Prunus sibirica

Ethnobotanical Studies

Bairin Area, Inner Mongolia

Uses: Cough, pneumonia, and tracheitis

DOI:: 10.1186/s13002-019-0300-9
PubMed:: 31269968

Gelao ethnic minority, North Guizhou, China

Uses: Chronic bronchitis

DOI:: 10.3389/fphar.2023.1217599
PubMed:: 37719846

Yi people, Mile, Yunnan, China

Uses: Constipation, pharyngitis

DOI:: 10.1186/s13002-024-00656-1
PubMed:: 38395900

Studies

Mandelonitrile lyase MDL2-mediated regulation of seed amygdalin and oil accumulation of Prunus Sibirica.

Chen F et al (2024).; BMC Plant Biol.
DOI:: 10.1186/s12870-024-05300-4
PubMed:: 38902595

[Plant community differentiation of desertification region in northwest Liaoning Province, China].

Chen Q et al (2024).; Ying Yong Sheng Tai Xue Bao.
DOI:: 10.13287/j.1001-9332.202401.002
PubMed:: 38511438

Seasonal Diet Composition of Goitered Gazelle (Gazella subgutturosa) in an Arid and Semi-Arid Region of Western China.

Zhang N et al (2024).; Animals (Basel).
DOI:: 10.3390/ani14050663
PubMed:: 38473048

Genome-wide identification, expression analysis, and potential roles under low-temperature stress of bHLH gene family in Prunus sibirica.

Summary

A study found 104 genes in the bHLH gene family in plants, classified into 23 subfamilies. Duplicated genes evolved under purifying selection and had similar structures. Some genes responded to cold stress and overexpression improved cold tolerance, providing insights into plant development and stress response.

Genetics

Liu Q et al (2023).; Front Plant Sci.
DOI:: 10.3389/fpls.2023.1267107
PubMed:: 37799546

Native promoter-mediated transcriptional regulation of crucial oleosin protein OLE1 from Prunus sibirica for seed development and high oil accumulation.

Hu J et al (2023).; Int J Biol Macromol.
DOI:: 10.1016/j.ijbiomac.2023.126650
PubMed:: 37666400

Genetic diversity and conservation of Siberian apricot (Prunus sibirica L.) based on microsatellite markers.

Wang X et al (2023).; Sci Rep.
DOI:: 10.1038/s41598-023-37993-2
PubMed:: 37433853

Genome-wide identification and analysis of the WRKY gene family and low-temperature stress response in Prunus sibirica.

Genetics

Liu Q et al (2023).; BMC Genomics.
DOI:: 10.1186/s12864-023-09469-0
PubMed:: 37370033

Colletotrichum fructicola Causal agent of Shot-Hole Symptoms on Leaves of Prunus sibirica in China.

Han S et al (2023).; Plant Dis.
DOI:: 10.1094/PDIS-04-22-0848-PDN
PubMed:: 36607332

Mining for genes related to pistil abortion in Prunus sibirica L.

Genetics

Chen J et al (2022).; PeerJ.
DOI:: 10.7717/peerj.14366
PubMed:: 36405023

10.

Insights Into the Molecular Mechanisms of Late Flowering in Prunus sibirica by Whole-Genome and Transcriptome Analyses.

Genetics

Xu W et al (2022).; Front Plant Sci.
DOI:: 10.3389/fpls.2021.802827
PubMed:: 35145534

11.

[Growth stability of four drought resistant plant species in different regions].

Yu X et al (2021).; Ying Yong Sheng Tai Xue Bao.
DOI:: 10.13287/j.1001-9332.202112.011
PubMed:: 34951262

12.

Selection of a core collection of Prunus sibirica L. germplasm by a stepwise clustering method using simple sequence repeat markers.

Sun Y et al (2021).; PLoS One.
DOI:: 10.1371/journal.pone.0260097
PubMed:: 34797843

13.

Transcriptomic analysis reveals candidate genes for male sterility in Prunus sibirica.

Genetics

Chen J et al (2021).; PeerJ.
DOI:: 10.7717/peerj.12349
PubMed:: 34722001

14.

Effects of season and food on the scatter-hoarding behavior of rodents in temperate forests of Northeast China.

Li D et al (2021).; Zookeys.
DOI:: 10.3897/zookeys.1025.60972
PubMed:: 33814946

15.

The complete chloroplast genome sequence of Prunus sibirica.

Genetics

Dong S et al (2020).; Mitochondrial DNA B Resour.
DOI:: 10.1080/23802359.2019.1710589
PubMed:: 33366656

16.

Metabolic, Enzymatic Activity, and Transcriptomic Analysis Reveals the Mechanism Underlying the Lack of Characteristic Floral Scent in Apricot Mei Varieties.

Bao F et al (2020).; Front Plant Sci.
DOI:: 10.3389/fpls.2020.574982
PubMed:: 33193512

17.

Screening of optimal reference genes for qRT-PCR and preliminary exploration of cold resistance mechanisms in Prunus mume and Prunus sibirica varieties.

Genetics

Ding A et al (2020).; Mol Biol Rep.
DOI:: 10.1007/s11033-020-05714-x
PubMed:: 32803506

18.

Effects of exogenous abscisic acid on oil content, fatty acid composition, biodiesel properties and lipid components in developing Siberian apricot (Prunus sibirica) seeds.

Huo K et al (2020).; Plant Physiol Biochem.
DOI:: 10.1016/j.plaphy.2020.06.020
PubMed:: 32570013

19.

Comprehensive evaluation of fuel properties and complex regulation of intracellular transporters for high oil production in developing seeds of Prunus sibirica for woody biodiesel.

Wang J et al (2019).; Biotechnol Biofuels.
DOI:: 10.1186/s13068-018-1347-x
PubMed:: 30622648

20.

Identification of AUXIN RESPONSE FACTOR gene family from Prunus sibirica and its expression analysis during mesocarp and kernel development.

Genetics

Niu J et al (2018).; BMC Plant Biol.
DOI:: 10.1186/s12870-017-1220-2
PubMed:: 29368590

21.

Development and characterization of microsatellite markers in Prunus sibirica (Rosaceae).

Liu HB et al (2013).; Appl Plant Sci.
DOI:: 10.3732/apps.1200074
PubMed:: 25202522

22.

Biodiesel from Siberian apricot (Prunus sibirica L.) seed kernel oil.

Wang L and Yu H (2012).; Bioresour Technol.
DOI:: 10.1016/j.biortech.2012.02.120
PubMed:: 22440572