A uniform gene and chromosome nomenclature system for oat (Avena spp.)
Eric N. Jellen
A * , Charlene P. Wight B , Manuel Spannagl C , Victoria C. Blake D E , James Chong F , Matthias H. Herrmann G , Catherine J. Howarth H , Yung-Fen Huang I , Jia Juqing J , Andreas Katsiotis K , Tim Langdon H , Chengdao Li L , Robert Park M , Nicholas A. Tinker B and Taner Z. Sen D N
A
B
C
D
E
F
G
H
I
J
K
L
M
N
Abstract
Several high-quality reference genomes for oat (Avena sativa L. and relatives) have been published, with the prospect of many additional whole-genome assemblies emerging in the near future.
This has necessitated an effort by the International Oat Nomenclature Committee (IONC; all co-authors on this paper) to devise a universal system for naming oat genomes and subgenomes, chromosomes, genes, gene models and quantitative trait loci.
We evaluated existing naming practices, recent data from oat whole-genome sequencing, and the newly published convention for wheat nomenclature.
A framework for these rules has been posted on the GrainGenes database website (https://wheat.pw.usda.gov/GG3/oatnomenclature). The gene naming convention requires adoption of a numerical identifier for each genotype; we propose that these identifiers be assigned by contacting the GrainGenes curators, the curator of the Oat Newsletter, or a member of the IONC (as listed at the GrainGenes link above).
We encourage oat researchers to refer to these resources, policies, procedures and conventions, adopting them as an international nomenclature standard.
Adoption of these standards will facilitate communication and dissemination of oat research and allow programmatic access and data sharing across platforms, and will contribute to oat breeding and research worldwide.
Keywords: Avena, chromosome nomenclature, data standardisation, gene nomenclature, genome nomenclature, oat, plant breeding, QTL nomenclature.
Introduction
The past 4 years have witnessed the publication of the first whole-genome sequence assemblies of the oat genus Avena L., classified within subfamily Pooideae of the Poaceae, tribe Poeae, subtribe Aveninae. The first oat whole-genome sequences published were for A- and C-genome diploids (Maughan et al. 2019), and rapidly progressed further to hexaploid A. sativa L. (2n = 6x = 42, AACCDD) with the online release of the hexaploid OT3098 sequence in 2020 on the GrainGenes database (Yao et al. 2022) website (https://wheat.pw.usda.gov/jb/?data=/ggds/oat-ot3098-pepsico). This release was followed by published assemblies of the OT3098 ver. 2 assembly in 2021, Swedish hulled oat cv. Sang (Kamal et al. 2022), and Chinese hulless cv. Sanfensan (Peng et al. 2022). Significantly, these whole-genome sequences permitted the assignment of each of the 21 oat chromosomes to their subgenome and homoeologous group. The group designations were based on synteny with the seven chromosomes of the non-Poeae grass barley (Hordeum vulgare L.). Whole-genome sequencing efforts are now progressing toward assemblies of multiple genotypes of common oat and closely related species in a coordinated international effort – the Oat Pangenome Project (PanOat). This has necessitated a reappraisal of the various existing oat chromosome, linkage group, gene and gene model designations and their unification into a single, universal nomenclature convention.
Oat geneticists in the 1960s were the first to suggest that A. sativa and its allohexaploid allied taxa – A. byzantina C. Koch (red oat), A. fatua L. (common wild oat) and A. sterilis L. (wild animated oat) – carried the AA, CC and DD subgenomes (Rajhathy and Thomas 1974). Their original karyotype-based nomenclature system was based on chromosome morphology without molecular cytogenetic or chromosome banding data (Rajhathy 1963), and gene nomenclature generally followed rules established in other cereal species, particularly those in the tribe Triticeae (Simons et al. 1966, 1978). We present a universal genome, chromosome, transcriptome and gene identification system approved by the International Oat Nomenclature Committee (IONC) for application to all Avena genotypes that are analysed moving forward. This system follows the convention for chromosome nomenclature established for barley (Singh and Tsuchiya 1982; Wang et al. 1996) and the new system for wheat (Boden et al. 2023).
