In perennial plants and especially those propagated through cuttings, several genotypes can coexist in a single individual, thus leading to chimeras. When the variant induces a noticeable phenotype modification, it can lead to a new cultivar. Viticulture already took economic advantage of this natural phenomenon: for instance, the berry skin of ‘Pinot gris’ derived from ‘Pinot noir’ by the selection of a chimera. Chimeras could also impact other crucial traits without being visually identified. Periclinal chimera where the variant has entirely colonized a cell layer is the most stable and can be propagated through cuttings. In grapevine, two functional cell layers are present in leaves, L1 and L2. However, lateral roots are formed from the L2 cell layer only. Thus, comparing DNA sequences of roots and leaves could allow chimera detection. In this study we used new generation Hifi long reads sequencing and recent bioinformatics tools applied to ‘Merlot’ to detect periclinal chimeras. Sequencing of ‘Magdeleine Noire des Charentes’ and ‘Cabernet franc’, the parents of ‘Merlot’, allowed haplotype resolved assembly. Pseudomolecules were built with few contigs, in some occasions only one per chromosome. This high resolution allowed haplotype comparison. Annotation from PN40024 was transferred to all pseudomolecules. Through variant detection, periclinal chimeras were found on both haplotypes. These results open new perspectives on chimera detection, which is an important resource to improve cultivars through clonal selection or breed new ones. Detailed results will be presented and discussed

Bert, Pierre-François

Donadel, Renate

Girollet, Nabil

Lacombe, Thierry

Laucou, Valérie

Le Cunff, Loïc

Roux, Catherine

Sarah, Gautier

This, Patrice

English

JKI Open Journal Systems (Julius Kühn-Institut)

