Extraordinary Ribosomal Spacer Length Heterogeneity in a Neotyphodium Endophyte Hybrid: Implications for Concerted Evolution

Extraordinary Ribosomal Spacer Length Heterogeneity in a Neotyphodium Endophyte Hybrid: Implications for Concerted Evolution

Austen R. D. Ganley^a and Barry Scott^a
^a Institute of Molecular BioSciences, Massey University, Palmerston North, New Zealand

Corresponding author: Barry Scott, Institute of Molecular BioSciences, Massey University, Private Bag 11222, Palmerston North, New Zealand., d.b.scott{at}massey.ac.nz (E-mail).

Communicating editor: G. B. GOLDING

ABSTRACT

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

An extraordinary level of length heterogeneity was found inthe ribosomal DNA (rDNA) of an asexual hybrid Neotyphodium grassendophyte, isolate Lp1. This hybrid Neotyphodium endophyte isan interspecific hybrid between two grass endophytes, Neotyphodiumlolii, and a sexual form, Epichlöe typhina, and the lengthheterogeneity was not found in either of these progenitor species.The length heterogeneity in the hybrid is localized to the intergenicspacer (IGS) and is the result of copy-number variation of atandemly repeated subrepeat class within the IGS, the 111-/119-bpsubrepeats. Copy number variation of this subrepeat class appearsto be a consequence of mitotic unequal crossing over that occursbetween these subrepeats. This implies that unequal crossingover plays a role in the concerted evolution of the whole rDNA.Changes in the pattern of IGS length variants occurred in justtwo rounds of single-spore purification. Analysis of the IGSlength heterogeneity revealed features that are unexpected ina simple model of unequal crossing over. Potential refinementsof the molecular details of unequal crossing over are presented,and we also discuss evidence for a combination of homogenizationmechanisms that drive the concerted evolution of the Lp1 rDNA.

CONCERTED evolution is the term used to describe the unusualevolutionary behavior of multigene families whose genes showa great deal of similarity to each other within an array andwithin a species but accumulate differences between species.This was first demonstrated in the ribosomal multigene family(the rDNA) in Xenopus by BROWN et al. 1972 . This ability ofindividual repeats in a multigene family to evolve in concertrather than independently is believed to result from a processthat is able to homogenize all the repeats in an array (DOVER1982 ), and this has been directly demonstrated in lizards (HILLISet al. 1991 ) and cotton (WENDEL et al. 1995 ). While the conceptof concerted evolution resulting from homogenization of therepeat arrays in multigene families is widely accepted, theprecise modus operandi of the homogenizing mechanism(s) is notwell understood (for recent reviews see ELDER and TURNER 1995; LI 1997 ).

The two mechanisms most commonly invoked as responsible forhomogenization are gene conversion (EDELMAN and GALLY 1970 ; NAGYLAKI and PETES 1982 ) and unequal crossing over (SMITH1973 ; OHTA 1976 ). These mechanisms, which fall under thegeneral term "recombination," are proposed to drive a singlerepeat unit within an array to fixation, with selection presumablyremoving unfit genes that spread through the array. Gene conversioninvolves the unidirectional transfer of information from oneDNA duplex to another, while unequal crossing over results inreciprocal exchange of information between two DNA duplexes.Much of our understanding of these processes comes from workdone in fungi.

The relative roles of unequal crossing over and gene conversionin homogenization are uncertain, and resolution of this debatehas been hampered by difficulties in distinguishing these mechanismsexperimentally with such a large number of essentially identicalgenes. Also, unequal crossing over and gene conversion are believedto be mechanistically linked (HOLLIDAY 1964 ; MESELSON andRADDING 1975 ; SZOSTAK et al. 1983 ), with gene conversionoften being associated with crossing over of flanking markers.However, the isolation of mutants that affect either gene conversionor unequal crossing over demonstrates that they are under somedegree of independent control (reviewed in WHITEHOUSE 1982). Recombination can be meiotic or mitotic, and these typesalso appear to be under at least partially independent control(reviewed in ORR-WEAVER and SZOSTAK 1985 ). Recombination eventscan occur between homologous chromosomes (allelic or classicalrecombination), between repeats on nonhomologous chromosomes(heterochromosomal recombination), between sister chromatids(sister chromatid recombination), and even between repeats onthe same chromatid (intrachromatid recombination); the lattertwo processes together are known as intrachromosomal recombination(from JINKS-ROBERTSON and PETES 1993 ). Intrachromosomal recombinationis believed to be the most important from a concerted evolutionperspective, occurring at a higher rate than the other recombinationevents (e.g., PETES and BOTSTEIN 1977 ; PETES 1980 ; SCHLOTTERERand TAUTZ 1994 ).

We have been investigating the structure and composition ofthe rDNA in a group of Neotyphodium grass endophytes from thefamily Clavicipitacea, which includes the fungus responsiblefor St. Anthony's Fire (ergotism) from contaminated rye. Neotyphodiumendophytes are asexual filamentous ascomycetes that form mutualisticsymbiotic relationships with pasture grasses, producing a rangeof secondary alkaloids, including a tremorgenic mycotoxin responsiblefor the neurotoxic disorder in grazing mammals, ryegrass staggers.Molecular phylogenetic studies indicate that the clavicipitaceousendophytes evolved from the teleomorphic (sexual) choke grasspathogen, Epichlöe (SCHARDL et al. 1991 ). These sexualforms exhibit pathogenic symptoms through the production ofexternal stroma on the inflorescences of their hosts. Stromalproduction, which represents the sexual stage of the fungus,prevents maturation of the host inflorescences and leads tosterility, a phenomenon known as "choking." This is in contrastto the Neotyphodium species, which are asexual and entirelyendophytic and are disseminated via the host grass seed.

It has been shown recently that several of these Neotyphodiumendophytes are interspecific hybrids. Several independent hybridizationevents appear to have occurred between various sexual Epichlöespecies and asexual Neotyphodium species, presumably throughhyphal fusion followed by nuclear fusion after dual infectionof one plant (TSAI et al. 1994 ). The endophyte we used in thisstudy arose through an interspecific hybridization event betweena sexual taxon (Epichlöe typhina) and an asexual taxon(Neotyphodium lolii-Lolium perenne taxonomic grouping 1 or LpTG-1)that associate with perennial ryegrass (L. perenne). The resultanthybrid has been designated taxonomic grouping LpTG-2 (E. typhinax N. lolii; SCHARDL et al. 1994 ). Lp1, an isolate from theLpTG-2 hybrid group, and its two progenitors, E. typhina isolateE8 and N. lolii isolate Lp5 (the extant isolate most closelyresembling the true progenitor), were used to investigate themechanisms of homogenization in the concerted evolution of therDNA.

