Screening of Cd‐tolerant Fungi with High Cd Removal Ability and Their Effects on Wheat Growth and Cd Accumulation

doi:10.15933/j.cnki.1004-3268.2025.05.007

Abstract

Abstract: This study screened native fungi with high cadmium tolerance and removal performance from soil and plants contaminated with heavy metals in wheat fields，and produced solid fermentation remediation agents. Then it conducted wheat safety testing in healthy soil and investigated the effects of remediation agents on wheat growth and cadmium absorption under in‐situ heavy metal pollution conditions.The results showed that four functional fungi（M6，M10，M7，M3）with tolerance of up to 600 μmol/L Cd²⁺concentration and high cadmium removal rate in liquid culture medium containing 50 mg/L Cd²⁺were isolated and screened，with removal rates of 99.7%，79.3%，64.1%，and 62.8%，respectively.They were identified as Fusarium sp.，Trichoderma harzianum，Alternaria sp. ，and Chaetomium sp..In wheat safety testing，only M6 was found to inhibit the emergence rate and biomass of wheat. Under in‐situ heavy metal contaminated soil，the addition of M3，M7，and M10 significantly increased the fresh weight （22.0%—43.7%）and dry weight（15.7%—64.4%）of wheat，meanwhile significantly reducing the accumulation of Cd in the wheat root（37.2%—53.4%）.Among them，M7 treatment had the best effect.In summary，Chaetomium sp.M7 could promote the growth of wheat seedlings under cadmium stress and reduce cadmium accumulation，which could be used for soil heavy metal pollution control.

Key words: Wheat, Fungi, Heavy metal, Cadmium, Microbial remediation

摘要： 从镉污染小麦田土壤和植株中筛选耐镉（Cd）、去除镉性能较优的本土真菌，并制作固体发酵物修复剂，在健康土壤中进行小麦安全性检测，探究原位重金属污染条件下修复剂对小麦生长和镉吸收的影响。结果表明，共分离筛选出4株耐受程度高达600 μmol/L Cd²⁺浓度、在含Cd²⁺质量浓度为50 mg/L的液体培养基中去镉率较高的功能真菌（M6、M10、M7、M3），去除率分别为99.7%、79.3%、64.1%、62.8%，经鉴定分别为镰刀菌属（Fusarium sp.）、哈茨木霉（Trichoderma harzianum）、毛壳属（Chaetomium sp.）和链格孢属（Alternaria sp.）。小麦安全性检测中，仅处理M6抑制小麦的出苗率和生物量。原位重金属污染土壤下，添加M3、M7和M10显著增加小麦的鲜质量（22.0%~43.7%）、干质量（15.7%~64.4%），显著降低小麦根系对Cd的积累（37.2%~53.4%），其中，M7处理效果最佳。综上，毛壳属M7可以促进小麦幼苗在镉胁迫下的生长并降低镉积累，具有用于土壤重金属污染治理的潜力。

关键词: 小麦, 真菌, 重金属, 镉, 微生物修复

CLC Number:

S512.1

LI Shihang, GAO Wei, LI Yangyang, SUN Shilong, BAN Jiahao, NIE Zhaojun, GENG Yuehua, WANG Min, ZHAO Peng. Screening of Cd‐tolerant Fungi with High Cd Removal Ability and Their Effects on Wheat Growth and Cd Accumulation[J]. Journal of Henan Agricultural Sciences, 2025, 54(5): 59-67.

李世行, 高巍, 李洋洋, 孙世龙, 班佳浩, 聂兆君, 耿月华, 汪敏, 赵鹏. 高去除性耐镉真菌的筛选及其对小麦幼苗生长和镉积累的影响[J]. 河南农业科学, 2025, 54(5): 59-67.