The nomenclature rules
Genomes and subgenomes
Whole-genome sequence assemblies (Kamal et al. 2022; Peng et al. 2022) along with prior work by various authors including Yan et al. 2016 and Latta et al. (2019) have confirmed the unique identities of the A, B, C and D genomes/subgenomes of Avena. In addition, we herein propose a separate genome designator for the perennial autotetraploid oat A. macrostachya, EE, because of its uniquely long chromosomes with dense pericentromeric heterochromatin patterns, highly symmetrical karyotype (Badaeva et al. 2010), and recalcitrance to crossing with other Avena species having genomes A, B and D, albeit with somewhat greater homology to genome C (Leggett 2011). In the current proposal, the subgenomes of A. sativa are indicated with the subscript ‘s’. Diploid genomes will follow several new conventions: Aa represents the A. atlantica–strigosa biological species group, Ac is for the A. canariensis genome, Ad for A. damascena, Al for A. longiglumis, and Ap for A. prostrata. For the CC diploids, Ce represents the genome of the A. eriantha–clauda group and Cv is used for A. ventricosa. The A. barbata group contains subgenomes Ab and B (which has not been identified in any other biological species). The C- and D-subgenomes in the Section Pachycarpa tetraploids are represented as Ci and Di in A. insularis, Cg and Dg in A. magna (syn. A. maroccana), and Cy and Dy in A. murphyi. Use of the subscript ‘m’ is discouraged owing to potential confusion with multiple tetraploid species names beginning with the letter ‘m’.
For the gene models, each Avena biological species-group has a five-letter species designator beginning with ‘AVxxx’ and each genotype is to be assigned its own specific five-digit code, beginning with the first set of assembled reference genomes (Table 1). Hereafter, each new sequenced genotype should be assigned a number after consultation between the researcher and the GrainGenes curation team. Genotypes of the same species are grouped within specified numerical ranges, as follows. Numbers 00001–09999 are reserved for natural hexaploids of the A. sativa group. Tetraploids are numbered 10000–15999. Diploids are numbered 20000–26999. Synthetics will be designated with numbers in the 30000s.
| Five-letter species designator code | Ploidy | Subgenomes | Included Avena taxa | Reserved genotype identifier codes | |
|---|---|---|---|---|---|
| AVAGA | 4x | A’A’B’B’ | agadiriana | 11000–11999 | |
| AVATL | 2x | AₐAₐ, sometimes AₐAₐAₐAₐ | atlantica | 20000–20999 | |
| brevis | |||||
| hirtula | |||||
| hispanica | |||||
| nuda | |||||
| nudibrevis | |||||
| strigosa | |||||
| wiestii | |||||
| AVBAR | 4x | AbAbBB | abyssinica | 10000–10999 | |
| barbata | |||||
| vaviloviana | |||||
| AVCAN | 2x | AcAc | canariensis | 21000–21999 | |
| AVDAM | 2x | AdAd | damascena | 22000–22999 | |
| AVERI | 2x | CₑCₑ | clauda | 25000–25999 | |
| eriantha | |||||
| pilosa | |||||
| AVINS | 4x | CiCiDiDi | insularis | 12000–12999 | |
| AVLON | 2x | AₗAₗ | longiglumis | 23000–23999 | |
| AVMAG | 4x | CgCgDgDg | maroccana | 13000–13999 | |
| magna | |||||
| AVMAC | 4x | EEEE (possibly EEE’E’) | macrostachya | 15000–15999 | |
| AVMUR | 4x | CyCyDyDy | murphyi | 14000–14999 | |
| AVPRO | 2x | AₚAₚ | prostrata | 24000–24999 | |
| AVESA | 6x | AₛAₛCₛCₛDₛDₛ | byzantina | 00001–09999 | |
| fatua | |||||
| ludoviciana | |||||
| occidentalis | |||||
| sativa | |||||
| sativa subsp. nuda | |||||
| sterilis | |||||
| AVSYN | 4x-10x | Various | Synthetic allopolyploids, e.g. Amagalon | 30000–30999 | |
| AVVEN | 2x | CvCv | bruhnsiana | 26000–26999 | |
| ventricosa |
Designations generally follow biological species concept groups as outlined by Ladizinsky (2012).