The rDNA in most eukaryotes (including fungi) consists of aseries of repeating units containing the 18S, 5.8S, and 28SrRNA (rrn) genes (LONG and DAWID 1980 ). These units are arrangedin a head-to-tail, tandem array with internal transcribed spacers(ITS) separating the rrn genes within a unit and an intergenicspacer (IGS) separating adjoining units. The 5S rrn gene repeatsare usually located separately (LONG and DAWID 1980 ). The rrngenes show a remarkable amount of conservation across a widerange of species, while the spacer elements diverge more rapidly.The difference in evolutionary rates arises because the spacerscan essentially "hitchhike" with the more functionally constrainedrrn genes during the homogenization process (SMITH 1973 ; KELLOGGand APPELS 1995 ). The IGS is normally maintained at a constantlength in the rDNA within a species, but in some species, itfluctuates in length between populations, individuals, and evenarrays. In many cases where the structure of the IGS has beendetermined, it has been found to contain small, tandem subrepeats,and in a number of instances, the length variation of the IGSresults from variation in the number of these IGS subrepeats(see DISCUSSION). Here we demonstrate unequal crossing overthat occurs within the IGS of the rDNA in the Neotyphodium grassendophyte hybrid Lp1. We show that significant changes in repeatvariants can arise in just a few generations, and that completelydifferent patterns of length variants arise in a few years.

MATERIALS AND METHODS

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

Strains and growth conditions:
Fungal isolates, ${lambda}$ clones, and plasmids used in this study arelisted in Table 1. Fungal isolates were cultured on 2.4% w/vpotato dextrose (PD; Difco, Detroit, MI) agar plates at 25°.

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Table 1. Fungal isolates, ${lambda}$ clones, and plasmids used in this study

Molecular biology techniques:
All subcloning was done using the plasmid vector pUC118 (VIEIRAand MESSING 1987 ), and transformation was performed using Escherichiacoli strain XL1-Blue (BULLOCK et al. 1987 ). Standard techniques(restriction digestion, ligation, electrophoretic separation,DNA gel purification, etc.) were done according to the methodsof AUSUBEL et al. 1987 (–1993), unless otherwise described.Purification of PCR products using the PCR Clean Up Kit (BoehringerMannheim, Mannheim, Germany) and ExoIII deletion using the Erase-A-Basesystem (Promega, Madison, WI) were done according to the manufacturers'instructions. DNA sequencing of both plasmid DNA and PCR productsusing the AmpliCycle (Perkin Elmer, Branchburg, NJ) cycle sequencingkit was performed according to the manufacturer's instructions,except that an annealing temperature of 50° was used. Reactionswere carried out in a model FTS-960 thermocycler (Corbett Research,Sydney, Australia).

Library screening and physical mapping:
A ${lambda}$ EMBL3A genomic library of Lp1 (COLLETT et al. 1995 ) was screenedby plaque hybridization using [ ${alpha}$ -³²P]dCTP-labeled YIp10.4 (TODAet al. 1984 ) by standard procedures (SAMBROOK et al. 1989 ).Physical mapping was performed using the ${lambda}$ mapping kit (Amersham,Buckinghamshire, England). A DNA fragment containing the 25SrRNA gene (2.4-kb HindIII/BamHI) was gel purified from YIp10.4.This was radiolabeled with [ ${alpha}$ -³²P]dCTP using the random primerextension method (FEINBERG and VOGELSTEIN 1983 ) for use asa hybridization probe. Primer combinations of ns7-ns8 and its5-its2(WHITE et al. 1990 ) were used with total DNA to generate PCRproducts of 350 and 300 bp, respectively. These products werepurified using the Magic PCR Preps system (Promega) and wereradiolabeled as described above for use as hybridization probes.These were then used as hybridization probes to restrictiondigests of ${lambda}$ PN1 to assign the positions of the rrn genes andspacers to the physical map.

DNA extraction:
Isolates Lp1 and Lp5 were grown for 6 days and isolate E8 wasgrown for 4 days in 30 ml of PD liquid broth in flasks on ashaker at 250 rpm at 25°. Mycelia were harvested by filtrationthrough 11-cm Whatman one-filter paper under vacuum, frozenin liquid N₂, and then freeze-dried. Total fungal DNA was preparedfrom the lyophilized mycelia as described previously (BROWNLEE1988 ).

Southern blotting:
Southern transfers were carried out according to AUSUBEL etal. 1987 (–1993). Probes were radiolabeled to a high specificactivity with [ ${alpha}$ -³²P]dCTP using the high prime random primingkit (Boehringer Mannheim), and the unincorporated nucleotideswere removed with a Sephadex G-50 column (ProbeQuant G-50 microcolumn; Pharmacia Biotech, Piscataway, NJ). DNA hybridizationswere carried out in 10x Denhardt's solution (3x SSC) at 65°for 16 hr. Three sets of washes were performed, each at roomtemperature in 2x SSC for 15 min. Detection and stripping ofthe Southern blots were performed as described in AUSUBEL etal. 1987 (–1993).

Single-spore purification:
Single-conidiospore-purified cultures of Lp1 were generatedas follows. Lp1 was cultured onto a fresh PD plate and grownfor 2 weeks at 25°. Conidiospore solutions were preparedby immersing a mycelial block from the plate culture in sterileH₂O. This solution was plated onto PD agar 2% (w/v) plates andallowed to germinate for 48 hr at 25°. Germinating conidiosporeswere identified by microscopy and then picked and patched ontofresh PD plates.

PCR analysis:
All PCR reactions were carried out in a final volume of 25 µlcontaining 10 mM Tris-HCl, 1.5 mM MgCl₂, 50 mM KCl, 50 µMof each dNTP, 200 nM of each primer, 1 unit of Taq DNA polymerase(Boehringer Mannheim), and 10 ng of genomic DNA. The temperatureregime used was as follows: 2 min at 94°; 25 cycles of 30sec at 94°, 30 sec at the temperature indicated, and 1 minat 72°; and 5 min at 72°. For the primer combinationsnts1 (5'-CGGCTCTTCCTATCATACCGAAG-3') with nts2 (5'-GACTCCCCTCGGGATTAGCATAG-3')and nts7 (5'-TGCGGGTGCGCTATCGAGATG-3') with nts8 (5'-GCAAATCACAGTCACCAGCGG-3'),a 57° annealing temperature was used. For the primer combinationnts3 (5'-TCTTGCAGACGTCTACTCCGTG-3') with nts4 (5'-GAGACAAGCATATGACTAC-3'),a 55° annealing temperature was used, and DMSO was addedto a final concentration of 2% (v/v). Reactions were carriedout in a model FTS-960 thermocycler (Corbett Research).

Multivariant repeat PCR (MVR-PCR) analysis:
For the mapping of the 111-/119-bp subrepeats, 18-mer oligonucleotidesspecific to each of the subrepeat types that covered the variableregion of the subrepeats at the 3' end of the primer were designedin both directions. In addition, an arbitrary 17-mer tail wasconstructed at the 5' end of each primer to produce the final35-mer repeat-specific primers, and a primer consisting of thissequence alone, the TAG primer (5'-TTTGTCCGCTCGGTTGC-3'), wasalso constructed. The repeat-specific primer sequences are asfollows: 111-L is 5'-TTTGTCCGCTCGGTTGCCGCGGGCAGAGTGGTGCC-3',111-R is 5'-TTTGTCCGCTCGGTTGCGCCCATCCCACCACTCTG-3', 119-L is5'-TTTGTCCGCTCGGTTGCTCAGAGTGGTGTCCTCGG-3', and 119-R is 5'-TTTGTCCGCTCGGTTGCCGCCCATCCAACCCGAGG-3'.The anchor primers, located to the left and right of the 111-/119-bpsubrepeat array, are previously designed primers, where anchor-Lis nts7, and anchor-R is nts4 for genomic DNA and is the pUC118forward primer for pPN50 DNA.