Figures/Tables 7

References

［1］GASPARATOS D. Soil contamination by heavy metals and metalloids［J］. Environments，2022，9（3）：32.
［2］赖才星，林华，刘泽蕙，等. 巨大芽孢杆菌-青葙组合对镉污染土壤微生物群落演替的驱动作用［J］.中国环境科学，2025，45（2）：1036‐1044.
LAI C X，LIN H，LIU Z H，et al. The driving effect of Bacillus megaterium‐Celosia argentea L.combination on the succession of microbial communities incadmium‐contaminated soil［J］. China Environmental Science，2025，45（2）：1036‐1044.
［3］ZANDT D I'，KOLAŘÍKOVÁ Z，CAJTHAML T，et al.Plant community stability is associated with a decoupling of prokaryote and fungal soil networks［J］.Nature Communications，2023，14（1）：3736.
［4］姚洁，鲍立宁，姜宇，等. 植物-耐铅微生物联合修复铅污染土壤研究［J］. 山东理工大学学报（自然科学版），2022，36（4）：7‐13.
YAO J，BAO L N，JIANG Y，et al. Research on the joint repair of lead‐contaminated soil by plant‐lead‐resistant microorganisms［J］. Journal of Shandong University of Technology（Natural Science Edition），2022，36（4）：7‐13.
［5］钟绍忆，梁兴慧，王登杰，等. 球孢白僵菌内生定殖豇豆对美洲斑潜蝇种群的影响［J/OL］.中国生物防治学报，2025：1‐13（2025‐01‐02）［2025‐02‐25］. https：//doi. org/10. 16409/j. cnki. 2095‐039x. 2024. 07. 018.
ZHONG SY，LIANG XH，WANG DJ，et al. The effect of endophytic colonization of cowpeas by Beauveria bassiana on Liriomyza sativae［J/OL］.Chinese Journal of Biological Control，2025：1‐13（2025‐01‐02）［2025‐02‐25］.https：//doi. org/10. 16409/j. cnki. 2095‐039x. 2024. 07.018.
［6］马莹，曹梦圆，石孝均，等. 植物促生菌的功能及在可持续农业中的应用［J］.土壤学报，2023，60（6）：1555‐1568.
MA Y，CAO M Y，SHI X J，et al. Functions of plant growth‐promoting bacteria and their application in sustainable agriculture［J］. Acta Pedologica Sinica，2023，60（6）：1555‐1568.
［7］ZHANG P P，ZHANG Y H，PANG W B，et al.Cenococcum geophilum impedes cadmium toxicity in Pinus massoniana by modulating nitrogen metabolism［J］.Science of the Total Environment，2024，946：174296.
［8］刘苏闽，周冬梅，杨敬辉，等. 复合菌剂对草莓黄萎病的田间防治效果［J］. 中国生物防治，2010，26（4）：501‐503.
LIU S M，ZHOU D M，YANG J H，et al. Control effect of composite biological agent on Verticillium wilt in strawberry in fields［J］. Chinese Journal of Biological Control，2010，26（4）：501‐503.
［9］尹艺，赵颖，马莲菊，等. 碱蓬内生真菌对镉胁迫水稻幼苗生长及生理生化指标的影响［J］. 贵州农业科学，2014，42（3）：23‐26.
YIN Y，ZHAO Y，MA L J，et al. Effects of endophyte isolated from Suaeda salsa on growth and physiological and biochemical indexes of rice seedlings［J］. Guizhou Agricultural Sciences，2014，42（3）：23‐26.
［10］ZHU L L，LI T，WANG C J，et al. The effects of dark septate endophyte （DSE） inoculation on tomato seedlings under Zn and Cd stress［J］. Environmental Science and Pollution Research International，2018，25（35）：35232‐35241.
［11］WANG J L，LI T，LIU G Y，et al. Unraveling the role of dark septate endophyte（DSE）colonizing maize（Zea mays）under cadmium stress：Physiological，cytological and genic aspects［J］. Scientific Reports，2016，6：22028.
［12］BAN Y H，XU Z Y，ZHANG H H，et al. Soil chemistry properties， translocation of heavy metals，and mycorrhizal fungi associated with six plant species growing on lead‐zinc mine tailings［J］. Annals of Microbiology，2015，65（1）：503‐515.
［13］ZHANG X H，YANG W J，WANG L M，et al. Effects of arbuscular mycorrhizal fungi（AMF）on growth of upland rice under soil Pb contamination［J］.Agricultural Science ＆ Technology，2013，14（11）：1624‐1628.
［14］卜和申，谢燕，徐倩，等. 哈茨木霉的耐镉性及其对狗牙根耐镉能力的影响［J］.草地学报，2020，28（1）：64‐71.
BU H S，XIE Y，XU Q，et al. Cadmium tolerance of Trichoderma harzianum and its effect on cadmium tolerance of bermudagrass［J］. Acta Agrestia Sinica，2020，28（1）：64‐71.
