Homing endonuclease structure and function

Homing endonucleases are encoded by open reading frames that are embedded within group I, group II and archael introns, as well as inteins (intervening sequences that are spliced and excised post-translationally). These enzymes initiate transfer of those elements (and themselves) by generating strand breaks in cognate alleles that lack the intervening sequence, as well as in additional ectopic sites that broaden the range of intron and intein mobility. Homing endonucleases can be divided into several unique families that are remarkable in several respects: they display extremely high DNA-binding specificities which arise from long DNA target sites (14-40 bp), they are tolerant of a variety of sequence variations in these sites, and they display disparate DNA cleavage mechanisms. A significant number of homing endonucleases also act as maturases (highly specific cofactors for the RNA splicing reactions of their cognate introns). Of the known homing group I endonuclease families, two (HNH and His-Cys box enzymes) appear to be diverged from a common ancestral nuclease. While crystal structures of several representatives of the LAGLIDADG endonuclease family have been determined, only structures of single members of the HNH (I-HmuI), His-Cys box (I-PpoI) and GIY-YIG (I-TevI) families have been elucidated. These studies provide an important source of information for structure-function relationships in those families, and are the centerpiece of this review. Finally, homing endonucleases are significant targets for redesign and selection experiments, in hopes of generating novel DNA binding and cutting reagents for a variety of genomic applications.     

Evolutionary dynamics of introns and their open reading frames in the U7 region of the mitochondrial rnl gene in species of Ceratocystis

The mtDNA rnl-U7 region has been examined for the presence of introns in selected species of the genus Ceratocystis. Comparative sequence analysis identified group I and group II introns encoding single and double motif LAGLIDADG open reading frames (ORFs) at the following positions L1671, L1787, and L1923. In addition downstream of the rnl-U7 region group I introns were detected at positions L1971 and L2231, and a group II intron at L2059. A GIY-YIG type ORF was located within one mL1923 LAGLIDADG type ORF and a degenerated GIY-YIG ORF fused to a nad2 gene fragment was found in association with the mL1971 group I intron. The diversity of composite elements that appear to be sporadically distributed among closely related species of Ceratocystis illustrates the potential for homing endonucleases and their associated introns to invade new sites. Phylogenetic analysis showed that single motif LADGLIDADG ORFs related to the mL1923 ORFs have invaded the L1787 group II intron and the L1671 group I intron. Phylogenetic analysis of intron encoded single and double motif LAGLIDADG ORFs also showed that these ORFs transferred four times from group I into group II B1 type introns.     

Protein footprinting approach to mapping DNA binding sites of two archaeal homing enzymes: evidence for a two-domain protein structure.

The archaeal intron-encoded homing enzymes I-PorI and I-DmoI belong to a family of endonucleases that contain two copies of a characteristic LAGLIDADG motif. These endonucleases cleave their intron- or intein- alleles site-specifically, and thereby facilitate homing of the introns or inteins which encode them. The protein structure and the mechanism of DNA recognition of these homing enzymes is largely unknown. Therefore, we examined these properties of I-PorI and I-DmoI by protein footprinting. Both proteins were susceptible to proteolytic cleavage within regions that are equidistant from each of the two LAGLIDADG motifs. When complexed with their DNA substrates, a characteristic subset of the exposed sites, located in regions immediately after and 40-60 amino acids after each of the LAGLIDADG motifs, were protected. Our data suggest that the enzymes are structured into two, tandemly repeated, domains, each containing both the LAGLIDADG motif and two putative DNA binding regions. The latter contains a potentially novel DNA binding motif conserved in archaeal homing enzymes. The results are consistent with a model where the LAGLIDADG endonucleases bind to their non-palindromic substrates as monomeric enzymes, with each of the two domains recognizing one half of the DNA substrate.     

