A super-pangenome of the North American wild grape species

Cochetel, Noé; Minio, Andrea; Guarracino, Andrea; Garcia, Jadran F.; Figueroa-Balderas, Rosa; Massonnet, Mélanie; Kasuga, Takao; Londo, Jason P.; Garrison, Erik; Gaut, Brandon S.; Cantu, Dario

doi:10.1186/s13059-023-03133-2

Cited by 12 publications

(3 citation statements)

References 108 publications

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“…The use of pangenomes for association testing has largely relied on presence/absence variation between groups (Brynildsrud et al, 2016; Leonard et al, 2022), decomposed graph genome variation (Chin et al, 2023), or genotypes obtained by mapping of short reads to pangenomes (Cochetel et al, 2023; Sirén et al, 2021). We have developed and applied an approach that compares path similarities and differences between assemblies of samples with divergent phenotypes.…”

Section: Discussionmentioning

confidence: 99%

Taurine pangenome uncovers a segmental duplication upstream ofKITassociated with depigmentation in white-headed cattle

Milia,

Leonard,

Mapel

et al. 2024

Preprint

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Cattle have been selectively bred for coat color, spotting, and depigmentation patterns. The assumed autosomal dominant inherited genetic variants underlying the characteristic white head of Fleckvieh, Simmental, and Hereford cattle have not been identified yet, although the contribution of structural variation upstream the KIT gene has been proposed. Here, we construct a graph pangenome from 24 haplotype assemblies representing seven taurine cattle breeds to identify and characterize the white head-associated locus for the first time based on long-read sequencing data. Through examining assembly path similarities within the graph, we reveal an association between two most likely serial alleles of a complex structural variant 66 kb upstream KIT and facial depigmentation. The complex structural variant contains a variable number of tandemly duplicated 14.3 kb repeats, consisting of LTRs, LINEs, and other repetitive elements, leading to misleading alignments of short and long reads when using a linear reference. We align 250 short-read sequencing samples spanning 15 cattle breeds to the pangenome graph, further validating that the alleles of the structural variant segregate with head depigmentation. We estimate an increased count of repeats in Hereford relative to Simmental and other white-headed cattle breeds from the graph alignment coverage, suggesting a large under-assembly in the current Hereford-based cattle reference genome which had fewer copies. We show that exploiting assembly path similarities within graph pangenomes can reveal trait-associated complex structural variants.

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Section: Discussionmentioning

confidence: 99%

Taurine pangenome uncovers a segmental duplication upstream ofKITassociated with depigmentation in white-headed cattle

Milia,

Leonard,

Mapel

et al. 2024

Preprint

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“…Chloride tolerance in Vitis is not fully understood, as various mechanisms are believed to exist across different species. Some species prevent chloride uptake in the leaves, instead of accumulating it in the root system, while others show no chloride accumulation in either plant organ (Heinitz et al, 2020; Cochetel et al, 2023). For instance, the chloride-excluder accession 140 Ru has been observed to accumulate less chloride in the leaves and more in the roots, due to decreased xylem loading and restricted root-to-shoot chloride transport (Tregeagle et al, 2010; Henderson et al, 2014; Heinitz et al, 2020).…”

Section: Discussionmentioning

confidence: 99%

Hyperspectral Sensing for High-Throughput Chloride Detection in Grapevines

Sharma,

Wong,

Bhattarai

et al. 2024

Preprint

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Soil salinity affects major viticultural areas worldwide with chloride ions being the primary source of salt toxicity in grapevines. This toxicity impacts vine health and reduces fruit yield and quality. Current breeding efforts to improve grapevine salinity tolerance are limited by the low throughput of available phenotyping methods, which are time-consuming, labor-intensive, and destructive. This study demonstrated that hyperspectral proximal sensing can be utilized as a high-throughput, non-destructive screening technique to identify salinity-tolerant grapevine germplasm. The predictive abilities of two different hyperspectral devices, which varied in price, resolution, and sensitivity, were compared across 23Vitisaccessions spanning eight species. Prediction models were built using hyperspectral reflectance and leaf chloride content measured with a lab chloridometer. Three distinct approaches were studied: 1) analyzing the correlation between individual wavelengths and chloride content; 2) employing machine learning models, including Partial Least Squares Regression (PLSR), Random Forest (RF), and Support Vector Machine (SVM), utilizing all wavelengths; and 3) classification-based prediction using Partial Least Squares Discriminant Analysis (PLSDA). Multiple regions in the spectrum, including 613-660 nm, 689-696 nm, and 1357-1358 nm, showed a medium correlation (0.30-0.50) with chloride content in the leaves. PLSR was the most effective machine learning approach, demonstrating moderate predictive capability for chloride content (maximumR²= 0.67), though performance varied between the two devices tested. With PLSDA, predictions increased considerably, up to an accuracy of 0.97, depending on the instrument used and the spectral data transformation. Overall, the more expensive and sensitive device with a wider spectral range outperformed the more affordable, shorter-range device. However, when the prediction model was based on classes (chloride excluders vs. non-excluders) rather than chloride content, the differences in prediction abilities were minimal, with both instruments performing very well. This is promising for identifying breeding materials with chloride exclusion capabilities at low cost and high throughput.

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“…Besides, a reference-unbiased super-pangenome work on nine assembled genomes of wild North American grapes has revealed both inter- and intraspecific genomic variation, along with accurately estimating similarity between hybrids and their parent species. Subsequent pan-GWAS successfully pinpointed loci linked to salt tolerance, showcasing the potential for implementing this reference-unbiased super-pangenome to expedite crop breeding efforts [ 19 ].…”

Section: Grape Genomics Provide the Basis Of Grape Studiesmentioning

confidence: 99%

Biography of Vitis genomics: recent advances and prospective

Wang,

Ding,

et al. 2024

Horticulture Research

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Grape genome is the basis for grape studies and breeding, which is also important for grape industries. In the last two decades, more than 44 grape genomes have been sequenced. Based on these genomes, researchers have made a substantial progress in the mechanism of biotic and abiotic resistance, berry quality formation, and breeding strategies. In addition, these works provide essential data for future pan-genome analysis. Apart from the de novo assembled genomes, more than six whole-genome sequencing projects have provided datasets comprising almost 5000 accessions. Based on these datasets, researchers explored domestications and origin of grape and clarified the gene flow that occurred during the dispersed history. Moreover, GWAS and other methods were used to identify more than 900 genes related to the resistance, quality, and developmental phases of grape. These findings have benefit grape studies and provide some basis for smart genomic selection breeding. Otherwise, the grape genome has played a great role in grape studies and industries, and the importance of genomics will increase sharply in the future.

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A super-pangenome of the North American wild grape species

Cited by 12 publications

References 108 publications

Taurine pangenome uncovers a segmental duplication upstream ofKITassociated with depigmentation in white-headed cattle

Taurine pangenome uncovers a segmental duplication upstream ofKITassociated with depigmentation in white-headed cattle

Hyperspectral Sensing for High-Throughput Chloride Detection in Grapevines

Biography of Vitis genomics: recent advances and prospective

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