All MVR-PCR reactions consisted of one initial cycle that wascarried out in a final volume of 50 µl containing 10 mMTris-HCl, 1.5 mM MgCl₂, 50 mM KCl, 5% (v/v) DMSO, 50 µMof each dNTP, 10 nM of the repeat specific primer, 300 nM ofthe appropriate anchor primer, 3 units of High Fidelity TaqDNA polymerase (Boehringer Mannheim), and 10 ng of genomic DNAor 0.2 ng of pPN50 DNA. The temperature regime was 3 min at92°, 30 sec at 60°, and 5 min at 70°. After this,300 nM TAG primer and an additional unit of High Fidelity TaqDNA polymerase were added to the reaction, and the reactionswere put back into the thermocycler with the following temperatureregime: 2 min at 92°; 25 cycles of 30 sec at 92°, 30sec at 60°, and 3 min at 70°; and 5 min at 70°.All reactions were carried out in a model FTS-960 thermocycler(Corbett Research). Reactions were then fractionated on agarosegels.

RESULTS

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

Cloning of an Lp1 rDNA unit:
A ${lambda}$ EMBL3A genomic library of Lp1 (COLLETT et al. 1995 ) was screenedfor rDNA clones with a 10.4-kb HindIII rDNA probe from Schizosaccharomycespombe (YIp10.4; TODA et al. 1984 ), and one clone, ${lambda}$ PN1, wasselected for further analysis. A physical map of this clonewas created using the restriction enzymes SalI and EcoRI (Figure1). A 2.4-kb HindIII/BamHI fragment from YIp10.4 encoding theS. pombe 25S rrn gene was used as a probe to Southern blotsof ${lambda}$ PN1 DNA to assign the position of this gene to the map. PCRproducts generated using "universal" fungal primers to the 18Srrn gene (ns7 and ns8) and the 18S-5.8S ITS-1 (its5 and its2; WHITE et al. 1990 ) were used as probes to assign the positionsof these regions to the map. Positions of the 5.8S rrn geneand the ITS-2 region have been inferred from DNA sequencingof these regions (SCHARDL et al. 1994 ). A map of the Lp1 rDNArepeat unit was constructed from these results (Figure 1). The5.6- and 4.1-kb SalI fragments from ${lambda}$ PN1 were subcloned intopUC118 to generate pPN49 and pPN50, respectively.

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Figure 1. Map of the ribosomal clone from Lp1, ${lambda}$ PN1. Fragments produced by SalI and EcoRI digestion are indicated. A diagrammatic representation of the organization of the rrn spacers (above) and coding regions (below) in ${lambda}$ PN1 is shown below the physical map. Shaded boxes indicate rrn coding regions. A complete rDNA unit is defined by two SalI sites, one cutting just before the 5' end of the 18S rrn gene, and the other cutting just after the 3' end of the 28S rrn gene, producing 4.1- and 5.6-kb fragments. The next SalI site begins the next rDNA unit in the array. The 2.2-kb SalI fragment is a partial copy of the 5.6-kb SalI fragment interrupted by the SalI site from the ${lambda}$ EMBL3A multicloning site. The other ${lambda}$ EMBL3A SalI site is the left-hand-most site in the map. There are also two EcoRI sites in the Lp1 rDNA. One cuts within the 5.8S rrn gene, and the other at the 3' end of the 28S rrn gene, producing the 3.2-kb fragment indicated. The rDNA unit is truncated before the next EcoRI site, which would be expected to produce a 6.5-kb fragment. The 5.6- and 4.1-kb SalI fragments were cloned into pUC118 to give pPN49 and pPN50, respectively.

Length heterogeneity discovered with a ribosomal probe:
To ensure that ${lambda}$ PN1 was representative of the genomic rDNA organization,Lp1 genomic DNA was cleaved with SalI, and a Southern blot wasprobed with the inserts from pPN49 and pPN50. The insert frompPN49, containing the three rrn genes on a 5.6-kb SalI fragment(the 5.6-kb coding region probe), hybridized to a 5.6-kb bandas expected (Figure 2A). When the insert from pPN50, containingthe IGS region on a 4.1-kb SalI fragment (the 4.1-kb IGS probe),was used to probe the same Southern blot, it hybridized to amultitude of bands ranging in size from 3.5 to >20 kb (Figure2B), including a band the size of the subcloned fragment. Allfour different cultures of the Lp1 isolate maintained in ourlaboratory (Lp1A, Lp1C, Lp1D, and Lp1F) exhibited distinct bandingpatterns when probed with the 4.1-kb IGS probe (results shownfor Lp1A and Lp1C in Figure 2B).

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Figure 2. Length heterogeneity in the rDNA of Lp1. Genomic DNA was digested with SalI, fractionated through a 0.7% agarose gel, and transferred to a nylon membrane. The resulting Southern blot was probed with the two SalI fragments from the Lp1 rDNA unit clone, ${lambda}$ PN1. (A) The 5.6-kb coding region probe reveals a single hybridizing band. This is the size of the probe, as indicated, except in the case of Lp5. (B) The 4.1-kb IGS probe reveals a remarkable amount of length variation in the rDNA despite being linked to the DNA in A in vivo. The smallest IGS length (3.5 kb) and the IGS length equivalent to the clone (4.1 kb) are indicated by arrows. The order of the lanes in B is identical to that in A. HindIII size markers from ${lambda}$ DNA are also shown. The original isolate and first and second round single-spore isolates are indicated by 0, 1, and 2, respectively.

This length variation in the Lp1 rDNA is not observed in theprogenitor isolates Lp5 and E8 (Figure 2B), although additionalbands are observed in these two isolates. In Lp5, three bands,ranging from 3.5 to 3.7 kb, hybridize to the 4.1-kb IGS probe.This limited length heterogeneity is qualitatively differentthan that seen with Lp1. In the case of E8, there is a stronglyhybridizing band of ~3.7 kb and a weaker band just above this.

Aside from some faint hybridization of ~3.2 kb in Lp1, no bandssmaller than the two progenitors are seen. Therefore, the hybridizingbands seen in Lp1 are at least as great in size as the bandspresent in the two progenitors.

