Double strand break-induced recombination in Chlamydomonas reinhardtii chloroplasts

Harnessing the Algal Chloroplast for Heterologous Protein Production

Photosynthetic microbes are gaining increasing attention as heterologous hosts for the light-driven, low-cost production of high-value recombinant proteins. Recent advances in the manipulation of unicellular algal genomes offer the opportunity to establish engineered strains as safe and viable alternatives to conventional heterotrophic expression systems, including for their use in the feed, food, and biopharmaceutical industries. Due to the relatively small size of their genomes, algal chloroplasts are excellent targets for synthetic biology approaches, and are convenient subcellular sites for the compartmentalized accumulation and storage of products. Different classes of recombinant proteins, including enzymes and peptides with therapeutical applications, have been successfully expressed in the plastid of the model organism Chlamydomonas reinhardtii, and of a few other species, highlighting the emerging potential of transplastomic algal biotechnology. In this review, we provide a unified view on the state-of-the-art tools that are available to introduce protein-encoding transgenes in microalgal plastids, and discuss the main (bio)technological bottlenecks that still need to be addressed to develop robust and sustainable green cell biofactories.

Therapy in Rhodopsin-Mediated Autosomal Dominant Retinitis Pigmentosa

Rhodopsin-mediated autosomal dominant retinitis pigmentosa (RHO-adRP) is a hereditary degenerative disorder in which mutations in the gene encoding RHO, the light-sensitive G protein-coupled receptor involved in phototransduction in rods, lead to progressive loss of rods and subsequently cones in the retina. Clinical phenotypes are diverse, ranging from mild night blindness to severe visual impairments. There is currently no cure for RHO-adRP. Although there have been significant advances in gene therapy for inherited retinal diseases, treating RHO-adRP presents a unique challenge since it is an autosomal dominant disease caused by more than 150 gain-of-function mutations in the RHO gene, rendering the established gene supplementation strategy inadequate. This review provides an update on RNA therapeutics and therapeutic editing genome surgery strategies and ongoing clinical trials for RHO-adRP, discussing mechanisms of action, preclinical data, current state of development, as well as risk and benefit considerations. Potential outcome measures useful for future clinical trials are also addressed.

Small RNA profiling in Chlamydomonas: insights into chloroplast RNA metabolism

In Chlamydomonas reinhardtii, regulation of chloroplast gene expression is mainly post-transcriptional. It requires nucleus-encoded trans-acting protein factors for maturation/stabilization (M factors) or translation (T factors) of specific target mRNAs. We used long- and small-RNA sequencing to generate a detailed map of the transcriptome. Clusters of sRNAs marked the 5' end of all mature mRNAs. Their absence in M-factor mutants reflects the protection of transcript 5' end by the cognate factor. Enzymatic removal of 5'-triphosphates allowed identifying those cosRNA that mark a transcription start site. We detected another class of sRNAs derived from low abundance transcripts, antisense to mRNAs. The formation of antisense sRNAs required the presence of the complementary mRNA and was stimulated when translation was inhibited by chloramphenicol or lincomycin. We propose that they derive from degradation of double-stranded RNAs generated by pairing of antisense and sense transcripts, a process normally hindered by the traveling of the ribosomes. In addition, chloramphenicol treatment, by freezing ribosomes on the mRNA, caused the accumulation of 32-34 nt ribosome-protected fragments. Using this 'in vivo ribosome footprinting', we identified the function and molecular target of two candidate trans-acting factors.