Original Article | 99 VITIS: Vol. 62 (Special Issue) 99–102 (2023) | DOI: 10.5073/vitis.2023.62.special-issue.99-102 | Sichel et al.(c) The author(s) 2023  This is an Open Access article distributed under the terms of the Creative Commons Attribution 4.0 International License (https://creativecommons.org/licenses/by/4.0/deed.en). Submitted/accepted for publication: March 30, 2023/September 20, 2023Victoria Sichel1, Gautier Sarah1, Nabil Girollet2, Valérie Laucou1, Catherine Roux1, Loïc Le Cunff3, Patrice This1*, Pierre-François Bert2, Thierry Lacombe1, 4High quality phased assembly of grape genome offer new opportunities in chimera detectionAffiliations1 UMR AGAP Institut, Univ. Montpellier, CIRAD, INRAE, Institut Agro, Montpellier, France 2 EGFV, Univ. Bordeaux, Bordeaux Sciences Agro, INRAE, ISVV, Villenave d’Ornon, France 3 Institut Français de la Vigne et du Vin, Montpellier, France 4 UMT Geno-Vigne®, IFV-INRAE-Institut Agro, Montpellier, FranceCorrespondenceVictoria Sichel: victoria.sichel@inrae.fr, Gautier Sarah: gautier.sarah@inrae.fr, Nabil Girollet: nabil.girollet@inrae.fr, Valérie Laucou: valerie.laucou@inrae.fr, Catherine Roux: catherine.roux@inrae.fr, Loïc Le Cunff: loic.lecunff@vignevin.com, Patrice This*: patrice.this@inrae.fr, Pierre-François Bert:  pierre-francois.bert@inrae.fr, Thierry Lacombe: thierry.lacombe@supagro.frSummaryIn perennial plants and especially those propagated through cuttings, several genotypes can coexist in a single individ-ual, thus leading to chimeras. When the variant induces a noticeable phenotype modification, it can lead to a new cultivar. Viticulture already took economic advantage of this natural phenomenon: for instance, the berry skin of ‘Pinot gris’ derived from ‘Pinot noir’ by the selection of a chimera. Chimeras could also impact other crucial traits without be-ing visually identified. Periclinal chimera where the variant has entirely colonized a cell layer is the most stable and can be propagated through cuttings. In grapevine, two function-al cell layers are present in leaves, L1 and L2. However, lat-eral roots are formed from the L2 cell layer only. Thus, com-paring DNA sequences of roots and leaves could allow chi-mera detection. In this study we used new generation Hifi long reads sequencing and recent bioinformatics tools ap-plied to ‘Merlot’ to detect periclinal chimeras. Sequencing of ‘Magdeleine Noire des Charentes’ and ‘Cabernet franc’, the parents of ‘Merlot’, allowed haplotype resolved assem-bly. Pseudomolecules were built with few contigs, in some occasions only one per chromosome. This high resolution allowed haplotype comparison. Annotation from PN40024 was transferred to all pseudomolecules. Through variant de-tection, periclinal chimeras were found on both haplotypes. These results open new perspectives on chimera detection, which is an important resource to improve cultivars through clonal selection or breed new ones. Detailed results will be presented and discussed.Key wordschimera, Hifi Sequencing, trio-binning, phased assembly, Whole genomeIntroductionA chimera is found when several sets of genotypes coexist in the same individual. The phenomenon was discovered in plants many centuries ago and has been fascinating scientist since then. They were used to understand plant ontogenesis (Satina, 1945, Szymkowiak and Sussex, 1996, Thompson and Olmo, 1963) but they are also an opportunity to breed new cultivars. In fact, viticulture has already been taking advan-tage out of chimeras by breeding different mutants of ‘Pinot noir’ under different cultivar names as the phenotype was so different. For instance, ‘Pinot blanc’ and ‘Pinot gris’ arose from two independent chimeras (Vezzulli et al., 2012). Or again, the dwarf grapevine commonly used in grape research programs and was obtained performing somatic embryogen-esis from ‘Pinot Meunier’ (Torregrosa et al., 2019).Chimeras are formed when a somatic genetic variation ap-pears in a cell and is propagated through cell divisions. It can colonise an entire cell layer and is then called periclinal (Blakeslee et al., 1939). In some rare cases, the mutation af-fects the phenotype and become visible (Bauhin, 1598, Nati, 1644).Chimeras can spread all along the cell layer but can’t jump from one cell layer to another unless there is a genetic acci-dent. Therefore, by comparing two cell layers we can detect chimeras. Fortunately, grapevine leaves have two functional cell layers L1 and L2 whereas lateral roots come from a dedi-fferentiation of pericycle cells and only have the L2 cell layer (Pratt et al., 1959, Thompson and Olmo, 1963). To compare L1 and L2 we need to sequence both roots and leaves from a non-grafted individual. But cell layers aren’t the only chal-lenge.Up to now, chimera detection or confirmation