Multiple Homing Pathways Used by Yeast Mitochondrial Group II Introns

doi:10.1128/MCB.20.22.8432-8446.2000

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Molecular and Cellular Biology, November 2000, p. 8432-8446, Vol. 20, No. 22
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

Multiple Homing Pathways Used by Yeast Mitochondrial Group II Introns

Robert Eskes,¹^, Lu Liu,¹ Hongwen Ma,² Michael Y. Chao,¹ Lorna Dickson,¹^, Alan M. Lambowitz,² and Philip S. Perlman¹^,^*

Department of Molecular Biology, University of Texas Southwestern Medical Center, Dallas, Texas 75390-9148,¹ and Institute for Cellular and Molecular Biology, Department of Chemistry and Biochemistry, and Section of Molecular Genetics and Microbiology, School of Biological Sciences, University of Texas at Austin, Austin, Texas 78712²

Received 16 February 2000/Returned for modification 14 April 2000/Accepted 17 August 2000

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

The yeast mitochondrial DNA group II introns aI1 and aI2 are retroelements that insert site specifically into intronless allelesby a process called homing. Here, we used patterns of flankingmarker coconversion in crosses with wild-type and mutant aI2 intronsto distinguish three coexisting homing pathways: two that werereverse transcriptase (RT) dependent (retrohoming) and one thatwas RT independent. All three pathways are initiated by cleavageof the recipient DNA target site by the intron-encoded endonuclease,with the sense strand cleaved by partial or complete reverse splicing,and the antisense strand cleaved by the intron-encoded protein.The major retrohoming pathway in standard crosses leads to insertionof the intron with unidirectional coconversion of upstream exonsequences. This pattern of coconversion suggests that the majorretrohoming pathway is initiated by target DNA-primed reversetranscription of the reverse-spliced intron RNA and completedby double-strand break repair (DSBR) recombination with the donorallele. The RT-independent pathway leads to insertion of the intronwith bidirectional coconversion and presumably occurs by a conventionalDSBR recombination mechanism initiated by cleavage of the recipientDNA target site by the intron-encoded endonuclease, as for groupI intron homing. Finally, some mutant DNA target sites shift upto 43% of retrohoming to another pathway not previously detectedfor aI2 in which there is no coconversion of flanking exon sequences.This new pathway presumably involves synthesis of a full-lengthcDNA copy of the inserted intron RNA, with completion by a repairprocess independent of homologous recombination, as found forthe Lactococcus lactis Ll.LtrB intron. Our results show that groupII intron mobility can occur by multiple pathways, the ratiosof which depend on the characteristics of both the intron andthe DNA target site. This remarkable flexibility enables groupII introns to use different recombination and repair enzymes indifferent hostcells.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Two self-splicing group II introns of the COXI gene of yeast mitochondrial DNA (mtDNA), aI1 and aI2, are mobile elements (reviewedin reference 8). In crosses between yeast strains carryingor lacking one or both of those introns, the introns insert sitespecifically in the intronless allele by a process known as homing(4, 10, 14). In wild-type crosses, most homing events occurby retrohoming, which depends on activities of both the intron-encodedreverse transcriptase (RT) protein and the intron RNA. The proteinfirst promotes splicing of the intron by facilitating formationof the catalytically active structure of the intron RNA, and itthen remains associated with the excised intron RNA lariat toform a ribonucleoprotein (RNP) particle that has RT and site-specificDNA endonuclease activities (7, 22, 23). Retrohoming isinitiated by this RNP endonuclease cleaving the DNA target sitelacking the intron. The intron RNA catalyzes its own insertioninto the sense strand by reverse splicing, and then the Zn domainof the intron-encoded protein cleaves the antisense strand ata site 10 nucleotides (nt) downstream in the 3' exon. The cleavedsite serves as the primer for first-strand cDNA synthesis in areaction known as target DNA-primed reverse transcription(TPRT).

In vitro, the aI2 RNP particles cleave the sense strand of a standard substrate primarily by a partial reverse splicing reactionthat joins the intron RNA lariat to the 3' exon (22). The aI1enzyme is similar in most respects, except that it is much moreefficient for full reverse splicing (~50%), which inserts thelinear intron RNA between the two DNA exons (21). Subsequentstudies showed that the proportion of full reverse splicing foraI2 is increased by certain DNA target site mutations (5).Group II intron homing and reverse splicing depend on three specificpairings between the intron RNA and the DNA target site (IBS1-EBS1,IBS2-EBS2, and $delta$ - $delta$ '), and consequently the target site specificitycan be altered by compensating changes in the target site andthe donor intron RNA (4, 5, 12). The protein componentof the endonuclease recognizes the upstream portion of the DNAtarget (positions $-$ 21 to $-$ 13) and contributes to DNA unwindingenabling the intron RNA to base pair to the DNA target betweenpositions $-$ 12 and +1 for the reverse splicing reaction. Additionalinteractions between the protein and the 3' exon region of theDNA target site (+1 to +10) are required for antisense strandcleavage (5).

In vivo homing tolerates sequence changes at some sites in the target exons (4, 10, 14). Both strain-specific polymorphismsand site-directed changes have been used as flanking markers incrosses to reveal that intron insertion is associated with coconversionof flanking exon sequences. For aI2 homing, there is very efficientcoconversion of markers for ca. 100 bp upstream but much lesscoconversion farther upstream and also less coconversion downstream.The initial explanation for this asymmetric coconversion was thatthe template for cDNA synthesis in retrohoming might be a pre-mRNAcontaining aI2 (14, 23). Using RNP particles from certainmutant strains, the aI2 RT was shown to utilize pre-mRNA as atemplate, initiating in the 3' exon at roughly the same positionas in TPRT reactions (7, 24).

Mutations of the YADD motif of the aI2 RT domain abolish RT activity but inhibit aI2 mobility only partially, indicating thatan active RT-independent homing pathway also exists (14). ThisRT-independent pathway is inhibited by mutations in the Zn (endonuclease)domain, indicating that it requires this function of the intron-encodedprotein. We subsequently showed that RT-deficient mutants stillhave the aI2-encoded endonuclease activity and that the levelof residual homing activity correlates with the level of endonucleaseactivity (22). Thus, RT-independent group II intron homing appearsto occur by a DNA-level pathway that is initiated by the intron-encodedendonuclease and completed by the very active double-strand breakrepair (DSBR) recombination system of yeast mitochondria (9).The excised intron RNA is essential for this pathway because itis crucial for DNA cleavage, but the intron RNA is not used asa template for cDNAsynthesis.

Detailed studies of flanking marker coconversion associated with aI1 homing better defined the two main homing pathways instandard crosses (4). Most aI1 retrohoming occurs with efficientunidirectional coconversion upstream. Because aI1 retrohomingoccurs without downstream coconversion, even in the part of thatexon that is copied by the RT (E2+1 to E2+10), the cleaved recipientDNA target site with its inserted aI1 RNA must be the initialtemplate for cDNA synthesis. In order to account for the efficientcoconversion of upstream markers, we proposed that aI1 retrohomingis a hybrid mechanism initiated by TPRT leading to the synthesisof a partial or complete cDNA of the intron, which can then invadea donor allele to initiate DSBR recombination. Homing of aI1 waslimited to RT-independent events by a mutation in the RT domain,and in that cross both upstream and downstream markers were coconverted,the pattern expected for conventional DSBR recombination eventsin this system. In wild-type aI1 crosses, about 80% of the recombinantprogeny have unidirectional upstream coconversion, indicativeof retrohoming, and 20% have bidirectional coconversion, indicativeof RT-independentevents.

Recent studies of homing of a group II intron, Ll.LtrB, from the gram-positive bacterium Lactococcus lactis, both in Escherichiacoli and in L. lactis (3, 13) revealed similarities to theyeast system but also several striking differences. Efficienthoming by Ll.LtrB is limited to retrohoming events that are independentof the host recA system. Also, Ll.LtrB is inserted without anycoconversion of flanking markers, and it was suggested that itsretrohoming depends on synthesis of full-lengthcDNAs.

The previously analyzed yeast aI2 crosses had useful 5' flanking markers but lacked markers in the first 10 bp of the 3' exonthat are needed to identify the template for initial cDNA synthesis(see Fig. 1) (14). In this study we constructed DNA target siteswith additional markers and used them to analyze aI2 homing. Inaddition, we took advantage of the earlier observation (5)that some mutations of the aI2 target site activate full reversesplicing by wild-type aI2 RNP particles. Thus, it was possibleto compare crosses in which either partial or full reverse splicingmight predominate. One mutant target site that increases boththe extent of reverse splicing and the proportion of full reversesplicing in vitro strongly activates a retrohoming pathway, previouslyundetected for aI2, in which the intron is inserted without coconversionof flanking exons, resembling the main pathway used by the Lactococcusintron. Our results indicate that the choice of a retrohomingpathway for aI2 is influenced strongly by the characteristicsof both the DNA target site and the intron, as well as by theDNA recombination and repair enzymes present inmitochondria.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Yeast strains and strain constructions. The COXI alleles of donor and recipient strains are denoted by a convention (4, 14) in which a superscript "+" indicatesthe wild-type intron, a superscript "o" indicates that the intronis absent, and other superscripts denote specific alleles. Threepreviously described aI2 donor alleles, 1^o2⁺ (previously called 1^o2^+t), 1^o2^YAAA, and 1^o2^P714T were used, each in the nuclear background of strain ID41-6/161(MATa ade1 lys1) (see reference 14). Donor mtDNAs havesix introns in the COXI gene (see Fig. 2A) and five introns inthe COB gene (14).