A Dynamic Tandem Repeat in Monocotyledons Inferred from a Comparative Analysis of Chloroplast Genomes in Melanthiaceae

Chloroplast genomes (cpDNA) are highly valuable resources for evolutionary studies of angiosperms, since they are highly conserved, are small in size, and play critical roles in plants. Slipped-strand mispairing (SSM) was assumed to be a mechanism for generating repeat units in cpDNA. However, research on the employment of different small repeated sequences through SSM events, which may induce the accumulation of distinct types of repeats within the same region in cpDNA, has not been documented. Here, we sequenced two chloroplast genomes from the endemic species Heloniopsis tubiflora (Korea) and Xerophyllum tenax (USA) to cover the gap between molecular data and explore "hot spots" for genomic events in Melanthiaceae. Comparative analysis of 23 complete cpDNA sequences revealed that there were different stages of deletion in the rps16 region across the Melanthiaceae. Based on the partial or complete loss of rps16 gene in cpDNA, we have firstly reported potential molecular markers for recognizing two sections (Veratrum and Fuscoveratrum) of Veratrum. Melathiaceae exhibits a significant change in the junction between large single copy and inverted repeat regions, ranging from trnH_GUG to a part of rps3. Our results show an accumulation of tandem repeats in the rpl23-ycf2 regions of cpDNAs. Small conserved sequences exist and flank tandem repeats in further observation of this region across most of the examined taxa of Liliales. Therefore, we propose three scenarios in which different small repeated sequences were used during SSM events to generate newly distinct types of repeats. Occasionally, prior to the SSM process, point mutation event and double strand break repair occurred and induced the formation of initial repeat units which are indispensable in the SSM process. SSM may have likely occurred more frequently for short repeats than for long repeat sequences in tribe Parideae (Melanthiaceae, Liliales). Collectively, these findings add new evidence of dynamic results from SSM in chloroplast genomes which can be useful for further evolutionary studies in angiosperms. Additionally, genomics events in cpDNA are potential resources for mining molecular markers in Liliales.

PCR analysis of chloroplast double-strand break (DSB) repair products induced by I-CreII in Chlamydomonas and Arabidopsis

Homing endonuclease I-CreII has been used to study the consequences and repair of a double-strand break (DSB) in the chloroplast genome of Chlamydomonas and Arabidopsis. Since I-CreII is from a mobile psbA intron of Chlamydomonas, it cleaves the psbA gene of an intronless-psbA strain of Chlamydomonas. And it cleaves specifically in the psbA gene of Arabidopsis, which is naturally intronless. We have shown further that most of the repair products of an I-CreII-induced break in chloroplast DNA can be defined by PCR analysis with total nucleic acids and the appropriate primers. Here, we provide protocols for small-scale preparation of nucleic acids from Chlamydomonas and Arabidopsis, as well as guidelines for the subsequent PCR analysis.

A novel rhodanese is required to maintain chloroplast translation in Chlamydomonas

Rhodanese-domain proteins (RDPs) are widespread in plants and other organisms, but their biological roles are mostly unknown. Here we report on a novel RDP from Chlamydomonas that has a single rhodanese domain, and a predicted chloroplast transit peptide. The protein was produced in Escherichia coli with a His-tag, but lacking most of the N-terminal transit peptide, and after purification was found to have rhodanese activity in vitro. It was also used to elicit antibodies for western blot analysis, which showed that the native Chlamydomonas protein migrated slower on SDS gels (apparent M(r) =34 kDa) than its predicted size (27 kDa), and co-fractionated with chloroplasts. To assess function in vivo, the tandem-RNAi approach was used to generate Chlamydomonas strains that had reductions of 30-70% for the mRNA and ~20-40% for the 34-kDa protein. These strains showed reduced growth under all trophic conditions, and were sensitive to even moderate light; properties reminiscent of chloroplast translation mutants. Pulse-labeling in the presence of cycloheximide indicated that chloroplast protein synthesis was broadly reduced in the RNAi strains, and transcript analysis (by RT-PCR and northern blotting) indicated the effect was mainly translational. These results identify a novel rhodanese-like protein that we have named CRLT, because it is required to maintain chloroplast translation.