Chromosome correspondences
Homoeologous chromosome groups were identified and subgenome assignments made based on common synteny within Avena and with chromosomes 1H–7H of Hordeum vulgare, along with distributions of subgenome-abundant repetitive motifs (Jiang et al. 2021; Kamal et al. 2022; Peng et al. 2022) (Table 2).
| PepsiCo, Yao et al. (2022), Jiang et al. (2021) | Chaffin et al. (2016) Mrg consensus linkage group | Sanz et al. (2010) chromosome designation | Maughan et al. (2019) diploid oat assemblies | NEW 2x chromosome designation | NEW 6x chromosome designation | |
|---|---|---|---|---|---|---|
| Genome A | ||||||
| 1Aₛ(−) | Mrg18(−) | 17A | AA2(+) | 1Aₐ | 1Aₛ | |
| 2Aₛ(+) | Mrg33(+) | 15A | AA5(−) | 2Aₐ | 2Aₛ | |
| 3Aₛ(+) | Mrg23(+) | 11A | AA3(+) | 3Aₐ | 3Aₛ | |
| 4Aₛ(+) | Mrg20(+) | 19A | AA4(−) | 4Aₐ | 4Aₛ | |
| 5Aₛ(+) | Mrg24(+) | 8A | AA6(−) | 5Aₐ | 5Aₛ | |
| 6Aₛ(+) | Mrg05(+) | 16A | AA7(−) | 6Aₐ | 6Aₛ | |
| 7Aₛ(+) | Mrg12(+) | 13A | AA1(−) | 7Aₐ | 7Aₛ | |
| Genome C | ||||||
| 1Cₛ(−) | Mrg28(−) | 7C | AE5(+) | 1Cₑ | 1Cₛ | |
| 2Cₛ(+) | Mrg13(+) | 5C | AE4(−) | 2Cₑ | 2Cₛ | |
| 3Cₛ(+) | Mrg15(−) | 2C | AE3(−) | 3Cₑ | 3Cₛ | |
| 7Cₛ(+) | Mrg11(+) | 1C | AE1(−) | 4Cₑ | 4Cₛ | |
| 5Cₛ(−) | Mrg03(−) | 4C | AE6(−) | 5Cₑ | 5Cₛ | |
| 6Cₛ(−) | Mrg17(−) | 3C | AE2(−) | 6Cₑ | 6Cₛ | |
| 4Cₛ(−) | Mrg09(−) | 6C | AE7(−) | 7Cₑ | 7Cₛ | |
| Genome D | ||||||
| 1Dₛ(−) | Mrg01(−) | 14D | – | – | 1Dₛ | |
| 2Dₛ(−) | Mrg08(−) | 12D | – | – | 2Dₛ | |
| 3Dₛ(+) | Mrg19(+) | 21D | – | – | 3Dₛ | |
| 4Dₛ(+) | Mrg21(+) | 20D | – | – | 4Dₛ | |
| 5Dₛ(−) | Mrg06(−) | 10D | – | − | 5Dₛ | |
| 6Dₛ(−) | Mrg04(−) | 18D | – | – | 6Dₛ | |
| 7Dₛ(−) | Mrg02(−) | 9D | – | − | 7Dₛ | |
The new chromosome numbering system (bolded columns) is based on synteny with pericentromeric core chromosome regions of Hordeum vulgare. The suffixes (+) and (−) denote the orientations of chromosomes relative to the new system (Kamal et al. 2022) As new Avena species are sequenced, their chromosomes will be oriented and numbered relative to the information presented here, using the genome and subgenome designations presented in Table 1. The reference for the PepsiCo release of OT3098 is as follows: Avena sativa – OT3098 v1, PepsiCo, https://wheat.pw.usda.gov/GG3/graingenes_downloads/oat-ot3098-pepsico). Note that in this table, chromosomes 4Cs and 7Cs are switched from the designation used in the PepsiCo OT3098 (Jiang et al. 2021; Yao et al. 2022) and Sanfensan genomes (Peng et al. 2022), in keeping with the analyses reported by Kamal et al. (2022).
