职 称

副教授

职 务

无

最后学历

研究生

最高学位

博士

办公电话

电子邮箱

1115482453@qq.com

一、教育经历与工作经历

教育经历：

2017.09 -   2021.07 北京林业大学园林植物与观赏园艺  农学博士

2014.09 -   2017.07 山西农业大学园林植物与观赏园艺 农学硕士

2012.09 -   2014.07 山西农业大学园林 农学学士

工作经历：

2024.02至今 山西农业大学林学院园林系 副教授

2021.07 –   2024.01 山西农业大学林学院园林系 讲师

二、研究方向

园林植物种质资源保存与利用

三、教学工作

教学方面，先后为本科生主讲《花卉学》、《植物学基础》、《园林苗圃学》等课程；为硕士生主讲《现代林木遗传育种进展与方法》、《现代林木遗传育种进展与方法》、《林木遗传改良与良种工程》、《林木种质资源学》、《高级分子生物学实验技术》，培养硕士研究生8名。

四、科研项目

[1] 国家自然科学基金--- 面上项目，32572128，α-亚麻酸对超低温保存芍药花粉生活力的影响及其调控机制，主持，2026.01- 2029.12

[2] 国家自然科学基金--- 青年项目(C类)，32201613，细胞骨架在芍药花粉超低温保存细胞程序性死亡中的作用机制，主持，2023.01- 2025.12

[3] 山西省基础研究计划--- 青年科学研究项目，202103021223170，珍稀濒危植物翅果油树种子保存方法的筛选及其生活力衰退机制研究，主持，2022.01- 2024.12

[4] 山西农业大学博士科研启动项目，2021BQ108，种子超低温保存中ROS和NO在细胞程序性死亡中的互作机制研究，主持，2021.09 - 2024.09

[5] 山西省博士毕业生、博士后研究人员来晋工作奖励经费科研项目，SXBYKY2022036，NO在种子超低温保存后生活力变化中的作用机制，主持，2022.05- 2024.4

[6] 国家自然科学基金--- 面上项目，32071825，芍药茎纤维素特征及其生长素调节机制，参加，2021.01- 2024.12

五、研究成果

以第一作者在 BMC Plant Biol、Horticulturae、BMC Genomics、Plant Cell Reports、Plant Cell, Tissue and Organ Culture (PCTOC)、Cryobiology等期刊发表SCI论文15篇，在植物生理学报、北京林业大学学报等CSCD期刊发表论文2篇；以通讯作者在 Horticulture, Environment, and Biotechnology等期刊发表SCI论文3篇。

[1] Ren RF*, Zhu QL, Guo JY, Ji Z, Yang XY. Integrated   transcriptomics and metabolomics elucidate the molecular mechanism underlying   post-preservation pollen viability alterations in Paeonia lactiflora   [J]. BMC Plant Biol, 2026. 26, 154.

[2] Ren RF*, Ji Z, Zhu QL, Zhang BR, Yang XY. Integrated   transcriptomic and physiological data offer novel insights into viability   changes in Paeonia lactiffora seeds after cryopreservation [J].   Horticulturae 2025, 11, 1494.

[3] Ren RF*，Guo JY, Ji Z, Du SH, Yang XY. Integrated   transcriptomics and metabolomics to explore the mechanisms of Elaeagnus   mollis Diels seed viability decline [J]. BMC Genomics. 2025, 26:333.

[4] Guo JY, Zhu QL, Huang JQ, Wang ZL, Ren   RF*. Screening of optimal preservation methods of Elaeagnus   mollis seeds and the role of apoptosis-like programmed cell death in seed   viability [J]. Plant Cell, Tissue and Organ Culture (PCTOC). 2025, 160:49.

[5] Huang JQ, Ji Z, Guo JYi, Yang XY, Ren   RF*. Effect of storage temperatures on the viability   and oxidative stress of Paeonia lactiflora pollen [J]. Horticulture,   Environment, and Biotechnology. 2025, 66:479-490.

[6] Ji Z, Guo JY, Huang JQ, Zhu QL, Ren   RF*. Effects of oxidative stress on the changes of   viability of Paeonia lactiflora seeds with different water content   before and after cryopreservation [J]. Cryobiology. 2024, 117：105165.