［15］徐少慧，蒋代华，史鼎鼎，等. 重金属复合污染土壤中耐铅镉微生物的筛选及鉴定［J］.应用与环境生物学报，2019，25（3）：532‐538.
XU S H，JIANG D H，SHI D D，et al. Screening and identification of lead and cadmium resistant microorganisms from combined heavy metal pollution soil［J］. Chinese Journal of Applied and Environmental Biology，2019，25（3）：532‐538.
［16］COLPAERT J V，WEVERS J H L，KRZNARIC E，et al.How metal‐tolerant ecotypes of ectomycorrhizal fungi protect plants from heavy metal pollution［J］.Annals of Forest Science，2011，68（1）：17‐24.
［17］LI J L，FU G X，XING S P，et al. Integrative application of biochar and arbuscular mycorrhizal fungi for enhanced chromium resistance in Medicago sativa［J］. Science of the Total Environment，2023，905：167289.
［18］金建勇，孙玉焕. 固定化微生物技术在重金属污染土壤修复中的研究进展［J］. 湖南生态科学学报，2021，8（2）：90‐96.
JIN J Y，SUN Y H. Research progress of immobilized microorganism technology in remediation of heavy metal contaminated soil［J］.Journal of Hunan Ecological Science，2021，8（2）：90‐96.
［19］TRIMUKHE K D，VARMA A J. Complexation of heavy metals by crosslinked chitin and its deacetylated derivatives［J］. Carbohydrate Polymers，2008，71（1）：66‐73.
［20］RANI A，SOUCHE Y S，GOEL R. Comparative assessment of in situ bioremediation potential of cadmium resistant acidophilic Pseudomonas putida 62BN and alkalophilic Pseudomonas monteilli 97AN strains on soybean［J］.International Biodeterioration & Biodegradation，2009，63（1）：62‐66.
［21］周海峰. 黄淮麦区小麦茎基腐病病原鉴定及其致病性研究［D］. 郑州：河南农业大学，2014.
ZHOU H F. Pathogen identification and pathogenicity of wheat stem rot in Huanghuai wheat area［D］.Zhengzhou：Henan Agricultural University，2014.
［22］LIU Y，ZHANG C B，ZHAO Y L，et al. Effects of growing seasons and genotypes on the accumulation of cadmium and mineral nutrients in rice grown in cadmium contaminated soil［J］. Science of the Total Environment，2017，579：1282‐1288.
［23］卓梦霞，刘思文，李春雨，等.镰刀菌属真菌毒素在植物和病原菌互作中的研究进展［J］. 广东农业科学，2024，51（3）：56‐69.
ZHUO M X，LIU S W，LI C Y，et al. Research progress on Fusarium mycotoxins in plant and pathogen interactions［J］. Guangdong Agricultural Sciences，2024，51（3）：56‐69.
［24］陈娥，杜兴媛，张朝阳，等. 1株芬芳镰刀菌的筛选鉴定及其提硒降镉效应［J］. 华中农业大学学报，2024，43（2）：99‐108.
CHEN E，DU X Y，ZHANG C Y，et al. Screening and identification of a fungus Fusarium redolens and its effect of selenium uptake and cadmium reduction on Cardamine violifolia［J］. Journal of Huazhong Agricultural University，2024，43（2）：99‐108.
［25］张萌，祁明月，张光伟，等. 环糊精强化镰刀菌修复土壤污染生态环境中高环多环芳烃的研究［J］. 林业与生态科学，2024，39（2）：207‐214.
ZHANG M，QI M Y，ZHANG G W，et al. Research on cyclodextrin enhanced Fusarium remediation of soil contaminated ecological environment with HMW‐PAHs［J］.Forestry and Ecological Sciences，2024，39（2）：207‐214.
［26］冯中红，孙广宇. 链格孢属及相关属分类研究新进展［J］.菌物研究，2020，18（4）：294‐303.
FENG Z H，SUN G Y. Advances in the classification of Alternaria and related Genera［J］. Journal of Fungal Research，2020，18（4）：294‐303.
［27］朱海霞. 茄链格孢Alternaria solani DT-15除草活性及生物学特性初步研究［J］. 中国农学通报，2023，39（36）：119‐124.
ZHU H X. Alternaria solani strain DT‐15：The herbicidal activity and biological characteristics［J］.Chinese Agricultural Science Bulletin，2023，39（36）：119‐124.
［28］冯超红，李丽娟，张姣姣，等. 球毛壳菌促生防病机制及应用研究进展［J］.中国生物防治学报，2023，39（4）：961‐969.
FENG C H，LI L J，ZHANG J J，et al. Mechanism of Chaetomium globosum in promoting growth and preventing disease and advance of its application and research［J］. Chinese Journal of Biological Control，2023，39（4）：961‐969.
［29］伍晓丽，王钰，刘飞，等. 复合木霉制剂防治黄连根腐病及其机理研究［J］. 植物保护，2024，50（1）：97‐109.