has been pos-sible when the mutation appeared on a heterozygous posi-tions meaning that three alleles were found on a locus. On homozygous positions, chimeras could hardly be confirmed 100 | Original ArticleVITIS: Vol. 62 (Special Issue) 99–102 (2023) | DOI: 10.5073/vitis.2023.62.special-issue.99-102 | Sichel et al.because it could be confused with haplotype difference. Then the second challenge is obtaining a very high quality reference sequence and a haplotype phased assembly. In our case, we studied ‘Merlot’, which is a cross between ‘Caber-net franc’ and ‘Magdeleine Noir des Charentes ’(Boursiquot et al., 2009).Material and MethodsLeaf samples of ‘Magdeleine Noire des Charentes’ were col-lected from INRAE Vassal Montpellier (Marseillan, France), while ‘Cabernet franc’ leaves and ‘Merlot’ clone 343 leaves and roots came from IFV collection, Domaine de l’Espiguette (Le Grau-du-Roi, France). Long fragment DNA extraction was performed followed by PACBIO® hiFI long reads sequencing using Sequel II technology. ‘Merlot’ reads were sorted per haplotype by trio-binning. We then obtained two files for each ‘Merlot’ sample: “Merlot-hap-CF” and “Merlot-hap-MG”. The reads were then assembled in contigs with hifiasm (Cheng et al., 2021) and finally chromosomes were built on following PNv4 (Rustenholz et al., 2021) model, which was completed by crossing contigs from the other haplotype. In order to have a functional approach, we transferred annota-tions from PN.vcost V3 with Liftoff software (Shumate, 2021). We also chose to work on the most stable part of the genome and took out all repeated sequences using Repeat mask-er (Smit et al., 2013-2015). All reads were mapped on both ‘Merlot’ assemblies and variants were called using DeepVari-ant (Ryan Poplin, 2018). Chimera detection was performed by filtering the Variant Calling File (VCF) with vcftools program (Danecek et al., 2011).Periclinal L1 cell layer chimeras were selected when the var-iant was carried by only one haplotype on the leaf sample but all the other packets of reads had the reference nucleo-tide (Fig. 1). Mutation in the L2 cell layer had the variant on all reads from roots and a few reads from leaves, parental reads and opposite haplotype will have the same nucleotide as leaves but different from roots (Fig. 2).ResultsHigh quality reference genomeThis results in a very high quality reference sequence per hap-lotype, where in some cases there is only one contig per chro-mosome and Liftoff correctly transferred 96% genes from PN.vcost V3 (Table 1).Detected chimerasWhen applying very selective criteria on SNV’s outside re-peated sequence, 104 positions were identified as chimeric throughout the entire genome, 33% were located in a gene body region and 15% in a coding region (Table 2).According to the transferred annotation it was possible to see if the chimeras located in coding regions induced a modifica-tion in the corresponding amino acid. Out of the 16 positions, 11 changed the amino acid which could have a very impor-tant impact on the final protein conformation.DiscussionFinally, this chimera detection method can be used both ways: from DNA sequencing to phenotype in order to identify non-visible chimeras or from phenotype to DNA sequencing to identify genetic regions controlling specific traits. Overall, chimeras are opportunities to understand metabolic path-ways. They can lead to new cultivars if interesting agronom-ical characteristics are modified, and they also contribute Fig. 1: An example of read distribution when a L1 chimeras was detected.Original Article | 101 VITIS: Vol. 62 (Special Issue) 99–102 (2023) | DOI: 10.5073/vitis.2023.62.special-issue.99-102 | Sichel et al.Table 1: Chromosome length, contig numbers and gene numbers for each pseudomoleculeMerlot_leaf_CF Merlot_leaf_MG Merlot_root_CF Merlot_root_MGLength Contigs Genes Length Contigs Genes Length Contigs Genes Length Contigs Geneschr01 23598264 2 2091 25285196 3 2308 23589260 2 2090 25812159 3 2229chr02 21618960 2 1711 20834059 2 1771 21612554 2 1710 20815648 2 1773chr03 22910969 2 1896 23738413 3 1853 22695420 4 1900 22863606 2 1856chr04 28028847 1 2171 28067391 1 2199 27848422 1 2172 28047555 1 2195chr05 28252839 3 2354 27194848 4 2190 28133326 2 2359 27245740 5 2197chr06 21902219 1 1997 25066429 2 1901 21887941 2 1999 25064422 2 1900chr07 31335031 1 2892 30285517 2 2877 31316563 1 2889 30272463 2 2875chr08 25084147 2 2260 25133383 2 2159 25068184 1 2264 25106757 2 2163chr09 23385614 3 1774 25283510 3 1789 23388363 3 1772 25079599 3 1785chr10 26473290 1 2156 25356578 3 2159 26466742 1 2159 25373432 3 2160chr11 20347376 2 1571 20416243 1 1563 19944127 2 1572 20402067 1 1569chr12 27064986 2 2447 24119349 4 2347 24025996 1 2400 24096300 3 2343chr13 29400470 2 2277 29181387 2 2244 29412682 3 