All 1^o2^o recipient strains have the nuclear background of strain GRF18 (MAT $alpha$ leu2 his3). The original COXI recipient allelefrom strain 1^o2^o Scap (also called GII-0 in reference 14) contains COXI exons1, 2, and 3 derived from Saccharomyces capensis. Sequence differencesbetween the 1^o2^o Scap allele and the Saccharomyces cerevisiae donor allele aresummarized in Fig. 1 and at the top of Table 1. New derivativesof the recipient COXI allele (the six shown in Fig. 1A plus $Delta$ E3)were constructed by site directed mutagenesis of plasmid pJVM161(4). In the $Delta$ E3 recipient allele positions E3+1 through E3+35are deleted. Each new allele was placed in mitochondria by biolistictransformation and transferred to 1^o2^o Scap mtDNA by recombination as described elsewhere (4).

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FIG. 1. Sequences of recipient alleles and base-pairing interactions with the intron RNA. (A) Diagram of the aI2 target site and sequence differences among recipient strains. The diagram shows the region of the COXI gene containing the target site for aI2 homing. The exon sequence containing the aI2 target site of the S. cerevisiae donor strain is shown with sequence differences between it and the 1^o2^o Scap recipient allele containing COXI exons 1 to 3 derived from S. capensis indicated as larger boldface letters. Nucleotides are numbered according to their distance from the aI2 insertion site, which is between E2 $-$ 1 and E3+1 (arrow and boldface vertical line). Other recipient alleles analyzed are derivatives of 1^o2^o Scap and are shown with nucleotide differences from the S. cerevisiae donor. Relevant sequence differences between donor and recipient COXI alleles outside of the region shown are indicated above the diagram. E1 $-$ 387 is a small insertion containing a HpaII site that is present in the donor but not in the recipient allele. As indicated at the bottom, the recognition site for aI2 homing extends from E2 $-$ 21 through E3+10 (5). (B) Effects of mutations on base pairing between the intron RNA and DNA target site. The diagram illustrates the known interactions between nucleotides of aI2 RNA and the sense strand of the aI2 target site. The conserved pairings IBS2-EBS2, IBS1-EBS1, and $delta$ - $delta$ ', spanning 7, 6, and 3 bp, respectively, are shown for the cross 1^o2⁺ × 1^o2^o Scap. Certain mutations alter one or another of those pairings, as shown. E2 $-$ 8G improves the EBS2-IBS2 pairing, changing a C-A pair to C-G. Mutations E2 $-$ 2T and E2 $-$ 5C exchange G-T and G-C base pairs in IBS1-EBS1. E3+2T destabilizes the extended $delta$ - $delta$ ' interaction of the original donor-recipient pair.

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TABLE 1. Analysis of crosses in which homing is associated with coconversion of flanking exon sequences^a

Flanking markers in exons 2 and 3 are named according to their sequence and location on the sense strand relative to the aI2insertion site (5). For example, E3+23 defines the nucleotidein exon 3 that is 23 bp downstream from the aI2 insertion site;E3+23A is the allele in all recipient strains used here, and E3+23Tis the allele in all donor strains (see Tables 1 and 2). Becausemarkers in exon 2 are upstream from the aI2 insertion site, theyare designated E2 $-$ n (e.g., E2 $-$ 8). Sites in exon 1 are named relativeto the aI1 insertion site (e.g., E1 $-$ 6) (see Fig. 1 and Tables1 and 2). When a strain contains several markers in a givenexon (e.g., E3+2T and E3+5G) we use the shorthand form E3+2T+5G.

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TABLE 2. Analysis of crosses using recipient strains that support retrohoming without coconversion of flanking exon markers^a

Genetic methods. Cell cultures and crosses were carried out at 30°C using standard media (14). All recombinants analyzed were obtained bya multistep screen of progeny colonies from crosses as describedpreviously (4). Three parallel colony blots were used to identifyprogeny that resulted from homing (i.e., those that have the insertedaI2 together with the 3' end of the recipient COXI gene plus therecipient COB allele). Southern hybridizations were used to confirmthat each isolate contains a recombinant COXI gene. Each strainwas also scored on a DNA blot for the polymorphic HpaII site 5'of the COXI coding sequence (E1 $-$ 387). RNA was extracted from aculture of each strain, and a cDNA was made by RT PCR using primersin COXI exons 1 and 4. The cDNA was then sequenced to score thatstrain for flanking markers (4).

Oligonucleotide probes used to screen colony blots were as follows: aI2, oligonucleotide aI2-S-4384, containing nt 4384 to4412 of the COXI gene; aI5 $gamma$ , oligonucleotide Snab-AS, complementaryto nt 9024 to 9041 of the COXI gene; and bI1, oligonucleotidebI1-S-748, containing nt 748 to 769 of bI1. The primer for reversetranscription of COXI mRNA is M2-AS, which is complementary toCOXI nt 6851 to 6869 (exon 4). The primer for amplification ofthe sense strand of COXI cDNA is JME1-S containing nt $-$ 6 to +15of the COXI exon 1; that oligonucleotide was biotinylated at its5' end so that the sense strand could be purified using magneticbeads. The primer for sequencing the resulting amplified cDNAis oligonucleotide E4-AS, which is complementary to nt 6730 to6751 of exon 4. All COXI and COB gene coordinates are as definedelsewhere (1, 18).

Analysis of homing in crosses. Homing of aI2 in crosses was analyzed by the restriction fragment length polymorphism (RFLP) procedures used previously (14).Briefly, mixed diploid progeny from tens of thousands of matingswere grown for about 20 generations following mating, and mtDNAwas isolated from a 200-ml culture by lysis of spheroplasts followedby banding in bisbenzimide CsCl gradients. The purified mtDNAwas desalted, digested with HpaII plus BamHI, and analyzed ina 1% agarose gel. Gels were blotted to Hybond-N nylon membranes(Amersham) and hybridized with a 5' end-labeled oligonucleotideprobe complementary to sequences in COXI exon 1 to determine theproportion of progeny with parental and nonparental COXI alleles.A blot of HincII-digested mtDNA was hybridized with a COB intron4 probe to determine the ratio of parental mtDNAs. The resultingsignals were quantitated with a PhosphorImager (Molecular Dynamics)using ImageQuant software. Each cross was carried out at leastin duplicate, and each DNA sample was analyzed at least twiceand some were analyzed manytimes.

The parameter "percent homing" for each cross measures the percentage of recipient COXI alleles that acquired aI2 by homing(14). For crosses with >20% homing, the value was calculatedusing the following formula: percent homing = [(COB-R $-$ COXI-R)/COB-R]× 100, where COB-R is the fraction of progeny with the recipientCOB allele and COXI-R is the fraction of progeny with the recipientCOXI allele. In the crosses shown in lanes 4 and 5 of Fig. 4C,where homing is <20%, the measured fraction of progeny with therecombinant COXI allele (REC) was used in place of (COB-R $-$ COXI-R)in the above formula. That approximation is more accurate thanusing the measured COXI-R in those cases where COXI-R is nearlythe same value as COB-R but could underestimate the level of homingby as much as 20% due to the small proportion of homing productsthat score as donor-like due to coconversion of the far-upstreammarker E1 $-$ 387.

Reverse splicing and DNA endonuclease assays. DNA substrates for reverse splicing and DNA endonuclease assays were 240-bp double-stranded DNAs generated by PCR. First,a region extending from exon 1 to intron 3 of the COXI gene wasamplified directly from recipient yeast cells by an initial PCRusing primers yt1 (nt 1 to 23 of COXI exon 1) and aI3 (complementaryto nt 5694 to 5722 of aI3). The initial PCR product was extractedwith phenol-chloroform-isoamyl alcohol, ethanol precipitated,purified in a 2% agarose gel, and then used as template for asecond PCR (25 cycles) with the same primers in the presence of[ $alpha$ -³²P]dTTP to obtain internally labeled substrate or with 5'-end-labeledprimer aI3 to obtain substrate labeled at the 5' end of the antisensestrand. The conditions for PCR and labeling were as describedelsewhere (22, 23). The final PCR product was purified ina 2% agarose gel for reverse splicing assays or in a nondenaturing6% polyacrylamide gel for DNA endonucleaseassays.

For reverse splicing and DNA endonuclease assays, ³²P-labeled DNA substrate (~150,000 cpm) was incubated with mtRNP particles(0.025 optical density at 260 nm unit) for 20 min at 37°C, asdescribed elsewhere (22, 23). Reverse splicing products weredenatured with glyoxal and analyzed in a 1% agarose gel, and endonucleaseproducts were analyzed in a denaturing 6% polyacrylamide gel.The gels were dried and quantitated with aPhosphorImager.

	RESULTS

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Flanking marker coconversion associated with aI2 homing. Our initial analysis of coconversion of exon markers flanking group II intron insertion sites was in a cross between a donorstrain carrying both aI1 and aI2 (1⁺2⁺) and a recipient strain lacking both introns (1^o2^o Scap) (14). The COXI exons of that recipient strain originatedin an isolate of S. capensis and differ in sequence from thoseof the S. cerevisiae donor strain at seven positions shown inFig. 1A (E1 $-$ 387, E1 $-$ 20, E1 $-$ 11, E1 $-$ 6, E2 $-$ 27, E2 $-$ 8, and E3+23).In nearly all of the intron homing events in that cross both aI1and aI2 were inserted into the recipient allele. All markers werescored in five individual recombinants, and E1 $-$ 387 and E2 $-$ 27 werealso analyzed as RFLPs in mtDNA isolated from a large sample ofprogeny cells. The homing events occurred with essentially quantitativecoconversion of the proximal upstream markers, E1 $-$ 20 through E2 $-$ 8,but only ~20% coconversion at the farthest upstream marker, E1 $-$ 387,and ~60% at the sole downstream marker, E3+23. Subsequent experimentsshowed that one of the point mutations in exon 1 of the recipientstrain blocks the independent mobility of aI1 (4) so that theefficient homing of aI1 in those crosses resulted solely fromcoconversion in aI2-initiatedevents.