Quantitative trait loci, genes and proteins
The IONC recognises the utility of having a consistent naming system for QTL. However, many quantitative trait loci (QTLs) have been identified in oat over the years, and changing the older names could cause confusion. Therefore, the committee proposes that:
The names of previously published QTLs be kept as is, unless this would duplicate a name used elsewhere. In such cases, the name would be modified, staying close to the original.
The names of new QTLs and previously published QTLs with no names assigned be given names using the following convention, which has been derived from the standard used by the GrainGenes database (Yao et al. 2022; https://wheat.pw.usda.gov/), and informed by the new wheat nomenclature rules outlined by Boden et al. (2023):
Field1 is the main trait name (two to five letters). If any additional trait or environment information is necessary to distinguish the QTL, then a dash followed by two to five more letters is added.
Field2 is the map name, with the year and a dash added if necessary to distinguish the work. Typically, the map name would either be an abbreviated version of the pedigree for a biparental cross, or the name given to an association mapping population.
Field3 is the linkage group name. If the group has been assigned to an ‘Mrg’ linkage group from the 2018 hexaploid oat consensus map (Bekele et al. 2018), then ‘Mrg’ is included in the name. If more than one QTL for the same trait is found on one linkage group, then a period is added, followed by a number to distinguish the QTL.
A simple example of a name created using this system would be ‘QHDNV.U8xU605_6’ (QTL for heading date using non-vernalised plants, mapped in the UFRGS 8/UFRGS 930605 (U8xU605) population on linkage group 6). A more complex example would be ‘QHD-Far11.2016-CORE_Mrg20.2’ (QTL for heading date recorded at Fargo, ND, in 2011, mapped using the CORE set of lines in 2016 on linkage group Mrg20, the second of two HD QTLs on that group). Examples of other styles of QTLs already in the literature include ‘Days to heading’, ‘KxO-11-c’ and ‘QPlumps.Aberd17.2A’ (in this last case, the chromosome number is identified).
We recognise the importance of consistent use of gene model identifiers across Avena genotypes to facilitate analysis and interpretation across studies (Schnable 2020). It is important to emphasise that no perfect solution for gene model nomenclature exists, and each choice has advantages and disadvantages. Indeed, we are aware that different plant researcher communities adopted slightly different guidelines for their species. With this in mind, we propose the adoption of the following gene-model syntax for Avena:
Field1 is a five-character-long descriptor for species as shown in Table 1 (‘designator code’). It will be shown in all upper case letters.
Field2 is a six-character-long descriptor for oat genotypes. The first five characters will be numerical, and the last character will be alphanumeric. The currently assigned genotype identifiers are shown in Table 3. The last character (shown as ‘x’ in Table 3 as a placeholder) will be to give flexibility to account for genotype variants, or in case more than one assembly exists for the very same cultivar (e.g. assemblies done by the same or different research groups). The six-character-long identifier in this field will be assigned by the IONC and will be publicly available through GrainGenes (Yao et al. 2022) at https://wheat.pw.usda.gov/GG3/oatnomenclature. To obtain a new identifier, researchers are encouraged to reach out to the IONC through GrainGenes (feedback@graingenes.org).