2277 29182803 3 2245chr14 30137549 1 2577 31130771 2 2564 30138415 1 2570 31044170 1 2545chr15 23518695 2 1552 23434760 2 1832 23494571 2 1545 23422104 2 1828chr16 22496135 1 1813 22861382 3 1840 22480932 3 1815 22716031 2 1844chr17 20156470 2 1552 20678794 5 1628 20368439 3 1554 20784459 4 1628chr18 36729617 2 3197 37876454 1 3161 36718487 2 3192 37875940 1 3164chr19 27613142 1 1978 25782670 2 1992 27618512 2 1979 25770078 2 1994Total length490054620 33 40266 491727134 47 40377 486208936 38 40218 490975333 44 40293Total + UKN499510259 499510259 500119474 503747540chrUn 9455639 7783125 13910538 12772207% Total length1.90% 1.60% 2.80% 2.50%Fig. 2: An example of read distribution when a L2 chimera was detected.102 | Original ArticleVITIS: Vol. 62 (Special Issue) 99–102 (2023) | DOI: 10.5073/vitis.2023.62.special-issue.99-102 | Sichel et al.to intra-varietal genetic diversity. Finally, if they are stable enough, they could be used as a clonal lineage signature and allow clonal identification.Additional data can be obtained from the following preprint in BMC Genomics: Sichel, V., Sarah, G., Girollet, V., Laucou, V., Roux, C., Bert, P., Le Cunff, L., This, P., Lacombe, T., 2022: Chimeras in Merlot grapevine revealed by phased assembly. https://doi.org/10.21203/rs.3.rs-2026816/v1Conflicts of interestThe authors declare that they do not have any conflicts of interest.ReferencesBauhin, C., 1598: Illustrated Exposition of Plants (the Pinax theatri botanici). sumptibus [et] typis Ludovici Regis.Blakeslee, A.F., Avery, A.G., Bergner, A.D., Satina, S.A., Sin-nott, E.W., 1939: Induction of periclinal chimeras in Datura stramonium by colchicine treatment. Science 89 (2314), 402.Boursiquot, J.M., Lacombe, T., Laucou, V., Julliard, S., Per-rin, F.X., Lanier, N., Legrand, D., Meredith, C., This, P., 2009: Parentage of Merlot and related winegrape cultivars of southwestern France: discovery of the missing link. Australi-an Journal of Grape and Wine Research 15 (2), 144-155, DOI: 10.1111/j.1755-0238.2008.00041.x.Cheng, H., Concepcion, G.T., Feng, X., Zhang, H., Li, H., 2021: Haplotype-resolved de novo assembly using phased assem-bly graphs with hifiasm. Nature Methods 18 (2), 170-175, DOI: 10.1038/s41592-020-01056-5.Danecek, P., Auton, A., Abecasis, G., Albers, C.A., Banks, E., Depristo, M.A., Handsaker, R.E., Lunter, G., Marth, G.T., Sherry, S.T., McVean, G., Durbin, R., 2011: The variant call format and VCFtools. Bioinformatics 27 (15), 2156-2158, DOI: 10.1093/bioinformatics/btr330.Nati, P., 1644: Petri Nati... Florentina phytologica obserua-tio de malo limonaia citrata-aurantia Florentiae vulgo la biz-zarria. Typis Hippolyti de Naue.Pratt, C., Einset, J., Zahur, M., 1959: Radiation Damage in Ap-ple Shoot Apices. American Journal of Botany 46 (7), 537-544, DOI: 10.2307/2439626.Rustenholz, C., Velt, A., Frommer, B., 2021: PN40024.v4 New Assembly. URL: https://integrape.eu/resources/genes-ge-nomes/genome-accessions/.Ryan Poplin, P.C.C., David Alexander, Scott Schwartz, Thom-as Colthurst, Alexander Ku, Dan Newburger, Jojo Dijamco, Nam Nguyen, Pegah T. Afshar, Sam S. Gross, Lizzie Dorfman, Cory Y. McLean, and Mark A. DePristo, 2018: DeepVariant: A universal SNP and small-indel variant caller using deep neural networks. Nature biotechnology 36, 983-987, DOI: 10.1038/nbt.4235.Satina, S., 1945: Periclinal chimeras in Datura in relation to the development and structure of the ovule. American Jour-nal of Botany, 72-81.Shumate, A., and Steven L. Salzberg, 2021: Liftoff: accurate mapping of gene annotations. Bioinformatics 37 (12), 1639-1643, DOI: 10.1093/bioinformatics/btaa1016.Smit, A.F.A., Hubley, R., Green, P., 2013-2015: RepeatMasker. URL: http://repeatmasker.org.Szymkowiak, E.J., Sussex, I.M., 1996: What chimeras can tell us about plant development. Annual Review of Plant Biology 47 (1), 351-376.Thompson, M.M., Olmo, H., 1963: Cytohistological studies of cytochimeric and tetraploid grapes. American Journal of Botany 50 (9), 901-906.Torregrosa, L.J.M., Rienth, M., Romieu, C., Pellegrino, A., 2019: The microvine, a model for studies in grapevine phys-iology and genetics. OENO One 53 (3), DOI: 10.20870/oe-no-one.2019.53.3.2409.Vezzulli, S., Leonardelli, L., Malossini, U., Stefanini, M., Ve-lasco, R., Moser, C., 2012: Pinot blanc and Pinot gris arose as independent somatic mutations of Pinot noir. Journal of Experimental Botany 63 (18), 6359-6369, DOI: 10.1093/jxb/ers290.Table 2: Number of chimeras found on each Merlot haplotypes and their distribution according to coding regions on the genomeMerlot Haplotype CF Merlot Haplotype MGL1 L2 L1 + L2 L1 L2 L1 + L2SNP, Non-repeated sequences Merlot specific  periclinal chimeras37 14 51 36 17 53Number of chimeras in non coding gene body 15 4 19 11 5 16Number of chimeras in coding region 6 3 9 6 1 7