To obtain control data for this study, we analyzed coconversion of flanking markers in the cross 1^o2⁺ × 1^o2^o Scap (Tables 1 and 3, cross A1), which uses a donor strainthat contains aI2 but not aI1 together with the same recipientstrain used in the original study. As reported previously (14),~89% of the recipient alleles acquire aI2 in this cross (Fig.2B, lane 3). Most aI2 insertions occur without coconversion ofthe HpaII site present at E1 $-$ 387 of the donor strain, forminga nonparental allele that gives a 1.8-kb HpaII fragment in a HpaII-BamHIdigest (Fig. 2A). The remaining aI2 insertions occur with coconversionof that HpaII site present at E1 $-$ 387 of the donor strain and arerecovered as an excess of donor-like alleles (1.2-kb HpaII-BamHIfragment) (see reference 14). The negative control cross, inwhich aI2 homing was inactivated by deleting the 35-bp exon 3of the recipient strain (Fig. 2B, lane 4), shows that the appearanceof the recombinant allele and the excess of donor alleles observedin the other crosses depend on an active target site. Eleven recombinantprogeny from cross A1 were scored for the seven flanking markers,and the results are summarized in Table 1. Coconversion of markersat E1 $-$ 20, E1 $-$ 11, E1 $-$ 6, E2 $-$ 27, and E2 $-$ 8 was 100% (11 of 11). Therewas much less coconversion at the most distal markers E1 $-$ 387 andE3+23, ~36% (4 of 11) for each. This outcome is basically thesame as was obtained in the 1⁺2⁺ × 1^o2^o cross, where both aI1 and aI2 are inserted together most of thetime.

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FIG. 2. Analysis of aI2 homing in crosses. (A) Diagram of the cross between strains with the 1^o2⁺ and 1^o2^o COXI alleles. The donor (1^o2⁺) and recipient (1^o2^o) COXI alleles and the major 1^o2⁺ recombinant allele resulting from aI2 homing are diagrammed. Relevant restriction sites and the sizes of restriction fragments that are diagnostic for each parent and the major recombinant COXI allele are indicated. Not all progeny with the 1.8-kb allele have the same 3' COXI features shown in the diagram; some also have introns aI5 $alpha$ , $beta$ , and $gamma$ due to aI5 $alpha$ homing and associated coconversion of aI5 $beta$ and 5 $gamma$ (16). The probe used hybridizes with the indicated part of exon 1. H, HpaII site; B, BamHI site. (B) Outputs of COXI alleles in crosses. Crosses between the indicated donor and recipient strains noted were carried out as described in Materials and Methods, and the output of COXI alleles was measured using the HpaII-BamHI digest diagrammed in panel A. Lanes 1 and 2 show the parental donor and recipient alleles, respectively. Lanes 3 to 10 show results of crosses between the pairs of strains indicated above each lane. Each lane contains DNA from mixed progeny of tens of thousands of matings so that the observed ratio of alleles reflects the extent of homing. Recipient strain $Delta$ E3 is deleted for exon 3 (E3+1 through E3+35) and is a negative control in which the wild-type donor strain has no residual homing activity. Donor strain 1^o2^YAAA (lane 5) has missense mutations inactivating the aI2 RT activity. Sequence differences among the recipient strains in lanes 6 to 10 are defined in Fig. 1A. This gel is a representative outcome of these crosses, each of which was carried out at least in duplicate with analysis of two or more blots of each DNA sample. The same DNA samples were also scored for the output of alleles of the COB gene (as in reference 14), and the percentage of progeny with the recipient COB allele (COB-R) is indicated below the lanes. The percent COB-R alleles was used to calculate the percent homing, which is defined as the percentage of recipient COXI alleles that acquired aI2 by homing (see Materials and Methods for details about this calculation). The values shown below the lanes are for this gel, and mean values for each cross are provided in Table 3, column 1. A minor band present in some of the samples is due to cross-hybridization with other sequences in the DNA sample (compare lane 2 with lane 11).

Homing by an RT-deficient aI2 donor strain occurs with nearly quantitative coconversion in the downstream exon. Next, coconversion was measured in the cross 1^o2^YAAA × 1^o2^o Scap, reported earlier to carry out some RT-independent homing of aI2(14). This donor strain lacks RT activity due to a mutationof the YADD motif of the aI2 RT domain but still gives ~40% conversionof 1^o2^o alleles to 1^o2⁺ alleles (Fig. 2B, lane 5). Flanking markers were scored from10 recombinants from that cross, and the results are summarizedin Table 1 (cross A2). These data show that homing without RTactivity occurs with coconversion of nearby sites in the upstreamexons but much less coconversion at E1 $-$ 387 farther upstream (2of 10 events). It is striking that coconversion of the downstreammarker, E3+23, is substantially more efficient (~90%) than inthe control cross A1 (~36%). One of the recombinants from theRT-deficient cross (line 7) is donor-like at E2 $-$ 8, the closestmarker to the aI2 insertion site, but recipient-like at E2 $-$ 27and the other markers farther upstream. This recombinant likelyresulted from repair of the cleaved target site with little gappingprior to strand invasion. This aI2 cross yielded essentially thesame outcome as the analogous aI1 cross in which it was concludedthat RT-independent homing events are initiated by the intronendonuclease and completed by DSBR recombination (4).

Both major coconversion patterns in the RT-deficient cross (Table 1, lines 5 and 6) were present as minor recombinant typesin the wild-type aI2 cross (Table 1, lines 3 and 4). The simplestinterpretation is that intron homing in the wild-type cross isa mixture of retrohoming and RT-independent events in a 64/36ratio. According to this interpretation, the E3+23 marker (orother downstream markers; see below) is the key to determiningwhether a given recombinant is the product of one pathway or theother. Coconversion at E3+23 indicates an RT-independent, or DNAlevel, event whereas no coconversion there indicates an RT-dependent(retrohoming) event. Although it is formally possible that coconversionat E3+23 could occur in an RT-dependent event by using a resectedantisense strand as a primer for reverse transcription of donorpre-mRNA, findings presented here and elsewhere indicate thatthe reverse-spliced intron RNA and not the pre-mRNA is by farthe predominant template for cDNA synthesis (see the next sectionand Discussion). Furthermore, it is unlikely that an antisensestrand resected beyond position E3+23 would remain in positionto function as a primer for RT bound to the DNA targetsite.

Identification of the initial template for cDNA synthesis in aI2 retrohoming events. To investigate whether the pre-mRNA or inserted intron RNA is the initial template for cDNA synthesis in aI2 retrohoming,it was necessary to modify the target site of the recipient strainso that coconversion could be evaluated in the key interval fromE3+1 to E3+10. Guo et al. (5) analyzed point mutations of anS. cerevisiae aI2 target site in vitro and reported that mutationsat E3+5 and E3+8 (Fig. 1A) do not greatly affect reverse splicingor antisense strand cleavage. Mutations at a few other sites inhibitantisense strand cleavage, and several greatly increase the proportionof full reverse splicing (seebelow).

The mutations E3+5G and E3+8G were tested for effects on reverse splicing and antisense strand cleavage activities. TheseDNA substrates were prepared with a longer 5' exon than previously(5, 22) to better separate products of full and partial reversesplicing. The results of reverse splicing and DNA endonucleaseassays using RNP particles from strain 1^o2⁺ with several DNA substrates are shown in Fig. 3A. Both the E3+5G(lane 2) and E3+8G (lane 3) substrates are somewhat more efficientfor reverse splicing than the control substrate (lane 1) (ratiosof 1.7 ± 0.5 and 2.0 ± 0.5; see the legend to Fig. 3). In bothcases the proportion of full reverse splicing remains quite low:5 to 10% for both mutant substrates and the wild-type control(Scap). The E3+5G substrate is about as active as the controlfor antisense-strand cleavage, while the E3+8G substrate is inhibitedabout 60% (Fig. 3B, lanes 5 to 7).

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FIG. 3. Assays of reverse splicing and antisense strand cleavage activities of RNP particles from strain 1^o2⁺. (A) Reverse splicing activity with different DNA substrates. Internally labeled DNA substrates were prepared from the recipient strains shown above each lane and incubated with RNP particles from strain 1^o2⁺, as described in Materials and Methods. Each lane contains the same number of counts of each substrate and the same amount of RNP particles. Size standards are shown to the left, and the substrate and the products of reverse splicing (RS) are identified to the right. The levels of reverse splicing products on this gel and four replicates were quantitated, and the mean values are reported in the text. (B) Antisense strand cleavage activity with different DNA substrates. DNA substrates from the indicated recipient alleles were made by PCR with a 5'-end label on the antisense strand, and antisense strand cleavage reactions were carried out with RNP particles from strain 1^o2⁺. The antisense strand is cleaved between nucleotides E3+10 and E3+11. The amount of cleavage product was quantitated on this gel and one repeat, and the values are reported in the text.

The E3+5G and E3+8G mutations were transformed into mtDNA, and the resulting recipient strains were analyzed in crosses withthe standard 1^o2⁺ donor strain (Fig. 2B, lanes 7 and 8). Each of those allelesis somewhat less efficient for aI2 homing than is the parentalallele (74 and 81% homing versus 89% in the control; see Table3 for the average of all experiments). Individual progeny resultingfrom aI2 insertion were isolated from each cross and scored forflanking markers, and the resulting data are summarized in Table1, crosses B (E3+5G) and C (E3+8G).

