04 Jul 2022
17:00 - 18:00
University of Latvia House of Nature - Courtyard- indor
Poster session 1
Confirmed Posters:
| Corresponding Author | Title | Theme | Poster Stand number |
| Jiawu Feng | Chromosome-scale and haplotype-resolved sequence assembly of Hordeum bulbosum genomes | The barley genome: from reference genome to structure and function. | 1 |
| Marek Marzec | Identification of genes involved in spike architecture and time of flowering in barley | The barley genome: from reference genome to structure and function. | 2 |
| Shengming Yang | Genetic and physical localization of a spot form net blotch susceptibility gene in barley | The barley genome: from reference genome to structure and function. | 3 |
| Thomas Lux | A Consolidated Gene Annotation for the Barley Pan-Genome | The barley genome: from reference genome to structure and function. | 4 |
| Hélène Pidon | Ryd4Hb: a major resistance locus to BYDV from the barley wild relative Hordeum bulbosum with a very large diversity in barley germplasm | Biotic stresses under Climate Change | 5 |
| Ramesh Pal Singh Verma | Collaborative approach for biotic stresses phenotyping excellence in developing world | Biotic stresses under Climate Change | 6 |
| Ping Yang | Genomic and pathogenic diversity of barley yellow mosaic virus and barley mild mosaic virus isolates in fields of China and their compatibility with resistance genes of cultivated barley | Biotic stresses under Climate Change | 7 |
| Elina Sokolova | Development of a marker within the candidate Un8 true loose smut resistance gene for use in Latvian barley breeding | Biotic stresses under Climate Change | 8 |
| Triin Vahisalu | HvOZ.26 – a newly identified recepto central for plant abiotic and biotic stress tolerance. | Biotic stresses under Climate Change | 9 |
| Ping Yang | Host specificity of soil-borne pathogens in Hordeum species and their relatives | Biotic stresses under Climate Change | 10 |
| Yu Cai | Towards deciphering various barley leaf rust resistances in the MBR1012 x Scarlett population | Biotic stresses under Climate Change | 11 |
| Andrea Visioni | Genome Wide Association Mapping for Net Form of Net Blotch in the ICARDA’s HI-AM panel reveals genomic hotspots for barley multiple resistance to biotrophic and necrotrophic diseases in barley | Biotic stresses under Climate Change | 12 |
| Alina Klaus | Root-zone-specific transcriptomic reprogramming of barley roots in response to water deficit | Abiotic stresses under Climate Change | 13 |
| Agata Daszkowska-Golec | The analysis of barley cbp20/cbp80 double mutant exposed to drought stress at the seedling stage. | Abiotic stresses under Climate Change | 14 |
| Agata Daszkowska-Golec | The role of ABA in barley response to drought at the pre-flowering stage | Abiotic stresses under Climate Change | 15 |
| Shakhira Zakhrabekova | Worldwide analysis of temperature and day length cues affecting flowering in barley | Abiotic stresses under Climate Change | 16 |
| Ramesh Pal Singh Verma | Genome wide association studies for yield components, physiological, and grain malting traits under late heat conditions in northern plains of India on global barley (Hordeum vulgare L.) collection from ICARDA | Abiotic stresses under Climate Change | 17 |
| Tianyu Lan | THE MOLECULAR MECHANISM OF TEMPERATURE-RESPONSIVE INFLORESCENCE DEVELOPMENT IN BARLEY (HORDEUM VULGARE) | Abiotic stresses under Climate Change | 18 |
| Kumsal Ecem Çolpan | Effect of High Ambient Temperature on Plant Growth and Reproductive Development in Barley Cultivars | Abiotic stresses under Climate Change | 19 |
| Ana M. Casas | Responses of barley to high ambient temperature are modulated by vernalization | Abiotic stresses under Climate Change | 20 |
| Brian Steffenson | Enhancing winter survival in autumn-sown barley | Abiotic stresses under Climate Change | 21 |
| Alessandro Tondelli | Water use efficiency of a spring 2-row barley population assessed in the PlantArray physiological phenotyping platform | Abiotic stresses under Climate Change | 22 |
| Vilius Mensonas | Investigation of aluminum toxicity response of Lithuanian barley cultivars | Abiotic stresses under Climate Change | 23 |
| Michael Anokye | The Hordeum genus: a rich resource for adaptive genetic variation | Abiotic stresses under Climate Change | 24 |
| Villő Bernád | Agronomic Characterization of European Heritage Collection (ExHIBiT) | Abiotic stresses under Climate Change | 25 |
| Julio Isidro Sánchez | Training set optimization for Sparse phenotyping in Genomic Selection | Barley breeding and new breading techniques: a way forward? | 26 |
| Lorena Cammarota-Ricco | Genetic determinants of malting quality traits in a barley population representative of elite breeding in South America | Barley breeding and new breading techniques: a way forward? | 27 |
| Liina Jakobson | Comparative study of powdery mildew resistance breeding strategies in barley | Barley breeding and new breading techniques: a way forward? | 28 |
| Claus Krogh Madsen | Optimizing barley genome editing with insights from ddPCR | Barley breeding and new breading techniques: a way forward? | 29 |
| Zelalem Eshetu Bekalu | Promoter bashing and modification of CREs in the HvNEP-1 promoter for improved expression and FHB disease resistance | Barley breeding and new breading techniques: a way forward? | 30 |
| Tobias Hanak | GEaReD – Genome Editing-accelerated Re-Domestication of wild barley Hordeum vulgare ssp. spontaneum as a toolkit for current and future challenges. |
Barley breeding and new breading techniques: a way forward? | 31 |
| Eyal Bdolach | The plamotype as a source for phenotypic diversity under stress in barley | Barley breeding and new breading techniques: a way forward? | 32 |
| Jovana Janjić | WILD BARLEY RE-DOMESTICATION: MAKING WILD BARLEY DWARF AND POWDERY MILDEW RESISTANT WITH CRISPR/CAS9 GENOME EDITING |
Barley breeding and new breading techniques: a way forward? | 33 |
Coffee&Snaks