WU X L，WANG Y，LIU F，et al. Control of Coptis chinensis root rot disease by compound Trichoderma agent and its mechanism［J］.Plant Protection，2024，50 （1）：97‐109.

［30］刘畅，张欣玥，蔡汶妤，等. 绿色木霉与哈茨木霉对黄瓜幼苗促生作用机理的研究［J］.江苏农业科学，2020，48（16）：156‐160.

LIU C，ZHANG X Y，CAI W Y，et al. Study on growth‐promoting mechanism of Trichoderma viride and Trichoderma harzianum to cucumber seedlings［J］.Jiangsu Agricultural Sciences，2020，48（16）：156‐160.

［31］唐若怡，王柏森，董纯辛，等. 棘孢木霉152-42诱导多年生黑麦草抗褐斑病的机理初探［J］.草地学报，2023，31（5）：1314‐1321.

TANG R Y，WANG B S，DONG C X，et al. Preliminary study on resistance mechanism of perennial ryegrass induced by Trichoderma asperellum 152‐42 against brown patch［J］. Acta Agrestia Sinica，2023，31（5）：1314‐1321.

［32］古添源，余黄，曾伟民，等. 功能内生菌强化超积累植物修复重金属污染土壤的研究进展［J］. 生命科学，2018，30（11）：1228‐1235.

GU T Y，YU H，ZENG W M，et al. Progress on the endophyte of hyperaccumulators and their beneficial role in heavy metal phytoremediation［J］. Chinese Bulletin of Life Sciences，2018，30（11）：1228‐1235.

