Terminal Regions of Wheat Chromosomes Select Their Pairing Partners in Meiosis

doi:10.1534/genetics.107.078121

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Terminal Regions of Wheat Chromosomes Select Their Pairing Partners in Meiosis

Eduardo Corredor^*, Adam J. Lukaszewski, Paula Pachón^*, Diana C. Allen and Tomás Naranjo^*^,1

^* Departamento de Genética, Facultad de Biología, Universidad Complutense, 28040 Madrid, Spain and Department of Botany and Plant Sciences, University of California, Riverside, California 92521

^¹ Corresponding author: Departamento de Genética, Facultad de Biología, Universidad Complutense, José Antonio Novais, 2, 28040 Madrid, Spain.
E-mail: toranjo{at}bio.ucm.es

Manuscript received June 25, 2007. Accepted for publication August 7, 2007.

ABSTRACT

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
LITERATURE CITED

Many plant species, including important crops like wheat, arepolyploids that carry more than two sets of genetically relatedchromosomes capable of meiotic pairing. To safeguard a diploid-likebehavior at meiosis, many polyploids evolved genetic loci thatsuppress incorrect pairing and recombination of homeologues.The Ph1 locus in wheat was proposed to ensure homologous pairingby controlling the specificity of centromere associations thatprecede chromosome pairing. Using wheat chromosomes that carryrye centromeres, we show that the centromere associations inearly meiosis are not based on homology and that the Ph1 locushas no effect on such associations. Although centromeres indeedundergo a switch from nonhomologous to homologous associationsin meiosis, this process is driven by the terminally initiatedsynapsis. The centromere has no effect on metaphase I chiasmatechromosome associations: homologs with identical or differentcentromeres, in the presence and absence of Ph1, pair the same.A FISH analysis of the behavior of centromeres and distal chromomeresin telocentric and bi-armed chromosomes demonstrates that itis not the centromeric, but rather the subtelomeric, regionsthat are involved in the correct partner recognition and selection.

POLYPLOIDY is widely acknowledged as a major mechanism of adaptationand speciation in plants. It is estimated that between 47 and70% of angiosperms are polyploid (RAMSEY and SCHEMSKE 1998).Most polyploid plant species, including important crops likewheat, are allopolyploids that arose after hybridization betweenrelated diploid progenitors. The polyploid condition conferssome advantages such as heterosis or gene redundancy but impliesdisadvantages such as the propensity to produce aneuploid meioticproducts that reduce fertility (COMAI 2005). This effect onfertility is conditioned by the presence of more than two geneticallyrelated chromosome sets capable of meiotic pairing. Many polyploidspecies have evolved genetic regulatory systems that ensurea diploid-like behavior with efficient disjunction of homologouschromosomes at the first division (JENCZEWSKI and ALIX 2004).The best-studied example is common bread wheat, Triticum aestivum,an allohexaploid species (2n = 6x = 42) with three genomes,A, B, and D, from three related diploid species. In spite ofthe genetic synteny between homeologous chromosomes, bread wheatforms 21 bivalents at diakinesis and metaphase I (MI) of meiosis.Several loci have been identified that affect chromosome pairingin hexaploid wheat (reviewed by SEARS 1976). The exclusive formationof homologous bivalents at MI is principally controlled by thePh1 (pairing homeologous) locus on the long arm of chromosome5B (RILEY and CHAPMAN 1958; SEARS and OKAMOTO 1958). The Ph1locus has been recently localized to a 2.5-Mb region containinga segment of subtelomeric heterochromatin inserted into a clusterof cdc-2 related genes (GRIFFITHS et al. 2006). However, itsmode of action remains to be elucidated.