In both crosses, about half of the homing events show coconversion at upstream markers but have both downstream markers fromthe recipient strain (E3+5G or E3+8G plus E3+23A) (Table 1, crossB, lines 8 and 9, and cross C, lines 12 and 13). As explainedabove, this pattern is expected to result from retrohoming inwhich initial cDNA synthesis uses the 5' overhang of the recipientexon 3 DNA and not pre-mRNA as template. Most of the remainingrecombinants show coconversion of both upstream and downstreammarkers typical of RT-independent homing (compare Table 1, lines10 and 11 and lines 14 to 16 with lines 5 to 7). Among these,the recombinants in lines 10 and 11 (cross B) and lines 14 and15 (cross C) differ only at the distal upstream marker, E1 $-$ 387,with only a minority being coconvertedthere.

Cross C yielded four recombinants with coconversion patterns different from those observed in the previous crosses. The recombinantsof line 13 show no coconversion downstream but are coconvertedupstream only through the E1 $-$ 11 marker; they presumably resultfrom the major retrohoming pathway, with resolution upstream betweenE1 $-$ 11 and E1 $-$ 20. The recombinant of line 16 is coconverted atboth sites in exon 3 but is not coconverted at any upstream site.This pattern likely results from an RT-independent homing eventin which there was resolution between E2 $-$ 1 and E2 $-$ 8. Finally,the recombinant in line 17 retains the recipient marker at E3+23but has donor markers at E3+8 and at upstream sites through E1 $-$ 20.This is the pattern predicted to result from retrohoming eventsin which the pre-mRNA was the template for cDNA synthesis; however,it could also have resulted from an RT-independent event in which3' resolution occurred between E3+8 and E3+23. This same patternis detected in a single event in three other crosses using thissame donor strain analyzed below (Table 1, cross D, line 25;Table 2, cross E1, line 8; and Table 2, cross G, line 28). Evenif all four such events resulted from retrohoming using pre-mRNAas a template, that mechanism would account for no more than aminor fraction of aI2retrohoming.

Retrohoming of aI2 with efficient full reverse splicing. Our studies show that the standard alleles of aI1 and aI2 are comparably efficient for homing (4, 14). However, unlikeaI1, which supports efficient full reverse splicing (4, 20,21), >90% of the reaction of aI2 RNP particles with the 1^o2^o Scap DNA substrate is partial reverse splicing (22). Detailedanalysis of the aI2 target site (5) showed that RNP particlesfrom the wild-type aI2 donor strain can carry out efficient fullreverse splicing, but only when a suitable variant DNA targetsite is used. Specifically, variants of the S. cerevisiae targetsite with point mutations at E3+1 and E3+2 activated a high proportionof full reversesplicing.

Crosses A1, B, and C of this study employed recipient alleles that support little (<10%) full reverse splicing, and the dataof Table 1 indicate that each cross has about 50% retrohomingevents (see Table 3). Published aI1 homing experiments, in whichthe proportion of full reverse splicing is at least 50%, havea higher proportion of retrohoming events (70 and 90% in two differentcrosses) (4). Thus, we wondered whether the nature of the reversesplicing reaction influences the ratio of retrohoming and DNAlevel events. In this and the next sections we analyzed aI2 homingin crosses using recipient strains with target sites that supportelevated levels of full reverse splicing and also have flankingmarkers that permit coconversion patterns to bescored.

The recipient strain E2 $-$ 2T $-$ 5C/E3+2T+5G was constructed some years ago for another purpose (15). It has four silent mutationsflanking the aI2 insertion site, two in exon 2 (E2 $-$ 2T and E2 $-$ 5C)that make compensating changes in the IBS1-EBS1 pairing (see Fig.1) and two in exon 3 (E3+2T and E3+5G). As shown in Fig. 3A, lane4, this mutant target site has slightly higher overall reversesplicing activity than the Scap target site (1.4 ± 0.7-fold infive experiments) and also supports an elevated proportion offull reverse splicing (28 to 49%). The level of antisense strandcleavage is about the same as with the Scap target site (Fig.3B, lanes 8 and 5, respectively). Significantly, this was thefirst recipient allele available for aI2 that supports a highproportion of full reverse splicing similar to that obtained foraI1 (4, 21).

The E2 $-$ 2T $-$ 5C/E3+2T+5G recipient strain supports about 84% aI2 homing in crosses with the standard donor strain (Fig. 2, lane9, and Table 3, column 1). Coconversion patterns were analyzedfor 40 recombinant progeny from this cross, and the findings aresummarized in Table 1, cross D (lines 18 to 25). Nearly all ofthese progeny have one of the coconversion patterns already discussedas resulting from retrohoming (lines 18 to 21) or RT-independenthoming (lines 22 to 24). The recombinant in line 25 resemblesthe one in line 17, discussed above, in being coconverted at upstreammarkers and proximal downstream markers (E3+2 and E3+5) but notat E3+23. Overall, the percentage of retrohoming (~52%) is aboutthe same as in the previous crosses (Table 3, column 3). Thissample of recombinant progeny is large enough to provide clearevidence for a gradient of upstream coconversion in both retrohomingand RT-independent homing events.

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TABLE 3. Summary of homing events analyzed in crosses A1 to G^a

These data show that products of aI2 homing with a DNA target site that supports 28 to 49% full reverse splicing in vitroare surprisingly similar to those in crosses A1, B, and C withtarget sites that support <10% full reverse splicing. These crosseshave similar overall levels of homing, and about half of the homingevents have coconversion patterns indicative of retrohoming, whilethe remainder have coconversion patterns like the progeny of theRT-independent cross (cross A2) (Table 3, columns 1 and 3). Thus,a DNA target site that increases the proportion of full reversesplicing in vitro does not, by itself, alter the ratio of retrohomingto RT-independent homing or the manner in which retrohoming eventsarecompleted.

A new recipient strain activates retrohoming without coconversion. We next constructed another recipient allele (E2 $-$ 8G E3+2T+5G) that also elevates the extent of full reverse splicing but givesa different outcome in crosses. All target sites used in crossesA through D have the E2 $-$ 8A allele, derived from the 1^o2^o Scap COXI gene. That allele introduces an A-C mismatch into the7-bp IBS2-EBS2 pairing with the donor intron RNA (Fig. 1B). Aderivative of the 1^o2^o Scap target site was made with E2 $-$ 8G to restore a G-C pair, andit was evaluated as an endonuclease substrate. As shown in Fig.3A, lane 5, the E2 $-$ 8G mutation increased the extent of reversesplicing relative to the control substrate ca. fourfold (3.9 ±0.2 compared with lane 1), but the proportion of full reversesplicing events remained low (12% ± 2%). This mutation also elevatedthe level of antisense-strand cleavage ~30% (Fig. 3B, lane 9).Next, the E2 $-$ 8G mutation was combined with the E3+2T mutation,which stimulates full reverse splicing (5), and the E3+5G allele(analyzed above), and the resulting triple mutant was analyzedin vitro. The E2 $-$ 8G E3+2T+5G target site supports ~5 times morereverse splicing than does the Scap substrate and gives a higherproportion of full reverse splicing (24% ± 4%), though not asmuch as the allele used in cross D (compare lanes 4 and 6 of Fig.3A). The triple-mutant substrate also supports 1.5- to 2.1-foldmore antisense strand cleavage than does the Scap substrate (Fig.3B, lane10).

These new alleles were transformed into mtDNA, and their activity in aI2 homing was analyzed in crosses. As shown in Fig.2B, E2 $-$ 8G (lane 10) and E2 $-$ 8G E3+2T+5G (lane 11) are both veryefficient homing sites (~90% homing; Table 3, column 1). Recombinantprogeny were first analyzed from the cross with the E2 $-$ 8G E3+2T+5Grecipient, and the resulting coconversion patterns are summarizedin Table 2, cross E1 (lines 1 to 8). Based on the fraction ofprogeny without coconversion in exon 3, this cross has about 45%retrohoming events (lines 1 to 4), and the rest have patternsexpected for RT-independent homing (lines 5 to8).

Of the 21 progeny attributed to retrohoming, 12 have patterns similar to those in the other crosses, with coconversion upstreambut not downstream of the inserted intron (lines 1 to 3). Theremaining nine progeny summarized in Table 2, line 4, have anew pattern of flanking markers not observed in any of the previousaI2 crosses: the intron was inserted with no coconversion upstreamor downstream. That pattern was observed at a much lower frequencyin one aI1 cross (4), where it was interpreted as resultingfrom retrohoming with resolution before the first 5' marker. Thispattern can also be explained by postulating a retrohoming pathwayanalogous to that for the Lactococcus Ll.LtrB intron, in whicha full-length cDNA is made and events are completed without switchingto DSBR recombination. Evidently, some feature of this mutanttarget site activates this retrohoming pathway, so that it nowaccounts for a substantial fraction (~43%) of the retrohomingevents.

Lack of coconversion with the E2 $-$ 8G E3+2T+5G substrate is not due to modification of the DSBR pathway. To exclude the possibility that the E2 $-$ 8G E3+2T+5G target site simply limits the extent of coconversion via the DSBR recombinationpathway, we carried out an additional cross using this recipientallele with a donor strain that lacks RT activity (cross E2).As summarized in Table 2, lines 9 to 11, all of the homing eventsin that cross occur with efficient bidirectional coconversion,as in cross A2 involving the RT-deficient donor strain with thestandard 1^o2^o Scap target site. The majority of homing events show coconversionat all markers, except for the most distal upstream marker (E1 $-$ 387).Two events are coconverted at all markers (line 9), and two arecoconverted at all markers except E1 $-$ 387 and E3+23 (line 11).These findings indicate that the retrohoming without coconversionobserved in cross E1 does not reflect modification of the DSBRpathway by the E2 $-$ 8G E3+2T+5G targetsite.