Heterogeneity occurs within the rDNA cluster:
To ascertain whether the variation in rDNA length is the resultof intercellular differences between rDNA clusters or occurswithin an rDNA cluster, different laboratory cultures were takenthrough two rounds of single-conidiospore purification, withgenomic DNA extracted after each round. Asexual isolates, includingthe interspecific hybrids, retain the ability to produce conidiospores.These spores are uninucleate (SCHARDL et al. 1994 ), allowingpure cultures of a homogenous nuclear composition to be generatedfrom mycelia by the germination of a single spore. The DNA fromthese laboratory cultures was digested with SalI and a Southernblot probed with the 4.1-kb IGS and 5.6-kb coding region probes(results shown for Lp1A and Lp1C in Figure 2). Each laboratoryculture retained its unique banding pattern through the single-sporingrounds with the 4.1-kb IGS probe. Two conclusions can be drawn.First, the rDNA length variants are present within the rDNAcluster rather than resulting from intercellular rDNA differences.Second, some changes in the banding patterns were observed throughthe single sporing, indicating that the mechanism(s) causingthe length heterogeneity is still active (e.g., Figure 2B,Lp1A lanes marked 1 and 2).

Heterogeneity localized to the intergenic spacer:
The banding pattern seen in Figure 2B may result from heterologoushybridization of the 4.1-kb IGS probe. Therefore, Lp1 genomicDNA was cleaved with EcoRI, and a Southern blot was probed withthe 4.1-kb IGS and 5.6-kb coding region probes (Figure 3). Thephysical map of ${lambda}$ PN1 (Figure 1) shows that an EcoRI genomic digestshould produce two rDNA fragments (excluding the flanking fragments),one corresponding approximately to the 5.8S and 28S genes (3.2kb in size) and the other corresponding to the 18S gene andthe IGS (6.5 kb in size). Probing with the 4.1-kb IGS probeproduced the same general banding pattern seen in the SalI digestion,with the bands all greater in size by 2.5 kb (the size of the18S gene) than the bands seen in Figure 2B. The 5.6-kb codingregion probe hybridized to a 3.2-kb band as expected, and italso hybridized to the same multitude of bands that the 4.1-kbIGS probe hybridized to. The heterogeneous banding pattern isthe result of linkage of the 18S gene and the IGS in the EcoRIdigest, with the 5.6-kb coding region probe hybridizing to the18S moiety. This demonstrates that the heterogeneous bandingpattern is not the result of heterologous hybridization of the4.1-kb SalI IGS probe, but that it is length variation of theIGS. It also confirms that the SalI bands seen in Figure 2Aand Figure B, are linked in vivo, and that the multitude ofbands seen in Figure 2B are ribosomal in origin. The same patternof hybridization is seen with the two progenitors, E8 and Lp5,but without the multitude of hybridizing bands, as expected.These results also rule out the possibility that the hybridizationpattern is the result of an unlikely experimental artefact,such as "star" activity of the restriction enzymes or methylationof the rDNA.

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Figure 3. Length heterogeneity in the rDNA is localized to the spacer. Genomic DNA was digested with EcoRI and fractionated through a 0.7% agarose gel and transferred to a nylon membrane. The resulting Southern blot was probed with the two SalI fragments used in Figure 2. The length heterogeneity observed in Figure 2B is also evident in this blot. The pattern of bands is the same as for the SalI genomic digests, but the sizes have increased by 2.5 kb, corresponding to the extra 18S-containing EcoRI/SalI fragment. The 5.6-kb coding region probe gives a pattern of hybridizing bands identical to that seen with the 4.1-kb IGS probe, excluding some of the very high molecular weight bands. In addition, a 3.2-kb band is seen, corresponding to the 28S-containing EcoRI fragment. The smallest IGS length (5.9 kb), equivalent to the 3.5-kb band in Figure 2B, is indicated by an arrow. HindIII size markers from ${lambda}$ DNA are also shown. Lp1A and Lp1C genomic DNA is from first-round single-spore-purified cultures.

Chromosomal karyotype analysis of the different laboratory culturesand their respective single-spore-purified isolates using pulsed-fieldgel electrophoresis revealed no differences in their chromosomalbanding patterns (A. R. D. GANLEY, unpublished results). Southernblots of restriction enzyme digests probed with an Lp1 pyr4clone (pMC11; COLLETT et al. 1995 ) and an Lp1 hmg clone (DOBSON1997 ) did not reveal any length heterogeneity within any ofthe laboratory cultures. Thus, the length heterogeneity observedwith the ribosomal probes does not appear to be a general featureof the Lp1 genome, nor is it a result of gross chromosomal rearrangements.

IGS contains subrepeat elements:
To investigate the nature of the length heterogeneity, the 4.1-kbIGS insert from pPN50 was sequenced. A set of nested deletionsof pPN50 was created using exonuclease III, and these were clonedand sequenced. Primers were designed from the sequence obtainedto fill gaps in the sequence. This resulted in a complete single-strandedsequence (barring some repetitive elements; see below for details)for the 4.1-kb IGS clone. Sequence was also obtained for theedges of the 5.6-kb coding region insert from pPN49.

Analysis of the IGS sequence revealed two subrepeat classes(Figure 4). The first, termed the 40-bp subrepeat class, isa relatively heterogeneous class, with a core consensus of 40bp (Figure 4). The individual repeats of this class are organizedin a head-to-tail tandem array, with eight repeats present inthe 4.1-kb IGS clone. This subrepeat class is characterizedby alternating pyrimidine-purine residues.

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Figure 4. Organization of the IGS in Lp1 rDNA. The positions and relative sizes of the 40- and 111-/119-bp subrepeat arrays are shown. Below are the consensus sequences for the subrepeats. The ambiguity characters in the 40-bp subrepeat consensus sequence, Y (C or T) and K (G or T), indicate that these nucleotides are present in that position in roughly equal proportions. The sequence in bold indicates differences between the 111- and 119-bp subrepeat consensus sequences. The HinfI site is underlined, and the ThaI site is double underlined. The primer pairs nts1-nts2, nts3-nts4, and nts7-nts8 used for sequence comparisons are indicated above the IGS diagram. Restriction sites are as follows: H, HinfI; R, RsaI; and S, SalI. Only the terminal HinfI sites in the 111-/119-bp subrepeats are shown. The three major IGS fragments defined by RsaI (0.4, 1.6, and 2.1 kb) that were used as probes in Figure 5 are shown as thick lines above the figure. The sequences for the PCR products and the 111-/119-bp subrepeats have been deposited in GenBank under accession numbers AF049246 and AF049673, AF049674, AF049675, AF049676, AF049677, AF049678, AF049679, AF049680, AF049681.

The second subrepeat class is termed the 111-/119-bp subrepeatclass and is composed of two very closely related subrepeats,one 111 bp in length (GenBank accession number AF049675) andthe other 119 bp in length (GenBank accession number AF049676).These show a high level of identity to each other and to themselves(Figure 4). They are also organized in a head-to-tail tandemarray. The subrepeats of this class are GC rich, containingon average 65% GC. The 4.1-kb IGS clone was shown to contain14 repeats (see below).