Mapping of the css (chloroplast splicing suppressor) gene(s) to a recombinationally suppressed region of chromosome III in Chlamydomonas reinhardtii

In previous work, three suppressors of defective group I introns (7151, 71N1, 7120) were isolated from a mutant of Chlamydomonas reinhardtii that had a splicing-deficient chloroplast large subunit (LSU) rRNA intron. Genetic analysis indicated that the 7151 and 71N1 suppressor mutations each involved single nuclear loci, and that the 7151 mutation was dominant. Here we present genetic evidence that the 7120 suppressor also involves a single nuclear locus and that the mutation is dominant in vegetative diploids. Moreover, we have employed crosses with the S1D2 strain and molecular markers to map the 7120 and 71N1 suppressors. Based on an analysis of 800 progeny from 7120 × S1D2, the 7120 suppressor is located in a region of ~400 kb on chromosome III that is devoid of recombination. The ~400-kb region contains at least 72 genes, about one-third of which (i.e., 22) are predicted to be organelle targeted. Similar analysis of 71N1 × S1D2 using 400 progeny also pointed to the recombination-deficient region of chromosome III, raising the possibility that these mutations could affect the same gene. These efforts lay the foundation for identifying the css (chloroplast splicing suppressor) gene(s), which promotes splicing of multiple chloroplast group I introns.

Divalent metal ion differentially regulates the sequential nicking reactions of the GIY-YIG homing endonuclease I-BmoI

Homing endonucleases are site-specific DNA endonucleases that function as mobile genetic elements by introducing double-strand breaks or nicks at defined locations. Of the major families of homing endonucleases, the modular GIY-YIG endonucleases are least understood in terms of mechanism. The GIY-YIG homing endonuclease I-BmoI generates a double-strand break by sequential nicking reactions during which the single active site of the GIY-YIG nuclease domain must undergo a substantial reorganization. Here, we show that divalent metal ion plays a significant role in regulating the two independent nicking reactions by I-BmoI. Rate constant determination for each nicking reaction revealed that limiting divalent metal ion has a greater impact on the second strand than the first strand nicking reaction. We also show that substrate mutations within the I-BmoI cleavage site can modulate the first strand nicking reaction over a 314-fold range. Additionally, in-gel DNA footprinting with mutant substrates and modeling of an I-BmoI-substrate complex suggest that amino acid contacts to a critical GC-2 base pair are required to induce a bottom-strand distortion that likely directs conformational changes for reaction progress. Collectively, our data implies mechanistic roles for divalent metal ion and substrate bases, suggesting that divalent metal ion facilitates the re-positioning of the GIY-YIG nuclease domain between sequential nicking reactions.

Microhomology-mediated and nonhomologous repair of a double-strand break in the chloroplast genome of Arabidopsis

Chloroplast DNA (cpDNA) is under great photooxidative stress, yet its evolution is very conservative compared with nuclear or mitochondrial genomes. It can be expected that DNA repair mechanisms play important roles in cpDNA survival and evolution, but they are poorly understood. To gain insight into how the most severe form of DNA damage, a double-strand break (DSB), is repaired, we have developed an inducible system in Arabidopsis that employs a psbA intron endonuclease from Chlamydomonas, I-CreII, that is targeted to the chloroplast using the rbcS1 transit peptide. In Chlamydomonas, an I-CreII-induced DSB in psbA was repaired, in the absence of the intron, by homologous recombination between repeated sequences (20-60 bp) abundant in that genome; Arabidopsis cpDNA is very repeat poor, however. Phenotypically strong and weak transgenic lines were examined and shown to correlate with I-CreII expression levels. Southern blot hybridizations indicated a substantial loss of DNA at the psbA locus, but not cpDNA as a whole, in the strongly expressing line. PCR analysis identified deletions nested around the I-CreII cleavage site indicative of DSB repair using microhomology (6-12 bp perfect repeats, or 10-16 bp with mismatches) and no homology. These results provide evidence of alternative DSB repair pathways in the Arabidopsis chloroplast that resemble the nuclear, microhomology-mediated and nonhomologous end joining pathways, in terms of the homology requirement. Moreover, when taken together with the results from Chlamydomonas, the data suggest an evolutionary relationship may exist between the repeat structure of the genome and the organelle's ability to repair broken chromosomes.

