2002年在哈尔滨师范大学获得硕士学位，2006年在北京大学获博士学位。2006年9月至2011年6月在东北林业大学担任教授从事教学和科研工作。以通讯作者和第一作者发表SCI收录论文30余篇。已培养硕士和博士19名；在读博士生和硕士生8名。

主要研究工作:

1 植物光合碳代谢研究：

以C4植物玉米和C3植物拟南芥和杨树为研究材料，利用分子生物学，生物化学、细胞学和遗传学方法研究C4植物高效固碳的分子生物学机理以及C4途径关键酶酶转录、翻译、翻译后修饰以及酶活活性的调控机制。

主持和参加的科研项目：

1）杨树Pin1At蛋白控制株型发育的分子机制，国家自然基金面上项目；项目批准编号：32371909，（2024.1-2027.12）资助额度：50万元，主持人。

2）杨树木材形成关键基因的挖掘，科技创新2030-重大项目；编号：2023ZD0406905，（2023.12-2025.12）资助额度：270万元，任务负责人。

3）基于高附加值生物质基需求的高固碳树种创制，CAS概念验证计划；项目编号：CAS-GNYZ-2022，（2023.7-2024.7）资助额度：20万元，主持人。

4）南疆抗逆、高产优质苜蓿品种选育及高效栽培技术研究与示范，兵团科技计划项目；（2023.1-2025.12）资助额度：85万元，主持人。

5）苜蓿蛋白表达生物反应器系统的建立和优化，横向课题；项目编号2022110043005026：2019C004，（2022.5-2025.4）资助额度：200万元，主持人。

6）作物高光效利用的分子机制，中国科学院战略性先导科技专项；子课题编号：XDA24010203，（2019.11-2024.12）资助额度：1084万元，子课题负责人。

7）杨树和苜蓿等重要林草植物基因编辑技术的建立，横向课题；项目编号：2019C092，（2019.11-2023.10）资助额度：500万元，主持人。

8）盐碱地草业发展关键技术集成与示范，中国科学院科技服务网络计划；编号：2016ZX08009003-005-001，（2019.1-2020.6）资助额度：40万元，课题负责人。

9）高光效优质牧草品种培育和扩繁技术研发，横向课题；项目编号：2019C004，（2019.1-2023.12）资助额度：100万元，主持人。

10）玉米光合固碳途径关键酶PPDK调节蛋白PDRP的双功能调控，国家自然科学基金面上项目；编号：31770262，（2018.1-2021.12）资助额度：60万元，主持人。

11）玉米产量、品质性状的功能基因组与调控网络，国家重点基础研究发展计划；课题编号：2016YFD0101003，（2016.7-2021.12）资助额度：60万元，子课题负责人。

12）重要性状基因克隆及功能验证，转基因生物新品种培育重大专项；编号：2016ZX08009003-005-001，（2016.1-2020.12）资助额度：135万元，任务负责人。

13）玉米PEPCK-C4光合碳代谢途径的调控机制研究，国家自然科学基金面上项目；编号：31471506，（2015.1-2018.12）资助额度：100万元，主持人。

14）玉米矮杆基因及其调控网络的发掘，国家自然科学基金重大研究计划培育项目；编号：91435109，（2015.1-2017.12）资助额度：100万元，主持人。

15）光高效玉米种植模式增产机理研究，中国科学院科技服务网络计划，项目编号：KFJ-EW-STS-066（2014.5-2016.5）资助额度：79万元，课题负责人。

16）玉米水分高效利用分子模块解析，中国科学院战略性先导科技专项；子课题编号：XDA08010206，（2013.8-2018.7）资助额度：3089万元，子课题负责人。

17）杨树抗旱光合关键基因的鉴定及分子育种技术研究，863项目，批准号：2013AA102701（2013.1-2017.12）资助额度：133万元，子课题负责人。

18）玉米高光效QTL克隆及分子机理研究，863项目，批准号：2012AA10A300（2012.1-2015.12）资助额度：66万元，子课题负责人。

19）玉米高光效分子机理研究，中国科学院知识创新工程项目； 批准号：O2819G1001，（2011.1-2013.12）资助额度：200万元，主持人。

20）杨树引入C4光合固碳途径关键酶的分子基础研究，国家自然基金重点项目； 批准号：31030017，（2011.1-2014.12）资助额度：204万元，主持人。

