Pericentromeric chromatin reorganisation follows the initiation of recombination and coincides with early events of synapsis in cereals

The reciprocal exchange of genetic information between homologous chromosomes during meiotic recombination is essential to secure balanced chromosome segregation and to promote genetic diversity. The chromosomal position and frequency of reciprocal genetic exchange shapes the efﬁciency of breeding programmes and inﬂuences crop improvement under a changing climate. In large genome cereals, such as wheat and barley, crossovers are consistently restricted to subtelomeric chromosomal regions, thus preventing favourable allele combinations being formed within a considerable proportion of the genome, including interstitial and pericentromeric chromatin. Understanding the key elements driving crossover des-ignation is therefore essential to broaden the regions available for crossovers. Here, we followed early meiotic chromatin dynamism in cereals through the visualisation of a homologous barley chromosome arm pair stably transferred into the wheat genetic background. By capturing the dynamics of a single chromosome arm at the same time as detecting the undergoing events of meiotic recombination and synapsis, we showed that subtelomeric chromatin of homologues synchronously transitions to an open chromatin structure during recombination initiation. By contrast, pericentromeric and interstitial regions preserved their closed chromatin organisation and become unpackaged only later, concomitant with initiation of recombi-natorial repair and the initial assembly of the synaptonemal complex. Our results raise the possibility that the closed pericentromeric chromatin structure in cereals may inﬂuence the fate decision during recombination initiation, as well as the spatial development of synapsis, and may also explain the suppression of crossover events in the proximity of the centromeres.


INTRODUCTION
Chromosomes in the cell nucleus are composed of arrays of chromatin loops irregularly folded into threedimensional chromosome domains that are framed by prominent structural features called centromeres and telomeres (Heslop-Harrison and Schwarzacher, 2011;Jerkovi c et al., 2020).The spatial organisation of chromosomes is defined by the extent of this chromatin folding, which has a major impact on key biological processes, such as DNA replication, recombination and transcription (Bell et al., 2011;Jordan et al., 2020).The capacity to quickly alter chromatin structure during the mitotic and meiotic cell cycle provides a considerable plasticity to chromosomes and allows implementation of a multitude of functions (Ma et al., 2015;Pecinka et al., 2020;Tiang et al., 2012).One fundamental developmental programme requiring abrupt adjustments in chromosome architecture is prophase I of meiosis (Loidl, 2016;Ronceret and Pawlowski, 2010;Schwarzacher, 2003).At the heart of prophase I lies the process of meiotic recombination, which involves the exchange of genetic material between one of the two chromatids of the homologous chromosomes, resulting in a wide variety of genetic diversity within the gametes.Besides ensuring genetic exchange, recombination provides physical connections between the homologous chromosomes, a fundamental requirement for accurate chromosome segregation.Meiotic recombination begins with the formation of programmed DNA doublestrand breaks (DSBs) (Keeney et al., 1997) followed by 5 0to 3 0 DNA end resection, homology search and strand invasion into an intact, homologous double stranded DNA segment located on one of the chromatids of the homologous partner chromosome (Hunter and Kleckner, 2001;Pradillo et al., 2012).The number of DSBs exceeds 700 per meiosis in hexaploid wheat (Triticum aestivum) and only a minority (typically one per chromosome arm) of them result in crossovers (Gardiner et al., 2019), whereas the majority are processed via repair mechanisms resulting in noncrossovers.
The introduction of genome-wide DSBs coincides with the progressive loading of proteinaceous axial elements along the chromosome axes (Armstrong et al., 2002;Chambon et al., 2018).Following homology recognition and strand invasion, the biochemical process of recombination becomes stabilised by the establishment of the synaptonemal complex (SC) (Higgins et al., 2005;Osman et al., 2006), which builds up between the homologous chromosomes in a meiosis-specific process termed synapsis.The SC is formed progressively by connecting axial elements (now becoming lateral elements) of the homologues via transverse filament proteins, which gives rise to the central element of the SC (Zhang et al., 2014).In many organisms, including higher plants, homologous recombination relies on the SC (Barakate et al., 2014) and crossover maturation occurs when homologues attain perfect synapsis.
These critical DNA-and synaptic events are spatially restricted along the chromosomes, so that mature crossover distribution (cytologically manifested as chiasmata within metaphase I chromosomes) recombination-and synapsis initiations occur in the euchromatic subtelomeric regions (Higgins et al., 2012;Osman et al., 2021).Chromosomes in the meiotic nucleus are spatially polarised themselves by telomere and centromere associations formed at the two extremes of the nucleus (Bass et al., 1997;Murphy et al., 2014;Naranjo and Corredor, 2004;Phillips et al., 2012).In this configuration, each chromosome forms a large loop with the ends (telomeres) attached to the nuclear envelope and folded back at the centromere at the opposite side of the nucleus.Immediately preceding synapsis initiation, a transient nuclear arrangement, the telomere bouquet, is almost universally formed inside the pollen mother cell nuclei (Scherthan, 2001) where telomeres are gathered together in a single group (Bass, 2003) and associate with the nuclear envelope (Varas et al., 2015).The telomeres assembled in the bouquet lead mechanical forces from the cytoskeleton to the chromosomes initiating the rapid movement characteristic of prophase I (Sheehan and Pawlowski, 2009;Sepsi and Schwarzacher, 2020).Rapid chromosome movements represent one of the most important elements of homology search because they can facilitate both chromosome encounters and dissociations (Chac on et al., 2016;Martinez-Garcia et al., 2018).Together with other prominent features of chromatin dynamics, prophase movements of chromosomes outline a strong mechanical aspect of meiosis that appears to be crucial for the initiation of meiotic recombination, homology recognition and progression of DSB repair pathways (Zickler and Kleckner, 2015).During the period of telomere bouquet formation, a highly dynamic chromatin reorganisation became clear from in situ hybridisation studies performed on nuclei of wheat and wheat-rye introgression lines (Colas et al., 2008;Corredor et al., 2007;Maestra et al., 2002;Prieto et al., 2004;Schwarzacher, 1997).An extreme polarisation of the meiotic nuclei was shown by the formation of the large centromere groups close to the nuclear envelope (Martinez-Perez et al., 2003) that led to the massive reorganisation of the centromeric chromatin.This implied the transition of the centromeric chromatin from a compact conformation to elongated structures, which coincided with the resolution of the centromeres from the groups and the nuclear periphery (Martinez-Perez et al., 2003).A pre-bouquet conformational change has also been shown for the subtelomeric regions (Prieto et al., 2004) and this phenomenon has subsequently became linked to homology recognition and pairing (Colas et al., 2008).Recent progress in describing the key modulators of plant meiosis (Mercier et al., 2015) allows the application of protein antibodies as meiotic markers to provide the accurate meiotic timing for chromatin dynamics studies supporting an integrated understanding of the complex multifaceted process of meiotic prophase I (Colas et al., 2017;Hurel et al., 2018;Osman et al., 2018;Sepsi et al., 2017;Varas et al., 2015).For example, centromere clustering and subsequent resolution has been confirmed by immunolabelling active centromeres in wheat and was shown to coincide with specific steps of synapsis (Sepsi et al., 2017).However, how chromatin remodelling at the subtelomeres and chromatin packaging along chromosome arms can be correlated with synapsis progression and the process of DNA recombination remains to be clarified.
Wheat-alien hybrid lines, carrying Robertsonian translocations from a related species added to the wheat background, are generally very stable (T€ urk€ osi et al., 2018) and suitable for following chromosome behaviour during the mitotic or meiotic cell cycle.By combining molecular cytogenetics with immunohistochemistry, the alien chromosome segment can be visualised within the accurate In the present study, we used a 7BS.7HL wheat-barley recombinant chromosome line in which we substituted one pair of wheat chromosome arms to a pair of an entire barley chromosome arms, giving rise to a homologous pair of translocation chromosomes (40 wheat + one pair of wheat-barley translocation chromosome).We followed the chromatin organisation of the two homologous barley chromosome arms as parts of entire chromosomes inside the wheat nucleus from chromosome axis formation to full synapsis.Chromatin organisation of the homologous chromosome arms was investigated by in situ hybridisation, as detected by optical sectioning with high-resolution laser scanning confocal microscopy, whereas precise meiotic timing including SC formation and recombination initiation was assessed by immunohistochemistry. Our study showed a temporal difference between the meiosisspecific reorganisation of different chromosomal regions, which correlated with recombination initiation and SC formation.We showed that, during recombination initiation, homologous subtelomeric regions become synchronously remodelled to an open chromatin structure, coincident with chromosome axis formation.During this period, interstitial regions and pericentromeres preserved a closed, highly condensed conformation.Synapsis emerged from the decondensed subtelomeres arranged into the bouquet coincident with the initiation of recombination repair and remodelling of the pericentromeric regions.Late remodelling of the pericentromeres was in line with a delayed juxtaposition between the homologous pericentromeric regions compared to the subtelomeres.Our study points to a clear temporal correlation between chromatin remodelling and key meiotic processes such as recombination repair, chromosome juxtaposition and synapsis.We propose that delayed chromatin remodelling within the pericentromeres has an effect on the fate of recombination repair, such that the closed chromatin structure possibly delays the repair processes, thus lengthening the timeframe for crossover-repair decisions.