Recombination and the maintenance of plant organelle genome stability

Like their nuclear counterpart, the plastid and mitochondrial genomes of plants have to be faithfully replicated and repaired to ensure the normal functioning of the plant. Inability to maintain organelle genome stability results in plastid and/or mitochondrial defects, which can lead to potentially detrimental phenotypes. Fortunately, plant organelles have developed multiple strategies to maintain the integrity of their genetic material. Of particular importance among these processes is the extensive use of DNA recombination. In fact, recombination has been implicated in both the replication and the repair of organelle genomes. Revealingly, deregulation of recombination in organelles results in genomic instability, often accompanied by adverse consequences for plant fitness. The recent identification of four families of proteins that prevent aberrant recombination of organelle DNA sheds much needed mechanistic light on this important process. What comes out of these investigations is a partial portrait of the recombination surveillance machinery in which plants have co-opted some proteins of prokaryotic origin but have also evolved whole new factors to keep their organelle genomes intact. These new features presumably optimized the protection of plastid and mitochondrial genomes against the particular genotoxic stresses they face.

Chlamydomonas chloroplasts can use short dispersed repeats and multiple pathways to repair a double-strand break in the genome

Certain group I introns insert into intronless DNA via an endonuclease that creates a double-strand break (DSB). There are two models for intron homing in phage: synthesis-dependent strand annealing (SDSA) and double-strand break repair (DSBR). The Cr.psbA4 intron homes efficiently from a plasmid into the chloroplast psbA gene in Chlamydomonas, but little is known about the mechanism. Analysis of co-transformants selected using a spectinomycin-resistant 16S gene (16S(spec)) provided evidence for both pathways. We also examined the consequences of the donor DNA having only one-sided or no homology with the psbA gene. When there was no homology with the donor DNA, deletions of up to 5 kb involving direct repeats that flank the psbA gene were obtained. Remarkably, repeats as short as 15 bp were used for this repair, which is consistent with the single-strand annealing (SSA) pathway. When the donor had one-sided homology, the DSB in most co-transformants was repaired using two DNAs, the donor and the 16S(spec) plasmid, which, coincidentally, contained a region that is repeated upstream of psbA. DSB repair using two separate DNAs provides further evidence for the SDSA pathway. These data show that the chloroplast can repair a DSB using short dispersed repeats located proximally, distally, or even on separate molecules relative to the DSB. They also provide a rationale for the extensive repertoire of repeated sequences in this genome.

Expression, purification, and biochemical characterization of the intron-encoded endonuclease, I-CreII

The ORF of the Cr.psbA4 intron of Chlamydomonas reinhardtii mediates efficient intron homing, and contains an H-N-H and possibly a GIY-YIG motif. The ORF was over-expressed in Escherichia coli without non-native amino acids, but was mostly insoluble. However, co-over-expression of E. coli chaperonins GroEL/GroES solubilized approximately 50% of the protein, which was purified by ion-exchange and heparin-affinity chromatography. Biochemical characterization showed that the protein is a double-strand-specific endonuclease that cleaves fused psbA exon 4-exon 5 DNA, and was named I-CreII. I-CreII has a relatively relaxed divalent metal ion requirement (Mg(2+), Mn(2+), Ca(2+), and Fe(2+) supported cleavage), is insensitive to salt <350 mM, and is stabilized by DNA. Cleavage of target DNA occurs close (4 nt on the top strand) to the intron-insertion site, and leaves 2-nt 3'-OH overhangs, similar to GIY-YIG endonucleases. The boundaries of the recognition sequence span approximately 30 bp, and encompass the cleavage and intron-insertion sites. Cleavage of heterologous psbA DNAs indicates the enzyme can tolerate multiple, but not all, substitutions in the recognition site. This work will facilitate further study of this novel endonuclease, which may also find use in site-specific manipulation of chloroplast DNA.