Both E2 $-$ 8G and E3+2T contribute to aI2 retrohoming without coconversion. To determine which changes in the E2 $-$ 8G E3+2T+5G target site induce this alternative mode of retrohoming, we analyzed coconversionpatterns in crosses using recipient strains, each carrying oneof the mutations present in the E2 $-$ 8G E3+2T+5G strain. Cross B,presented above, using a recipient strain with E3+5G, had no progenywith this new coconversion pattern (Table 1, lines 8 to 11).The E2 $-$ 8G recipient strain was analyzed in cross F (Table 2,lines 15 to 20), and the E3+2T recipient strain was analyzed incross G (Table 2, lines 21 to 28). E3+2T and E3+5G support somewhatless homing than does E2 $-$ 8G (Table 3, column 1), though all threecrosses have similar proportions of retrohoming (Table 3, column3). The E2 $-$ 8G allele supports ~13% retrohoming without coconversion(Table 2, line 18), while E3+2T supports ~39% (line 24). We concludethat both E2 $-$ 8G, which increases the overall level of reversesplicing, and E3+2T, which increases the proportion of full reversesplicing, contribute to the activation of retrohoming withoutcoconversion. The recipient strain used in the previous crossD (E2 $-$ 2T $-$ 5C E3+2T+5G) also contained E3+2T and had an elevatedlevel of full reverse splicing; however, it did not give detectableretrohoming without coconversion, presumably due to interferenceby one or both of the markers, E2 $-$ 2T and E2 $-$ 5C, that are uniqueto thatcross.

An endonuclease mutation favors RT-dependent pathways over RT-independent ones. The mutation P714T in the Zn domain of the aI2 protein strongly inhibits both reverse splicing and antisense-strand cleavageactivity with the 1^o2^o Scap DNA substrate and eliminates detectable homing with thatrecipient strain (14, 22, 23). Significantly, P714T is theonly Zn domain mutation in our collection that retains high RTactivity, which is activated even in the absence of the normalTPRT primer (7, 24). We analyzed reverse splicing and antisensestrand cleavage activity of RNP particles from strain 1^o2^P714T using the 1^o2^o Scap and E2 $-$ 8G E3+2T+5G DNA substrates. As shown in Fig. 4A,RNP particles from the mutant strain have a very low level ofreverse splicing activity with the 1^o2^o Scap substrate and a higher level of activity with the E2 $-$ 8GE3+2T+5G substrate (~10% of the control reaction using wild-typeRNP particles; compare lanes 2 and 4 of Fig. 4A). It is strikingthat nearly all of the reaction with the latter substrate is fullreverse splicing. The P714T RNP particles have ~8% of the controllevel of antisense strand cleavage activity with the 1^o2^o Scap substrate and a somewhat higher level (20%) with the E2 $-$ 8GE3+2T+5G substrate (Fig. 4B, lanes 7 and 8).

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FIG. 4. Analysis of effects of the Zn domain mutation P714T on reverse splicing, antisense strand cleavage, and homing. (A) Reverse splicing. Internally labeled DNA substrates were prepared from the recipient strains shown above each lane and incubated with RNP particles from strain 1^o2⁺ (WT) and 1^o2^P714T (P714T), as described in Fig. 3A. Size standards are shown on the right, and the substrate and products of reverse splicing are identified on the left. The levels of products were quantitated, and the values are reported in the text. (B) Antisense strand cleavage. DNA substrates from the recipient alleles shown above the lanes were made by PCR with a 5'-end label on the antisense strand, and antisense strand cleavage reactions were carried out with RNP particles from the wild-type (WT) and P714T strains as in Fig. 3B. The amounts of cleavage product were quantitated, and the values are reported in the text. (C) Homing in 1^o2^P714T × 1^o2^o crosses. Crosses between the Zn domain mutant P714T donor strain and the indicated recipient strains were carried out and analyzed as in Fig. 2B. The RFLP alleles are as diagrammed in Fig. 2A. Lanes 1 and 2 contain DNA from the parental strains, and lane 3 contains DNA from the control cross between 1^o2⁺ × 1^o2^o E2 $-$ 8G E3+2T+5G (cross E1, see Table 2). Data for cross E3 are shown in lanes 6 and 7. The parameters "% COB-R" and "% homing" are as defined in Fig. 2 and in Materials and Methods.

As shown in Fig. 4C, the P714T donor strain has a very low level of homing with the 1^o2^o Scap recipient (~3%) and a much higher level of homing in thecross with the E2 $-$ 8G E3+2T+5G recipient (~70%). Crosses with theother recipient strains demonstrate that the higher level of homingshown here is mainly due to the mutation at E2 $-$ 8G with a smallcontribution from E3+2T (not shown). Flanking marker coconversionpatterns were analyzed in 14 progeny from the cross 1^o2^P714T × 1^o2^o E2 $-$ 8G E3+2T+5G and the results are summarized as cross E3 inTable 2. Strikingly, this cross has the highest proportion ofretrohoming events in this study (~86% versus ~50% in the othercrosses), divided equally between events with and without upstreamcoconversion (Table 2, lines 12 and 13). Only 2 of the 14 eventsscored have the coconversion pattern predicted for RT-independenthoming (line 14). This cross shows that a combination of donorand recipient alleles can make retrohoming without coconversionmore prominent by reducing the fraction of homing intermediateschanneled through the RT-independent pathway. This outcome mayresult from the combined effects of the greatly increased proportionof full reverse splicing, the decreased rate of antisense strandcleavage, and the activation of RTactivity.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

This study provides genetic and molecular data that define three major pathways of site-specific homing of the group II intronaI2 of yeast mtDNA (Fig. 5 and 6). All three pathways are initiatedby cleavage of the recipient DNA target by the intron endonuclease,with the sense strand cleaved by reverse splicing and the antisensestrand cleaved by the endonuclease (Zn) domain of the intron-encodedprotein (Fig. 6). In the retrohoming pathways, the fully or partiallyreverse spliced intron is used as the template for cDNA synthesis,whereas in the RT-independent pathway the double-strand breakat the target site leads to insertion of an intron copy by DSBRrecombination as in group I intron homing. Although all of thestrains used here are wild type for mitochondrial recombination,some retrohoming events occur without coconversion of flankingexon sequences and are presumably completed by a repair mechanismindependent of the homologous recombination system (Fig. 6). Wefind that the choice and relative levels of the different homingpathways are strongly influenced by specific nucleotides of thetarget site and by mutations of the intron-encoded protein.

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FIG. 5. Coconversion patterns associated with aI2 homing. The first two lines are diagrams of the aI2 donor and recipient alleles used in the crosses analyzed here. These crosses yield three major coconversion patterns in various proportions as discussed in the text. Pattern 1, in which there is efficient coconversion of markers in both 5' and 3' exons, results from the main pathway for RT-independent homing in which cleavage of the DNA target site is followed by DSBR (see also Fig. 6d). Pattern 2, in which there is efficient coconversion of markers in the 5' exon but no coconversion in the 3' exon, results from the major retrohoming pathway (Fig. 6b and c). Pattern 3, in which there is no coconversion associated with aI2 insertion, results from retrohoming events that are activated by the E2 $-$ 8G and E3+2T mutations of the recipient strain (Fig. 6a). Also shown are three minor coconversion patterns that reveal a gradient of coconversion. Patterns 1a and 1b result from RT-independent homing events, while pattern 2a results from retrohoming events.

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FIG. 6. Different pathways used for aI2 homing. The diagram summarizes features of the aI2 homing pathways analyzed in this study. The donor and recipient alleles are shown in the first line. Sense and antisense strands of the donor and recipient DNAs are identified, and the strand polarity is indicated by half arrowheads at the 3' ends. White strands indicate recipient DNA exons, black strands indicate donor DNA exons, and thick gray strands indicate intron DNA. The donor strain synthesizes aI2 RNP particles containing excised intron RNA (thick dashed lines) and the intron-encoded RT protein. Homing is initiated by partial or full reverse splicing into the aI2 DNA target site. The next line shows the products of partial and full reverse splicing, which are intermediates in all of these homing pathways. Each intermediate can potentially be reverse transcribed by the intron-encoded RT to yield partial or full-length cDNAs (gray lines). In pathway a, a full-length cDNA synthesized from fully reverse spliced intron RNA leads to retrohoming via a repair process that does not appear to involve recombination. This pathway results in insertion of the intron into the recipient DNA with no coconversion of flanking exon sequences, as indicated at the bottom of the figure. In pathways b and c, incomplete cDNAs synthesized from fully or partially reverse spliced intron RNA complete retrohoming by using the mitochondrial DSBR recombination system are shown. The figure illustrates strand invasion of the donor DNA by the cDNA and completion of the intron DNA synthesis using the donor DNA as template with copying beginning in the intron and extending into the 5' exon, followed by strand exchange back to the recipient DNA. Subsequent steps, including removal of the intron RNA and synthesis of the opposite DNA strand, are not shown. These events result in insertion of the intron with unidirectional coconversion of upstream exon sequences. In the RT-independent pathway d, a cleaved DNA target site containing partially reverse-spliced intron RNA leads to homing via gapping and strand invasion of the donor mtDNA. The same outcome could result from a cleaved DNA target site that initially contains a fully reverse spliced intron RNA (not shown, for simplicity). The RT-independent pathway results in insertion of the intron with coconversion of both upstream and downstream exon sequences, as in group I intron homing.

Products of RT-independent homing have a distinctive coconversion pattern. Crosses A2 and E2, in which the donor strain lacks RT activity, define a surprisingly efficient RT-independent homing pathwayfor aI2. This pathway is initiated by cleavage of the intronlessrecipient allele by the aI2 endonuclease, which remains activein the RT-deficient mutant (22), and leads to aI2 insertionwith bidirectional coconversion of flanking markers (Fig. 5, pattern1), as expected for a conventional DSBR recombination mechanism(see also reference 3). The coconversion of markers downstreamfrom the antisense strand cleavage site presumably results fromgapping of the cleaved target site before strand invasion of thedonor mtDNA (Fig. 6d).