Development and cytological characterisation of the wheat-barley translocation line
To investigate the order of chromosome arm pairing during meiotic prophase I in large genome cereals, we developed a wheat-barley translocation chromosome line that carries 20 pairs of normal wheat chromosomes and one pair of wheat-barley translocation chromosomes.The line was obtained by crossing a wheat/barley 7H addition line (21 wheat chromosome pairs and one added pair of barley 7H chromosome) (Moln ar-L ang et al., 2012) with Chinese Spring wheat carrying the ph1b mutation.The wheat ph1b mutation (Griffiths et al., 2006) promotes non-homologous recombination at meiosis (see Experimental procedures) and is thus suitable for inducing intergenomic rearrangements between the wheat and barley chromosomes.We detected the translocation chromosome in the F 2 generation of the cross as a monosome (40 wheat chromosomes and a single translocation chromosome), whereas stable disomics (40 wheat chromosomes and a pair of the translocation chromosomes) (Figure 1a,b) were selected from the F 3 generation.Genomic in situ hybridisation showed that the translocation is made up of a wheat chromosome arm fused by its centromere to a complete barley (7H) chromosome arm framed by the barley centromere and a telomere (centric fusion) (Figure 1a).The elimination of the ph mutation was confirmed by molecular marker analysis (Xpsr574) showing that the translocation line carries the wild-type Ph1 allele (Figure S1).
Three-colour fluorescence in situ hybridisation (FISH) (with Afa-family, pSc119.2, and pTa71 repetitive DNA probes) allowed identification of all wheat chromosomes present and revealed that the barley chromosome arm translocated to the short arm of wheat chromosome 7B-(7BS) (Figure 1a,b).Barley 7HS and 7HL chromosome armspecific molecular markers (Bmac0031 SSR and HvCSIF6 STS markers, respectively) (Cseh et al., 2011) identified the barley chromosome arm as 7HL (Figure 1e).These results showed that the translocation occurred between the wheat 7BS and barley 7HL chromosome arms giving rise to the 7BS/7HL translocation.Genomic in situ hybridisation (GISH) combined with in situ hybridisation of the centromeric retrotransposon of wheat (CRW) and the barley centromere-specific G + C repeat revealed that the centromere of the translocation chromosome carries a hybrid centromere, where one half originates from wheat (7BS centromere) and the other half originates from barley (7HL centromere) (Figure 1c,d).The translocation line showed full fertility (Figure 1f) and exhibited stable chromosome inheritance throughout meiosis II (Figure 2).Consequently, 100% of the screened progenies carried the translocation chromosome pair in the background of 40 wheat chromosomes, indicating that the chromosome set including the barley chromosome arm follows balanced segregation, making the line suitable for studying the behaviour of a chromosome arm during meiotic division of wheat.

SC development and centromere dynamics in the 7BS.7HL translocation line
To study chromosome arm dynamics within an exact meiotic timing in the 7BS.7HL translocation line, key events of synapsis and recombination were visualised by immunolabelling.In wheat and barley, meiocytes within the three anthers per floret are in synchronised meiotic stages and can therefore be regarded as identical with respect to meiotic development (Bennett et al., 1971(Bennett et al., , 1973a;;Schwarzacher, 1997).Meiotic proteins related to the SC axial elements (ASY1) (Armstrong et al., 2002;Boden et al., 2009) and transverse filament proteins (ZYP1) (Higgins et al., 2005) were immunolabelled on preparations made from anthers adjacent to those used to investigate chromosome morphogenesis via in situ hybridisation.In addition to SC proteins, active centromeres were labelled concurrently by an anti-centromere-specific histone H3 (anti-CENH3) antibody to confirm the meiotic stages.ASY1 and ZYP1 antibodies revealed the status of the SC progression, whereas CENH3 staining added meiosis-specific centromere dynamics and thus allowed precise measurement of the timing of prophase I. SC formation and centromere dynamics in the 7BS.7HL line proceeded as in wild-type wheat (Desjardins et al., 2020;Osman et al., 2021;Sepsi et al., 2017).Briefly, axial elements formed short stretches along the 4 0 -6-diamino-2-phenylindole (DAPI) stained chromatin and centromeres associated at one half of the nuclear periphery at early leptotene (Figure 3a).Axial elements were fully linear at late leptotene (Figure S2), whereas the associations of telomeres into the bouquet (telomere bouquet) could be distinguished by the prominent concentration of axial elements at the nuclear periphery, opposite the centromeric pole (Figure 3a).Chromosome synapsis was detected in early zygotene as short stretches of SC central elements opposite the centromere side (Figure S2).Centromeres begin to disperse from the periphery coincident with the appearance of synapsis and later occupied random locations in the nucleus.To be able to provide a detailed reference for chromosome arm pairing as synapsis progressed gradually from early to late zygotene, we subdivided zygotene into four substages according to the extent of the synapsis progression observed within the nucleus.'Early zygotene' was defined by < 10% of synapsed chromosome axes; 'early-mid zygotene' nuclei were distinguished by 10-50% of synapsed axes where significant subtelomeric synapsis was observed with multiple synapsis initiation events located within the chromosome arms; 'mid zygotene' carried 50-80% synapsed axes and was characterised by progression of chromosome arm synapsis; and 'late zygotene' was defined by 80-95% synapsed axes (Figures 3a and S2).
Chromosomes were fully synapsed by pachytene.