The spread of LAGLIDADG homing endonuclease genes in rDNA

Group I introns that encode homing endonuclease genes (HEGs) are highly invasive genetic elements. Their movement into a homologous position in an intron-less allele is termed homing. Although the mechanism of homing is well understood, the evolutionary relationship between HEGs and their intron partners remains unclear. Here we have focused on the largest family of HEGs (encoding the protein motif, LAGLIDADG) to understand how HEGs and introns move in rDNA. Our analysis shows the phylogenetic clustering of HEGs that encode a single copy of the LAGLIDADG motif in neighboring, but often evolutionarily distantly related, group I introns. These endonucleases appear to have inserted into existing introns independent of ribozymes. In contrast, our data support a common evolutionary history for a large family of heterologous introns that encode HEGs with a duplicated LAGLIDADG motif. This finding suggests that intron/double-motif HEG elements can move into heterologous sites as a unit. Our data also suggest that a subset of the double-motif HEGs in rDNA originated from the duplication and fusion of a single-motif HEG encoded by present-day ribozymes in LSU rDNA.     

The restriction fold turns to the dark side: a bacterial homing endonuclease with a PD-(D/E)-XK motif

The homing endonuclease I-Ssp6803I causes the insertion of a group I intron into a bacterial tRNA gene-the only example of an invasive mobile intron within a bacterial genome. Using a computational fold prediction, mutagenic screen and crystal structure determination, we demonstrate that this protein is a tetrameric PD-(D/E)-XK endonuclease - a fold normally used to protect a bacterial genome from invading DNA through the action of restriction endonucleases. I-Ssp6803I uses its tetrameric assembly to promote recognition of a single long target site, whereas restriction endonuclease tetramers facilitate cooperative binding and cleavage of two short sites. The limited use of the PD-(D/E)-XK nucleases by mobile introns stands in contrast to their frequent use of LAGLIDADG and HNH endonucleases - which in turn, are rarely incorporated into restriction/modification systems.     

Characterization of the I-Spom I endonuclease from fission yeast: insights into the evolution of a group I intron-encoded homing endonuclease

The first group I intron in the cox1 gene (cox1I1b ) of the mitochondrial genome of the fission yeast Schizosaccharomyces pombe is a mobile DNA element. The mobility is dependent on an endonuclease protein that is encoded by an intronic open reading frame (ORF). The intron-encoded endonuclease is a typical member of the LAGLIDADG protein family of endonucleases with two consensus motifs. In addition to this, analysis of several intron mutants revealed that this protein is required for intron splicing. However, this protein is one of the few group I intron-encoded proteins that functions in RNA splicing simultaneously with its DNA endonuclease activity. We report here on the biochemical characterization of the endonuclease activity of this protein artificially expressed in Escherichia coli. Although the intronic ORF is expressed as a fusion protein with the upstream exon in vivo, the experiments showed that a truncated translation product consisting of the C-terminal 304 codons of the cox1I1b ORF restricted to loop 8 of the intron RNA secondary structure is sufficient for the specific endonuclease activity in vitro. Based on the results, we speculate on the evolution of site-specific homing endonucleases encoded by group I introns in eukaryotes.     

DNA binding and cleavage by the HNH homing endonuclease I-HmuI

The structure of I-HmuI, which represents the last family of homing endonucleases without a defining crystallographic structure, has been determined in complex with its DNA target. A series of diverse protein structural domains and motifs, contacting sequential stretches of nucleotide bases, are distributed along the DNA target. I-HmuI contains an N-terminal domain with a DNA-binding surface found in the I-PpoI homing endonuclease and an associated HNH/N active site found in the bacterial colicins, and a C-terminal DNA-binding domain previously observed in the I-TevI homing endonuclease. The combination and exchange of these features between protein families indicates that the genetic mobility associated with homing endonucleases extends to the level of independent structural domains. I-HmuI provides an unambiguous structural connection between the His-Cys box endonucleases and the bacterial colicins, supporting the hypothesis that these enzymes diverged from a common ancestral nuclease.     