The junction between the 3' end of the 28S gene (in pPN49) andthe 5' end of the IGS (in pPN50) was spanned using primers designedfrom the sequence obtained (nts1 and nts2). PCR amplificationof Lp1 genomic DNA using this primer combination produced aproduct of the expected size, 210 bp, and sequencing confirmedthat this product contained a SalI site at the appropriate location(GenBank accession number AF049679). This is further confirmationthat the 4.1-kb IGS and 5.6-kb coding region fragments are linkedin vivo. The nts1-nts2 PCR product is wholly 28S rrn sequence,although we have not precisely determined the 3' end of the28S gene. The junction between the 3' end of the IGS (in pPN50)and the 5' end of the 18S gene (in pPN49) was spanned usinga primer that is the reverse complement of ns1 (WHITE et al.1990 ; referred to as nts4) and a primer designed from the sequenceof the 4.1-kb IGS clone (nts3). PCR amplification using thisprimer combination with Lp1 genomic DNA produced a product ofthe expected size, 479 bp, and sequencing confirmed that thisproduct contained a SalI site at the appropriate location (GenBankaccession number AF049246).

Digestion of the 111-/119-bp subrepeats abolishes heterogeneity:
Length variation in the IGS of other organisms results fromvariation in the number of subrepeats, and we suspected thatthe 111-/119-bp subrepeats were responsible for the length heterogeneityin Lp1. We identified two restriction enzymes (HinfI and ThaI)that cleave these subrepeats once (Figure 4). If copy-numbervariation of these subrepeats is responsible for the lengthheterogeneity, cleaving them with either HinfI or ThaI shouldabolish the heterogeneity, leaving a high-copy-number band thesize of the subrepeats.

To simplify the analysis of the results, we identified a restrictionenzyme (RsaI) that cleaves the IGS into three smaller fragmentssuitable for probes (Figure 4). Genomic DNA was cleaved withHinfI and ThaI, and the Southern blots were probed with thethree RsaI subfragments derived from the 4.1-kb IGS fragment.The results for HinfI are shown in Figure 5. None of the threeRsaI probes reveals any evidence of the length heterogeneityseen in Figure 2B. The bands present (except the 270-bp band,see below) are all of the sizes predicted from the sequenceof the 4.1-kb IGS clone. The probe covering the region thatincludes the 111-/119-bp subrepeats is the 2.1-kb RsaI probe.This shows no evidence of length heterogeneity after HinfI digestionfor any Lp1 culture studied, and, as predicted, there is a stronglyhybridizing band the size of a single subrepeat (~115 bp). Inone of the Lp1 laboratory cultures (Lp1A), an unexpected bandis found (1.1 kb; marked with an asterisk). This appears tobe a length polymorphism in the spacer that is not the resultof the 111-/119-bp subrepeats. However, it is not able to explainthe level of the IGS length heterogeneity seen in Figure 2B.The precise nature of this polymorphism is not clear. Digestionwith ThaI also abolished all evidence of length heterogeneity(A. R. D. GANLEY, unpublished results). Abolition of lengthheterogeneity with enzymes that cut the 111-/119-bp subrepeatsdemonstrates that the IGS length heterogeneity is the resultof copy-number variation of the 111-/119-bp IGS subrepeats.

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Figure 5. Digestion of the 111-/119-bp IGS subrepeats abolishes the length heterogeneity. Genomic DNA was digested with HinfI and fractionated through a 3.0% agarose gel and transferred to a nylon membrane. The resulting Southern blot was probed with the three RsaI IGS subfragments shown in Figure 4. All three probes produce the expected pattern of hybridizing bands, and their sizes are indicated (refer to Figure 4). The two exceptions are the 270-bp band seen with the 2.1-kb RsaI probe and the band marked with as asterisk (see text). Several bands smaller than 200 bp are not visible in all these exposures. A strongly hybridizing band at ~115 bp is observed with the 2.1-kb RsaI subfragment. This band corresponds to the 111-/119-bp subrepeats, and the strong hybridization indicates high copy number. None of these RsaI probes show any evidence of length heterogeneity. Lp1A and Lp1C genomic DNA is from first-round single-spore-purified cultures.

Probing E. typhina isolate E8 genomic DNA with the 2.1-kb RsaIfragment produces the same bands seen in Lp1, except that theintensity of hybridization of the band at ~115 bp is not asstrong (Figure 5). The N. lolii isolate Lp5 produces a somewhatdifferent pattern of bands, and there does not appear to beany hybridization at ~115 bp (Figure 5). The IGS structure inLp5 appears to differ from that found in Lp1 and E8 (see below).

Arrangement of the 111-/119-bp subrepeats in the IGS:
Information on the number and distribution of repeats withinan array can give insights into the processes that are shapingthe array. We used MVR-PCR (JEFFREYS et al. 1991 ) to determinethe order of the two types of subrepeats in the 111-/119-bpsubrepeat array (DOVER et al. 1993 ). We found that the HighFidelity Taq DNA polymerase (Boehringer-Mannheim) used in thePCR reactions had difficulty in traversing these subrepeats.Hence, two MVR-PCR reactions, initiating from each end of thesubrepeat array, were needed to determine the order of the entirearray in the clone. The strategy we used to determine the orderof the subrepeat array is shown schematically in Figure 6,and we carried this out for both the Lp1 clone (pPN50) and genomicDNA. The order of subrepeats for each half of the array is determinedby reading the order of bands up the pairs of lanes in the gelsshown in the lower part of Figure 6 for each L-R subrepeat-specificprimer set. Combining the results from each end of the arrayand finding the overlap gives the complete order of subrepeatsin the clone (shown in Figure 6). No obvious pattern of organizationof the two subrepeats is evident.

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Figure 6. Multivariant repeat PCR analysis of the 111-/119-bp subrepeats. The upper part of the figure shows the general scheme used for the MVR-PCR analysis. The 111-/119-bp subrepeats are shown in boxes; the orientation is the same as that shown in Figure 4. The first round of PCR amplification is shown schematically from each end of the subrepeat array. The subrepeat-specific primers 111-L, 111-R (open arrows), 119-L, and 119-R (stippled arrows) anneal specifically to the appropriate subrepeat in the array, and they amplify the intervening sequence in combination with the anchor-L or anchor-R primers (solid arrows). The ladder of products from this first round of amplification is shown as thick lines. These products are then stably amplified by further PCR rounds using the TAG primer (shown as a filled tail on the subrepeat-specific primers) and the anchor-L/anchor-R primers. The amplification products from the IGS clone (pPN50) and Lp1 genomic DNA for each half of the subrepeat are shown in the gels in the lower part of the figure. Reading the ladders of subrepeats from the gels gives the order of the subrepeats. The subrepeat order in the upper part of the figure is the order found in the IGS clone. An extra band seen with genomic DNA on the left-hand side of the array is indicated by an asterisk.

The 111-L subrepeat-specific primer is not specific for the111-bp subrepeats, but it amplifies both the 111- and 119-bpsubrepeats equally well. This is likely to be a consequenceof the primer sequence, as the only bases in this primer thatare specific for the 111-bp subrepeat are the two 3'-most bases.This difference does not appear to be sufficient to distinguishthe two subrepeats under the PCR conditions used. Raising theannealing temperature abolished amplification (data not shown),presumably because of the left anchor primer failing to anneal.This lack of specificity does not prevent the ordering of thesubrepeats because the specificity of the 119-L subrepeat-specificprimer clearly shows the order.