| Common name | Source | Avena taxa | Five-letter species designator code | Number | |
|---|---|---|---|---|---|
| OT 3098 | PanOat/PepsiCo | sativa | AVESA | 00001 x | |
| GMI 423 | PanOat/GMI | sativa | AVESA | 00002 x | |
| Bingo | PanOat | sativa | AVESA | 00003 x | |
| FM13 | PanOat | sativa | AVESA | 00004 x | |
| Hative des Alpes | PanOat | sativa | AVESA | 00005 x | |
| Bannister | PanOat | sativa | AVESA | 00006 x | |
| Bilby | PanOat | sativa | AVESA | 00007 x | |
| Clintland 60 (CIav 7234) | PanOat/USDA | sativa | AVESA | 00008 x | |
| Nicolas | PanOat/Canada | sativa | AVESA | 00009 x | |
| Sang | PanOat/Scanoat | sativa | AVESA | 00010 x | |
| OT 380 | PanOat/USDA | sativa | AVESA | 00011 x | |
| Aslak | PanOat/LUKE | sativa | AVESA | 00012 x | |
| Lion | PanOat | sativa | AVESA | 00013 x | |
| Rhapsody | PanOat | sativa | AVESA | 00014 x | |
| Delfin | PanOat | sativa | AVESA | 00015 x | |
| HiFi | PanOat/Canada | sativa | AVESA | 00016 x | |
| Park | PanOat/Canada | sativa | AVESA | 00017 x | |
| GS7; 94197A1-9-2-2-2-5 | PanOat/Canada | sativa | AVESA | 00018 x | |
| Leggett | AAFC | sativa | AVESA | 00019 x | |
| AC Morgan | AAFC | sativa | AVESA | 00020 x | |
| Sanfensan | Yuanying Peng | sativa subsp. nuda | AVESA | 00400 x | |
| PI 182478 | PanOat/USDA | sativa subsp. nuda | AVESA | 00401 x | |
| Gehl | PanOat/Canada | sativa subsp. nuda | AVESA | 00402 x | |
| PI 258586 | PanOat/IBERS | byzantina | AVESA | 00500 x | |
| Victoria | PanOat | byzantina | AVESA | 00501 x | |
| CN 25955 | PanOat | fatua | AVESA | 00600 x | |
| Tn1 | PanOat/IBERS | sterilis | AVESA | 00700 x | |
| Tn5 | PanOat/IBERS | sterilis | AVESA | 00701 x | |
| PI 388828 | PanOat/USDA | barbata | AVBAR | 10000 x | |
| PI 411152 | BYU/USDA | abyssinica | AVBAR | 10001 x | |
| BYU 209 | PanOat | insularis | AVINS | 12000 x | |
| CN 108634 | Yuanying Peng | insularis | AVINS | 12001 x | |
| CN 58138 | PanOat | longiglumis | AVLON | 23000 x | |
| CN 58139 | Yuanying Peng | longiglumis | AVLON | 23001 x | |
| Amagalon | PanOat | magna X longiglumis | AVSYN | 30000 x |
Note that ‘x’ in the number column is only used as a placeholder (as described in the text) to account for genotype variants, or in case more than one assembly exists for the same cultivar.
Field3 is a two-character-long descriptor for the annotation release version for a given assembly. The first release will be r1, the second r2, and so forth. One example could be the same group working on the same assembly creating a second set of annotations.
Field4 is a 10-character-long descriptor. The first two characters are alphanumeric and designate the chromosome (e.g. 4D). The third character is ‘g’ for gene locus, even for transcripts or proteins. The lower case, as opposed to upper case, ‘g’ was selected to increase the readability of the preceding chromosome descriptor. The following seven characters are the gene model identifier based on the position ordering from the 5’ to 3’ DNA sequence for each chromosome (i.e. first predicted gene loci on the 1A chromosome will be 1Ag0000001, 1Ag0000002, and so forth; first predicted gene locus on the 2A chromosome will be 2Ag0000001). There is a caveat for researchers: these numbers are dependent on the annotation pipelines/assemblies, and therefore, the same gene identifier may not point to the same gene locus for different releases or between different genotypes. To obtain orthologous relationships between the individual gene models of all genotypes included in PanOat, we will provide an orthologous gene framework with the pan-genome analysis.