Invasion of protein coding genes by green algal ribosomal group I introns

The spread of group I introns depends on their association with intron-encoded homing endonucleases. Introns that encode functional homing endonuclease genes (HEGs) are highly invasive, whereas introns that only encode the group I ribozyme responsible for self-splicing are generally stably inherited (i.e., vertical inheritance). A number of recent case studies have provided new knowledge on the evolution of group I introns, however, there are still large gaps in understanding of their distribution on the tree of life, and how they have spread into new hosts and genic sites. During a larger phylogenetic survey of chlorophyceaen green algae, we found that 23 isolates contain at least one group I intron in the rbcL chloroplast gene. Structural analyses show that the introns belong to one of two intron lineages, group IA2 intron-HEG (GIY-YIG family) elements inserted after position 462 in the rbcL gene, and group IA1 introns inserted after position 699. The latter intron type sometimes encodes HNH homing endonucleases. The distribution of introns was analyzed on an exon phylogeny and patterns were recovered that are consistent with vertical inheritance and possible horizontal transfer. The rbcL 462 introns are thus far reported only within the Volvocales, Hydrodictyaceae and Bracteacoccus, and closely related isolates of algae differ in the presence of rbcL introns. Phylogenetic analysis of the intron conserved regions indicates that the rbcL699 and rbcL462 introns have distinct evolutionary origins. The rbcL699 introns were likely derived from ribosomal RNA L2449 introns, whereas the rbcL462 introns form a close relationship with psbA introns.     

Recognition of a common rDNA target site in archaea and eukarya by analogous LAGLIDADG and His-Cys box homing endonucleases

The presence of a homing endonuclease gene (HEG) within a microbial intron or intein empowers the entire element with the ability to invade genomic targets. The persistence of a homing endonuclease lineage depends in part on conservation of its DNA target site. One such rDNA sequence has been invaded both in archaea and in eukarya, by LAGLIDADG and His–Cys box homing endonucleases, respectively. The bases encoded by this target include a universally conserved ribosomal structure, termed helix 69 (H69) in the large ribosomal subunit. This region forms the ‘B2a’ intersubunit bridge to the small ribosomal subunit, contacts bound tRNA in the A- and P-sites, and acts as a trigger for ribosome disassembly through its interactions with ribosome recycling factor. We have determined the DNA-bound structure and specificity profile of an archaeal LAGLIDADG homing endonuclease (I-Vdi141I) that recognizes this target site, and compared its specificity with the analogous eukaryal His–Cys box endonuclease I-PpoI. These homodimeric endonuclease scaffolds have arrived at similar specificity profiles across their common biological target and analogous solutions to the problem of accommodating conserved asymmetries within the DNA sequence, but with differences at individual base pairs that are fine-tuned to the sequence conservation of archaeal versus eukaryal ribosomes.     

Identification of a family of group II introns encoding LAGLIDADG ORFs typical of group I introns

Group I and group II introns are unrelated classes of introns that each encode proteins that facilitate intron splicing and intron mobility. Here we describe a new subfamily of nine introns in fungi that are group II introns but encode LAGLIDADG ORFs typical of group I introns. The introns have fairly standard group IIB1 RNA structures and are inserted into three different sites in SSU and LSU rRNA genes. Therefore, introns should not be assumed to be group I introns based solely on the presence of a LAGLIDADG ORF.     

Rapid evolution of the DNA-binding site in LAGLIDADG homing endonucleases

Sequence analysis of chloroplast and mitochondrial large subunit rRNA genes from over 75 green algae disclosed 28 new group I intron-encoded proteins carrying a single LAGLIDADG motif. These putative homing endonucleases form four subfamilies of homologous enzymes, with the members of each subfamily being encoded by introns sharing the same insertion site. We showed that four divergent endonucleases from the I-CreI subfamily cleave the same DNA substrates. Mapping of the 66 amino acids that are conserved among the members of this subfamily on the 3-dimensional structure of I-CreI bound to its recognition sequence revealed that these residues participate in protein folding, homodimerization, DNA recognition and catalysis. Surprisingly, only seven of the 21 I-CreI amino acids interacting with DNA are conserved, suggesting that I-CreI and its homologs use different subsets of residues to recognize the same DNA sequence. Our sequence comparison of all 45 single-LAGLIDADG proteins identified so far suggests that these proteins share related structures and that there is a weak pressure in each subfamily to maintain identical protein–DNA contacts. The high sequence variability we observed in the DNA-binding site of homologous LAGLIDADG endonucleases provides insight into how these proteins evolve new DNA specificity.     