The results for the MVR-PCR with genomic DNA are also shownin the gels in Figure 6. The results for genomic DNA give someidea about the conservation or lack thereof of subrepeat orderin the IGS within the rDNA cluster. The bands from the right-handside of the subrepeat array can be ordered for about six subrepeats,and this order is the same as in the clone. The specificityof banding is not as clear as in the clone, indicating thatsome heterogeneity of subrepeat order exists among the populationof IGS, but, nevertheless, the order can be determined. Conversely,the results for the left-hand side of the subrepeat array donot resemble the clone, and there does not appear to be anyclear ordering of the subrepeats at this edge of the array.Once again, the lack of specificity of the 111-L subrepeat-specificprimer is not likely to confound the results, as gaps in the119-L subrepeat-specific primer ladder would be expected. Instead,the 119-L subrepeat-specific primer anneals to many more subrepeatswith genomic DNA as the template than with the clone. This indicatesthat the population of IGS has considerable variation in theorder of subrepeats at this end of the array. Another featurenot found with the clone is the presence of an extra band inthe ladder of subrepeats on the left-hand side of the array(marked with an asterisk in Figure 6). This appears to resultfrom two truncated subrepeats appearing in the array, whosecombined size is approximately that of a single, full-lengthsubrepeat. These truncated subrepeats would not contain HinfIsites, and this appears to be the origin of the 270-bp bandseen in Figure 5 that is not predicted from the IGS sequence.

Lp1 rDNA is derived from E8:
To determine how the sequence of the rDNA in Lp1 related tothe hybrid nature of Lp1, PCR was performed with genomic DNAfrom the two progenitor isolates and with genomic DNA from Lp1.We used the nts1-nts2, nts3-nts4, and nts7-nts8 primer combinations(refer to Figure 4). The resulting PCR products were sequencedand compared. Lp1 and E8 had identical sequences for all threePCR products. Comparing the nts1-nts2 PCR products derived fromthe 3' end of the 28S rrn gene, between Lp1 and Lp5, we foundsix substitutions and one indel over 205 bp (94.6% identity).Comparing the nts3-nts4 PCR products derived from the 3' endof the IGS, between Lp1 and Lp5, we found 30 substitutions andthree indels over 482 bp (93.7% identity). No product was amplifiedusing nts7-nts8 in Lp5, indicating that this region is sufficientlydifferent in this endophyte to prevent amplification (GenBankaccession numbers AF049246, AF049673, AF049674, and AF049677, AF049678, AF049679, AF049680, AF049681). Therefore, therDNA in Lp1 appears to be exclusively derived from E8, withno evidence of any Lp5 rDNA sequence being found. Restrictionenzyme digests and Southern blotting data are all consistentwith this conclusion.

DISCUSSION

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ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

The results reported here reveal a high level of length heterogeneityin the ribosomal IGS region of the hybrid endophyte isolateLp1. We have shown that this heterogeneity is intragenomic andis not the result of length differences between cells. The lengthheterogeneity arises from copy-number variation of a subrepeatclass, the 111-/119-bp subrepeats, which are located withinthe IGS. This copy number variation is likely to be a consequenceof unequal crossing over occurring in the register of the 111-/119-bpsubrepeats. Unequal crossing over occurs when tandemly repeatedelements misalign and then undergo a reciprocal exchange. Asa consequence of this misalignment, the two reciprocal productsthat are formed each contain a different number of repeats fromthe original molecules, and the extent of misalignment determinesthe extent of change of copy numbers in the products. IGS lengthheterogeneity as a consequence of copy-number variation of subrepeatshas been reported in a number of organisms previously, includingvertebrates (WELLAUER et al. 1976 ; BOTCHAN et al. 1977 ; KRYSTAL and ARNHEIM 1978 ; ARNHEIM and KUEHN 1979 ), insects(WELLAUER and DAWID 1978 ; SCHAFER et al. 1981 ; COEN et al.1982 ; ISRAELEWSKI and SCHMIDT 1982 ; TAUTZ et al. 1987 ),plants (see ROGERS and BENDICH 1987 ), and fungi (MARTIN 1990). However, the extent of the length heterogeneity, the factthat it is clearly intragenomic, and the sudden appearance ofthe heterogeneity from organisms that do not display such heterogeneity(the two progenitor isolates) make this system particularlyinteresting.

The unequal crossing over we have demonstrated within the IGSsubrepeats is likely to play a role in the concerted evolutionof the whole rDNA if there is also unequal crossing over betweenwhole rDNA units. There is no a priori reason to suspect thatmisalignment of the subrepeats occurs with equal crossing overof the rDNA units in the array. Indeed, the size of the rDNAcluster is found to vary in many species, implying that variationin rDNA unit copy number as a result of unequal crossing overis common. Therefore, we propose that the unequal crossing overthat generates the copy number variation of the 111-/119-bpsubrepeats in the IGS is concomitant with unequal crossing overin the register of the rDNA units and, therefore, plays a homogenizingrole in the concerted evolution of the Lp1 rDNA.

These data present an apparent paradox—the process thatplays a role in the homogenization of repeats (unequal crossingover) is responsible for generating a high level of heterogeneityin these repeats. This paradox is expected as the homogenizationprocess is working at the sequence level, and the misalignmentthat drives the sequence homogenization produces heterogeneityat the level of length. So unequal crossing over will tend tospread a particular repeat throughout the array, but, as thisrepeat spreads, different copies acquire different numbers ofsubrepeats strictly as a result of the process of spread (KELLYet al. 1990 ).

Although the distinction between mitotic and meiotic recombinationis well appreciated, little has been done to assess the relativeroles that these different forms of recombination play in concertedevolution. The unequal crossing over we have demonstrated hereis strictly mitotic, as Lp1 is an asexual organism (M. CHRISTENSEN,personal communication). There is evidence, aside from the lackof breakdown of multigene families in asexual organisms, thatmitotic recombination plays an important role in concerted evolution.Both unequal crossing over (SZOSTAK and WU 1980 ) and gene conversion(JACKSON and FINK 1981 ) occur in mitosis. Interestingly, therate of mitotic recombination is normally low in the genome,with the rDNA being an exception to this rule (SZOSTAK and WU1980 ). It has even been suggested that meiosis may slow therate of homogenization that would occur with mitosis alone (ELDERand TURNER 1995 ). However, it is likely that the importanceof mitosis in concerted evolution is the result of intrachromosomalrather than interchromosomal recombination doing much of the"work" in concerted evolution, as mitotic recombination is primarilyintrachromosomal. Our results concur with this idea.