Presynaptic chromatin reorganisation: pericentromeric reorganisation is delayed
Having established the stages of SC development in the 7BS.7HL line, we followed the morphogenesis and pairing of the translocated 7HL barley chromosome arm by in situ hybridisation on anthers adjacent and thus synchronous (Bennett et al., 1973b) to those accurately staged by ASY1/-ZYP1/CENH3 immunolabelling.To reveal the barley chromosome arm and its orientation inside the nucleus, we used a set of different fluorochromes in multicolour FISH experiments and marked barley DNA together with the barley centromere (G + C microsatellite repeat probe) and telomeres (universal telomeric repeat probe).The organisation of the barley chromosome arm was visualised from meiotic initiation through SC formation to the appearance of chiasmata showing mature crossovers between the homologous chromosomes.
Multicolour FISH showed that the 7HL chromosome arms lie parallel in separate territories at early leptotene with the centromeres and telomeres anchored at opposite poles of the nucleus (Figure 3a).The detected barley chromatin was packaged into large globular subdomains at this stage, indicating a closed chromatin structure where the total length of the 7HL barley chromosome arm reached 21.3 AE 7.47 µm (mean AE SD; n = 28) (Figure 3b,c).The distance between the two homologous centromeric or telomeric loci was > 0.2 µm (centromeres and telomeres were perceived as two separate spots) in all cases (n = 71) (Figure 3d), indicating that no centromere-or telomere pairing occurs during leptotene.
In late leptotene nuclei, the telomere bouquet becomes apparent from the accumulation of the telomeric FISH signals in one narrow group at the nuclear periphery (Figure 3a).Concurrently, one part of the barley chromatin, emerging from the telomere bouquet and progressing into the subtelomeres of the 7HL arm, become elongated (chromosome width: 0.22-0.45µm), indicating the decondensation of the 7HL subtelomeric region (Figure 3a-c   chromosome segments, the larger proportion of the chromosome arm, which also carried the centromere-specific G + C FISH signal, maintained the condensed organisation observed in early leptotene (chromosome width: 0.7-1.81µm), showing that decondensation of chromatin did not extend to the interstitial-and pericentromeric regions (Figure 3a-c).The decondensed subtelomeric region covered half (53.8%) of the total length of the chromosome arm measured in late leptotene (28.7 AE 10.1 µm; mean AE SD; n = 27), which corresponded to the length of the diameter of the nucleus (32.7 AE 10.0 µm; mean AE SD; n = 27) (Figure 3c).This indicated a chromosome arm elongation of 35% compared to early leptotene.The barley chromosome arms become synchronously decondensed along their entire length in early zygotene and reached their maximum prophase I length (62.02AE 21.4 µm; mean AE SD; n = 25) (Figure 3a-c).The quasi-parallel organisation of the homologous chromosome arms was retained up to early zygotene, with the telomeres and the centromeres oriented at the two extremes of the nucleus.

Barley centromeres follow dynamics characteristic of the host genome
To reveal whether barley centromeres follow the activity of wheat chromosomes during the highly dynamic early stages of prophase I, we performed ImmunoFISH experiments, where we simultaneously applied barley centromere-specific G + C repeat sequence FISH with CENH3 immunolabelling to meiocytes ranging from leptotene to early-mid zygotene.
CENH3 labelling showed all the active centromeres present, whereas the G + C DNA probe indicated the nuclear localisation of the barley centromere part of the translocation chromosome.The barley centromere-specific repeat overlapped with the CENH3 signal in all nuclei analysed (n = 147), indicating that the barley centromere loads centromere-specific histone protein in the wheat background and thus represents a functional centromere.In leptotene, when large, polarised centromere groups are formed in wheat (ranging from nine to 15 groups), the two homologous barley centromeres were observed to join different groups (Figure 4, top row).In early zygotene (Figure 4, middle row) and early-mid zygotene nuclei (Figure 4, lower row), the barley centromeres were still separated from one another but occupied smaller groups or were perceived individually, most likely as a result of the progressive dispersion of large centromere clusters.We measured the regions marked by the barley centromeric repeat DNA probe from leptotene to early-mid zygotene aiming to reveal whether they undergo reorganisation between leptotene and early zygotene, typical of wheat chromosomes (Sepsi et al., 2017).An elongation of the G + C signal was observed between the period of leptotene (number of nuclei = 15) and early zygotene (number of nuclei = 15) All active centromeres are visualized by an anti-CENH3 antibody (rabbit, detected by Alexa 594, red).The synaptonemal complex axial elements related protein ASY1 and the synaptonemal complex transverse filament protein visualized by anti-ASY1 (guineapig, detected by Alexa 647, pseudo coloured in grey) and rat anti-ZYP1 antibodies (detected by Alexa 488, green) reveal distinct stages of synaptonemal complex development.Formation of the telomere bouquet is seen by intensive ASY1 staining (arrow on the late leptotene image).For single channel images, see Figure S2.Scale bar = 5 lm.
Right: In situ hybridization showing the orientation and morphogenesis of the homologous barley chromosome arms (red), framed by their centromere (green) and telomere (grey) during substages of meiotic prophase I. Nuclei encompassing meiotic stages from leptotene to pachytene were obtained from adjacent anthers and are thus synchronous to those used for the CENH3, ASY1, ZYP1 immunolabelling (left) (Bennett et al., 1973b).Meiotic nuclei were counterstained with DAPI.Scale bars 5 lm.Early leptotene: Telomeres are dispersed within one half of the nucleus and centromeres are located within the other nuclear hemisphere.The barley chromosome arms are separated and the chromatin is condensed into globular domains.Late leptotene: The telomere bouquet is formed and the barley telomeres although located in close proximity to one another remain separated.The barley centromeres are separated from one another and located close to the nuclear periphery opposite the telomeres.The pericentromeric and interstitial regions maintain their condensed organisation, whereas the subtelomeric regions are elongated into thin chromatin threads.Early zygotene: Barley telomeres are paired, whereas centromeres (green, highlighted by yellow arrowheads) are at the opposite pole of the nucleus and remain separated from one another.The barley chromosome arms running parallel show an elongated organisation that eventually forms finger-like structures curved out transversally on both sides of the chromosome axis.Early-mid zygotene: Close juxtaposition of the barley 7HL from the subtelomeric region onwards demonstrates synapsis initiation while centromeres and the pericentromeric regions remain separated at a considerable distance from each other.Mid zygotene: Subtelomeres colocalise and interstitial regions show numerous 'juxtaposed interstitial segments' with variable length, where the two homologous chromosome arms colocalise.Homologous contacts formed by the 'juxtaposed interstitial segments' are interspersed with non-colocalised, parallel 'interstitial chromatin alignments' of various lengths (for more detail, see Figure 3) and this chromosome configuration extends from the subtelomeres to the pericentromeric regions.Pericentromeres are widely separated from their homologous chromosome segments forming a fork-like structure.(Figure S3), which did not increase further between early zygotene and early-mid zygotene (number of nuclei = 15).The barley centromere, representing half of the 7BS-7HL centromere, thus followed reorganisation dynamics similar to that of wheat chromosomes during the early stages of meiotic prophase I.

The progression of pairing between individual chromosome arms during zygotene
In a fraction of the analysed early zygotene nuclei (34%), homologous 7HL telomeres colocalised, whereas centromeres remained as two distinct foci at a considerable distance from one another (Figure 3a,d).Coincident with the appearance of telomere pairing, GISH showed the juxtaposition (the distance between the two chromosome threads was < 0.15 µm and thus they were perceived as one) of short chromosome segments located in the proximity of telomeres, indicating early events of chromosome synapsis within the subtelomeres (Figure 3a).Subtelomeres were defined as the chromosomal regions located near the telomeres that extended into the chromosome arms to the length observed to be decondensed at leptotene (17.91 AE 4.37 µm; mean AE SD) (Figure 3c).This region consisted of one-third of the total length of the fully decondensed chromosome arm as measured at zygotene (Figure 3c).These findings were in agreement with the results obtained from immunolabelling, which showed early traces of linear ZYP1.Progression of subtelomeric juxtaposition was evident in the majority of early-mid zygotene nuclei examined (n = 26).In some cases, juxtaposition was measured beyond the subtelomeres indicating early events of homologous interstitial chromosome contacts (Figure 3a).These colocalised 'juxtaposed interstitial segments' did not form a continuum with the juxtaposed subtelomeric regions; rather, a discontinuous interstitial juxtaposition became evident at a number of foci dispersed throughout the chromosome arms.This implied that homologous chromosome connections were regularly spaced by homologous non-colocalised 'interstitial chromatin alignments' varying in width between 0.2 and 7.3 µm (SD 0.7 µm; n = 26).The occurrence of the parallel alignments varied from cell to cell ranging from 5 to 23 with alignment lengths extending from 0.2 to 11.9 µm (SD 1.4 µm) (Figure 5).This was in line with our earlier studies showing multiple synapsis initiation sites within the chromosome arms and also with the immunolabelling results observed for the early-mid and mid-zygotene nuclei showing multiple synapsis initiation sites within the interstitial chromosome arms (see Figure 3a and Figure S2 and compare Figure 5a,b).Furthermore, in situ hybridisation showed that, although subtelomeric and interstitial regions were periodically united, the homologous barley centromeres marked by the G + C probe remained consistently at a considerable distance from one another, exhibiting a fork-like structure (Figure 3a,d).Importantly, centromeres no longer occupied a territory in the proximity of the nuclear periphery but were randomly located in the interior of the nucleus (Figure 3a,d).Their location varied from cell to cell, indicative of dynamic chromosome movement.Homologous centromere pairing was initially detected within a minority (14%) of the mid-zygotene nuclei (n = 70), whereas telomeres colocalised in the 94% of the pollen mother cells (Figure 3d) and juxtaposition of interstitial segments progressed into the pericentromeres (Figure 3a).