Field5 is a flexible-length descriptor to show transcripts, isoforms/splice variants, and proteins. Field5 will be blank for gene loci. For gene models, gene transcripts, isoforms and proteins, the field will be numbered as 1, 2, and so forth.
As an example, the following is an acceptable instance for Avena sativa (therefore ‘AVESA’) OT3098 genotype’s (‘00001’) ver. 1 assembly (‘a’; if this was ver. 2 assembly, it would have been ‘b’) and ver. 2 annotation set (‘r2’), on the 1A chromosome (‘1A’), for the first gene locus (‘0000001’):
Existing oat gene names will continue to be used, but moving forward, the guidelines developed for wheat gene nomenclature detailed in Boden et al. (2023) will be followed.
The system for designating loci controlling reaction to biotic agents that attack oat proposed by Simons et al. (1978) (Table 4) will continue to be followed but with the omission of the hyphen in designations (e.g. ‘Pc1’ rather than ‘Pc-1’) to reflect the more common usage of the former in publications since 1978. It should be noted that the chromosomal locations of many of the loci that have been catalogued to date remain unknown, and that some of these may prove to be allelic once this is resolved. If this arises, it will be necessary to change the numbering of the locus/loci involved, and possibly delete others from the catalogue, as has occurred in wheat (e.g. the deletion of Sr1 due to synonymy with Sr9d, and of Sr3 and Sr4 due to a lack of single gene stocks; McIntosh et al. 1995) (Park et al. 2022).
| Pathogen | Disease | Gene designation | Notes | |
|---|---|---|---|---|
| Blumeria graminis f. sp. avenae (syn. Erysiphe graminis) | Powdery mildew | Pm | Formerly Eg (Hsam et al. 2014) | |
| Ditylenchus dipsaci | Stem nematode | Dd | ||
| Heterodera avenae | Cereal cyst nematode | Ha | ||
| Helminthosporium (Cochliobolus) victoriae | Victoria blight | Hv | ||
| Puccinia coronata f. sp. avenae | Crown rust | Pc | ||
| Puccinia graminis f. sp. avenae | Stem rust | Pg | ||
| Pseudomonas coronafaciens pv. coronafaciens | Halo blight | Psc | Kim (2020) | |
| Pseudomonas coronafaciens pv. striafaciens | Stripe blight | Pcs | Dutta et al. (2018) | |
| Schizaphis graminum | Greenbug | Grb | Radchenko et al. (2018) | |
| Ustilago kolleri | Covered smut | U | ||
| Ustilago avenae | Loose smut | U |
The protein notation for gene models is specified in the Gene model Identifiers section above. For the protein names associated with gene loci, Boden et al. (2023) will be followed.
Discussion
The rules and guidelines outlined above represent an effort to accommodate over 100 years of gene, genome and chromosome nomenclature in Avena, while providing for standardisation, not only within the oat research community, but also extending to the broader cereal grass research community working on barley, wheat, rye and triticale. The time is ripe for this standardised nomenclature system, given the rapid expansion of oat and Triticeae genome sequencing efforts. It is our expectation that genome sequence information from other cereal grass genera will be essential resources to leverage in identifying economically important gene homologs within the A. sativa genome. We strongly encourage all oat researchers to familiarise themselves with this nomenclature and with the online resources and personnel at GrainGenes (https://wheat.pw.usda.gov/GG3/; Yao et al. 2022) and to adhere to the policies above through consultation with the GrainGenes team.
Data availability
Data sharing is not applicable because no new data were generated or analysed during this study.
Conflicts of interest
Robert Park is an Associate Editor of Crop & Pasture Science. To mitigate this potential conflict of interest, he was blinded from the review process. The authors declare no other conflicts of interest.
Declaration of funding
VCB and TZS were supported by the US Department of Agriculture, Agricultural Research Service, Project No. 2030-21000-056-00D.
