proteins bind tightly to the COB intron. RNase footprinting shows that the C-terminal and full-length proteins bind to the same regions and induce the same conformational changes in the COB intron. Together, these results show that the C-terminal fragment of I-AniI is necessary and sufficient for maturase activity and suggests that I-AniI acquired splicing function by utilizing a relatively small protein surface that likely represents a novel RNA binding motif. This fragment of I-AniI represents the smallest group I intron splicing cofactor described to date.     

A comprehensive characterization of a group IB intron and its encoded maturase reveals that protein-assisted splicing requires an almost intact intron RNA

The group I intron (AnCOB) of the mitochondrial apocytochrome b gene from Aspergillus nidulans encodes a bi-functional maturase protein that is also a DNA endonuclease. Although the AnCOB intron self-splices, the encoded maturase protein greatly facilitates splicing, in part, by stabilizing RNA tertiary structure. To determine their role in self-splicing and in protein-assisted splicing, several peripheral RNA sub-domains in the 313 nucleotide intron were deleted (P2, P9, P9.1) or truncated (P5ab, P6a). The sequence in two helices (P2 and P9) was also inverted. Except for P9, the deleted regions are not highly conserved among group I introns and are often dispensable for catalytic activity. Nevertheless, despite the very tight binding of AnCOB RNA to the maturase and the high activity of the bimolecular complex (the rate of 5' splice-site cleavage was >20 min(-1) with guanosine as the cofactor), the intron was surprisingly sensitive to these modifications. Several mutations inactivated splicing completely and virtually all impaired splicing to varying degrees. Mutants containing comparatively small deletions in various regions of the intron significantly decreased binding affinity (generally >10(4)-fold), indicating that none of the domains that remained constitutes the primary recognition site of the maturase. The data argue that tight binding requires tertiary interactions that can be maintained by only a relatively intact intron RNA, and that the binding mechanism of the maturase differs from those of two other well-characterized group I intron splicing factors, CYT-18 and Cpb2. A model is proposed in which the protein promotes widespread cooperative folding of an RNA lacking extensive initial tertiary structure.     

Optimization of in vivo activity of a bifunctional homing endonuclease and maturase reverses evolutionary degradation

The LAGLIDADG homing endonuclease (LHE) I-AniI has adopted an extremely efficient secondary RNA splicing activity that is beneficial to its host, balanced against inefficient DNA cleavage. A selection experiment identified point mutations in the enzyme that act synergistically to improve endonuclease activity. The amino-acid substitutions increase target affinity, alter the thermal cleavage profile and significantly increase targeted recombination in transfected cells. The RNA splicing activity is not affected by these mutations. The improvement in DNA cleavage activity is largely focused on one of the enzyme's two active sites, corresponding to a rearrangement of a lysine residue hypothesized to act as a general base. Most of the constructs isolated in the screen contain one or more mutations that revert an amino-acid identity to a residue found in one or more close homologues of I-AniI. This implies that mutations that have previously reduced the endonuclease activity of I-AniI are identified and reversed, sometimes in combination with additional ‘artificial’ mutations, to optimize its in vivo activity.     

A novel mechanism for protein-assisted group I intron splicing

Previously it was shown that the Aspergillus nidulans (A.n.) mitochondrial COB intron maturase, I-AniI, facilitates splicing of the COB intron in vitro. In this study, we apply kinetic analysis of binding and splicing along with RNA deletion analysis to gain insight into the mechanism of I-AniI facilitated splicing. Our results are consistent with I-AniI and A.n. COB pre-RNA forming a specific but labile encounter complex that is resolved into the native, splicing-competent complex. Significantly, kinetic analysis of splicing shows that the resolution step is rate limiting for splicing. RNA deletion studies show that I-AniI requires most of the A.n. COB intron for binding suggesting that the integrity of the I-AniI-binding site depends on overall RNA tertiary structure. These results, taken together with the observation that A.n. COB intron lacks significant stable tertiary structure in the absence of protein, support a model in which I-AniI preassociates with an unfolded COB intron via a "labile" interaction that facilitates correct folding of the intron catalytic core, perhaps by resolving misfolded RNAs or narrowing the number of conformations sampled by the intron during its search for native structure. The active intron conformation is then "locked in" by specific binding of I-Anil to its intron interaction site.     

Evolution from DNA to RNA recognition by the bI3 LAGLIDADG maturase

LAGLIDADG endonucleases bind across adjacent major grooves via a saddle-shaped surface and catalyze DNA cleavage. Some LAGLIDADG proteins, called maturases, facilitate splicing by group I introns, raising the issue of how a DNA-binding protein and an RNA have evolved to function together. In this report, crystallographic analysis shows that the global architecture of the bI3 maturase is unchanged from its DNA-binding homologs; in contrast, the endonuclease active site, dispensable for splicing facilitation, is efficiently compromised by a lysine residue replacing essential catalytic groups. Biochemical experiments show that the maturase binds a peripheral RNA domain 50 A from the splicing active site, exemplifying long-distance structural communication in a ribonucleoprotein complex. The bI3 maturase nucleic acid recognition saddle interacts at the RNA minor groove; thus, evolution from DNA to RNA function has been mediated by a switch from major to minor groove interaction.     

Connections between RNA splicing and DNA intron mobility in yeast mitochondria: RNA maturase and DNA endonuclease switching experiments.

