解修俊，男，博士，副研究员，主要从事藻类光合作用生理过程与调控的分子基础研究。在关键技术方面，开发建立了适合条斑紫菜的质粒载体基因编辑系统，实现了核基因组的精准编辑，获得了靶向基因敲除的系列纯合藻株；设计了双核酶介导的反向干扰表观修饰基因表达的策略，解析了限制大型海藻外源基因表达的表观分子基础。在光合作用调控机制方面，从光能捕获与淬灭、光合电子传递、碳浓缩与光呼吸等层面系统比较研究了藻类响应环境变化过程中光能利用与光保护间的协同调控机制，揭示了藻类在光合色素（玉米黄素）、关键蛋白（高光诱导蛋白）以及碳代谢通路（如光呼吸等）等层面独特的光合调控分子机制。

(1). 藻类基因编辑与遗传改良底层技术开发

(2). 藻类光合作用生理过程与调控机制研究

(3). 优良性状藻类种质新材料的精准创制

招生专业：海洋生物学

招生方向：生理生化过程与调控，遗传学与遗传工程

三、研究室及联系方式       

实验海洋生物学重点实验室

xjxie@qdio.ac.cn

18560639836

1. 青岛市产业培育引领专项-海洋关键技术攻关项目，高纯医用海洋荧光蛋白原料的合成生物学制备与诊断医疗产品开发，2025/04-2027/04，81.00万元，参与，在研。

2. 国家自然科学基金面上项目，条斑紫菜跨类囊体膜质子动力势与光合电子传递的调控机制（41876160），2019/01-2022/12，62.00万元，主持，已结题。   

3. 国家自然科学基金青年基金，条斑紫菜-胡萝卜素羟化酶基因表达与光保护间的协同关系（41506172），2016/01-2018/12，20.00万元，主持，已结题。

1. 自然资源科学技术奖，二等奖（排名第七），中国海洋红藻资源与应用，自然资源科学技术奖励委员会。

2. 海洋工程科学技术奖，二等奖（排名第三），菌藻协同-暗光耦联高效利用海水高浓有机物的技术原理，中国海洋工程咨询协会。

1.Shao, Z., Guo, M., Wang, H., Gu, W., Xie, X. * and Wang, G. * (2025) Overexpression of Rboh enhances inorganic carbon acquisition through coordinating with carbonic anhydrase in Pyropia yezoensis. Plant Science, 356, 112497.

2.Wang, H. #, Xie, X. #, *, Gu, W., Zheng, Z., Zhuo, J., Shao, Z., Huan, L., Zhang, B., Niu, J., Gao, S., Wang, X. and Wang, G. (2024) Gene editing of economic macroalga Neopyropia yezoensis (Rhodophyta) will promote its development into a model species of marine algae. New Phytologist, 244, 1687-1691.

3.Wang, L. #, Xie, X. #, Gu, W., Zheng, Z., Chen, M.* and Wang, G.* (2023) LHCF15 facilitates the absorption of longer wavelength light and promotes growth of Phaeodactylum tricornutum under red light. Algal Research, 75, 103249.

4.He, B. #, Zheng, Z. #, Wang, H., Xie, X. * and Wang, G. * (2023) The high light-inducible protein (NyHLIP1) has a long half-life and possesses an important role in the high light stress response of resurrection intertidal red algae. Algal Research, 76, 103282.

5.Shao, Z. #, Xie, X.#, Liu, X., Zheng, Z., Huan, L., Zhang, B.* and Wang, G.* (2022) Overexpression of mitochondrial γCAL1 reveals a unique photoprotection mechanism in intertidal resurrection red algae through decreasing photorespiration. Algal Research, 66, 102766.

6.He, B. #, Zheng, Z.#, Xie, X.* and Wang, G.* (2022) Overexpression of adenosine 5′-monophosphate deaminase increased umami substance—Inosine 5′- mononucleotide and promoted Neopyropia yezoensis quality. Algal Research, 65, 102737.

7.He, B., Niu, J., Xie, X.* and Wang, G.* (2021a) Development of free-living sporangial filaments regulated by light and culture density in Neopyropia yezoensis. Algal Research, 58, 102378.

8.He, B. #, Gu, W. #, Wang, L. #, Zheng, Z., Shao, Z., Huan, L., Zhang, B., Ma, Y., Niu, J., Xie, X.* and Wang, G.* (2021b) RNA-seq between asexual archeospores and meiosis-related conchospores in Neopyropia yezoensis using Smart-seq2. Journal of Phycology, 57, 1648-1658.

9.Xie, X. #, Lu, X. #, Wang, L., He, L. and Wang, G.* (2020) High light intensity increases the concentrations of β-carotene and zeaxanthin in marine red macroalgae. Algal Research, 47, 101852.

10.Xie, X.#, Huang, A. #, Gu, W. #, Zang, Z., Pan, G., Gao, S., He, L., Zhang, B., Niu, J., Lin, A. and Wang, G.* (2016) Photorespiration participates in the assimilation of acetate in Chlorella sorokiniana under high light. New Phytologist, 209, 987-998.