Three major meiotic processes—chromosome pairing (i.e.,an interaction of chromosomes that results in the alignmentof homologs), synapsis [i.e., the formation of the proteinaceoussynaptonemal complex (SC) structure between each homologouspair], and crossing over—are involved in the formationof bivalents. Homologous chromosomes previously distributedthroughout the nucleus (BASS et al. 2000; MAESTRA et al. 2002)must approach and recognize each other to enter into intimatecontact and form bivalents. How homologous chromosomes get intoclose physical proximity with each other to undergo interactionrepresents one of the least-understood mechanisms of the meioticprocess (ROEDER 1997; ZICKLER and KLECKNER 1998; PAGE and HAWLEY 2003;PAWLOWSKI et al. 2003; PAWLOWSKI and CANDE 2005). In most organisms,telomeres attach to the inner nuclear envelop and congregateto form the so-called meiotic bouquet (BASS et al. 2000; NIWA et al. 2000;TRELLES-STICKEN et al. 2000; COWAN et al. 2001; SCHERTHAN 2001;HARPER et al. 2004). This chromosome arrangement is thoughtto facilitate homologous recognition.

An ultrastructural analysis of spread silver-stained meioticnuclei of hexaploid wheat by HOLM (1986) revealed that, at thebeginning of the zygotene stage, telomeres aggregate and chromosomepairing and SC formation is initiated distally. In nuclei atmid-zygotene, generally the longest SC segments were those joiningthe distal segments. The presence of only one pairing partnerexchange in most SC multivalents formed in polyploid wheatsis also in agreement with the initiation of pairing and synapsisin distal chromosome regions (MARTÍNEZ et al. 2001a,b).Distal chromosome pairing initiation in wheat explains the failureof homologous synapsis after colchicine-induced inhibition ofbouquet formation (CORREDOR and NARANJO 2007). Distal, but notproximal, regions of wheat chromosomes are also critical forMI chiasmate chromosome associations (LUKASZEWSKI 1997; JONES et al. 2002).The commencement of pairing usually at distal sites and succeededby numerous intercalary initiations has been observed in otherplant species such as maize (GILLIES 1975), Lilium (HOLM 1977),rye (GILLIES 1985), or Allium (ALBINI and JONES 1987).

Studies denoting polarization and association of centromeresin premeiotic cells postulated a possible role of this chromosomestructure in meiotic pairing. Three-dimensional reconstructionof microsporocyte nuclei from electron micrographs of serialthin sections in Allium fistulosum, Lilium speciosum, Ornithogalumvirens, wheat, rye (Secale cereale L.), and triticale (X TriticosecaleWittmack) showed polarization of centromeres opposite the telomeresbut were not conclusive in establishing whether presynapsticcentromere association was based on homology (CHURCH and MOENS 1976;BENNETT et al. 1979; CHURCH 1981; DELFOSSE and CHURCH 1981).A fluorescence in situ hybridization (FISH) analysis of chromosomearrangement in hexaploid wheat showed that centromeres associateprior to meiosis, usually in pairs (ARAGÓN-ALCAIDE et al. 1997;MARTÍNEZ-PÉREZ et al. 1999, 2001). This suggestedthat the Ph1 locus suppresses homeologous pairing through thecontrol of the specificity of centromere association. However,MAESTRA et al. (2002) reported that, in a majority of cellsat premeiotic interphase and leptotene, two homologous chromosomesadded to wheat occupied separated territories both in the presenceand in the absence of the Ph1 locus. In early leptotene in wheat,centromeres associate in multimeric structures. On the basisof the formation of seven centromere structures in a small numberof microsporocytes at leptotene, MARTÍNEZ-PÉREZ et al. (2003)proposed that these clusters represent an important componentof the chromosome-sorting mechanism. Each cluster would includethree pairs of centromeres corresponding to chromosomes of thesame homeologous group. After homologous recognition, clustersresolve into pairs of homologous centromeres under the controlof Ph1. This hypothesis might seem feasible in the light ofthe chromosome dynamics at meiosis in yeast (TSUBOUCHI and ROEDER 2005).Centromeres of yeast chromosomes associate in pairs that initiallyare nonhomologous and then undergo switching until all pairsare homologous. Unlike in yeast, however, the composition ofindividual centromere clusters in wheat has never been establishedbecause of the paucity of chromosome- or genome-specific DNAprobes.