In vivo selection of engineered homing endonucleases using double-strand break induced homologous recombination

Homing endonucleases, endonucleases capable of recognizing long DNA sequences, have been shown to be a tool of choice for precise and efficient genome engineering. Consequently, the possibility to engineer novel endonucleases with tailored specificities is under strong investigation. In this report, we present a simple and efficient method to select meganucleases from libraries of variants, based on their cleavage properties. The method has the advantage of directly selecting for the ability to induce double-strand break induced homologous recombination in a eukaryotic environment. Model selections demonstrated high levels of enrichments. Moreover, this method compared favorably with phage display for enrichment of active mutants from a mutant library. This approach makes possible the exploration of large sequence spaces and thereby represents a valuable tool for genome engineering.

A horizontally acquired group II intron in the chloroplast psbA gene of a psychrophilic Chlamydomonas: in vitro self-splicing and genetic evidence for maturase activity

The majority of known group II introns are from chloroplast genomes, yet the first self-splicing group II intron from a chloroplast gene was reported only recently, from the psbA gene of the euglenoid, Euglena myxocylindracea. Herein, we describe a large (2.6-kb) group II intron from the psbA gene (psbA1) of a psychrophilic Chlamydomonas sp. from Antarctica that self-splices accurately in vitro. Remarkably, this intron, which also encodes an ORF with putative reverse transcriptase, maturase, and endonuclease domains, is in the same location, and is related to the E. myxocylindracea intron, as well as to group IIB2 introns from cyanobacteria. In vitro self-splicing of Chs.psbA1 occurred via a lariat, and required Mg(2+) (>12 mM) and NH(4)(+). Self-splicing was improved by deleting most of the ORF and by using pre-RNAs directly from transcription reactions, suggestive of a role for folding during transcription. Self-splicing of Chs.psbA1 pre-RNAs showed temperature optima of ~44 degrees C, but with a broad shoulder on the low side of the peak; splicing was nearly absent at 50 degrees C, indicative of thermolability. Splicing of wild-type Chs.psbA1 also occurred in Escherichia coli, but not when the ORF was disrupted by mutations, providing genetic evidence that it has maturase activity. This work provides the first description of a ribozyme from a psychrophilic organism. It also appears to provide a second instance of interkingdom horizontal transfer of this group IIB2 intron (or a close relative) from cyanobacteria to chloroplasts.

Chloroplast RNA processing and stability

Primary chloroplast transcripts are processed in a number of ways, including intron splicing, internal cleavage of polycistronic RNAs, and endonucleolytic or exonucleolytic cleavages at the transcript termini. All chloroplast RNAs are also subject to degradation, although a curious feature of many chloroplast mRNAs is their relative longevity. Some of these processes, e.g., psbA splicing and stability of a number of chloroplast mRNAs, are regulated in response to light-dark cycles or nutrient availability. This review highlights recent advances in our understanding of these processes in the model organism Chlamydomonas reinhardtii, focusing on results since the extensive reviews published in 1998 [Herrin DL et al. 1998 (pp. 183-195), Nickelsen Y 1998 (pp. 151-163), Stern DB and Drager RG 1998 (pp. 164-182), in Rochaix JD et al. (eds) The Molecular Biology of Chloroplasts and Mitochondria in Chlamydomonas. Kluwer Academic Publishers, Dordrecht, The Netherlands]. We also allude to studies with other organisms, and to the potential impact of the Chlamydomonas genome project where appropriate.

Mutagenesis of a light-regulated psbA intron reveals the importance of efficient splicing for photosynthetic growth

The chloroplast-encoded psbA gene encodes the D1 polypeptide of the photosystem II reaction center, which is synthesized at high rates in the light. In Chlamydomonas reinhardtii, the psbA gene contains four self-splicing group I introns whose rates of splicing in vivo are increased at least 6-10-fold by light. However, because psbA is an abundant mRNA, and some chloroplast mRNAs appear to be in great excess of what is needed to sustain translation rates, the developmental significance of light-promoted splicing has not been clear. To address this and other questions, potentially destabilizing substitutions were made in several predicted helices of the fourth psbA intron, Cr.psbA4, and their effects on in vitro and in vivo splicing assessed. Two-nucleotide substitutions in P4 and P7 were necessary to substantially reduce splicing of this intron in vivo, although most mutations reduced self-splicing in vitro. The P7-4,5 mutant, whose splicing was completely blocked, showed no photoautotrophic growth and synthesis of a truncated D1 (exons 1-4) polypeptide from the unspliced mRNA. Most informative was the P4'-3,4 mutant, which exhibited a 45% reduction in spliced psbA mRNA, a 28% reduction in synthesis of full-length D1, and an 18% reduction in photoautotrophic growth. These results indicate that psbA mRNA is not in great excess, and that highly efficient splicing of psbA introns, which is afforded by light conditions, is necessary for optimal photosynthetic growth.