Merged G + C repeat FISH CENH3
Early-mid zygotene Periodical juxtaposition connected a considerable amount of the chromosome arms at late-zygotene and the telomere bouquet began to disintegrate (Figure 3a,d).An increase in the frequency of centromere pairing was also observed (52% of nuclei displayed paired centromeres; n = 58).Full synapsis of the 7HL chromosome arms at pachytene coincided with an apparent arm shortening (52.0 AE 22.0 µm; mean AE SD; n = 20), indicative of chromatin condensation (Figure 3a,b).

Meiotic recombination initiation by SPO11-dependent
DSBs can be detected cytologically with antibodies recognising the phosphorylation of the histone H2AX at the serine-139 residue, resulting in phospho histone H2AX ser139 (cH2AX) (Ku et al., 2020).To link SC axial element formation, centromere dynamics and ultimately chromosome arm morphogenesis with recombination initiation, we immunolabelled cH2AX foci together with ASY1 and CENH3 proteins in the pollen mother cell nuclei of the 7BS.7HL translocation line.Meiotic nuclei between the meiotic leptotene and zygotene stages exhibited numerous chromatin and axis associated cH2AX foci with considerable variation in fluorescence intensities (Figure 6a).We measured the relative fluorescence intensities of the immunolocalized cH2AX foci per individual leptotene and zygotene nuclei (n = 23) staged according to the ASY1/ CENH3 signal.We observed a high relative fluorescence intensity cH2AX indicative of extensive DSB formation at leptotene (n = 12) when the homologous chromosome axes were continuous but still separated (Figure 6a,b).This was in agreement with previous studies reporting recombination initiation in late G2-leptotene (Ku et al., 2020;Osman et al., 2021;Storlazzi et al., 2008).Zygotene nuclei (n = 11), characterised by partially juxtaposed chromosome axes, showed a substantial (85%) drop in the cH2AX relative fluorescence intensity (Figure 6a,b), denoting the initiation of DNA repair mechanisms as reported in other studies (Mahadevaiah et al., 2001;Su et al., 2017;Woglar and Villeneuve, 2018).

DSBs distribution is non-random within the nucleus
To understand the spatial distribution of DSBs inside individual leptotene nuclei, we quantified the relative fluorescence intensity of cH2AX foci at the nuclear periphery and at the centre.The nuclear periphery carried significantly lower cH2AX intensity levels (< 50%) compared to the nuclear centre (Figure 6c).One specific region of the nuclear periphery distinguished by a concentrated conical ASY1 signal, indicative of the telomere bouquet, carried a cH2AX immunosignal comparable to that observed for the centre of the nucleus (Figure 6c), indicating a higher DSB activity in the vicinity of the telomeres.This is in agreement with the subtelomeric initiation of the early DSBs in both wheat and barley (Higgins et al., 2014;Osman et al., 2021).Although DSBs are formed at leptotene, the centromeres are also peripherally located, opposite the telomeric pole (Carlton and Cande, 2002;Wen et al., 2012).We therefore examined whether the crossover devoid centromeric and pericentromeric regions carry reduced levels of recombination initiations at leptotene, as indicated by the lower DSB signals measured at the nuclear periphery.By selecting single focal planes containing both peripherally located centromeres and a prominent telomere bouquet at the opposite side of the nuclear periphery, we specifically measured fluorescence intensities in two dimensions within the centromeres (n = 13), the nuclear centre and the telomeres.According to our measurements, significantly lower DSB levels were detected within the chromatin marked by CENH3 staining compared to the nuclear centre and the telomeres (Figure 6d), indicating that the core centromere somehow protected but did not completely inhibit DSB formation.Centromeres carried 25% lower cH2AX intensities than the nuclear centre and 50% lower intensities than telomeres confirming extensive DSB formation within the subtelomeric regions (Figure S4).

DISCUSSION
Understanding the mechanisms influencing the spatial distribution of early meiotic events is increasingly important in crops where specific allele combinations may determine the productivity of recent varieties (Lambing and Heckmann, 2018).The present study correlates chromatin dynamics with key steps of recombination and synapsis by assaying a single pair of homologous barley chromosome arms added to the wheat genome (Figure 7) in the form of a translocation (7BS.7HLtranslocation) at the same time as providing a precise prophase I timing.The stability of the barley chromosome arm in the 7BS.7HL line, leading to stable meiosis II and full fertility, shows that the meiotic morphogenesis of the barley chromosome is relevant to the understanding of chromosome behaviour in wheat.Additionally, we have demonstrated that the activity of the barley centromeres and their dynamics within the wheat nucleus followed a meiotic program characteristic of the host genome.This is in agreement with previous studies on wheat-rye introgression lines confirming that the pattern of chromatin remodelling of the alien (rye) chromosome at meiosis is directed by the host genetic background in which the chromosome is present (Naranjo, 2018).

Chromatin reorganisation precedes chromosome juxtaposition at the subtelomeres
We established a coherent chronology of chromosome arm pairing by correlating chromosome arm morphogenesis with the progression of synapsis and recombination.We showed that, in early leptotene, chromosome arms were condensed and organised into irregular globular subdomains with telomeres and centromeres pointing to opposite poles of the nucleus.This condensed early chromosome conformation and the bipolar orientation of telomeres versus centromeres was in agreement with several previous studies analysing chromatin dynamics in wheat-rye introgression lines (Corredor and Naranjo, 2007;Maestra et al., 2002;Mart ınez-P erez et al., 1999;Mikhailova et al., 2001;Schwarzacher, 1997).We demonstrated that this condensed chromatin structure coincided with recombination initiation by numerous nucleus wide DSBs, whereas homologous chromosome arms were located at considerable distances from one another (Figure 7).
By late leptotene when chromosome axes were fully linear, without any sign of synapsis emerging from the prominent telomere bouquet, the homologous arms become partially and synchronously reorganised.Reorganisation explicitly involved the elongation of subtelomeric chromatin, which emerged from the fully formed telomere bouquet (Figure 7).The elongation of subtelomeric chromatin during the period of telomere bouquet formation has already been demonstrated as one of the earliest events of meiotic prophase I by in situ hybridisation on whole floret vibratome sections of a wheat-rye recombinant chromosome line carrying an interstitial rye chromosome segment.Prior telomere clustering wheat subtelomeric regions elongated and then both rye homologous segments elongated synchronously and intimately aligned (Prieto et al., 2004).The conformational change of the subtelomeric chromatin was found to be triggered by the mutual recognition of homologous chromosome partners, followed by their intimate alignment, indicating the important role of chromatin unpackaging in the homology recognition process (Colas et al., 2008).
The present study, based on the timeline set up by synaptonemal protein labelling, showed that, although both barley subtelomeres were included in the bouquet in late leptotene, homologous chromosome arms, including the subtelomeres, remained physically separated and localised at a considerable distance from one another.This shows that extensive presynaptic homologous coalignments, as observed in Sordaria macrospora (Storlazzi et al., 2010), are absent in large genome cereals.Short regions of chromosome axes coalign in wheat leptotene nuclei as well (Sepsi et al., 2018), although, as a result of the large genome and the multitude of chromosome threads, it cannot be determined whether these alignments involve homologous chromosomes.The present analysis suggests that leptotene axis alignments may occur between non-homologues or represent transient inter-or intra-chromosomal associations as indicated by the tight chromatin packaging within the interstitial and pericentromeric chromatin.