The rate and nature of turnover in the IGS:
The rate of turnover caused by unequal crossing over in Lp1is high. Two rounds of single-spore purification are sufficientto produce noticeable changes in the pattern of IGS lengths(Figure 2B). Furthermore, this turnover is able to produce drasticchanges in a relatively short space of time. The two laboratorycultures presented here, Lp1A and Lp1C, were derived from theinitial isolate culture Lp1 and were maintained as separateplate cultures for ~4 yr before the DNA used in this study wasextracted. In this time, they have evolved their own distinctbanding profiles, arising from one initial profile. Other laboratorycultures have evolved their own distinct profiles as well (A.R. D. GANLEY, unpublished results). This rapid rate of turnovermay explain the remarkable spread of IGS lengths that we observe.The longest IGS lengths must contain at least 200 subrepeatunits. This would involve a great number of sequential unequalcrossing over events from the original 10–15 subrepeats.The problem is exacerbated if the degree of misalignment allowedin unequal crossing over is small. However, it also remainspossible that the long IGS lengths that show up faintly withE8 in Figure 2 may have somehow "seeded" the great number oflong IGS lengths found in Lp1.

The changes in the IGS banding pattern through the two roundsof single-spore purification have an unexpected feature. Severalof the bands that appear or disappear through the single sporingare strongly hybridizing and, therefore, must represent a numberof copies of that particular IGS length. Unequal crossing overbetween rDNA units will result in the stochastic loss or gainof rDNA units. Therefore, loss of a strongly hybridizing bandis likely to represent the loss of a block of rDNA units, allwith the same IGS length. This implies that rDNA units withthe same IGS lengths are clustered together, and further impliesthat the strongly hybridizing bands that appear are also clustered.Clustering of length variants may arise when the degree of misalignmentin recombination is small. SZOSTAK and WU 1980 found thatthe degree of misalignment in yeast rDNA mitotic unequal crossingover was six to eight units, and this corresponds well withthat found in Drosophila melanogaster 5S RNA unequal crossingover (SAMSON and WEGNEZ 1988 ). DVORAK et al. 1987 showedthat gene conversion in the IGS subrepeats was distance dependent.These results suggest that clustering may arise as a consequenceof the localized mode of action of the homogenization mechanism(s),and DVORAK and APPELS 1986 , CREASE 1995 , and COPENHAVERand PIKAARD 1996 explained clustering along these lines. However,the limited time required by our results to generate such clusteredlength variants stretches the bounds of plausibility, as severalsequential misalignment events would be required in the amountof mitotic growth it takes to generate a fungal disk from asingle spore (assuming a length variant arises once and is thenamplified). The process also appears to be targeted in the sensethat only very few length variants alter their copy number,but those that do then change by a significant number of copies. REEDER et al. 1976 found a similar phenomenon in the rDNAof Xenopus laevis. They suggested this was a consequence ofextrachromosomal amplification of rDNA units and their insertioninto the rDNA array. However, this form of amplification, welldocumented in the oocytes of Xenopus, has not been reportedin fungi.

The IGS lengths we see do not represent a clean ladder of bandsat ~115-bp intervals, as one might expect if the length variedas a result of the 111-/119-bp subrepeats. Instead, the numberof lengths observed is limited (the cultures presented in Figure2 contain 8–16 predominant bands). Lp1A in particular showsa very skewed range of IGS lengths, falling almost entirelyin either the high- or low-molecular-weight part of the range.Restriction of IGS lengths to a small number of the total possibleset is presumably the result of a homogenization process that(stochastically) amplifies this subset of IGS lengths at theexpense of others. This homogenization process is unlikely tobe unequal crossing over, as this would tend to increase theIGS length variation as long as there was misalignment of thesubrepeats. We are then left with the possibility that geneconversion is responsible for the restriction of IGS lengthswe observe. Previous workers have proposed a combination ofmechanisms to account for homogenization (WILLIAMS et al. 1989; LINARES et al. 1994 ; CREASE 1995 ).

Molecular details of the IGS subrepeat behavior do not conform to the standard model of unequal crossing over:
Our lack of understanding of the mechanisms behind homogenizationextends to a lack of knowledge of the biochemistry and geneticsof these mechanisms. Therefore, systems that provide data onthe particular mechanisms of homogenization, such as the onewe have studied, may also provide information on the moleculardetails of these mechanisms.

In repeat arrays shaped by the forces of unequal crossing over,variants that arise and become eliminated from the array doso by being moved to the edges of the array, a phenomenon knownas terminal exclusion (DOVER et al. 1993 ). This occurs becausethe crossover point is assumed to be random. The MVR-PCR analysiswe performed gives the order of the 111-/119-bp subrepeats inthe clone, and the distribution of the presumed "variant" (119-bp)subrepeat toward the center of the array shows that terminalexclusion is not occurring for this IGS. The results in genomicDNA corroborate this. We also find little evidence from thesequence for degraded subrepeats at the edges of the array.Two alternative but not mutually exclusive explanations canbe made for the lack of terminal exclusion. Either the 111-and 119-bp subrepeats are both required for some role in theIGS, particularly its concerted evolution, or other forces alongsideunequal crossing over are also shaping this subrepeat array.

The incongruity in subrepeat patterns between the right andleft sides of the array in genomic DNA (Figure 6) is unexpected.From the assumption of crossing over occurring at a random point,it follows that both ends of the array should behave the same,but they appear not to, as one end resembles the clone and theother does not. Two explanations are possible: either the crossoverpoint is not random but is specifically initiated from one sideof the array, or other forces alongside unequal crossing overare involved in the subrepeat array. Although we have presentedsome circumstantial evidence for mechanisms of homogenization,most probably gene conversion, that occur alongside unequalcrossing over in the rDNA, we believe there is little justificationfor assuming a random crossover point; thus, the first explanationmerits further consideration.

Many advances have been made recently in understanding the biochemistryof recombination. In the best-studied system, the Chi systemin prokaryotes (reviewed in EGGLESTON and WEST 1996 ), a double-strandbreak (DSB) is made, and the RecBCD complex unwinds and degradesthe DNA until it encounters a Chi sequence from the 3' sidein the correct orientation. Further unwinding generates a single-strandtail with Chi at its 3' end, which initiates pairing and strandexchange with the help of RecA. Thus, Chi has both orientationdependence and directionality. Holliday junctions are formed,and branch migration occurs via the action of RuvAB. Finally,resolution of the Holliday junction to generate recombinantmolecules is catalyzed by RuvC, which preferentially nicks theDNA at a short target sequence. Thus, there are three potentialsites that mediate recombination—initiation of DSB, initiationof strand exchange, and a signal to resolve the Holliday junction.

Biochemical understanding of eukaryote recombination lags behindthat of prokaryotes, but many features seem to be conserved.If recombination in the Lp1 rDNA also required these three sitesof recombination mediation, nonrandom crossover points couldresult. A potential model for bias of the crossover point tothe left-hand side of the 111-/119-bp subrepeat array (in theorientation shown in Figure 6) is presented in Figure 7.