In crosses with wild-type donor strains, retrohoming and RT-independent homing occur concurrently. Importantly, the activityof the RT-independent pathway for aI2 (36 to 50% homing in crosseswith the RT-deficient donor strains) is sufficient to accountfor all of the events involving bidirectional coconversion incrosses with wild-type donor strains (36 to 58%) (Table 3). Bycontrast, crosses with RT-deficient mutants of aI1 gave about46% homing, whereas only about 20% of the progeny of wild-typedonor crosses showed bidirectional coconversion (4). This situationlikely reflects that following antisense strand cleavage thereis competition among factors that favor the retrohoming or RT-independentpathways (Fig. 6). For example, retrohoming requires the retentionof the inserted intron RNA in the cleaved target site long enoughfor initial cDNA synthesis to occur, while RT-independent homingmay be favored by removal of the RNA to facilitate end resectionand strand invasion. Also, resection of the 3' end of the antisensestrand by a 3' exonuclease (Fig. 6) may divert intermediates awayfrom retrohoming by placing the primer for cDNA synthesis in aposition where it is less accessible to the RT. The preferentialuse of the retrohoming pathway in wild-type donor aI1 crossesmay reflect that the coupling between antisense strand cleavageand that initiation of reverse transcription is tighter for aI1than foraI2.

The major retrohoming pathway for aI2 uses reverse spliced intron RNA as a template for cDNA synthesis. Initially, we suggested that the pre-mRNA may be the initial template for cDNA synthesis in aI2 retrohoming (14). The subsequentdiscovery that intron RNA inserts into the DNA target site byreverse splicing did not exclude that hypothesis but supporteda scenario in which the template for TPRT is the reverse splicedintron RNA (21, 22). As shown previously for aI1 (4), thesemodels can be distinguished by analyzing coconversion patternsin the 3' exon, particularly in the region +1 to +10, which couldbe copied from either the donor pre-mRNA or the 5' overhang ofthe sense strand in the cleaved recipient DNA. A key feature ofthe present study was the development of new markers between E3+1and E3+10 so that these two hypotheses could be distinguishedforaI2.

Among 81 progeny attributed to retrohoming in six suitably marked crosses using the wild-type (1^o2⁺) donor strain (crosses B, C, D, E1, and G), 77 retain the recipientmarkers at all positions in the 3' exon, including the key regionbetween E3+1 and E3+10. This finding shows that by far the majorretrohoming pathway for aI2 involves the RT copying the 5' overhangof the sense strand of the cleaved DNA target site (Fig. 6a toc). This conclusion is also supported by in vitro evidence thatthe reverse spliced intron is the predominant template for cDNAsynthesis in TPRT reactions of both aI1 and aI2 (20, 24).

Only 5% of the inferred retrohoming products (4 of 81) have the coconversion pattern expected to result from use of pre-mRNAas the initial template (donor markers between E3+1 and E3+10,recipient marker at E3+23; Table 1, lines 17 and 25, and Table2, lines 8 and 28). This same pattern was obtained at an evenhigher frequency in crosses using the RT-deficient donor strain(10% of events in cross A2; 17% of events in cross E2) and wasalso evident in a cross with an RT-deficient aI1 donor strain(21%) (4). Clearly, this pattern can also result from a subsetof RT-independent events in which downstream gapping does notextend as far as E3+23.

Of the 77 retrohoming events that have no downstream coconversion, 79% are coconverted for some or all of the upstream markers.Thus, the major retrohoming pathway inserts aI2 with no coconversiondownstream but very efficient coconversion upstream. As proposedfirst for aI1, the efficient coconversion of upstream markersis explained by the hypothesis that most aI2 retrohoming eventsare completed by DSBR recombination (see Fig. 6b and c). In thatcase, retrohoming does not require synthesis of a full-lengthcDNA of the inserted intron. Pausing of cDNA synthesis at siteswithin the intron may be followed by the incomplete cDNA initiatingstrand invasion of a donor mtDNA (Fig. 6b and c). Target sitesin which the intron is inserted by partial reverse splicing maybe inefficient templates for cDNAs longer than 17 nt, due to thestrong stop at the lariat branch point. Pausing there may sometimesbe followed by template switching, either to an excised intronRNA or to an aI2-containing pre-mRNA, leading to synthesis oflonger cDNAs that initiate gap repair (not shown in Fig. 6). Afull-length cDNA copy of the reverse spliced intron could alsoinitiate gap repair. If there is any read-through of lariat branchpointsduring cDNA synthesis, it appears to be highly accurate becausenine products of retrohoming from crosses B and C, where thereis little full reverse splicing in vitro, were found to have thewild-type intron sequence at and around the branch nucleotide(L. Liu and P. S. Perlman,unpublished).

A coconversion gradient supports a role for recombination in group II intron homing. In the present work, we analyzed enough progeny to obtain clear evidence for a gradient of coconversion upstream of the introninsertion site in both retrohoming and RT-independent events (seeFig. 5, patterns 1a, 1b, and 2a). Summing up all of the crossesusing the wild-type donor strain, 23% of the progeny (47 of 203)were coconverted at the most upstream marker, E1 $-$ 387 (see Fig.1), and 124 of the remaining 156 were coconverted at the nextclosest site, E1 $-$ 20. Assuming that this pattern arises duringcompletion of events by DSBR, then ~62% of events resolve betweenE1 $-$ 20 and E1 $-$ 387, while ~23% resolve upstream of E1 $-$ 387. Fourteenprogeny (~7%) result from resolution in the 56 bp between theaI2 insertion site and E1 $-$ 20. This gradient of coconversion supportsthe inference that recombination is a key factor in generatingthe upstream coconversion in both the major retrohoming pathwayand the RT-independentpathway.

Of the 127 RT-independent homing events scored in all of these crosses, 124 (98%) are coconverted at the nearest upstreammarker and 121 (95%) are coconverted at the most distant exon3 marker, E3+23. Evidently when downstream gapping of cleavedtarget sites occurs, it progresses beyond E3+23 most of the time.These data show clearly that coconversion is bidirectional inthe RT-independent homing pathway. The two progeny of cross E2that are coconverted at E3 sites proximal to the intron but havethe recipient allele at E3+23 (Table 2, line 11) indicate a gradientof coconversion downstream from the intron insertionsite.

Insertion of mobile group I introns into target sites in yeast mtDNA occurs by DSBR and is associated with efficient coconversionof flanking markers (8). In yeast mitochondria, coconversionhas been most thoroughly characterized for the $omega$ intron of thelarge subunit rRNA gene (6). A point mutation 54 nt downstreamfrom the $omega$ intron is coconverted ~99% of the time compared to~95% for the E3+23 site in aI2 RT-independent events. A pointmutation 736 bp upstream from the $omega$ intron is coconverted about40% of the time compared to 23% coconversion of the E1 $-$ 387 site,located 423 bp 5' of the aI2 insertion site. These data indicatethat the coconversion gradient upstream is somewhat steeper foraI2 than for $omega$ . It is not clear, however, whether this differenceis caused by the different mobile introns or flanking DNAsequences.

Target site mutations activate a retrohoming pathway in which there is no coconversion. Cross E1, involving the recipient strain E2 $-$ 8G E3+2T+5G, gave the unexpected finding that target site mutations can activatea retrohoming pathway, previously undetected for this intron,in which insertion of the intron occurs without any coconversionof flanking exon markers (Fig. 5, pattern 3, and Fig. 6a). Analysisof crosses B, F, and G, each using a recipient strain carryingjust one of the above mutations, showed that this pathway is activatedby a combination of the E2 $-$ 8G and E3+2T mutations, which togetherlead to an increased level of full reverse splicing. The E2 $-$ 8Gmutation fixes a non-Watson-Crick pairing in IBS2-EBS2 (Fig. 1B)and results in a fourfold increase in the level of reverse splicingbut no increase in the proportion of full reverse splicing (Fig.3A). By itself, this mutation only weakly supports retrohomingwithout coconversion (13%). The other mutation, E3+2T, has littleeffect on the level of reverse spliced products but increasesthe proportion of full reverse splicing (see reference 5).This mutation, by itself, activates the new retrohoming pathwayto nearly the same extent as does the triple mutant target siteused in cross E1 (39 versus 43%). The E3+2T mutation may weakenRNA or protein interactions with the 3' exon that are requiredfor antisense strand cleavage and thus improve the extent of thesecond step of reverse splicing (5). As noted previously, thewild-type E3+2C allele potentially extends the $delta$ - $delta$ ' interactionbetween the intron and the 3' exon boundary (see Fig. 1B), andthat extra base pair is disrupted by the E3+2Tmutation.

An even more dramatic change in the ratio of homing pathways was observed in a cross between the donor strain with the P714Tmutation of the Zn domain and recipient strain E2 $-$ 8G E3+2T+5G(cross E3). While the levels of reverse splicing and antisensestrand cleavage activities were reduced from wild-type controllevels by the P714T mutation about 10-fold and 5-fold, respectively,and the level of homing with this target site was reduced to about70%, the fraction of retrohoming was increased from ~50 to 86%.In this cross, 43% of all homing events occurred without coconversion.Our finding that RNP particles from that mutant strain yield over90% full reverse splicing in vitro (Fig. 4A, lane 4) stronglysupports our inference that full reverse splicing favors retrohomingby that pathway. Other experiments show that the no-coconversionpathway also accounts for the previously described rare recombinantsin the cross 1⁺2⁺ × 1^o2^o, where aI2 inserts independently of aI1 (reference 14 and unpublisheddata).