High quality phased assembly of grape genome offer new opportunities in chimera detection

In perennial plants and especially those propagated through cuttings, several genotypes can coexist in a single individual, thus leading to chimeras. When the variant induces a noticeable phenotype modification, it can lead to a new cultivar. Viticulture already took economic advantage of this natural phenomenon: for instance, the berry skin of ‘Pinot gris’ derived from ‘Pinot noir’ by the selection of a chimera. Chimeras could also impact other crucial traits without being visually identified. Periclinal chimera where the variant has entirely colonized a cell layer is the most stable and can be propagated through cuttings. In grapevine, two functional cell layers are present in leaves, L1 and L2. However, lateral roots are formed from the L2 cell layer only. Thus, comparing DNA sequences of roots and leaves could allow chimera detection. In this study we used new generation Hifi long reads sequencing and recent bioinformatics tools applied to ‘Merlot’ to detect periclinal chimeras. Sequencing of ‘Magdeleine Noire des Charentes’ and ‘Cabernet franc’, the parents of ‘Merlot’, allowed haplotype resolved assembly. Pseudomolecules were built with few contigs, in some occasions only one per chromosome. This high resolution allowed haplotype comparison. Annotation from PN40024 was transferred to all pseudomolecules. Through variant detection, periclinal chimeras were found on both haplotypes. These results open new perspectives on chimera detection, which is an important resource to improve cultivars through clonal selection or breed new ones. Detailed results will be presented and discussed. © 2023 Bundesanstalt fur Zuchtungsforschung an Kulturpflanzen. All rights reserved

SICHEL, Victoria

SARAH, Gautier

GIROLLET, Nabil

LAUCOU, Valerie

ROUX, Catherine

LE CUNFF, Loic

THIS, Patrice

BERT, Pierre-Francois

LACOMBE, Thierry

Oskar Bordeaux

https://oskar-bordeaux.fr/bitstream/20.500.12278/188332/1/EGFV_Vitis_2023_Sichel.pdf

High quality phased assembly of grape genome offer new opportunities in chimera detection

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