真菌线粒体cob中Ⅱ型LAGLIDADG归巢内切酶进化分析

以已公布的114种真菌线粒体基因组数据为依据,对cob内含子及其编码的Ⅱ型LAGLIDADG归巢内切酶进行全面分析,以揭示其进化规律。在cob内含子中共发现27个Ⅱ型LAGLIDADG归巢内切酶基因,其中18个位于S433内含子插入位点,其余9个散布在另外8个插入位点。结合Pfam数据,将Ⅱ型LAGLIDADG归巢内切酶分成10个主要类群,其中4个类群存在不同生物界物种间的水平迁移。S433位点的18个归巢内切酶均属于类群1,它们与宿主内含子可能从共同祖先垂直遗传而来,并在传递过程中伴有水平迁移;其他归巢内切酶及宿主内含子则应是水平迁移的结果。类群1中的归巢内切酶可分为两个亚类,两亚类识别的靶序列存在明显差异;保守模体氨基酸序列分析显示它们大多数具有潜在内切酶活性。全面呈现了真菌线粒体cob内含子及其编码的Ⅱ型LAGLIDADG归巢内切酶的存在状态和进化模式,为归巢内切酶的改造和设计提供了新素材。     

Discovery of a group I intron in the SSU rDNA of Ploeotia costata (Euglenozoa)

The gene coding for the small ribosomal subunit RNA of Ploeotia costata contains an actively splicing group I intron (Pco.S516) which is unique among euglenozoans. Secondary structure predictions indicate that paired segments P1-P10 as well as several conserved elements typical of group I introns and of subclass IC1 in particular are present. Phylogenetic analyses of SSU rDNA sequences demonstrate a well-supported placement of Ploeotia costata within the Euglenozoa; whereas, analyses of intron data sets uncover a close phylogenetic relation of Pco.S516 to S-516 introns from Acanthamoeba, Aureoumbra lagunensis (Stramenopila) and red algae of the order Bangiales. Discrepancies between SSU rDNA and intron phylogenies suggest horizontal spread of the group I intron. Monophyly of IC1 516 introns from Ploeotia costata, A. lagunensis and rhodophytes is supported by a unique secondary structure element: helix P5b possesses an insertion of 19 nt length with a highly conserved tetraloop which is supposed to take part in tertiary interactions. Neither functional nor degenerated ORFs coding for homing endonucleases can be identified in Pco.S516. Nevertheless, degenerated ORFs with His-Cys box motifs in closely related intron sequences indicate that homing may have occurred during evolution of the investigated intron group.     

Modular organization of inteins and C-terminal autocatalytic domains.

Analysis of the conserved sequence features of inteins (protein "introns") reveals that they are composed of three distinct modular domains. The N-terminal (N) and C-terminal (C) domains are predicted to perform different parts of the autocatalytic protein splicing reaction. An optional endonuclease domain (EN) is shown to correspond to different types of homing endonucleases in different inteins. The N domain contains motifs predicted to catalyze the first steps of protein splicing, leading to the cleavage of the intein N terminus from its protein host. Intein N domain motifs are also found in C-terminal autocatalytic domains (CADs) present in hedgehog and other protein families. Specific residues in the N domain of intein and CADs are proposed to form a charge relay system involved in cleaving their N-termini. The intein C domain is apparently unique to inteins and contains motifs that catalyze the final protein splicing steps: ligation of the intein flanks and cleavage of its C terminus to release the free intein and spliced host protein. All intein EN domains known thus far have dodecapeptide (DOD, LAGLI-DADG) type homing endonuclease motifs. This work identifies an EN domain with an HNH homing-endonuclease motif and two new small inteins with no EN domains. One of these small inteins might be inactive or a "pseudo intein." The results suggest a modular architecture for inteins, clarify their origin and relationship to other protein families, and extend recent experimental findings on the functional roles of intein N, C, and EN motifs.     

Self-splicing group I and group II introns encode homologous (putative) DNA endonucleases of a new family.