Homologous recombination and gene targeting in plant cells

Gene targeting has become an indispensable tool for functional genomics in yeast and mouse; however, this tool is still missing in plants. This review discusses the gene targeting problem in plants in the context of general knowledge on recombination and gene targeting. An overview on the history of gene targeting is followed by a general introduction to genetic recombination of bacteria, yeast, and vertebrates. This abridged discussion serves as a guide to the following sections, which cover plant-specific aspects of recombination assay systems, the mechanism of recombination, plant recombination genes, the relationship of recombination to the environment, approaches to stimulate homologous recombination and gene targeting, and a description of two plant systems, the moss Physcomitrella patens and the chloroplast, that naturally have high efficiencies of gene targeting. The review concludes with a discussion of alternatives to gene targeting.

A cosmid vector containing a dominant selectable marker for cloning Chlamydomonas genes by complementation

Cosmid vectors containing a dominate selectable marker (ble) for complementation cloning of genes in Chlamydomonas reinhardtii were created. The usefulness of these vectors, which differ in the orientation of the ble cassette, was demonstrated by transforming C. reinhardtii to phleomycin resistance, by constructing a large library (approximately 5 x 10(5) recombinants) in one of them using DNA from a C. reinhardtii mutant, and by transforming C. reinhardtii with recombinant cosmid clones and pools.

Creation of an artificial bifunctional intein by grafting a homing endonuclease into a mini-intein

The majority of inteins are comprised of a protein splicing domain and a homing endonuclease domain. Experimental evidence has demonstrated that the splicing domain and the endonuclease domain in a bifunctional intein are largely independent of each other with respect to both structure and activity. Here, an artificial bifunctional intein has been created through the insertion of an existing homing endonuclease into a mini-intein that is naturally lacking this functionality. The gene for I-CreI, an intron-encoded homing endonuclease, was grafted into the monofunctional Mycobacterium xenopi GyrA intein at the putative site of the missing endonuclease. The resulting fusion protein was found to be capable of protein splicing similar to that of the parent intein. In addition, the protein demonstrated site-specific endonuclease activity that is characteristic of the I-CreI homing endonuclease. The function of each domain therefore remained unaffected by the presence of the other domain. This artificial fusion of the two domains is a potential novel mobile genetic element.

Mobile self-splicing group I introns from the psbA gene of Chlamydomonas reinhardtii: highly efficient homing of an exogenous intron containing its own promoter

Introns 2 and 4 of the psbA gene of Chlamydomonas reinhardtii chloroplasts (Cr.psbA2 and Cr.psbA4, respectively) contain large free-standing open reading frames (ORFs). We used transformation of an intronless-psbA strain (IL) to test whether these introns undergo homing. Each intron, plus short exon sequences, was cloned into a chloroplast expression vector in both orientations and then cotransformed into IL along with a spectinomycin resistance marker (16S rrn). For Cr.psbA2, the sense construct gave nearly 100% cointegration of the intron whereas the antisense construct gave 0%, consistent with homing. For Cr.psbA4, however, both orientations produced highly efficient cointegration of the intron. Efficient cointegration of Cr.psbA4 also occurred when the intron was introduced as a restriction fragment lacking any known promoter. Deletion of most of the ORF, however, abolished cointegration of the intron, consistent with homing. The Cr.psbA4 constructs also contained a 3-(3,4-dichlorophenyl)-1,1-dimethylurea resistance marker in exon 5, which was always present when the intron integrated, thus demonstrating exon coconversion. Remarkably, primary selection for this marker gave >100-fold more transformants (>10,000/microgram of DNA) than did the spectinomycin resistance marker. A trans homing assay was developed for Cr.psbA4; the ORF-minus intron integrated when the ORF was cotransformed on a separate plasmid. This assay was used to identify an intronic region between bp -88 and -194 (relative to the ORF) that stimulated homing and contained a possible bacterial (-10, -35)-type promoter. Primer extension analysis detected a transcript that could originate from this promoter. Thus, this mobile, self-splicing intron also contains its own promoter for ORF expression. The implications of these results for horizontal intron transfer and organelle transformation are discussed.