Telomeres and centromeres are involved in complex multimericstructures formed in presynaptic meiotic cells, in which previouslyseparate chromosomes can interact. Functionally equivalent regionsof different chromosomes, such as telomeres or centromeres,provide excellent starting points for homology recognition thatavoids scanning of the entire genome, a complicated task inlarge genomes. However, because wheat chromosomes are bi-armedand very large—in mid-zygotene they reach an average lengthof 112 µm (MARTÍNEZ et al. 2001b)—it is difficultto envisage how a mechanism of chromosome recognition operatingat the centromeres may trigger the initiation of synapsis atthe telomeres.

We have taken advantage of wheat chromosomes with centromereintrogressions from rye to study centromere positioning in earlymeiotic cells and their effect on MI chiasmate chromosome associations,both in the presence and in the absence of Ph1. These centromereintrogressions were produced by recurrent centric breakage-fusionevents (LUKASZEWSKI 1993; ZHANG et al. 2001). Rye centromerescontain species-specific repeats that can be identified by FISHwith probe pAWRC.1 when in a wheat background (LANGRIDGE et al. 1998;FRANKI 2001). We find that homologous centromeres are mainlyseparate in presynaptic stages and that the transition to homologousassociation is driven by synapsis. Modification of the centromereconstitution in homozygous or heterozygous condition has noeffect on MI chiasmate chromosome associations either in thewild-type or in the Ph1– mutant. On the other hand, usingchromosome-specific markers, we verify that terminal and subterminalregions pair earlier than centromeres of bi-armed chromosomes.This excludes centromeres as components of the chromosome-sortingmechanism.

MATERIALS AND METHODS

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
LITERATURE CITED

Plant material:
The following hexaploid wheat (T. aestivum; 2n = 6x = 42; genomeAABBDD) genotypes were used to analyze the role of the centromerein chromosome pairing: the wild-type (Ph1) and the ph1b (Ph1–)mutant lines in cv. Pavon 76 homozygous and heterozygous forchromosome 1B with the centromere from rye chromosome 1R (1Brc),homozygous and heterozygous for chromosome 2B with the centromerefrom rye chromosome 2R (2Brc), and a double monosomic 2Brc,2R. The role of distal regions in homologous recognition wasassessed in two lines with different conformation for the longarm (L) of rye chromosome 2R: the Robertsonian 2BS.2RL translocationline of cv. Pavon and the ditelocentric 2RL (Dt2RL) additionline of cv. Chinese Spring.

Analysis of chiasmate chromosome associations:
Anthers with pollen mother cells (PMCs) at MI were fixed ina 3:1 ethanol–acetic acid solution. Squashed preparationswere C-banded as previously described (GIRÁLDEZ et al. 1979)or subject to FISH with pAWRC.1 containing a rye-specific centromererepeat (LANGRIDGE et al. 1998; FRANKI 2001) for identificationof marked chromosomes. Observations were under a Nikon EclipseE400 microscope or Zeiss Axioscope 20. MI chiasmate chromosomeassociations were scored in plants grown in two environmentsand in three different growing seasons. As there were no significantdifferences between sites and seasons, all data were pooled.The overall levels of homologous and homeologous MI chromosomeassociations in Ph1+ and Ph1– plants was carried out byC-banding in samples of 100 PMCs for each line.

Fluorescence in situ hybridization, microscopy, and image processing:
Fixed anthers were digested in a pectolytic enzyme mixture,transferred to a clean slide, and spread according to ZHONG et al. (1996).This procedure involves no mechanical pressure to spread thecells on the slide and the three-dimensional information islargely preserved. Preparations were pretreated as previouslydescribed (MAESTRA et al. 2002).

