Fruit Quality Traits and Self‐ (In)compatibility Allele Status of Some Apricot (Prunus armeniaca L.) Seedlings Obtained by Cross‐Breeding [PDF]
Food Science &Nutrition, Volume 13, Issue 11, November 2025.Hybrid genotypes 6, 3, 8, and 39 having high fruit weight, an important character in table apricots, and hybrid genotypes 34, 35, 47, and 68 having high SSC, an important feature in dried apricots, were determined to be self‐compatible. Although hybrid genotype 3 was self‐incompatible, it attracted attention with its red fruit color and weight.
Derya Taşdemir Karaoğlan +4 more
wiley +2 more sources
Phylogeographic and Potential Distribution of Wild Apricot (Prunus armeniaca) in Xinjiang: Insights From Chloroplast/Nuclear DNA and Ecological Niche Modeling [PDF]
Ecology and Evolution, Volume 16, Issue 3, March 2026.This study employed integrated analyses of chloroplast DNA and nuclear genes, which revealed significant divergence in genetic structure between the two genomic compartments in Xinjiang wild apricots, reflecting complex evolutionary processes influenced by natural selection, genetic drift, and gene flow. Population history analyses indicated an absence
Mingyu Li +9 more
wiley +2 more sources
A T2T reference genome and haplotype-resolved assembly of cultivar ‘Guozhixian’ for future apricot breeding [PDF]
Scientific DataApricots (Prunus armeniaca L.) are valued for their flavor and appearance. Recent advancements have enabled the first Telomere-to-Telomere (T2T) genome assembly for the hybrid cultivar P. armeniaca L.
Qiuping Zhang +9 more
doaj +2 more sources
Horticultural Science, 2014 Tree growth, flowering, yield and fruit quality of Prunus armeniaca L. cv. Ninfa grafted on peach cv. Nemaguard [Prunus persica (L.) Batsch] and cv. Real Fino apricot (Prunus armeniaca L.) as rootstocks were analysed in experimental orchard under organic
L.F. Pérez-Romero +4 more
doaj +1 more source
Multiple Events of Allopolyploidy in the Evolution of the Racemose Lineages in Prunus (Rosaceae) Based on Integrated Evidence from Nuclear and Plastid Data. [PDF]
, 2016 Prunus is an economically important genus well-known for cherries, plums, almonds, and peaches. The genus can be divided into three major groups based on inflorescence structure and ploidy levels: (1) the diploid solitary-flower group (subg.
Chang, Zhao-Yang +8 more
core +4 more sources
Plant Varieties Studying and Protection, 2012 The high content of phenolic compounds (quercetin-3-O-glycoside, izoramnetine-3-O-glycoside, 4'-metoxykempferol-3-O-glycoside, 4'-metoxyqvercetine-3-0-glycoside, apigenine and luteoline) in flowers of Prunus cerasifera Ehrh.
В. М. Горіна +2 more
doaj +1 more source
Blood plasma levels of anterior pituitary hormones of rabbits after apricot seed exposure in vivo [PDF]
Journal of Central European Agriculture, 2016 The present study describes possible changes in plasma levels of anterior pituitary hormones induced by bitter apricot (Prunus armeniaca L.) seeds in young female rabbits in vivo. Prunus armeniaca L.
Katarína MICHALCOVÁ +7 more
doaj +1 more source
Proteomic analysis of apricot fruit during ripening [PDF]
, 2012 Ripening of climacteric fruits involves a complex network of biochemical and metabolic changes that make them palatable and rich in nutritional and health-beneficial compounds.
Arena, S +7 more
core +1 more source
Re-description of Bdella muscorum Ewing (Acari: Bdellidae) from Western Iran
Persian Journal of Acarology, 2018 This paper presents the re-description of Bdella muscorum Ewing, 1909, collected from soil and litter under apricot trees, Prunus armeniaca L. (Rosaceae), Hamedan region, Iran. Also, a key to Iranian Bdella species is provided.
Amir Hossein Eghbalian +1 more
doaj +1 more source
Microsatellite variability between apricot and related Prunus species [PDF]
, 2011 Poster presentation from IUFRO Tree Biotechnology Conference 2011: From Genomes to Integration and Delivery Arraial d’Ajuda, Bahia, Brazil.
Fatemeh Maghuly, Margit Laimer
core +1 more source