A new family of protein domains consisting of 50-80 amino acid residues is described. It is composed of nearly 40 members, including domains encoded by plastid and phage group I introns; mitochondrial, plastid, and bacterial group II introns; eubacterial genomes and plasmids; and phages. The name "EX1HH-HX3H" was coined for both domain and family. It is based on 2 most prominent amino acid sequence motifs, each encompassing a pair of highly conserved histidine residues in a specific arrangement: EX1HH and HX3H. The "His" motifs often alternate with amino- and carboxy-terminal motifs of a new type of Zn-finger-like structure CX2,4CX29-54[CH]X2,3[CH]. The EX1HH-HX3H domain in eubacterial E2-type bacteriocins and in phage RB3 (wild variant of phage T4) product of the nrdB group I intron was reported to be essential for DNA endonuclease activity of these proteins. In other proteins, the EX1HH-HX3H domain is hypothesized to possess DNase activity as well. Presumably, this activity promotes movement (rearrangement) of group I and group II introns encoding the EX1HH-HX3H domain and other gene targets. In the case of Escherichia coli restrictase McrA and possibly several related proteins, it appears to mediate the restriction of alien DNA molecules.     

The nicking homing endonuclease I-BasI is encoded by a group I intron in the DNA polymerase gene of the Bacillus thuringiensis phage Bastille

Here we describe the discovery of a group I intron in the DNA polymerase gene of Bacillus thuringiensis phage Bastille. Although the intron insertion site is identical to that of the Bacillus subtilis phages SPO1 and SP82 introns, the Bastille intron differs from them substantially in primary and secondary structure. Like the SPO1 and SP82 introns, the Bastille intron encodes a nicking DNA endonuclease of the H-N-H family, I-BasI, with a cleavage site identical to that of the SPO1-encoded enzyme I-HmuI. Unlike I-HmuI, which nicks both intron-minus and intron-plus DNA, I-BasI cleaves only intron-minus alleles, which is a characteristic of typical homing endonucleases. Interestingly, the C-terminal portions of these H-N-H phage endonucleases contain a conserved sequence motif, the intron-encoded endonuclease repeat motif (IENR1) that also has been found in endonucleases of the GIY-YIG family, and which likely comprises a small DNA-binding module with a globular ββααβ fold, suggestive of module shuffling between different homing endonuclease families.     

Structural characterization of the catalytic subunit of a novel RNA splicing endonuclease

The RNA splicing endonuclease is responsible for recognition and excision of nuclear tRNA and all archaeal introns. Despite the conserved RNA cleavage chemistry and a similar enzyme assembly, currently known splicing endonuclease families have limited RNA specificity. Different from previously characterized splicing endonucleases in Archaea, the splicing endonuclease from archaeum Sulfolobus solfataricus was found to contain two different subunits and accept a broader range of substrates. Here, we report a crystal structure of the catalytic subunit of the S.solfataricus endonuclease at 3.1 angstroms resolution. The structure, together with analytical ultracentrifugation analysis, identifies the catalytic subunit as an inactive but stable homodimer, thus suggesting the possibility of two modes of functional assembly for the active enzyme.     

Hjc resolvase is a distantly related member of the type II restriction endonuclease family

Hjc resolvase is an archaeal enzyme involved in homologous DNA recombination at the Holliday junction intermediate. However, the structure and the catalytic mechanism of the enzyme have not yet been identified. We performed database searching using the amino acid sequence of the enzyme from Pyrococcus furiosus as a query. We detected 59 amino acid sequences showing weak but significant sequence similarity to the Hjc resolvase. The detected sequences included DpnII, HaeII and Vsr endonuclease, which belong to the type II restriction endonuclease family. In addition, a highly conserved region was identified from a multiple alignment of the detected sequences, which was similar to an active site of the type II restriction endonucleases. We substituted three conserved amino acid residues in the highly conserved region of the Hjc resolvase with Ala residues. The amino acid replacements inactivated the enzyme. The experimental study, together with the results of the database searching, suggests that the Hjc resolvase is a distantly related member of the type II restriction endonuclease family. In addition, the results of our database searches suggested that the members of the RecB domain superfamily are evolutionarily related to the type II restriction endonuclease family.