Processing of a composite large subunit rRNA. Studies with chlamydomonas mutants deficient in maturation of the 23s-like rrna

(Cr.LSU). Little is known of the cis and trans requirements or of the processing pathway for this essential RNA. Previous work showed that the ribosome-deficient ac20 mutant overaccumulates an unspliced large subunit (LSU) RNA, suggesting that it might be a splicing mutant. To elucidate the molecular basis of the ac20 phenotype, a detailed analysis of the rrn transcripts in ac20 and wild-type cells was performed. The results indicate that processing of the ITSs, particularly ITS-1, is inefficient in ac20 and that ITS processing occurs after splicing. Deletion of the Cr.LSU intron from ac20 also did not alleviate the mutant phenotype. Thus, the primary defect in ac20 is not splicing but most likely is associated with ITS processing. A splicing deficiency was studied by transforming wild-type cells with rrnL genes containing point mutations in the intron core. Heteroplasmic transformants were obtained in most cases, except for P4 helix mutants; these strains grew slowly, were light sensitive, and had an RNA profile indicative of inefficient splicing. Transcript analysis in the P4 mutants also indicated that ITS processing can occur on an unspliced precursor, although with reduced efficiency. These latter results indicate that although there is not an absolutely required order for LSU processing, there does seem to be a preferred order that results in efficient processing in vivo.

Purification, biochemical characterization and protein-DNA interactions of the I-CreI endonuclease produced in Escherichia coli

I- CreI is a member of the LAGLI-DADG family of homing nucleases; however, unlike most members of this family it contains only a single copy of this signature motif. I- CreI was over-expressed in Escherichia coli, and a simple purification protocol developed that gave reasonably pure protein in high yield. Size-exclusion chromatography and chemical cross-linking indicated that the protein is a dimer in solution. DNA cleavage by I- CreI was absolutely dependent on Mg2+(or Mn2+), and was inhibited by monovalent cations. I- CreI displayed a surprisingly high temperature optimum (>50 degrees C), with full activity occurring even at 70 degrees C. Interestingly, SDS was needed for efficient release of the cleavage products from the protein, indicating formation of very stable DNA-protein complexes. In contrast to these robust characteristics, purified I- CreI was unstable; however, it could be stabilized by the addition of either target or non-target DNA. Mobility shift assays revealed that I- CreI binds to DNA in the absence of Mg2+. Hydroxyl radical footprinting showed that I- CreI strongly protected the backbone of a continuous stretch of at least 12 nt on each strand that were shifted, relative to each other, by 2 bp in the 3'direction. Methylation protection and interference analyses were also performed, and together with the hydroxyl radical footprinting, indicate that I- CreI binds in both the major and minor grooves of its target DNA.

Homing endonucleases: keeping the house in order

Homing endonucleases are rare-cutting enzymes encoded by introns and inteins. They have striking structural and functional properties that distinguish them from restriction enzymes. Nomenclature conventions analogous to those for restriction enzymes have been developed for the homing endonucleases. Recent progress in understanding the structure and function of the four families of homing enzymes is reviewed. Of particular interest are the first reported structures of homing endonucleases of the LAGLIDADG family. The exploitation of the homing enzymes in genome analysis and recombination research is also summarized. Finally, the evolution of homing endonucleases is considered, both at the structure-function level and in terms of their persistence in widely divergent biological systems.