研究论文（注*为通讯作者）：

2023

1. Gao ZF,Yang X,Mei YC,Zhang J,Chao Q*,Wang BC*. 2023. A dynamic phosphoproteomic analysis provides insight into the C4 plant maize (Zea mays L.) response to natural diurnal changes. Plant J,113: 291-307.
2. Yang MY,Yang X,Yan Z,Chao Q,Shen J,Shui GH,Guo PM,Wang BC*. 2023. OsTST1,a key tonoplast sugar transporter from source to sink,plays essential roles in affecting yields and height of rice (Oryza sativa L.). Planta,258(1):4.
3. Zhang SY,Zhao BG,Shen Z,Mei YC,Li G,Dong FQ,Zhang J,Chao Q*,Wang BC*. 2023. Integrating ATAC‑seq and RNA‑seq to identify differentially expressed genes with chromatin‑accessible changes during photosynthetic establishment in Populus leaves. Plant Mol Biol,113: 59-74.

2022

4. Yan Z,Yang MY,Zhao BG,Li G,Chao Q,Tian F,Gao G,Wang BC*. 2022. OsAPL controls the nutrient transport systems in the leaf of rice (Oryza sativa L.). Planta,256: 11.
5. Zhao BG,Li G,Wang YF,Yan Z,Dong FQ,Mei YC,Zeng W,Lu MZ,Li HB,Chao Q*,Wang BC*. 2022. PdeHCA2 affects biomass in Populus by regulating plant architecture,the transition from primary to secondary growth,and photosynthesis. Planta,255: 101.

2020

6. Yan Z,Shen Z,Chao Q,Kong L,Gao ZF,Li QW,Zheng HY,Zhao CF,Lu CM,Wang YW*,Wang BC*. 2020. Genome-wide transcriptome and proteome profiles indicate an active role of alternative splicing during de-etiolation of maize seedlings. Planta,252: 60.
7. Gao ZF,Shen Z,Chao Q,Yan Z,Ge XL,Lu TC,Zheng HY,Qian CR*,Wang BC*. 2020. Large-scale proteomic and phosphoproteomic analysis of maize seedling leaves during de-etiolation. Genom Proteom Bioinf,18: 6.
8. Yan Z,Shen Z,Gao ZF,Chao Q,Qian CR,Zheng HY,Wang BC*. 2020. A comprehensive analysis of the lysine acetylome reveals diverse functions of acetylated proteins during de-etiolation in Zea mays. J Plant Physiol,248: 153-158.

2019

9. Chao Q,Gao ZF,Zhang D,Zhao BG,Dong FQ,Fu CX,Liu LJ,Wang BC*. 2019. The developmental dynamics of the Populus stem transcriptome. Plant Biotechnol J,17: 206-219.
10. Wang YF,Chao Q,Li Z,Lu TC,Zheng HY,Zhao CF,Shen Z,Li XH*,Wang BC*. 2019. Large-scale identification and time-course quantification of ubiquitylation events during maize seedling de-etiolation. Genom Proteom Bioinf,17: 603-622.

2017

11. Li Y,Dong XM.,Jin F,Shen Z,Chao Q,Wang BC. 2017. Histone acetylation modifications affect tissue-dependent expression of poplar homologs of C4 photosynthetic enzyme genes. Front Plant Sci,8: 950.
12. Li Y,Jin F,Chao Q,Wang BC*. 2017. Proteomics analysis reveals the molecular mechanism underlying the transition from primary to secondary growth of Poplar. J Plant Physiol, 213: 1-15.
13. Shen Z,Dong XM,Gao ZF,Chao Q,Wang BC. 2017. Phylogenic and phosphorylation regulation difference of phosphoenolpyruvate carboxykinase of C3 and C4 plants. J Plant Physiol,213: 16-22.
14. Bu TT,Shen J,Chao Q,Shen Z,Yan Z,Zheng HY,Wang BC. 2017. Dynamic N-glycoproteome analysis of maize seedling leaves during de-etiolation using Concanavalin A lectin affinity chromatography and a nano-LC–MS/MS-based iTRAQ approach. Plant Cell Rep,36: 1943-1958.