[1]	LI Xiaode, BAI Xintong, WU Enzhao, LÜ Chunlei, CHEN Shulin, YIN Guihong, WANG Daowen, ZHANG Kunpu. Composition Analysis of Vernalization and Photoperiod Genes in Varieties（lines）Derived from Core Wheat Parent Zhou 8425B [J]. Journal of Henan Agricultural Sciences, 2025, 54(5): 23-30.
[2]	ZHAO Lishang 1, YANG Tiancong 2, ZHANG Xiaomei2, SONG Quanhao 1, MA Zhiyao 2, FENG Wei 2, DUAN Jianzhao2. Effects of Tillage and Straw Returning Methods on Yield and N₂O Emission of Winter Wheat [J]. Journal of Henan Agricultural Sciences, 2025, 54(4): 27-36.
[3]	GE Menglong, HE Bing, BAI Feng, HUANG Peiyuan, HE Mengying, LI Jianhua, LI Yuyang, SHEN Hongtao, GAO Jiakai, WANG Yanfang, LIU Ling. Effects of Flue‐cured Tobacco and Wheat Intercropping on Soil Microorganisms and Fertility in Xuchang Tobacco Growing Area [J]. Journal of Henan Agricultural Sciences, 2025, 54(4): 66-79.
[4]	LI Sha, YANG Jiahu, WANG Yanhui, HUANG Xinqiu, YANG Wen. Identification and Functional Characterization of Endophytic Microbes from Mulberry Tree（Morus alba L.） [J]. Journal of Henan Agricultural Sciences, 2025, 54(3): 77-86.
[5]	GAO Cuimin, TIAN Yuan, ZHANG Ruiqing, HE Fang, HAN Weifeng, ZHANG Yunhong, PAN Xiaoying, YANG Yonghui. Effects of Irrigation Methods on Crop Yield and Water⁃Nitrogen Use Efficiency under Wheat⁃Peanut Rotation System [J]. Journal of Henan Agricultural Sciences, 2025, 54(3): 31-39.
[6]	ZHANG Bowen, JIN Haiyang, XU Haixia, ZHENG Fei, HE Ning, SU Yazhong, ZHAO Guojian, CHENG Hongjian, CHENG Xiyong, LI Xiangdong. Effect of Spraying Amino Acid Chelated Zinc after Anthesis on Synthesis and Accumulation of Starch and Protein in Wheat Grains [J]. Journal of Henan Agricultural Sciences, 2025, 54(3): 8-19.
[7]	PAN Juxiu, SHEN Qi, WANG Xiaoting, KANG Qi, WUJISIGULENG, HE Weizhong, WANG Cheng. Analysis of Soil Heavy Metal Pollution Levels and Sources in Melon Fields in Two Typical Producing Areas of Xinjiang [J]. Journal of Henan Agricultural Sciences, 2025, 54(2): 88-98.
[8]	PENG Chaojun, HUA Xia, WANG Songfeng, GAO Chong, DONG Haibin, HU Lin. Effect of Drought Stress on Photosynthetic and Physiological Characteristics of Flag Leaves of Different Wheat Varieties at Filling Stage [J]. Journal of Henan Agricultural Sciences, 2025, 54(2): 40-47.
[9]	HAN Ruifeng, REN Rongkui, DONG Xiangyang, HU Zebin, GUO Fangjun, FANG Tiantian, MA Wenhao, ZHANG Shuhong. Effects of Application Depth and Amount of Different Types of Fertilizers on Growth and Development of Winter Wheat [J]. Journal of Henan Agricultural Sciences, 2025, 54(2): 30-39.
[10]	ZHANG Fuyan, SUN Congwei, CHEN Xiaojie, WANG Jiahuan, CHENG Zhongjie, ZHAO Wan, MA Xuhui, ZHANG Jianwei, FAN Jialin. Phenotypic Analysis and Preliminary Mapping of Wheat Dwarf Small⁃Kernel Mutant smk56 [J]. Journal of Henan Agricultural Sciences, 2025, 54(2): 21-29.
[11]	JIANG Guofei, WANG Xuqin, ZHANG Lingyuan, BAI Yutao, ZHANG Ping, LIU Junna, LI Li, LI Hanxue, QIN Peng. Evaluation of Adaptability of Dianmai 7 and Dianmai 12 and Detection of Stripe Rust Resistant Genes at Adult Plant Stage [J]. Journal of Henan Agricultural Sciences, 2025, 54(1): 9-20.
[12]	ZHANG Haoran, LIU Xiaoying, ZHOU Fenglong, XU Mingchen, GUO Zhengzheng, CHENG Jiayu, ZHANG Kunpu, WANG Daowen, SHI Cuilan. Creation and Phenotypic Analysis of TaGW2‑A1‑Overexpression Transgenic Wheat Germplasm [J]. Journal of Henan Agricultural Sciences, 2025, 54(1): 1-8.
[13]	CHE Yali, WU Sujun, WANG Kunyang, WANG Yanli, ZHANG Kai, QIAO Yake, YUAN Quan. Genome‑wide Association Analysis of Wild Soybean Seedling Traits and Screening of Candidate Cadmium‑tolerant Genes [J]. Journal of Henan Agricultural Sciences, 2025, 54(1): 40-54.
[14]	YUAN Lianlian, LIU Tianbo, LI Xiaodong, DENG Zhengyu, TENG Kai, SHEN Lili, JIAO Yubing, WANG Yingwen, YANG Jinguang, LI Ying. Study on Antifungal Activity and Nano‑selenization Application of Paenilbacillus polymyxa [J]. Journal of Henan Agricultural Sciences, 2025, 54(1): 101-108.
[15]	DAI Ziju, LI Wenxu, YANG Huimin, ZHU Xiuhua, WANG Yahuan, XU Fuxin, LIU Dongyang, HOU Jinna, QIN Maomao, WU Zhengqing, ZHOU Zhengfu, LEI Zhensheng. Identification and Evaluation of Resistance to Stripe Rust of 480 Wheat Germplasms [J]. Journal of Henan Agricultural Sciences, 2024, 53(9): 1-15.