The intron-encoded proteins bI4 RNA maturase and aI4 DNA endonuclease can be faithfully expressed in yeast cytoplasm from engineered forms of their mitochondrial coding sequences. In this work we studied the relationships between these two activities associated with two homologous intron-encoded proteins: the bI4 RNA maturase encoded in the fourth intron of the cytochrome b gene and the aI4 DNA endonuclease (I-SceII) encoded in the fourth intron of the gene coding for the subunit I of cytochrome oxidase. Taking advantage of both the high recombinogenic properties of yeast and the similarities between the two genes, we constructed in vivo a family of hybrid genes carrying parts of both RNA maturase and DNA endonuclease coding sequences. The presence of a sequence coding for a mitochondrial targeting peptide upstream from these hybrid genes allowed us to study the properties of their translation products within the mitochondria in vivo. We thus could analyze the ability of the recombinant proteins to complement RNA maturase deficiencies in different strains. Many combinations of the two parental intronic sequences were found in the recombinants. Their structural and functional analysis revealed the following features. (i) The N-terminal half of the bI4 RNA maturase could be replaced in total by its equivalent from the aI4 DNA endonuclease without affecting the RNA maturase activity. In contrast, replacing the C-terminal half of the bI4 RNA maturase with its equivalent from the aI4 DNA endonuclease led to a very weak RNA maturase activity, indicating that this region is more differentiated and linked to the maturase activity. (ii) None of the hybrid proteins carrying an RNA maturase activity kept the DNA endonuclease activity, suggesting that the latter requires the integrity of the aI4 protein. These observations are interesting because the aI4 DNA endonuclease is known to promote the propagation, at the DNA level, of the aI4 intron, whereas the bI4 RNA maturase, which is required for the splicing of its coding intron, also controls the splicing process of the aI4 intron. We propose a scenario for the evolution of these intronic proteins that relies on a switch from DNA endonuclease to RNA maturase activity.     

A latent intron-encoded maturase is also an endonuclease needed for intron mobility

Some yeast mitochondrial introns encode proteins that promote either splicing (maturases) or intron propagation via gene conversion (the fit1 endonuclease). We surveyed introns in the coxl gene for their ability to engage in gene conversion and found that the group I intron, al4 alpha, was efficiently transmitted to genes lacking it. An endonucleolytic cleavage is detectable in recipient DNA molecules near the site of intron insertion in vivo and in vitro. Conversion is dependent on an intact al4 alpha open reading frame. This intron product is a latent maturase, but these data show that it is also a potent endonuclease involved in recombination. Dual function proteins that cleave DNA and facilitate RNA splicing may have played a pivotal role in the propagation and tolerance of introns.     

Maturase and endonuclease functions depend on separate conserved domains of the bifunctional protein encoded by the group I intron aI4 alpha of yeast mitochondrial DNA.

Intron 4 alpha (aI4 alpha) of the yeast mitochondrial COXI gene is a mobile group I intron that contains a reading frame encoding both the homing endonuclease I-SceII and a latent maturase capable of splicing both aI4 alpha and the fourth intron of the cytochrome b (COB) gene (bI4). The aI4 alpha reading frame is a member of a large gene family recognized by the presence of related dodecapeptide sequence motifs called P1 and P2. In this study, missense mutations of P1 and P2 were placed in mitochondrial DNA by biolistic transformation. The effects of the mutations on intron mobility, endonuclease I-SceII activity and maturase function were tested. The mutations of P1 strongly affected mobility and endonuclease I-SceII activity, but had little or no effect on maturase function; mutations of P2 affected splicing but not mobility or endonuclease I-SceII activity. Surprisingly, the conditional (temperature-sensitive) mutations at P1 and P2 block one or the other function of the protein but not both. This study indicates that the two functions depend on separate domains of the intron-encoded protein.     

Replacement of two non-adjacent amino acids in the S.cerevisiae bi2 intron-encoded RNA maturase is sufficient to gain a homing-endonuclease activity.

Two homologous group I introns, the second intron of the cyt b gene, from related Saccharomyces species differ in their mobility. The S.capensis intron is mobile and encodes the I-ScaI endonuclease promoting intron homing, whilst the homologous S.cerevisiae intron is not mobile, but functions as an RNA maturase promoting splicing. These two intron-encoded proteins differ by only four amino acid substitutions. Taking advantage of the remarkable similarity of the two intron open reading frames and using biolistic transformation of mitochondria, we show that the replacement of only two non-adjacent residues in the S.cerevisiae maturase carboxy-terminal sequence is sufficient to induce a homing-endonuclease activity without losing the splicing function. Also, we demonstrate that these two activities reside in the S.capensis bi2-encoded protein which functions in both splicing and intron mobility in the wild-type cells. These results provide new insight into our understanding of the activity and the evolution of group I intron-encoded proteins.     

Coevolution of a homing endonuclease and its host target sequence

We have determined the specificity profile of the homing endonuclease I-AniI and compared it to the conservation of its host gene. Homing endonucleases are encoded within intervening sequences such as group I introns. They initiate the transfer of such elements by cleaving cognate alleles lacking the intron, leading to their transfer via homologous recombination. Each structural homing endonuclease family has arrived at an appropriate balance of specificity and fidelity that avoids toxicity while maximizing target recognition and invasiveness. I-AniI recognizes a strongly conserved target sequence in a host gene encoding apocytochrome B and has fine-tuned its specificity to correlate with wobble versus nonwobble positions across that sequence and to the amount of degeneracy inherent in individual codons. The physiological target site in the host gene is not the optimal substrate for recognition and cleavage: at least one target variant identified during a screen is bound more tightly and cleaved more rapidly. This is a result of the periodic cycle of intron homing, which at any time can present nonoptimal combinations of endonuclease specificity and insertion site sequences in a biological host.