For the analysis of the behavior of centromeres and distal chromosomeregions, the following repeat DNA probes were used: clone pAtT4containing the Arabidopsis telomeric tandem repeat (RICHARDS and AUSUBEL 1988),clone 6C6 containing a cereal-specific centromere repeat (ZHANG et al. 2004),clone pAWRC.1 containing a rye-specific centromere repeat, clonepSc74 containing a rye-specific 480-bp tandem repeat (BEDBROOK et al.1980;CUADRADO and SCHWARZACHER 1998), clone pSc119.2 containing a120-bp tandem repeated sequence unit from rye that identifieswheat B-genome chromosomes (BEDBROOK et al.1980; MUKAI et al. 1993;CUADRADO and JOUVE 1994), and sonicated or boiled rye genomicDNA (fragment size <2 kb). These clones were used in differentcombinations for in situ hybridization as previously described(MAESTRA et al. 2002; CORREDOR and NARANJO 2007). Concentrationsof DNA probes in the different hybridization mixes were 5 ng/µlfor pAtT4; 10 ng/µl for 6C6, pAWRC.1, pSc74, and pSc119.2;and 2.2 ng/µl for rye genomic DNA.

Clones pAtT4, 6C6, pAWRC.1, pSc74, and pSc119.2 were labeledby nick translation with biotin-16-dUTP or digoxigenin-11-dUTP,and rye genomic DNA was random primed labeled with digoxigenin-11-dUTP.In the Dt2RL and 2BS.2RL plants, pAtT4 was labeled with bothdigoxigenin-11-dUTP and biotin-16-dUTP to produce an orangecolor. Two sequential rounds of hybridization were used formulticolor painting of chromosome 2RL with pAtT4, pAWRC.1, pSc199.2,and rye total genomic DNA probes in somatic cells. The digoxigenin-labeledprobes were detected with 6–8 ng/µl of the FITC-conjugatedantidigoxigenin antibody (Sigma, St. Louis) in 4B (0.5% blockingreagent in 4x SSC) and biotin-labeled probes with 10–15ng/µl of the Cy3-conjugated avidine (Sigma) in 4B.

Microscopy and image processing have been previously described(CORREDOR and NARANJO 2007).

RESULTS

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
LITERATURE CITED

Chromosome pairs studied:
We have used wheat chromosomes 1B and 2B with the rye centromeres(rc) (1Brc and 2Brc, respectively) to produce lines that havemodified the centromere constitution of one chromosome pairin both the presence and absence of the Ph1 locus. The threechromosome combinations that we studied were (i) chromosomepairs 1Brc–1Brc and 2Brc–2Brc (homologous chromosomes–homologouscentromeres; Figure 1A; supplemental Figure 1 at http://www.genetics.org/supplemental/),(ii) chromosome pairs 1B–1Brc and 2B–2Brc (homologouschromosomes–homeologous centromeres; Figure 1A), and (iii)chromosome pair 2Brc–2R, the first from wheat and thesecond from rye (homeologous chromosomes–homologous centromeres;Figure 1B; supplemental Figure 1).

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FIGURE 1.— Rye-specific DNA sequences in centromeres of wheat and rye chromosomes and their arrangement at early meiosis. (A) Bivalents 2Brc–2Brc and 2B–2Brc at MI with rye centromeres labeled with probe pAWRC.1. Signals of the pSc119.2 probe identify B-genome chromosomes. (B) Rye centromere in univalents 2Brc and 2R at MI; chromosome 2R shows the location of the rye-specific pSc74 DNA repeat. (C) Nuclei at early leptotene (EL), leptotene–zygotene transition (LLEZ), late zygotene (LZ), and pachytene (P) of homozygotes 2Brc–2Brc and double monosomic 2Brc–2R. Homologous centromeres of rye (arrows) are separated in EL and LZ and associated in LLEZ and P, respectively. Wheat centromeres and telomeres were labeled with the 6C6 and pAtT4 DNA probes, respectively. (D) Frequency of associations of homologous rye centromeres in pairs 1Brc–1Brc, 2Brc–2Brc, and 2Brc–2R at EL, LLEZ, mid-zygotene (MZ), LZ, and P stages in Ph1+ and Ph1– wheat lines. Mean number of PMCs, n = 43 ± 3. Bars, 10 µm.