References
Badaeva ED, Shelukhina OY, Diederichsen A, Loskutov IG, Pukhalskiy VA (2010) Comparative cytogenetic analysis of Avena macrostachya and diploid C-genome Avena species. Genome 53, 125-137.
| Crossref | Google Scholar |
Bekele WA, Wight CP, Chao S, Howarth CJ, Tinker NA (2018) Haplotype-Based genotyping-by-sequencing in oat genome research. Plant Biotechnology Journal 16, 1452-1463.
| Crossref | Google Scholar |
Boden SA, McIntosh RA, Uauy C, Krattinger SG, Dubcovsky J, Rogers WJ, Xia XC, Badaeva ED, Bentley AR, Brown-Guedira G, Caccamo M, Cattivelli L, Chhuneja P, Cockram J, Contreras-Moreira B, Dreisigacker S, Edwards D, Gonzalez FG, Guzman C, Ikeda TM, Karsai I, Nasuda S, Pozniak C, Prins R, Sen TZ, Silva P, Simkova H, Zhang Y, the Wheat Initiative (2023) Updated guidelines for gene nomenclature in wheat. Theoretical and Applied Genetics 136, 72.
| Crossref | Google Scholar | PubMed |
Chaffin AS, Huang Y-F, Smith S, Bekele WA, Babiker E, Gnanesh BN, Foresman BJ, Blanchard SG, Jay JJ, Reid RW, Wight CP, Chao S, Oliver R, Islamovic E, Kolb FL, McCartney C, Mitchell Fetch JW, Beattie AD, Bjornstad A, Bonman JM, Langdon T, Howarth CJ, Brouwer CR, Jellen EN, Klos KE, Poland JA, Hsieh T-F, Brown R, Jackson E, Schlueter JA, Tinker NA (2016) A consensus map in cultivated hexaploid oat reveals conserved grass synteny with substantial subgenome rearrangement. The Plant Genome 9, plantgenome2015.10.0102.
| Crossref | Google Scholar |
Dutta B, Gitaitis R, Agarwal G, Coutinho T, Langston D (2018) Pseudomonas coronafaciens sp. nov., a new phytobacterial species diverse from Pseudomonas syringae. PLoS ONE 13, e0208271.
| Crossref | Google Scholar | PubMed |
Hsam SLK, Mohler V, Zeller FJ (2014) The genetics of resistance to powdery mildew in cultivated oats (Avena sativa L.): current status of major genes. Journal of Applied Genetics 55, 155-162.
| Crossref | Google Scholar | PubMed |
Jiang W, Jiang C, Yuan W, Zhang M, Fang Z, Li Y, Li G, Jia J, Yang Z (2021) A universal karyotypic system for hexaploid and diploid Avena species brings oat cytogenetics into the genomics era. BMC Plant Biology 21, 213.
| Crossref | Google Scholar | PubMed |
Kamal N, Renhuldt NT, Bentzer J, Gundlach H, Haberer G, Juhasz A, Lux T, Bose U, Tye-Din JA, Lang D, van Gessel N, Reski R, Fu Y-B, Spegel P, Ceplitis A, Himmelbach A, Waters AJ, Bekele WA, Colgrave ML, Hansson M, Stein N, Mayer KFX, Jellen EN, Maughan PJ, Tinker NA, Mascher M, Olsson O, Spannagl M, Sirijovski N (2022) The mosaic oat genome gives insights into a uniquely healthy cereal crop. Nature 606, 113-119.
| Crossref | Google Scholar | PubMed |
Kim YC (2020) First report of oat halo blight caused by Pseudomonas coronafaciens in South Korea. Plant Disease 104, 1853.
| Crossref | Google Scholar |
Latta RG, Bekele WA, Wight CP, Tinker NA (2019) Comparative linkage mapping of diploid, tetraploid, and hexaploid Avena species suggests extensive chromosome rearrangement in ancestral diploids. Scientific Reports 9, 12298.
| Crossref | Google Scholar | PubMed |
Leggett JM (2011) Further hybrids involving the perennial autotetraploid oat Avena macrostachya. Genome 35, 273-275.