Key
Chromosome arms Telomere Centromere DSBs are predominant towards the centre of the nucleus and in the proximity of the telomere bouquet Here, we showed that, although genome-wide DSBs are introduced at leptotene, the pericentromeric/interstitial chromatin remains initially enclosed in large globular domains, identical to their closed structure detected at the onset of meiotic prophase.Using quantitative image analysis, we detected a non-random distribution of DSBs inside the nucleus, where chromatin located at the nuclear periphery showed a lower DSB activity relative to the chromatin located at the nuclear centre.Subtelomeres, however, assembled into the telomere bouquet, showed an exception to this rule because they demonstrated DSB activity comparable to the nuclear centre.DSBs have been reported to be spatiotemporally confined to the subtelomeric regions prior to chromosome juxtaposition in wheat (Osman et al., 2021), barley (Higgins et al., 2012), zebrafish (Danio rerio) (Blokhina et al., 2019) and human males (Pratto et al., 2014) and have also been suggested to play a role in homology recognition and pairing.
When specifically assaying the core centromere of leptotene nuclei, we detected the lowest occurrence of recombination initiations, although centromeres were not completely devoid of DSBs.As expected, these events did not lead to crossovers, reflecting the local predominance of non-crossover repair.These results were in agreement with recent molecular work in wheat showing centromeric DSBs to be resolved as gene conversions representing non-reciprocal genetic exchanges (Gardiner et al., 2019).Examination of maize meiocytes showed that DSB formation at late leptotene coincides with a transient remodelling of axial elements as well, where a coiled axis morphology transitions to linear structures (Ku et al., 2020), suggesting a possible SPO11-1 dependent mechanism to orchestrate changes in axial element structures.
A significant variation in DSB distribution across the leptotene nucleus showed lower DSB activity for chromatin in proximity to the nuclear periphery, including the condensed centromeric chromatin.The subtelomeric regions showed an elevated DSB activity that coincided with the presynaptic chromatin remodelling into an open chromatin thread.The present study does not resolve whether the elevated DSB levels trigger chromatin remodelling at the subtelomeres or whether the open chromatin structure renders the subtelomeric region more prone to the DNA damage machinery.Chromatin remodelling is known as a key element of recombination patterning (Sz ekv€ olgyi et al., 2015), although DNA damage itself can also affect chromatin organisation and mobility (Hauer and Gasser, 2017).An important question to consider is whether the compact chromatin structure together with the reduced DSB activity observed at the pericentromeres delays the recombination repair pathways and thus promotes non-crossover outcomes in the proximity of centromeres.This scenario is supported by evidence showing that the crossover/noncrossover decision is taken earlier in meiosis, possibly as early as DSB formation (Allers and Lichten, 2001;Bishop and Zickler, 2004).In line with this, a recent study in mice proposed that the fine scale chromatin structure and timing of DSBs influence the outcome of meiotic recombination.Earlier formed DSBs have been shown to occupy more open chromatin and be more prone to repair as crossovers than those that are formed later, suggesting that the crossover decision may need specific protein complexes that are absent at later stages (Chen et al., 2020).
Another element to be considered in terms of restricting crossover events within the centromeric/pericentromeric regions is the formation of early non-homologous centromere-centromere associations.They have been reported in cereal species (present study; Martinez-Perez et al., 2003;Phillips et al., 2012;Sepsi et al., 2017) and the model plant Arabidopsis (da Ines et al., 2012;Pradillo et al., 2014;Ronceret et al., 2009), although they appear in early meiotic prophase I of budding yeast (Saccharomyces cerevisiae) (Tsubouchi and Roeder, 2005) and Drosophila melanogaster (Kurdzo et al., 2017).Non-homologous centromere associations in wheat are consistent with earlier electron microscopy data on SC formation (Jenkins, 1983), revealing partner switches (homologous alignments interrupted by non-homologous pairing) within the interstitial chromosomal regions during zygotene.Non-homologous centromere interactions, thus ensuring spatial separation of the homologous centromeres, may to some extent prevent centromeric DSBs from being repaired via crossover pathways.
The present study suggests that the variation in chromatin packaging concentrates the whole chromosome recognition machinery to act initially at the subtelomeric regions.Homology testing and recognition promotes SC formation and progression of recombination repair mechanisms.Interstitial and pericentromeric regions may be masked by their globular, closed chromatin structure, implying a temporal shift in recognition, juxtaposition and initiation of repair, which results in the preference of the repair processes leading to non-crossovers.

Interstitial chromosome pairing progresses from multiple sites forming periodical juxtapositions interspersed with 'interstitial chromatin alignments'
The delayed remodelling of interstitial and pericentromeric chromatin compared to the subtelomeric regions (Figure 7) is in line with the temporal shift of the synapsis at the distal and proximal regions (Banerjee and Jones, 1999;Blokhina et al., 2019;Xiang et al., 2014).Initial chromatin juxtapositions occur between the subtelomeres in cereals.This process has been proposed to be mediated by the telomere bouquet and a telomere-led chromosome movement (Martinez-Garcia  , 2018;Sheehan and Pawlowski, 2009), which facilitates DSB-dependent homologous interactions specifically in the proximity of telomeres (Marshall and Fung, 2016).The specific composition of the subtelomeric DNA (Aguilar and Prieto, 2020;Calder on et al., 2014) may accelerate the recognition and juxtaposition process.As expected, homologous interstitial-and pericentromeric regions visualised in the present study showed multiple local juxtapositions that were interspersed by loose parallel chromosome arm alignments.These were in agreement with previous ultrastructural studies in wheat showing two bivalents connected by multiple short SC stretches located within the interstitial chromosomal regions (Holm, 1977(Holm, , 1986;;Jenkins, 1983).A similar pattern of SC development was reported in barley where subtelomeric synapsis was accompanied by multiple interstitial synaptic sites (Phillips et al., 2012).
The present study showed that apparition of intimate interstitial alignment and synapsis coincides with a considerable reduction in DSBs in zygotene, indicating initiation of crossover repair mechanisms.
The irregular, periodical pattern of interstitial juxtapositions suggested a progressive and random capture and connection of the homologous chromosome arms.During these dynamic juxtapositions, centromeres were released from the nuclear periphery.Their position varied greatly from cell to cell and their dynamics appeared to be solely limited by the progression of the pairing and attachment of their telomeres to the nuclear envelope.The direction of this random chromatin capture progressed from the subtelomeres towards the centromeres and reached the centromeres by late zygotene.Taken together, this reflects a coordinated highly dynamic pairing process, greatly influenced by the physical boundaries of the nuclear envelope and the association/release of the centromeres from the nuclear periphery, as well as the assumed, highly dynamic, telomere-led chromosome movement.
Here, we showed that changes in chromatin packaging are significant at the chromosome, chromosome arm and chromosome region level.Expanding knowledge on the coordination of chromatin dynamics with the fundamental processes of recombination and synapsis reveals chromosome pairing under the influence of a multitude of genetically/epigenetically defined physical factors, such as orientation, chromatin associations, nuclear envelope tethering, accessibility, proximity, tensions and movements.Spatiotemporal and functional relationships of these elements point to an evolutionary process that has shaped the chromatin context so that physical constraints acting on chromosomes are constantly accommodated during the highly complex homology recognition process to ensure a high-fidelity chromosome pairing and accurate transmission of the genome to the next generation.Further understanding of their role in meiotic processes may shed light on the complex mechanisms that result in the polarised distribution of the crossovers and thus contribute to crossover formation in chromosomal regions away from the telomeres.