The wild-type and Ph1– mutant phenotypes:
The main phenotypic feature of Ph1– mutant wheat is theformation of multivalent configuration at MI, which is accompaniedby a reduction in the number of chiasmate chromosome associations.We have verified the genotype of the lines studied by quantificationof the overall levels of chromosome configurations at MI insamples of 100 PMCs. The results obtained appear in Table 1.As expected, in the mutant lines, the mean number of multivalentsper cell increases and the mean number of bound arms decreasesrelative to wild-type lines.

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TABLE 1 Mean values of univalents, ring bivalents, open bivalents, trivalents, and other multivalents and bound arms per cell at metaphase I in samples of 100 PMCs of different wheat lines

Presynaptic centromere association is nonhomologous:
To determine the nature of the early centromere associationsin the presence and absence of the Ph1 locus, we analyzed byFISH the physical distribution of homologous rye centromerepairs relative to wheat centromeres, which were hybridized withprobe 6C6 in plants with 1Brc–1Brc, 2Brc–2Brc, and2Brc–2R in meiocytes from leptotene to pachytene (Figure 1C).In leptotene, telomeres migrate to form a tight cluster andcentromeres appear as compact structures. Chromatin undergoesa conformational change that results in chromosome elongation(MIKHAILOVA et al. 1998; MAESTRA et al. 2002), which is apparentin centromere signals at the leptotene–zygotene transition.As synapsis progresses in mid-zygotene, the telomere bouquetdisintegrates (HOLM 1986). Late zygotene and pachytene are postbouquetstages, with high levels of synapsis or with complete synapsis(HOLM 1986; MIKHAILOVA et al. 1998), and differ by the degreeof chromatin condensation.

In leptotene of the Ph1+ lines, rye centromere pairs 1Brc–1Brcand 2Brc–2Brc were physically separated and included indifferent clusters (Figure 1C) in 88% of meiocytes (Figure 1D).The labeled centromeres were considered to be physically associatedin the remainder meiocytes (12%), which showed only one FISHsignal or two signals in the same cluster and were separatedby <1 µm. The latter was an infrequent event. The frequencyof associations of these rye centromeres increased with theprogression of meiosis, reaching 100% for 2Brc–2Brc atpachytene. A low frequency of homologous centromere associationsin leptotene and a gradual increase through the zygotene–pachytenesuggests that these associations are a result of the synaptonemalcomplex expansion and not some presynaptic event or process.In Ph1–, the arrangement of labeled centromeres of the1Brc–1Brc and 2Brc–2Brc pairs at leptotene was similarto that in Ph1+. The level of associations in pairs increasedin the course of prophase I but the frequencies observed inzygotene and pachytene were lower than the corresponding frequenciesin the wild type. We interpret this as being in agreement witha delay in the initiation and development of synapsis in theabsence of a functional Ph1 allele, known to exist in wheat(MIKHAILOVA et al. 1998; MAESTRA et al. 2002). Homologous centromeresin the 2Brc–2R pair were separated in 97 and 100% of Ph1+and Ph1– cells at leptotene, respectively, and their associationlevel did not increase in the course of prophase I. These observationssupport the conclusion that, in wheat, centromere clusteringin early meiosis is not based on homology and therefore cannotpromote recognition of homologous chromosomes. The transitionfrom nonhomologous to homologous centromere associations inmeiotic prophase is driven by synapsis; because synapsis beginsat the ends of homologs, eventually homologous centromeres associate.