| Crossref | Google Scholar |
Maughan PJ, Lee R, Walstead R, Vickerstaff RJ, Fogarty MC, Brouwer CR, Reid RR, Jay JJ, Bekele WA, Jackson EW, Tinker NA, Langdon T, Schlueter JA, Jellen EN (2019) Genomic insights from the first chromosome-scale assemblies of oat (Avena spp.) diploid species. BMC Biology 17, 92.
| Crossref | Google Scholar | PubMed |
Park RF, Boshoff WHP, Cabral AL, Chong J, Martinelli JA, McMullen MS, Fetch JWM, Paczos-Grzeda E, Prats E, Roake J, Sowa S, Ziems L, Singh D (2022) Breeding oat for resistance to the crown rust pathogen Puccinia coronata f. sp. avenae: achievements and prospects. Theoretical and Applied Genetics 135, 3709-3734.
| Crossref | Google Scholar |
Peng Y, Yan H, Guo L, Deng C, Wang C, Wang Y, Kang L, Zhou P, Yu K, Dong X, Liu X, Sun Z, Peng Y, Zhao J, Deng D, Xu Y, Li Y, Jiang Q, Li Y, Wei L, Wang J, Ma J, Hao M, Li W, Kang H, Peng Z, Liu D, Jia J, Zheng Y, Ma T, Wei Y, Lu F, Ren C (2022) Reference genome assemblies reveal the origin and evolution of allohexaploid oat. Nature Genetics 54, 1248-1258.
| Crossref | Google Scholar | PubMed |
Radchenko EE, Kuznetsova TL, Chumakov MA, Loskutov IG (2018) Greenbug (Schizaphis graminum) resistance in oat (Avena spp.) landraces from Asia. Genetic Resources and Crop Evolution 65, 571-576.
| Crossref | Google Scholar |
Rajhathy T (1963) A standard karyotype for Avena sativa. Canadian Journal of Genetics and Cytology 5, 127-132.
| Crossref | Google Scholar |
Sanz MJ, Jellen EN, Loarce Y, Irigoyen ML, Ferrer E, Fominaya A (2010) A new chromosome nomenclature system for oat (Avena sativa L. and A. byzantina C. Koch) based on FISH analysis of monosomic lines. Theoretical and Applied Genetics 121, 1541-1552.
| Crossref | Google Scholar | PubMed |
Schnable JC (2020) Genes and gene models, an important distinction. New Phytologist 228, 50-55.
| Crossref | Google Scholar | PubMed |
Singh RJ, Tsuchiya T (1982) Identification and designation of telocentric chromosomes in barley by means of Giemsa N-banding technique. Theoretical and Applied Genetics 64, 13-24.
| Crossref | Google Scholar | PubMed |
Wang RR-C, von Bothmer R, Dvorak J, Fedak G, Linde-Laursen I, Muramatsu M (1996) Genome symbols in the Triticeae (Poaceae). In ‘Proceedings of the 2nd International Triticeae Symposium’. Logan, Utah, 1994. (Eds RR-C Wang, KB Jensen, C Jaussi) pp. 29–34. (Utah State University, Herbarium Publications: Logan, UT, USA)
Yan H, Bekele WA, Wight CP, Peng Y, Langdon T, Latta RG, Fu Y-B, Diederichsen A, Howarth CJ, Jellen EN, Boyle B, Wei Y, Tinker NA (2016) High-density marker profiling confirms ancestral genomes of Avena species and identifies D-genome chromosomes of hexaploid oat. Theoretical and Applied Genetics 129, 2133-2149.
| Crossref | Google Scholar | PubMed |
Yao E, Blake VC, Cooper L, Wight CP, Michel S, Cagirici HB, Lazo GR, Birkett CL, Waring DJ, Jannink J-L, Holmes I, Waters AJ, Eickholt DP, Sen TZ (2022) GrainGenes: a data-rich repository for small grains genetics and genomics. Database 2022, baac034.
| Crossref | Google Scholar |