EXPERIMENTAL PROCEDURES Plant materials
The 7BS.7HL disomic translocation line used in the present study was obtained from a cross between the wheat/barley ('Asakazekomugi'/'Manas') 7H disomic addition line (carrying a pair of barley 7H chromosome in the normal wheat background, 2n = 44, Moln ar-L ang et al., 2012) and the Chinese Spring (CS) ph mutant line (carrying a mutation in the pairing homologous, ph gene; ref, Kansas State University, Manhattan, KS, USA; Genebank: TA 3809), which was performed to induce translocations between the wheat and barley chromosomes.Nine monosomic plants with a wheat-barley centric fusion chromosome were selected from 60 F 2 seeds by GISH.Following selfing of the F 2 generation, stable disomics were identified in the F 3 .
For the fertility tests, the translocation plants and the parental wheat cultivars were grown in growth cabinets (Conviron PGR-15; Controlled Environments Ltd, Winnipeg, MB, Canada) in Martonv as ar.Fifteen plants were randomly selected from CS wheat and the F 6 generation of the 7BS/7HL translocation line for fertility (seeds/floret) analysis.

Cytological procedures
Chromosome and nuclei preparation.Somatic chromosome spreads were developed as described by Kruppa et al. (2013).Meiotic tissue was fixed and prepared as described by Sepsi et al. (2018).In brief, the three anthers per florets (containing meiocytes in synchronised meiotic stages) (Bennett, 1971) were excised and divided as follows: two anthers were immediately transferred into fresh 4% paraformaldehyde to be processed for immunohistochemistry.The remaining (third) anther was placed into Carnoy fixative (ethanol: acetic acid, 3:1) and was later used for in situ hybridization.Position of the florets/spikelets/ear was recorded for each fixed anther to keep track of the progression of meiotic stages.
ImmunoFISH was carried out as described by Sepsi et al. (2018).
Molecular marker analysis-Genomic DNA was extracted from the wheat cultivar ʻChinese Springʼ, wheat/barley 7H addition line and the wheat/barley translocation line using Quick Gene-Mini80 (FujiFilm, Tokyo, Japan) with a Quick-Gene DNA tissue kit (FujiFilm).PCR reactions were carried out as described in Cseh et al., (2011) using Bmac0031 SSR and HvCSLF6 STS markers.PCR products were separated with a Fragment Analyzer TM Automated CE System equipped with a 96-Capillary Array Cartridge (Advanced Analytical Technologies, Ankeny, IA, USA).The results were interpreted using PROsize, version 2.0 (Advanced Analytical Technologies).
The deletion of the Ph gene from the 5BL chromosome arm was detected by the Xpsr574 STS marker as described by Roberts et al. (1999).Primers amplifying DNA fragments within the ph1b deletion can be used in a plus/minus PCR assay to detect lines carrying deletions in this region.The PCR products of ʻChinese Springʼ ph mutant line, 'Asakazekomugi'/'Manas' 7H disomic addition line and the wheat/barley 7BS/7HL translocation line were separated using 2.2% SeaKem agarose gel (Cambrex Bio Science, East Rutherford, NJ, USA).
Confocal microscopy, image processing-Confocal microscopy was carried out using a TCS SP8 confocal laser-scanning microscope (Leica Microsystems GmbH, Wetzlar, Germany).Series of confocal images (z stacks) were acquired using a HC PL APO CS2 639/1.40 oil immersion objective (Leica Microsystems GmbH).Size of confocal aperture was set to 0.65 Airy units.Image acquisition was carried out by bidirectional scanning along the xaxis, and images were averaged from three distinct image frames to reduce image noise.Fluorescence signals were detected using a hybrid detector set to photon counting mode for the accurate measurements.The fluorochromes used throughout the study were: DAPI (excited at 405 nm, detected from 410 to 450 nm), Alexa Fluor 488 (excited at 488 nm, detected from 490 to 520 nm), Alexa Fluor 594 (excited at 561 nm, detected from 565 to 620 nm) and Alexa Fluor 647 (excited at 633 nm, detected from 640 to 680 nm).Image stack deconvolution was performed using Huygens Essential,version 17.10 (Scientific Volume Imaging,Hilversum,The Netherlands).
Fluorescence signal intensities were measured on the collected image series (z-stacks) using Leica Advanced Fluorescence software, version 3.7.3.23245 (Leica Microsystems GmbH).Relative fluorescence intensities were determined by the quantifying functions 'Stack profile' and 'Line profile' of the software.Measurements were carried out on original, unprocessed (deconvolution, etc.) image series.All microscope settings (i.e.laser power, detector gain, detection spectra, etc.) were saved for each fluorescence labelled secondary antibody and kept the same throughout all the repetitions.

Statistical analysis
Fertility assay.To determine the possible differences between the fertility of CS (15 plants and 74 spikes) and the 7BS.7HL translocation line (15 plants and 73 spikes), we counted the relative fertility (number of seeds/florets/spikes) and computed the results using a t-test of independence.The assumption homogeneity of variances was tested and satisfied via Levene's F-test.
Chromosome arm length assay.Differences in the 7HL chromosome arm lengths within the defined meiotic phases (early leptotene, late leptotene, zygotene and pachytene) were measured using LAS X software (Leica Microsystems GmbH) on z-stacks obtained with confocal laser scanning microscopy.The measured lengths were analysed by one-way analysis of variance and classified using Tukey's B post hoc test.
Measured relative fluorescence intensity data were analysed by one-way analysis of variance and Tukey's B test, after the assumptions verified by the methods of d'Agostino (Tabachnick and Fidell, 2012).Statistical analyses were performed using SPSS, version 16.0 (SPSS Inc., Chicago, IL, USA).
Pairing between two loci (telomeres, centromeres and interstitial loci) was defined by measuring the interval in micrometre between them.Two homologous loci were counted as paired when the distance between them has fallen below a threshold of 0.2 µm (and thus were visually perceived as one).
carried out data analysis.AF, EM and DM contributed to the confocal microscopy experiments, and performed the nuclear measurements and statistical analysis.AS and ALT wrote the paper.

Figure 1 .
Figure 1.Chromosome composition and fertility of the 7BS.7HL wheat-barley translocation line.(a) Detection of the translocated 7HL barley chromosome arm together with its centromere and telomere by multicolour in situ hybridization on mitotic chromosomes of the 7BS.7HLRobertsonian translocation line.The 7HL barley chromosome arm was labelled with Alexa Fluor 594 (red), the barley centromere-specific G + C repeat sequences (arrow) were detected by Alexa Fluor 488 (green), and all telomeres are shown by the plant telomere-specific repeat sequence (TRS) labelled with Alexa Fluor 647 (far-red and pseudo coloured in grey).(b) Fluorescence in situ hybridization on mitotic chromosomes of the 7BS.7HLRobertsonian translocation line.Repetitive DNA probes Afa family (red), Oligo-pSc119.2(green) and Oligo-pTa71 (far-red, pseudo coloured in yellow) were used to identify all wheat chromosomes present in the 7BS.7HL translocation line.The translocation chromosome is marked by an arrow and the chromosomes were counterstained with DAPI (blue).Scale bars = 5 µm.(c) Centromere organisation of the translocation chromosome carrying both barley-and wheat specific centromeric sequences (arrow) as shown by multicolour in situ hybridization on mitotic chromosomes of the 7BS.7HLRobertsonian translocation line.In situ hybridization visualised the 7HL barley chromosome arm (labelled with Alexa Fluor 647, far-red, pseudo coloured in white), the barley centromere-specific G + C repeat sequences (Alexa Fluor 488, green) and the Ty3/gypsy centromeric retrotransposons of wheat (CRWs) (Alexa Fluor 594, red, pseudo coloured in magenta).DAPI staining is shown in blue.Scale bars = 5 µm.(d) Close up image of the 7BS.7HL translocation chromosome shown in Figure 1c highlighting the wheat and barley centromeric regions.Scale bars = 5 µm.(e) Capillary gel electrophoresis patterns of the Bmac0031 (7HS) and HvCsIF6 (7HL) barley 7H chromosome arm-specific molecular markers on DNA templates 'Chinese Spring' (CS) wheat, 'Asakazekomugi'/'Manas' 7H disomic addition line (7H) and 7BS.7HL disomic Robertsonian translocation line (RobT).Chromosome arm-specific bands are indicated by arrows.(f) Spike morphology and fertility of the 7BS.7HLRobT line compared to the parental Chinese Spring wheat.A t-test of independence revealed no difference between the fertility potentials of the two genotypes (MD = 0.0024; d.f.= 145, P = 0.957).The assumption of homogeneity of variances was tested and satisfied via Levene's F-test (F = 0.009, P = 0.924).