Centromere heterozygosity does not affect pairing and recombination:
If synapsis expansion brings homologous centromeres together,centromere identity cannot influence the selection of the correctpartner for pairing and recombination. We have tested this hypothesisby studying the level of chiasmate chromosome associations atMI for chromosomes with rye centromeres. Each pair can forma ring bivalent or an open bivalent or fail to pair (Figure 1, A and B).We have quantified the frequency of arms bound for each chromosomepair in the presence and absence of the Ph1 locus (Table 2).

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TABLE 2 MI frequencies of bound arms per chromosome for chromosome pairs with replaced centromeres

Homozygosity or heterozygosity for the centromere had no effecton the frequencies of the MI chiasmate associations of labeledchromosome in Ph1+. Pairs 1Brc–1Brc and 1B–1Brcand pairs 2Brc–2Brc and 2B–2Brc showed almost equalnumbers of bound arms. In the Ph1– lines, pairs 2Brc–2Brcand 2B–2Brc behaved in the same way but the 1Brc–1Brchomozygote showed a decrease in the mean number of arms boundper pair relative to the 1B–1Brc heterozygote. This resultis explained by reduced overall chiasmate bonds in the former(Table 1). The Ph1 locus is known to suppress pairing betweenstandard chromosomes 2B and 2R (NARANJO et al. 1987); in Ph1–,there is practically no chiasmate association of the short armsand some chiasmate association of the long arms (NARANJO and FERNÁNDEZ-RUEDA 1996).This did not change when rye 2R and wheat 2B had identical ryecentromeres. Homologous centromeres did not make homeologouschromosomes pair and recombine, even in Ph1–. Therefore,the centromere does not determine whether or not two homeologouschromosomes can pair.

Distal regions pair earlier than centromeres:
We assessed the role of terminal regions on homologous recognitionrelative to centromeres by studying the arrangement of centromeric,subtelomeric, and telomeric markers of rye chromosome arm 2RLin the presynaptic and synaptic stages of meiosis in two differentlines of wheat: one with a Robertsonian translocation 2BS.2RLand another with a ditelosomic addition 2RL (Dt2RL). In theRobertsonian translocation, the 2RL arm is fused to 2BS andthe centromere is located in the central chromosome region.In the telocentric 2RL, the centromere is located at one telomere.Multicolor FISH labeling of 2RL highlights the positions ofthe centromere, the telomeres, a terminal heterochromatic knob,and another knob that is subterminal (Figure 2, A and B). Thesetwo knobs can be recognized by a difference in signal size.

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FIGURE 2.— The centromere and the terminal and subterminal knobs of chromosome 2RL and their arrangement in premeiotic interphase and in early meiosis. (A) The centromere and knobs of telocentric 2RL in a mitotic prometaphase after two rounds of FISH. (B) The arms 2RL and their rye centromeres in the ring bivalent formed by the 2BS.2RL translocation pair at MI after two-color FISH. (C) PMCs at the premeiotic interphase (PI), early leptotene (EL), and mid-zygotene (M) in the Dt2RL and 2BS.2RL lines showing the arrangement of the rye centromeres (red arrows), knobs (green), and telomeres (orange). Centromeres are separated in PI and ELs and associated in MZ. In the EL of Dt2RL, rye centromeres are incorporated at the telomere pole. Distal knobs are separated in PI and associated in the three other PMCs while subdistal knobs are associated only in the EL and MZ PMCs of Dt2RL. Bars, 10 µm.