Our biochemical and genetic data suggest that retrohoming without coconversion involves synthesis of a full-length cDNA copyof the inserted intron RNA with homing events completed by a repairmechanism that is independent of the mitochondrial DSBR system(Fig. 6a). An intact antisense strand could be restored by nucleasetrimming of excess nucleotides, followed by ligation of the cDNAto the resected DNA strand. Removal of the inserted RNA by anmtRNase H would form a gap in the sense strand that could be filledin by a DNA polymerase activity and the event completed by ligation.This scenario is the same as that deduced for the major retrohomingpathway used by the L. lactis Ll.LtrB intron (3).

In principle, retrohoming without coconversion of flanking exon sequences could also result from a pathway in which the intronRNA reverse splices into an mRNA transcribed from recipient mtDNAto yield a recombinant pre-mRNA, which is then reverse transcribedand incorporated into mtDNA by homologous recombination. Thatpathway was proposed previously to account for the low level ofectopic transposition of aI1 (17) and also appears to be usedfor transposition of the Ll.LtrB intron to ectopic sites in L.lactis (2). Retrohoming via reverse splicing into RNA is expectedto require the RT activity of the aI2 protein but not its DNAendonuclease activity. In that case, the P714T mutation, whichincreases RT activity but inhibits endonuclease activity, shouldincrease the proportion of retrohoming events without coconversionand decrease the proportion that occur by TPRT with upstream coconversion.The finding that the P714T donor strain does not alter the proportionof retrohoming events occurring with or without upstream coconversionargues that both pathways are initiated by reverse splicing intoDNA followed by TPRT. While recombination with cDNAs probablyplays a role in intron deletion events in yeast mitochondria (11),the frequency of such events is very low relative to retrohoming.More direct tests of the possible role of reverse splicing intoRNA as a step in retrohoming or ectopic transposition of yeastmitochondrial introns are underway.

Factors that affect the choice of retrohoming pathway. In all cases analyzed thus far, homing is initiated by reverse splicing of the intron into the sense strand of the DNA targetsite, followed by antisense strand cleavage. As diagrammed inFig. 6, the products of these events, which may contain eitherfully or partially reverse spliced intron RNA, are then partitionedamong different pathways, leading to three different outcomesin terms of coconversion of flanking exon sequences. The two retrohomingpathways result in either unidirectional upstream coconversion(Fig. 6b and c) or no coconversion (Fig. 6a), while the RT-independentpathway results in bidirectional coconversion (Fig. 6d). In bothyeast mitochondria and bacteria, the primary retrohoming pathwaysare initiated by the RT copying the 5' overhang of the cleavedrecipient DNA, followed by synthesis of a cDNA copy of the intron.In yeast mitochondria, this pathway may be completed either byDSBR recombination or by synthesis of a full-length cDNA, insertionof which occurs by an as-yet-uncharacterized repair mechanism.In the bacterial systems, which do not carry out efficient DSBR,the latter retrohoming pathwaypredominates.

The proportion of full to partial reverse splicing is one factor in the choice of retrohoming pathway but not the only factor.Thus, the aI2 crosses A1, B, and C with DNA target sites thatsupport mostly partial reverse splicing in vitro still use thesame major retrohoming pathway as aI1, which has a much higherlevel of full reverse splicing. Moreover, the aI2 homing siteused in cross D (E2 $-$ 2T $-$ 5C/E3+2T+5G) increased the proportion offull reverse splicing of aI2 in vitro to about the same levelfound for aI1 but did not increase the proportion of retrohoming.Even in crosses with the E2 $-$ 8G E3+2T+5G recipient strain, whereincreased full reverse splicing activated retrohoming withoutcoconversion, the fraction of retrohoming was not changed. Together,these findings suggest that in crosses with wild-type aI2 theinitial intermediate containing either partially or fully reversespliced intron is divided in a fixed proportion between the RT-dependentand RT-independent pathways. This division likely reflects a balanceamong the rate of initiation of cDNA synthesis, dissociation ofthe RT, degradation of the reverse spliced intron RNA, and DNase-mediatedresection of the antisensestrand.

Our results indicate that the fixed proportion of the homing intermediate that enters the retrohoming pathway can itself bedivided between two pathways in which events are completed withor without coconversion of upstream exon sequences. The pathwaywith no coconversion is activated by mutations in the DNA targetsite (E2 $-$ 8G and E3+2T) that increase the level of full reversesplicing in vitro and thus presumably provide an increased opportunityto synthesize full-length intron cDNAs. Other factors that couldinfluence the synthesis of full-length cDNAs include mutationsthat affect the processivity of the RT, deoxynucleoside triphosphateconcentrations in vivo, the rate of degradation of the RNA template,and the folded structure of the intron RNA. Such factors may accountfor the finding that the target site used in cross D (E2 $-$ 2T $-$ 5C/E3+2T+5G)also includes the E3+2T mutation and leads to increased overalland full reverse splicing but does not lead to increased retrohomingwith no coconversion. This target site contains two mutationsimmediately upstream of the aI2 insertion site that substitutebase pairs in the IBS1-EBS1 interaction. Such substitutions couldaffect the tertiary structure of the intron or protein bindingin a way that makes it more difficult to synthesize a full-lengthcDNA. In addition, it is possible that the level and proportionof full reverse splicing for some target sites differs in vitroand invivo.

Finally, the most dramatic variation in the ratio of homing pathways was in cross E3, between the Zn domain mutant P714T andthe E2 $-$ 8G E3+2T+5G recipient. Although the overall level of homingwas reduced (from 92 to 72%), presumably due to the decreasedlevel of DNA endonuclease activity, the proportion of retrohoming(86%) was much higher than in any other aI2 cross. This changein partitioning of the intermediate toward retrohoming may bedue to the activation of RT activity in this mutant, thus increasingthe rate of initiation or extent of cDNA synthesis after antisensestrand cleavage (6, 23). The ability to use different homingpathways presumably facilitates the dispersal of group II intronsby enabling them to use different recombination and repair enzymesand adapt to different conditions in different hostcells.

	ACKNOWLEDGMENTS

This research was supported by research grants from the National Institutes of Health (GM31480 to P.S.P. and GM37949 to A.M.L.).Robert Eskes was a fellow of the Robert A. Welch Foundation (grantI-1211) during part of this research, and Michael Chao was anNIH predoctoral trainee (T32-HL07360).

Fahd Nasr constructed several of the recipient alleles used in this study. Steven Zimmerly made several observations thathelped to focus this study on the recipient allelesshown.

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Molecular Biology, University of Texas Southwestern Medical Center, Dallas,TX 75390-9148. Phone: (214) 648-1464. Fax: (214) 648-1488. E-mail:philip.perlman{at}utsouthwestern.edu.

Present address: JWG-Universität Frankfurt am Main ZIM-Med Klinik III-Molekulare Haematologie, D-60596 Frankfurt,Germany.

Present address: Pacific Northwest Research Institute, Seattle, WA98122.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

1. Bonitz, S. G., G. Coruzzi, B. E. Thalenfield, A. Tzagoloff, and G. Macino. 1980. Assembly of the mitochondrial membrane system. Structure and nucleotide sequence of the gene coding for subunit I of cytochrome oxidase. J. Biol. Chem. 255:11927-11941[Abstract/Free Full Text].

2. Cousineau, B., S. Lawrence, D. Smith, and M. Belfort. 2000. Retrotransposition of a bacterial group II intron. Nature 404:1018-1021[CrossRef][Medline].

3. Cousineau, B., D. Smith, S. Lawrence-Cavanagh, J. E. Mueller, J. Yang, D. Mills, D. Manias, G. Dunny, A. M. Lambowitz, and M. Belfort. 1998. Retrohoming of a bacterial group II intron: mobility via complete reverse splicing, independent of homologous DNA recombination. Cell 94:451-462[CrossRef][Medline].

4. Eskes, R., J. Yang, A. Lambowitz, and P. Perlman. 1997. Mobility of yeast mitochondrial group II introns: engineering a new site specificity and retrohoming via full reverse splicing. Cell 88:865-874[CrossRef][Medline].

5. Guo, H., S. Zimmerly, P. S. Perlman, and A. M. Lambowitz. 1997. Group II intron endonucleases use both RNA and protein subunits for recognition of specific sequences in double-stranded DNA. EMBO J. 16:6835-6848[CrossRef][Medline].

6. Jacquier, A., and B. Dujon. 1985. An intron-encoded protein is active in a gene conversion process that spreads an intron into a mitochondrial gene. Cell 41:383-394[CrossRef][Medline].

7. Kennell, J. C., J. V. Moran, P. S. Perlman, R. A. Butow, and A. M. Lambowitz. 1993. Reverse transcriptase activity associated with maturase-encoding group II introns in yeast mitochondria. Cell 73:133-146[CrossRef][Medline].

8. Lambowitz, A. M., and M. Belfort. 1993. Introns as mobile genetic elements. Annu. Rev. Biochem. 62:587-622[CrossRef][Medline].

9. Lambowitz, A. M., M. G. Caprara, S. Zimmerly, and P. S. Perlman. 1999. Group I and group II ribozymes as RNPs: clues to the past and guides to the future, p. 451-485. In R. Gesteland, T. R. Cech, and J. Atkins (ed.), The RNA world, 2nd ed. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.

10. Lazowska, J., B. Meunier, and C. Macadre. 1994. Homing of a group II intron in yeast mitochondrial DNA is accompanied by unidirectional co-conversion of upstream-located markers. EMBO J. 13:4963-4972[Medline].

11. Levra-Juillet, E., A. Boulet, B. Seraphin, M. Simon, and G. Faye. 1989. Mitochondrial introns aI1 and/or aI2 are needed for the in vivo deletion of intervening sequences. Mol. Gen. Genet. 217:168-171[CrossRef][Medline].