Figure 2 .
Figure 2. Meiotic segregation of the barley 7HL chromosome arm in the 7BS.7HL wheat/barley disomic translocation line as detected by GISH.The barley genomic DNA probe was labelled with Alexa Fluor 594 (red), whereas the DNA was counterstained with DAPI (blue).The meiotic stages shown are: diakinesis, metaphase I, anaphase I, telophase I, interphase I, metaphase II, anaphase II and tetrad.Scale bar = 5 lm.

©
2021 The Authors.The Plant Journal published by Society for Experimental Biology and John Wiley & Sons Ltd., The Plant Journal, (2021), doi: 10.1111/tpj.15391

Figure 3 .
Figure3.Chromosome arm morphogenesis and pairing of different chromosomal regions during key events of synapsis at meiotic prophase I. (a) Left: Examples of 7BS.7HL translocation line nuclei at different substages (leptotene to pachytene) of meiotic prophase I, showing synaptonemal complex progression and centromere dynamics.All active centromeres are visualized by an anti-CENH3 antibody (rabbit, detected by Alexa 594, red).The synaptonemal complex axial elements related protein ASY1 and the synaptonemal complex transverse filament protein visualized by anti-ASY1 (guineapig, detected by Alexa 647, pseudo coloured in grey) and rat anti-ZYP1 antibodies (detected by Alexa 488, green) reveal distinct stages of synaptonemal complex development.Formation of the telomere bouquet is seen by intensive ASY1 staining (arrow on the late leptotene image).For single channel images, see FigureS2.Scale bar = 5 lm.Right: In situ hybridization showing the orientation and morphogenesis of the homologous barley chromosome arms (red), framed by their centromere (green) and telomere (grey) during substages of meiotic prophase I. Nuclei encompassing meiotic stages from leptotene to pachytene were obtained from adjacent anthers and are thus synchronous to those used for the CENH3, ASY1, ZYP1 immunolabelling (left)(Bennett et al., 1973b).Meiotic nuclei were counterstained with DAPI.Scale bars 5 lm.Early leptotene: Telomeres are dispersed within one half of the nucleus and centromeres are located within the other nuclear hemisphere.The barley chromosome arms are separated and the chromatin is condensed into globular domains.Late leptotene: The telomere bouquet is formed and the barley telomeres although located in close proximity to one another remain separated.The barley centromeres are separated from one another and located close to the nuclear periphery opposite the telomeres.The pericentromeric and interstitial regions maintain their condensed organisation, whereas the subtelomeric regions are elongated into thin chromatin threads.Early zygotene: Barley telomeres are paired, whereas centromeres (green, highlighted by yellow arrowheads) are at the opposite pole of the nucleus and remain separated from one another.The barley chromosome arms running parallel show an elongated organisation that eventually forms finger-like structures curved out transversally on both sides of the chromosome axis.Early-mid zygotene: Close juxtaposition of the barley 7HL from the subtelomeric region onwards demonstrates synapsis initiation while centromeres and the pericentromeric regions remain separated at a considerable distance from each other.Mid zygotene: Subtelomeres colocalise and interstitial regions show numerous 'juxtaposed interstitial segments' with variable length, where the two homologous chromosome arms colocalise.Homologous contacts formed by the 'juxtaposed interstitial segments' are interspersed with non-colocalised, parallel 'interstitial chromatin alignments' of various lengths (for more detail, see Figure3) and this chromosome configuration extends from the subtelomeres to the pericentromeric regions.Pericentromeres are widely separated from their homologous chromosome segments forming a fork-like structure.Late zygotene: The telomere bouquet disperses; the elongated chromosome arms show multiple 'juxtaposed interstitial segments' disrupted by 'interstitial chromatin alignments' and this conformation reaches the centromeric regions.Centromeres are juxtaposed on the majority of nuclei.Pachytene: Synapsis is fully formed between the homologous barley chromosome arms.(b) Expansion and condensation of the 7HL chromosome arm during substages of meiotic prophase I Statistical analysis revealed a highly significant difference (F = 32.614;d.f. 1 = 3; d.f. 2 = 96; P = 1.24 9 10 -14 between the chromosome arm length measured at the different stages.Tukey's B post hoc test categorized these differences into three (a, b, c) groups (indicated by lowercase letters): Early Leptotene, Average (ave.):21.34 (ashortest); Late Leptotene, Average: 37.58 (bmedium length); Zygotene, Average: 62.03; and Pachytene, Average: 51.90 (both clongest).(c) Proportions of the condensed (grey horizontal bar) and decondensed (green horizontal bar) chromosomal regions within the barley chromosome arms (chr.arm) during prophase I with respect to the nuclear diameter (fine vertical line underneath the bars representing the barley chromosome arm).The positions of the telomere (grey vertical bar) and centromere (red vertical bar) are indicated by uppercase letters (C and T, respectively).Descriptive statistical data is shown on the right side.(d) Diagram showing the proportion of cells carrying paired 7HL centromeres (green line) and paired 7HL telomeres (grey line) during different stages of prophase I. Initiation of pairing is marked by red circles in both cases.
Figure3.Chromosome arm morphogenesis and pairing of different chromosomal regions during key events of synapsis at meiotic prophase I. (a) Left: Examples of 7BS.7HL translocation line nuclei at different substages (leptotene to pachytene) of meiotic prophase I, showing synaptonemal complex progression and centromere dynamics.All active centromeres are visualized by an anti-CENH3 antibody (rabbit, detected by Alexa 594, red).The synaptonemal complex axial elements related protein ASY1 and the synaptonemal complex transverse filament protein visualized by anti-ASY1 (guineapig, detected by Alexa 647, pseudo coloured in grey) and rat anti-ZYP1 antibodies (detected by Alexa 488, green) reveal distinct stages of synaptonemal complex development.Formation of the telomere bouquet is seen by intensive ASY1 staining (arrow on the late leptotene image).For single channel images, see FigureS2.Scale bar = 5 lm.Right: In situ hybridization showing the orientation and morphogenesis of the homologous barley chromosome arms (red), framed by their centromere (green) and telomere (grey) during substages of meiotic prophase I. Nuclei encompassing meiotic stages from leptotene to pachytene were obtained from adjacent anthers and are thus synchronous to those used for the CENH3, ASY1, ZYP1 immunolabelling (left)(Bennett et al., 1973b).Meiotic nuclei were counterstained with DAPI.Scale bars 5 lm.Early leptotene: Telomeres are dispersed within one half of the nucleus and centromeres are located within the other nuclear hemisphere.The barley chromosome arms are separated and the chromatin is condensed into globular domains.Late leptotene: The telomere bouquet is formed and the barley telomeres although located in close proximity to one another remain separated.The barley centromeres are separated from one another and located close to the nuclear periphery opposite the telomeres.The pericentromeric and interstitial regions maintain their condensed organisation, whereas the subtelomeric regions are elongated into thin chromatin threads.Early zygotene: Barley telomeres are paired, whereas centromeres (green, highlighted by yellow arrowheads) are at the opposite pole of the nucleus and remain separated from one another.The barley chromosome arms running parallel show an elongated organisation that eventually forms finger-like structures curved out transversally on both sides of the chromosome axis.Early-mid zygotene: Close juxtaposition of the barley 7HL from the subtelomeric region onwards demonstrates synapsis initiation while centromeres and the pericentromeric regions remain separated at a considerable distance from each other.Mid zygotene: Subtelomeres colocalise and interstitial regions show numerous 'juxtaposed interstitial segments' with variable length, where the two homologous chromosome arms colocalise.Homologous contacts formed by the 'juxtaposed interstitial segments' are interspersed with non-colocalised, parallel 'interstitial chromatin alignments' of various lengths (for more detail, see Figure3) and this chromosome configuration extends from the subtelomeres to the pericentromeric regions.Pericentromeres are widely separated from their homologous chromosome segments forming a fork-like structure.Late zygotene: The telomere bouquet disperses; the elongated chromosome arms show multiple 'juxtaposed interstitial segments' disrupted by 'interstitial chromatin alignments' and this conformation reaches the centromeric regions.Centromeres are juxtaposed on the majority of nuclei.Pachytene: Synapsis is fully formed between the homologous barley chromosome arms.(b) Expansion and condensation of the 7HL chromosome arm during substages of meiotic prophase I Statistical analysis revealed a highly significant difference (F = 32.614;d.f. 1 = 3; d.f. 2 = 96; P = 1.24 9 10 -14 between the chromosome arm length measured at the different stages.Tukey's B post hoc test categorized these differences into three (a, b, c) groups (indicated by lowercase letters): Early Leptotene, Average (ave.):21.34 (ashortest); Late Leptotene, Average: 37.58 (bmedium length); Zygotene, Average: 62.03; and Pachytene, Average: 51.90 (both clongest).(c) Proportions of the condensed (grey horizontal bar) and decondensed (green horizontal bar) chromosomal regions within the barley chromosome arms (chr.arm) during prophase I with respect to the nuclear diameter (fine vertical line underneath the bars representing the barley chromosome arm).The positions of the telomere (grey vertical bar) and centromere (red vertical bar) are indicated by uppercase letters (C and T, respectively).Descriptive statistical data is shown on the right side.(d) Diagram showing the proportion of cells carrying paired 7HL centromeres (green line) and paired 7HL telomeres (grey line) during different stages of prophase I. Initiation of pairing is marked by red circles in both cases.