In the prebouquet stage, in both chromosomes 2RL and 2BS.2RL,the terminal and subterminal knobs were associated in <8%of PMCs (Figure 3). Telomere convergence increased the frequencyof these associations. At the leptotene–zygotene transition,the terminal knobs on 2RL were associated in 65 and 68% of PMCsin the Dt2RL and 2BS.2RL lines, while the subterminal knobswere associated in 37 and 27% of the meiocytes, respectively.These differences are consistent with the progression of synapsisfrom the telomere toward the center of the chromosome. At latezygotene, the levels of associations of the terminal and subterminalknobs were >92% for both chromosomes. In summary, the terminaland subterminal regions of the 2RL arm in the telocentric andthe translocation chromosomes behaved the same. The centromeres,on the other hand, behaved in a similar fashion only in thepresynaptic stages when they were located at the centromerepole of the nucleus and physically separated in 85% of cells.At early zygotene, because of the telomere dominance in bouquetformation (MAESTRA et al. 2002), the centromeres of the telocentricswere able to enter the bouquet and were paired in 59% of PMCs;centromeres of the bi-armed translocated chromosomes remainedstationary and separated (93%) at the centromere pole of thenucleus. The difference in the level of physical associationof the centromeres of the two types of chromosomes remainedthe same through mid-zygotene and decreased at late zygotene.Physical association of the centromeres of telocentrics wasat a level comparable to that of the distal knob.

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FIGURE 3.— The frequencies (%) of association of centromeres (Cen), and the terminal (Tm) and subterminal (Sm) knobs at the premeiotic interphase and in early meiosis in the Dt2RL and 2BS.2RL wheat lines. PI, premeiotic interphase. EL, early leptotene, LLEZ, late leptotene–early zygotene. MZ, mid-zygotene. LZ, late zygotene. Mean number of PMCs, n = 52 ± 6.

	DISCUSSION

TOP ABSTRACT MATERIALS AND METHODS RESULTS DISCUSSION ACKNOWLEDGEMENTS LITERATURE CITED

Our results on the behavior of labeled centromeres in earlymeiotic stages are unequivocal in showing that centromeres donot take part in the homologous recognition. Both the centromeresof chromosomes 1Rrc and 2Brc and the centromeres of the translocated2BS.2RL and telocentric 2RL are separated in leptotene. Thisarrangement was also observed for the centromeres of chromosomes5R and 5RL in wheat–rye additions (CORREDOR and NARANJO 2007).All chromosomes studied also show that the transition from nonhomologousto homologous centromere associations is affected once synapsishas been triggered at the telomeres. Exceptions are centromeresof telocentric chromosomes, such as those of chromosomes 2RLstudied here and of 5RL (CORREDOR and NARANJO 2007). These centromeresabandon the centromere pole of the nucleus during leptotene,dragged along by their telomeric sequence with which they arecapped, and incorporate into the bouquet, behaving like anydistal chromosome regions. On the other hand, homologous centromeresof nonhomologous chromosomes, such as the 2Brc–2R pairhere, that remain unpaired at MI, probably by not undergoingsynapsis, remain separated during the entire prophase I. Thus,progression of synapsis in zygotene from the telomere towardthe centromere is the main force that brings homologous centromereregions together.

An argument could be raised that, unlike the three-dimensionalstudy of MARTÍNEZ-PÉREZ et al. (1999, 2001, 2003),the chromosome spreading technique used in this study coulddisrupt the presynaptic association of homologous centromeresand hence provide misleading results. It needs, therefore, tobe pointed out that both technical approaches—the three-dimensionalconfocal microscopy on preparations from anther sections (MARTÍNEZ-PÉREZ et al. 1999,2001, 2003) and the analyses of spread nuclei (MAESTRA et al. 2002;CORREDOR and NARANJO 2007)—reveal the same associationsof centromeres in pairs in premeiotic interphase and the formationof more complex structures in early leptotene. Thus, spreadingpreserves the overall presynaptic centromere arrangement detectedin intact nuclei.