2016

15. Jiang L,Chen YB,Zheng JG,Chen ZH,Liu YJ,Tao Y,Wu W,Chen ZZ,Wang BC*. 2016. Structural basis of reversible phosphorylation by maize pyruvate orthophosphate dikinase regulatory protein. Plant Physiol,170: 732-741.
16. Chao Q,Gao ZF,Wang YF,Li Z,Huang XH,Wang YC,Mei YC,Zhao BG,Li L,Jiang YB,and Wang BC*. 2016. The proteome and phosphoproteome of maize pollen uncovers fertility candidate proteins. Plant Mol Biol,91: 287-304.
17. Dong XM,Li Y,Chao Q,Shen J,Gong XJ,Zhao BG,Wang BC*. 2016. Analysis of gene expression and histone modification between C4 and non-C4 homologous genes of PPDK and PCK in maize. Photosynth Res,129: 71-83.
18. Chen YB,Wang D,Ge XL,Zhao BG,Wang XC,Wang BC*. 2016. Comparative proteomics of leaves found at different stem positions of maize seedlings. J Plant Physiol,198: 116-28.
19. Ning DL,Liu KH,Liu CC,Liu JW,Qian CR,Yu Y,Wang YF,Wang YC,Wang BC*. 2016. Large-scale comparative phosphoprotein analysis of maize seedling leaves during greening. Planta,243: 501-507.

2015

20. Jiang L,Chen YB,Zheng JG,Chen ZH,Liu YJ,Tao Y,Wu W,Chen ZZ,Wang BC*. 2015. Structural basis of reversible phosphorylation by maize pyruvate orthophosphate dikinase regulatory protein (PDRP). Plant Physiol,170(2):732.

2014

21. Meng LB,Chen YB,Lu TC,Wang YF,Qian CR,Yu Y,Ge XL,Li XH,Wang BC*. 2014. A systematic proteomic analysis of NaCl-stressed germinating maize seeds. Mol Biol Rep,41(5):3431-3443.

2011

22. Bi YD,Wang HX,Lu TC,Li XH,Shen Z,Chen YB,Wang BC*. 2011.Large-scale analysis of phosphorylated proteins in maize leaf. Planta,233: 383-392.
23. Liu XY,Wu YD,Shen ZY,Shen Z,Li HH,Yu XM,Yan XF,Guo CH,Wang BC*. 2011.Shotgun proteomics analysis on maize chloroplast thylakoid membrane. Front Biosci,3: 250-5.
24. Bi YD,Wei ZG,Shen Z,Lu TC,Cheng YX,Wang BC*,Yang CP. 2011. Comparative temporal analyses of the Pinus sylvestris L. var. mongolica litv. apical bud proteome from dormancy to growth. Mol Biol Rep,38: 721-729.

2010及以前

25. Liu CC,LuTC,Li HH,Wang HX,Liu GF,Ma L,Yang CP,Wang BC*. 2010.Phosphoproteomic identification and phylogenetic analysis of ribosomal P-proteins in Populus dormant terminal buds. Planta,231: 571-581.
26. Ni RJ,Shen Z,Yang CP,Wu YD,Bi YD,Wang BC*. 2010. Identification of low abundance polyA-binding proteins in Arabidopsis chloroplast using polyA-affinity column.Mol Biol Rep,37: 637-641.
27. Shen Z,Li P,Ni RJ,Mark R,Yang CP,Liu GF,Ma W,Liu GJ,Ma L,Li SJ,Wei ZG,Wang HX,Wang BC*. 2009.Label-free quantitative proteomics analysis of etiolated maize seedling leaves during greening.Mol Cellular Proteomics,8: 2443-2460.
28. Zhu H,Bi YD,Yu LJ,Guo DD,Wang BC*. 2009. Comparative proteomic analysis of apomictic monosomic addition line of Beta corolliflora and Beta vulgaris L. in sugar beet.Mol Biol Rep,36: 2093-8.
29. Lu TC,Meng LB,Yang CP,Liu GF,Liu GJ,Ma W,Wang BC*. 2008. A shotgun phosphoproteomics analysis of embryos in germinated maize seeds.Planta,228: 1029–1041.
30. Wu FZ,Lu TC,Shen Z,Wang BC*,Wang HX. 2008.N-Terminal acetylation of two major latex proteins from Arabidopsis thaliana using electrospray ionization tandem mass spectrometry.Plant Mol Biol Rep,26: 88-97.
31. Wang BC,Pan YH,Meng DZ,Zhu YX. 2006.Identification and quantitative analysis of significantly accumulated proteins during the Arabidopsis seedling de-etiolation process. J Integr Plant BioL,48: 104-113.
32. Wang BC,Wang HX,Feng JX,Meng DZ,Qu LJ,Zhu YX. 2006. Post-translational modifications,but not transcriptional regulation,of major chloroplast RNA-binding proteins are related to Arabidopsis seedling development. Proteomics,6: 2555-2563.