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Figure 7. Model detailing bias of the cross-over point to the left-hand side of the 111-/119-bp subrepeat array. The diagram shows a hypothetical model for unequal crossing-over in the Lp1 IGS with the 111-/119-bp subrepeats misaligned. Initiation proceeds via a DSB (shown here in the 40-bp subrepeats) with exonuclease activity proceeding up to an initiator of strand exchange (shown as arrowheads in the 111-/119-bp subrepeats). The crossover point is then determined by the site of Holliday junction resolution. This preferentially occurs at a cleavage site (shown as asterisks) in the 111-/119-bp subrepeats once branch migration has proceeded to such a site. The 40-bp subrepeats are shown as shaded boxes. Individual 111-/119-bp subrepeats are delineated by short, vertical lines. Broken lines indicate exonuclease activity, and dotted lines indicate flanking sequence. The strand exchange initiator is only shown on the initiating strand, and the orientation dependence is indicated by the direction of the arrowheads. Cleavage of the Holliday junction on the outer strands as shown will result in reciprocal exchange products. The diagram is not drawn to scale.

First, a DSB is made to the left of the 111-/119-bp subrepeatarray. We have diagrammed this occurring in the 40-bp subrepeats,as LINARES et al. 1994 in their examination of the unusualsubrepeat organization in the D. melanogaster rDNA IGS implicateda smaller, more poorly maintained subrepeat array containingsimple sequence motifs in the initiation of gene conversionthat shapes the larger subrepeat array. An area of sequencesimplicity has also been implicated in rDNA recombination inwheat (BARKER et al. 1988 ). Therefore, subrepeat arrays withsimple sequence motifs may act as recognition sites for theinitiation of recombination, perhaps as the site of DSB.

The DSB may then be enlarged by exonuclease activity until aninitiator of strand exchange with orientation dependence analogousto Chi is reached. It is interesting to note that the 111-bpsubrepeat contains a sequence (AGTGGTGG; the reverse complementof the sequence shown in Figure 4) that is very similar tothe Chi sequence (GCTGGTGG). This is in the orientation thatwould stimulate recombination if the DSB initiation point wereto the left-hand side of the subrepeat array, and it containsthe two paired guanosines that HIBNER et al. 1991 found tobe present in many recombination-stimulating sequences.

Finally, branch migration would extend the resulting Hollidayjunction to a consensus site of a Holliday junction resolvasesuch as a topoisomerase I (SEKIGUCHI et al. 1996 ). If thissite were in the 111-/119-bp subrepeats and occurred on theouter strands as diagrammed in Figure 7, then resolution wouldresult in crossing over, with the crossover point biased tothe left-hand side of the subrepeat array. The extent of branchmigration would determine how far to the right the crossoverpoint occurred. Bias of crossover to the left-hand side of thesubrepeat array would conserve the subrepeat order at the right-handend of the array while tending to rearrange the order at theleft-hand end, unless misalignments occurred with the right-handside of one of the subrepeat arrays. This is consistent withthe observed results.

Lp1 is a hybrid organism, and the two progenitor isolates havebeen identified. The size of the "original" IGS in Lp1 is thereforeknown, as both progenitors have IGS lengths of ~4 kb. This leadsto an interesting conclusion—the length heterogeneity inLp1 is almost exclusively an increase in length, yet the reciprocalnature of unequal crossing over dictates that for every largerproduct formed, a smaller product must also be formed. The smallestIGS length is 3.5 kb, which would contain nine 111-/119-bp subrepeats—enoughfor more to be lost. This suggests a form of "selection" againstshort spacers. We propose some sort of homology interaction.It seems likely that the recombination equipment is limiting(LOIDL and NAIRZ 1997 ), leading to competition between rDNAunits for this equipment. JINKS-ROBERTSON et al. 1993 and YUAN and KEIL 1990 found that recombination in yeast betweennontandem duplications requires at least 250 bp of homology,and the rate increases linearly up to 1 kb of homology, afterwhich it plateaus off. Nine 111-/119-bp subrepeats represent~1 kb; therefore efficient recombination might be achieved onlyby rDNA units with at least this number of subrepeats. It isinteresting in this light that MCKEE et al. 1992 found thatmeiotic chromosome pairing in D. melanogaster required at leasttwo rDNA IGS subrepeat elements. Spread of a repeat throughan array by unequal crossing over requires that repeat to participatein unequal crossing over, so any repeats not participating inunequal crossing over, such as those with short 111-/119-bpsubrepeat arrays, will be eliminated from the array as otherrepeats spread.

The IGS length heterogeneity arises through hybridization:
The extraordinary length heterogeneity in the Lp1 IGS seemsto be a consequence of the hybridization event, as neither ofthe Lp1 progenitors show such length heterogeneity. However,it does not seem to be an outcome of hybridization per se, asother hybrid endophytes from independent hybridization eventsdo not display such IGS length heterogeneity (A. R. D. GANLEY,unpublished results). Rather, control of length homogeneityseems to have been disrupted as a result of the hybridization.The nature of this disruption is not known, but could fall intothree general categories: (1) loss of alignment control of the111-/119-bp subrepeats, allowing misalignment that would generatethe length heterogeneity and (2) loss of control of a maximumlength for the 111-/119-bp subrepeat array. STEPHAN and CHO1994 established a theoretical base for selection of a maximumsize limit for a repeat array that is required for its maintenance,and WILLIAMS et al. 1987 invoked a similar form of selectionon experimental grounds. Although no mechanism of action isknown, it is possible that such an activity exists, or (3) alterationin the relative balance of gene conversion and unequal crossingover in favor of crossing over, destabilizing control of length.Such disruptions could be a consequence of chromosome expulsionduring hybridization, gene doubling, or novel interactions betweenthe two genomes analogous in a sense to the phenomenon of nucleolardominance (REEDER and ROAN 1984 ).

Concluding comments:
The very nature of multigene families makes them recalcitrantto analysis of the mechanisms behind their evolution. We havedemonstrated the occurrence of unequal crossing over in therDNA of Lp1, and this implies that unequal crossing over isa mechanism of homogenization in the concerted evolution ofthe rDNA. We have also presented circumstantial evidence forthe specific initiation and for homology requirements of unequalcrossing over, as well as circumstantial evidence for the involvementof another mechanism of homogenization, most probably gene conversion,in the concerted evolution of the rDNA in Lp1. As our understandingof the biochemistry and genetics of recombination increases,we will be able to transfer this knowledge to systems undergoingconcerted evolution to test for similarities and differences.In the meantime, we must look to the systems that have beencharacterized, as well as to new systems, to find common threadsthat present testable ideas to tease out the details of themechanisms responsible for homogenization.

ACKNOWLEDGMENTS

We thank Carolyn Young, Kim Gan, Dianne Bird, and Kelly Marriottfor expert technical assistance. We thank Mike Christensen forassistance with endophyte biology, especially the single-sporingwork, and John Mackay for advice on PCR. We are also gratefulto Max Scott, Brendon Monahan, and David Penny for helpful discussions.This work was supported by a Massey University Doctoral Scholarshipto A.R.D.G.

Manuscript received April 13, 1998; Accepted for publication August 22, 1998.

LITERATURE CITED

TOP
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RESULTS
DISCUSSION
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