As deduced from the MI chromosome association results, centromereconstitution does not affect the ability of chromosomes to recombine.Homologous chromosomes carrying the same or different centromeresshow the same frequencies of chiasmate associations at MI, andhomeologous chromosomes rarely pair although they possess homologouscentromeres. In wheat, genetic mapping of the physical attributesof chromosomes and deletion mapping of genetic markers has shownthat crossing over was concentrated in the terminal segmentsof the chromosome arms and was practically absent from the proximalhalves of the arms (JONES et al. 2002 and references therein).In fungi, mammals, and plants, but not in Drosophila or Caenorhabditiselegans, chromosome pairing is largely dependent on the initiationand progression of recombination (reviewed in PAWLOWSKI and CANDE 2005;ZICKLER 2006). The absence of any effect of centromeres in wheaton the presence or absence of chiasmate bonds at MI is in agreementwith this link between pairing and recombination, as well aswith the observation that pairing progresses from the chromosomeends to the center of the chromosome.

What is the role of centromere association in leptotene? Duringthis stage, chromosomes undergo profound changes in the chromatinconformation and its spatial arrangement. Wheat chromosomesmultiply their length fivefold in leptotene relative to premeioticinterphase (MIKHAILOVA et al. 1998). Because the size of thenucleus remains the same at the leptotene–zygotene transitionor is even reduced (MAESTRA et al. 2002), chromosomes span theentire nucleus. Meanwhile, telomeres move to converge in a smallregion of the nuclear periphery opposite the centromeres. Boththe chromosome elongation movement and telomere migration areconcurrent and affect all chromosomes. Chromatin conformationalchanges may generate random chromosome movement, which couldinterfere with the oriented telomere migration. Centromere associationmay act to stabilize the centromere pole to reduce the degreeof disorder introduced by chromosome elongation and to maintaina reference point for the telomere migration.

The data presented here do not support in any way the statementthat the Ph1 locus in wheat controls bivalent pairing throughthe centromeres. This is consistent with an earlier observationthat, in a chromosome formed by a fusion of two homeologousarms at the centromere, intrachromosomal homeologous pairingtakes place only in the absence of the Ph1 locus but is suppressedin its presence (DVORAK and LUKASZEWSKI 2000). On the otherhand, long and perfectly homologous segments of an asymmetricalisochromosome do not pair in MI probably because telomere clusteringdoes not juxtapose homologous segments of these arms (LUKASZEWSKI 1997).The formation of multivalents at metaphase I in the absenceof Ph1 is preceded by different synaptonemal complex dynamics.Although both wild-type and mutant wheats form synaptonemalcomplex multivalents, these are transformed into bivalents atthe end of the zygotene in the wild type but not in the mutant(HOLM and WANG 1988; MARTÍNEZ et al. 2001a,b). Failureof the pairing correction mechanism allows for both homologousand homeologous chromosomes to form chiasmata and for multivalentsto become evident in MI. Failure of the multivalent correctionmechanism in the mutant is accompanied by, and might be dependenton, a delay of synapsis. DUBCOVSKY et al. (1995) reported thatrecombination between homeologous chromosome segments is dramaticallyreduced by the presence of Ph1 even when they are introgressedin intercalary positions of homologs. Taking into account thatin most organisms the initiation of recombination interactswith chromosome pairing, it is not possible to conclude whetherthe suppression of recombination induced by Ph1 is a consequenceof the SC multivalent correction or, by contrast, is the triggerof the pairing correction mechanism. A realistic explanationof how the homology of synapsed chromosomes is scrutinized inthe presence of the Ph1 locus needs more data but we do notsee any evidence that the control is exercised through the centromere.

ACKNOWLEDGEMENTS

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
LITERATURE CITED

We thank B. Friebe, P. Landgridge, and A. Cuadrado for kindlysupplying clones 6C6, pAWRC.1, and pSc119.2, respectively. Thiswork has been supported by grant 2003-04 from New Del Amo Programfrom the University of California-Universidad Complutense deMadrid, by grant BFU2004-02261 from Dirección Generalde Investigación, Ministerio de Educación y Cienciaof Spain, and by grant PR27/05-13984 from Banco Santander-UniversidadComplutense de Madrid.

LITERATURE CITED

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
LITERATURE CITED

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Communicating editor: J. A. BIRCHLER