[7] Ren RF, Guo JY, Ji Z, Yang XY*. ROS‑induced oxidative   stress affects the viability of cryopreserved Paeonia lactiflora   pollen with different moisture contents [J]. Plant Cell, Tissue and Organ   Culture (PCTOC). 2023, 155:117-126.

[8] Ren RF, Ji Z, Guo JY, Yang XY*. Cryopreservation of   herbaceous Asteraceae seeds: Effects of seed reserves on seed germination and   seedling regrowth [J]. Cryobiology. 2023, 112: 104562.

[9] Ren RF, Zhang LL, Jiang XR, Zhou H, Liu Y*. Hydrogen   peroxide participated in programmed cell death by mediating   ethylene during the cryopreservation of Dendrobium nobile   protocorm‑like bodies[J]. Acta Physiologiae Plantarum. 2023, 45:85.

[10] Ren RF, Zhou H, Zhang LL, Jiang XR, Liu Y*. Ca²⁺   participates in programmed cell death by modulating ROS during pollen   cryopreservation [J]. Plant Cell Reports. 2022, 41:1043-1057.

[11] Ren RF, Zhou H, Zhang LL, Jiang XR, Zhang M, Liu Y*.   ROS-induced PCD affects the viability of seeds with different moisture   content after cryopreservation [J]. Plant Cell, Tissue and Organ Culture   (PCTOC). 2022, 148:623-633.

[12] Ren RF, Gao JZ, Zhou H, Zhu MT, Liu Y*. Changes of   pollen viability after preservation of Paeonia lactiflora in different   provenances [J]. Cryobiology. 2022, 105:10-19.

[13] Ren RF, Zhou H, Zhang LL, Jiang XR, Liu Y*.   Cryopreserved-pollen viability is regulated by NO‑induced programmed cell   death [J]. Plant Cell Reports, 2021, 40:2383-2395.

[14] Ren RF, Li ZD, Zhang LL, Zhou H, Jiang XR, Liu Y*.   Enzymatic and nonenzymatic antioxidant systems impact the viability of   cryopreserved Paeonia suffruticosa pollen [J]. Plant Cell, Tissue and   Organ Culture (PCTOC). 2021, 144: 233-246.

[15] Ren RF, Li ZD, Jiang XR, Liu Y*. The ROS‑associated   programmed cell death causes the decline of pollen viability   recovered from cryopreservation in Paeonia lactiflora [J].   Plant Cell Reports. 2020, 39:941-952.

[16] Ren RF, Li ZD, Zhou H, Zhang LL, Jiang XR, Liu   Y*. Changes in apoptosis‑like programmed cell death and viability   during the cryopreservation of pollen from Paeonia   suffruticosa [J]. Plant Cell, Tissue and Organ Culture (PCTOC). 2020,   140:357-368.  

[17] Ren RF, Li ZD, Li BL, Xu J, Jiang XR, Liu Y*, Zhang KY.   Changes of pollen viability of ornamental plants after long-term preservation   in a cryopreservation pollen bank [J]. Cryobiology. 2019, 89: 14-20.

[18] Ren RF, Jiang XR, Di W, Li ZD, Li BL, Xu J, Liu Y*.   HSP70 improves the viability of cryopreserved Paeonia lactiflora   pollen by regulating oxidative stress and apoptosis‑like programmed cell   death events [J]. Plant Cell, Tissue and Organ Culture (PCTOC). 2019, 139:   53-64.

[19] 任瑞芬，李泽迪，朱梦婷，刘燕*，张孔英. ROS 诱导的氧化应激和细胞程序性死亡对超低温保存后花粉生活力的影响[J]. 北京林业大学学报, 2022, 44(2): 92- 100.

[20] 任瑞芬，李泽迪，张玲玲，周好，刘燕*. AsA-GSH抗氧化系统在超低温保存后牡丹花粉活力下降中的作用机制[J]. 植物生理学报，2021, 57 (7): 1517-1526.

六、其他

2022年度考核优秀个人

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