12. Matsuura, M., R. Saldanha, H. Ma, H. Wank, J. Yang, G. Mohr, S. Cavanagh, G. M. Dunny, M. Belfort, and A. M. Lambowitz. 1997. A bacterial group II intron encoding reverse transcriptase, maturase, and DNA endonuclease activities: biochemical demonstration of maturase activity and insertion of new genetic information within the intron. Genes Dev. 11:2910-2924[Abstract/Free Full Text].

13. Mills, D. A., D. A. Manias, L. L. McKay, and G. M. Dunny. 1997. Homing of a group II intron from Lactococcus lactis subsp. lactis ML3. J. Bacteriol. 179:6107-6111[Abstract/Free Full Text].

14. Moran, J. V., S. Zimmerly, R. Eskes, J. C. Kennell, A. M. Lambowitz, R. A. Butow, and P. S. Perlman. 1995. Mobile group II introns of yeast mitochondrial DNA are novel site-specific retroelements. Mol. Cell. Biol. 15:2828-2838[Abstract].

15. Moran, J. V. 1994. Ph.D. dissertation. University of Texas Southwestern Medical Center, Dallas.

16. Moran, J. V., C. M. Wernette, K. L. Mecklenburg, R. A. Butow, and P. S. Perlman. 1992. Intron 5 $alpha$ of the COXI gene of yeast mitochondrial DNA is a mobile group I intron. Nucleic Acids Res. 20:4069-4076[Abstract/Free Full Text].

17. Mueller, M. W., M. Allmaier, R. Eskes, and R. J. Schweyen. 1993. Transposition of group-II intron al1 in yeast and invasion of mitochondrial genes at new locations. Nature 366:174-176[CrossRef][Medline].

18. Nobrega, F., and A. Tzagoloff. 1980. Assembly of the mitochondrial membrane system. DNA sequence and organization of the cytochrome b gene in Saccharomyces cerevisiae D273-10B. J. Biol. Chem. 255:9828-9837[Abstract/Free Full Text].

19. Perlman, P. S., and H. R. Mahler. 1983. Genetics and biogenesis of cytochrome b. Methods Enzymol. 9:347-395.

20. Yang, J., G. Mohr, P. S. Perlman, and A. M. Lambowitz. 1998. Group II intron mobility in yeast mitochondria: target DNA primed reverse transcription activity of aI1 and reverse splicing into DNA transposition sites in vitro. J. Mol. Biol. 282:505-523[CrossRef][Medline].

21. Yang, J., S. Zimmerly, P. S. Perlman, and A. M. Lambowitz. 1996. Efficient integration of an intron RNA into double-stranded DNA by reverse splicing. Nature 381:332-335[CrossRef][Medline].

22. Zimmerly, S., H. Guo, R. Eskes, J. Yang, P. S. Perlman, and A. M. Lambowitz. 1995. A group II intron RNA is a catalytic component of a DNA endonuclease involved in intron mobility. Cell 83:529-538[CrossRef][Medline].

23. Zimmerly, S., H. Guo, P. S. Perlman, and A. M. Lambowitz. 1995. Group II intron mobility occurs by target DNA-primed reverse transcription. Cell 82:545-554[CrossRef][Medline].

24. Zimmerly, S., J. V. Moran, P. S. Perlman, and A. M. Lambowitz. 1999. Group II intron reverse transcriptase in yeast mitochondria. Stabilization and regulation of reverse transcriptase activity by the intron RNA. J. Mol. Biol. 289:473-490[CrossRef][Medline].

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1.	Bonitz, S. G., G. Coruzzi, B. E. Thalenfield, A. Tzagoloff, and G. Macino. 1980. Assembly of the mitochondrial membrane system. Structure and nucleotide sequence of the gene coding for subunit I of cytochrome oxidase. J. Biol. Chem. 255:11927-11941[Abstract/Free Full Text].
2.	Cousineau, B., S. Lawrence, D. Smith, and M. Belfort. 2000. Retrotransposition of a bacterial group II intron. Nature 404:1018-1021[CrossRef][Medline].
3.	Cousineau, B., D. Smith, S. Lawrence-Cavanagh, J. E. Mueller, J. Yang, D. Mills, D. Manias, G. Dunny, A. M. Lambowitz, and M. Belfort. 1998. Retrohoming of a bacterial group II intron: mobility via complete reverse splicing, independent of homologous DNA recombination. Cell 94:451-462[CrossRef][Medline].
4.	Eskes, R., J. Yang, A. Lambowitz, and P. Perlman. 1997. Mobility of yeast mitochondrial group II introns: engineering a new site specificity and retrohoming via full reverse splicing. Cell 88:865-874[CrossRef][Medline].
5.	Guo, H., S. Zimmerly, P. S. Perlman, and A. M. Lambowitz. 1997. Group II intron endonucleases use both RNA and protein subunits for recognition of specific sequences in double-stranded DNA. EMBO J. 16:6835-6848[CrossRef][Medline].
6.	Jacquier, A., and B. Dujon. 1985. An intron-encoded protein is active in a gene conversion process that spreads an intron into a mitochondrial gene. Cell 41:383-394[CrossRef][Medline].
7.	Kennell, J. C., J. V. Moran, P. S. Perlman, R. A. Butow, and A. M. Lambowitz. 1993. Reverse transcriptase activity associated with maturase-encoding group II introns in yeast mitochondria. Cell 73:133-146[CrossRef][Medline].
8.	Lambowitz, A. M., and M. Belfort. 1993. Introns as mobile genetic elements. Annu. Rev. Biochem. 62:587-622[CrossRef][Medline].
9.	Lambowitz, A. M., M. G. Caprara, S. Zimmerly, and P. S. Perlman. 1999. Group I and group II ribozymes as RNPs: clues to the past and guides to the future, p. 451-485. In R. Gesteland, T. R. Cech, and J. Atkins (ed.), The RNA world, 2nd ed. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.
10.	Lazowska, J., B. Meunier, and C. Macadre. 1994. Homing of a group II intron in yeast mitochondrial DNA is accompanied by unidirectional co-conversion of upstream-located markers. EMBO J. 13:4963-4972[Medline].
11.	Levra-Juillet, E., A. Boulet, B. Seraphin, M. Simon, and G. Faye. 1989. Mitochondrial introns aI1 and/or aI2 are needed for the in vivo deletion of intervening sequences. Mol. Gen. Genet. 217:168-171[CrossRef][Medline].
12.	Matsuura, M., R. Saldanha, H. Ma, H. Wank, J. Yang, G. Mohr, S. Cavanagh, G. M. Dunny, M. Belfort, and A. M. Lambowitz. 1997. A bacterial group II intron encoding reverse transcriptase, maturase, and DNA endonuclease activities: biochemical demonstration of maturase activity and insertion of new genetic information within the intron. Genes Dev. 11:2910-2924[Abstract/Free Full Text].
13.	Mills, D. A., D. A. Manias, L. L. McKay, and G. M. Dunny. 1997. Homing of a group II intron from Lactococcus lactis subsp. lactis ML3. J. Bacteriol. 179:6107-6111[Abstract/Free Full Text].
14.	Moran, J. V., S. Zimmerly, R. Eskes, J. C. Kennell, A. M. Lambowitz, R. A. Butow, and P. S. Perlman. 1995. Mobile group II introns of yeast mitochondrial DNA are novel site-specific retroelements. Mol. Cell. Biol. 15:2828-2838[Abstract].
15.	Moran, J. V. 1994. Ph.D. dissertation. University of Texas Southwestern Medical Center, Dallas.
16.	Moran, J. V., C. M. Wernette, K. L. Mecklenburg, R. A. Butow, and P. S. Perlman. 1992. Intron 5 $alpha$ of the COXI gene of yeast mitochondrial DNA is a mobile group I intron. Nucleic Acids Res. 20:4069-4076[Abstract/Free Full Text].
17.	Mueller, M. W., M. Allmaier, R. Eskes, and R. J. Schweyen. 1993. Transposition of group-II intron al1 in yeast and invasion of mitochondrial genes at new locations. Nature 366:174-176[CrossRef][Medline].
18.	Nobrega, F., and A. Tzagoloff. 1980. Assembly of the mitochondrial membrane system. DNA sequence and organization of the cytochrome b gene in Saccharomyces cerevisiae D273-10B. J. Biol. Chem. 255:9828-9837[Abstract/Free Full Text].
19.	Perlman, P. S., and H. R. Mahler. 1983. Genetics and biogenesis of cytochrome b. Methods Enzymol. 9:347-395.
20.	Yang, J., G. Mohr, P. S. Perlman, and A. M. Lambowitz. 1998. Group II intron mobility in yeast mitochondria: target DNA primed reverse transcription activity of aI1 and reverse splicing into DNA transposition sites in vitro. J. Mol. Biol. 282:505-523[CrossRef][Medline].
21.	Yang, J., S. Zimmerly, P. S. Perlman, and A. M. Lambowitz. 1996. Efficient integration of an intron RNA into double-stranded DNA by reverse splicing. Nature 381:332-335[CrossRef][Medline].
22.	Zimmerly, S., H. Guo, R. Eskes, J. Yang, P. S. Perlman, and A. M. Lambowitz. 1995. A group II intron RNA is a catalytic component of a DNA endonuclease involved in intron mobility. Cell 83:529-538[CrossRef][Medline].
23.	Zimmerly, S., H. Guo, P. S. Perlman, and A. M. Lambowitz. 1995. Group II intron mobility occurs by target DNA-primed reverse transcription. Cell 82:545-554[CrossRef][Medline].
24.	Zimmerly, S., J. V. Moran, P. S. Perlman, and A. M. Lambowitz. 1999. Group II intron reverse transcriptase in yeast mitochondria. Stabilization and regulation of reverse transcriptase activity by the intron RNA. J. Mol. Biol. 289:473-490[CrossRef][Medline].