Figure 4 .
Figure 4. ImmunoFISH showing the relative position of homologous barley centromeres in nuclei of the 7BS.7HLRobertsonian translocation line at different substages of meiotic prophase I. Arrows in the merged image (left) indicate the barley centromeres marked by the G + C repeat sequences (FISH, Alexa 594, pseudo coloured in green) overlapping with the CENH3 (rabbit, detected by Alexa 488, green and pseudo coloured in red) signal, which visualise all active centromeres.The encircled (dashed yellow line) signal on the right shows the centromere group including the barley centromere.Meiotic nuclei were counterstained with DAPI.Scale bars = 5 lm.

Figure 5 .
Figure 5. Patterns of homologous juxtaposition within the interstitial chromosome regions and the pericentromeres of the 7HL chromosome arm during zygotene.(a, b) In situ hybridisation signal of the barley chromosome arm (in red) shows 'juxtaposed interstitial segments' disrupted by numerous non-juxtaposed 'interstitial chromatin alignments' (arrowheads).The orientation of the centromeres (CEN) and telomeres (TEL) are indicated by green and white arrows, respectively.(c) ASY1 (blue threads) and ZYP1 (bright orange threads) immunolabelling shows similar patterns of interstitial synapsis interspersed by unsynapsed parallel axis alignments (arrowheads).Bars = 2 lm.(d) Examples of the pattern and number of 'interstitial chromatin alignments' within the analysed barley chromosome arms, showing the length (y-axis) and number (x-axis) of parallel, non-juxtaposed chromosomal regions per chromosome arms.Groups represent data measured within one nucleus (Nl.) and thus a single pair of barley chromosome arms.Bars within one group from left to right represent measurements onwards the subtelomeres and progressing towards the centromeres.

Figure 6 .
Figure 6.(a) Examples of microscopic images showing variations in the cH2AX levels between the leptotene and zygotene stages of the 7BS.7HL translocation line.cH2AX loci are labelled by an anti-cH2AX antibody (rabbit, detected by Alexa 488, green).For precise stage identification, the synaptonemal complex axial elements related protein ASY1 is shown using anti-ASY1 antibody (guineapig, detected by Alexa 647, pseudo coloured in grey) and CENH3 is sequentially labelled and visualized using anti-CENH3 antibody (rabbit, detected by Alexa 594, red).An orange arrow points to the telomere bouquet apparent by the concentrated ASY1 signal at leptotene.(b) Relative fluorescence intensities of the cH2AX signals measured at the leptotene and zygotene stages in the 7BS.7HL translocation line.Significant differences were detected by Student's t-test (P = 0.0005).(c) Spatial distribution of the cH2AX signal within the leptotene nuclei of the 7BS.7HL translocation line.Comparative analysis of relative fluorescence intensities of the nuclear periphery (grey colour, Nl. periphery), the nuclear centre (green colour, Nl. centre) and the nuclear volume including the telomere bouquet (magenta, bouquet).Measurements for each region of interest were carried out in three-dimensions (z direction, right) with LAS X software.Significantly lower relative fluorescence intensities were detected for the nuclear periphery than the nuclear centre.The telomere bouquet, although peripherally located, shows comparable relative fluorescence intensity to the nuclear centre (analysis of variance, d.f.1 = 2; d.f. 2 = 30; F = 11.07;***P = 2.51 9 10 -5 ).Lowercase letters (a, b) indicate significant differences (by Tukey's honestly significant post hoc test) between groups.(d) Comparison between the cH2AX levels within the peripherally located centromeric regions, the chromatin located at the nuclear centre and the subtelomeric regions.Variations in relative fluorescence intensities of the cH2AX signal are shown with respect to DAPI (blue line), CENH3 (red line) and ASY1 (grey line) signals across a single focal point (frame) of a leptotene pollen mother cell nucleus.DAPI demarcates the area of the nucleus.The CENH3 signal shows characteristic peripheral centromere localisation (indicated by a dotted line, 'centromere group'), whereas the elevated ASY1 signal intensity at the opposite pole of the centromere indicates the location of the telomere bouquet (highlighted by a dotted line).The top image of the microscopic photograph represents an example of the region of interest (yellow dotted line) selected for the measurements.The bottom image aims to represent the decline of the cH2AX signal around the centromeres.[Correction added on 06 August 2021, after first online publication: Part (d) of Figure 6 has been corrected in this version.]

©
2021 The Authors.The Plant Journal published by Society for Experimental Biology and John Wiley & Sons Ltd., The Plant Journal, (2021), doi: 10.1111/tpj.15391

Figure 7 .
Figure 7. Chromatin dynamics, centromere and telomere associations during prophase I of meiosis.Left: Cartoon diagram of the chromatin morphogenesis and dynamics through the prophase I stages.Central panel: Microscopic images of single focal planes photographed within pollen mother cell nuclei of the 7BS.7HL wheat-barley line labelled with in situ hybridisation to detect the barley chromatin (Alexa Fluor 594, shown in red).Chrt., chromatin, Scale bars = 5 µm.Right: Chronology of synaptonemal complex (SC) development, recombination progression and chromosome dynamics during prophase I of meiosis (present study;Higgins et al., 2012;Osman et al., 2021;Sepsi et al., 2017).[Correction added on 06 August 2021, after first online publication: The definition for Chromosome arms in the Key of Figure 7 has been corrected in this version.]© 2021 The Authors.The Plant Journal published by Society for Experimental Biology and John Wiley & Sons Ltd., The Plant Journal, (2021), doi: 10.1111/tpj.15391

©
2021 The Authors.The Plant Journal published by Society for Experimental Biology and John Wiley & Sons Ltd., The Plant Journal, (2021), doi: 10.1111/tpj.15391et al.