Stavros Veresoglou

基本信息Basic Information

姓名:Stavros Veresoglou

性别：男

职称：副教授

导师类型：博士生导师

电子邮箱: stavrosv@mail.sysu.edu.cn，sveresoglou@zedat.fu-berlin.de

研究人员唯一标识符(Researcher Unique Identifiers)：

ORCID ID: 0000-0001-6387-4109

Researcher ID: D-5087-2011

Publons ID: 1078406

办公地址:中山大学（深圳校区）医学园2栋，1210

自我介绍 Self-introduction

我是一名全球土壤生物学家，专门研究植物与土壤的相互作用。我将我的研究应用于农业和自然系统。在我发表的80多篇同行评审文章中，有40篇是第一作者，h因子（谷歌学术）为37。其中大部分科研成果发表在高影响因子期刊上，如Nature Communications（IF=17.7），National Academy of Sciences USA（IF=13.4），Trends in Ecology and Evolution（IF=21.0），New Phytologist（IF=10.7）和Journal of Ecology（IF=7.1）。我的工作被引用（谷歌学术引用）>3000次，其中有20篇论文被引用>100次。我成功获得过超过70万欧元的竞争性研究经费，主要是作为德国资助机构DFG的唯一PI，我目前主持着一项NSFC外国优秀青年学者研究基金项目。

I am a global soil biologist specializing on plant-soil interactions. I apply my research to both agricultural and natural systems. Out of the 80+ peer-reviewed articles I author, I am the first author of 45 and have an h factor (google scholar) of 37. The list includes numerous papers in high impact factor journals such as Nature Communications (IF=12.1), Proceedings of the National Academy of Sciences USA (IF=9.7), Trends in Ecology and Evolution (IF=15.3) New Phytologist (IF=7.7), and Journal of Ecology (IF=5.4). My work has been cited (google scholar citations) >5000 times and I have twenty papers that have been cited >100 times. I have been successful in securing over €700,000 of competitive research funding mainly as sole PI from the German funding agency, DFG and I currently manage an NSFC 外国优秀青年学者研究基金项目 grant.

教学理念Teaching

I am passionate about integrating my teaching philosophy with my research and vice versa. In my very first class at Sun Yat-Sen University, addressing the topic "scientific writing" I challenged the students with writing a paper. The paper in the end got published in a SCI journal (Veresoglou et al. 2022 Soil Ecology Letters doi: 10.1007/s42832-022-0145-3), and all of the attendants were coauthors. I also have three additional papers that originated from teaching (I list them in the end of the paragraph) and I have published a paper in an educational journal (i.e. Journal of Biological Education – full reference in the end of the paragraph).

I work in a similar way with my mentees outside the class. I offer to my mentees the freedom to develop their projects by themselves, while at the same time with regular meetings I can guide them to maximize the chances that the projects will end up being successful. The Chinese system requires some early publications from the students which I think it is possible through further integrating some syntheses exercises into the projects of the students. I received for example last year an MSc student, Guolin Li, who had not made it to get any scholarship. Through publishing together two papers in one year he was able in 2022 to get a first grade scholarship.

I see my limited understanding of Chinese as a welcomed challenge and not as a barrier. I try for example to prepare additional material in writing (e.g. descriptions of activities in classes) but at the same as this makes me more dependent on my students (and vice versa) it offers us the opportunity to create stronger relationships.

Veresoglou SD, Anderson IC, de Sousa NMF, Hempel S, Rillig MC. 2016. Resilience of fungal communities to elevated CO2. Microbial Ecology 72: 493-495.

Veresoglou SD, Wang D, Andrade-Linares DR, Hempel S, Rillig MC. 2017. Fungal decision to exploit or explore depends on growth rate. Microbial Ecology 75:  86.

Veresoglou SD, Yang G, Mola M, Manntschke A, Mating M, Forstreuter M, Rillig MC. 2020. Excluding arbuscular mycorrhiza lowers variability in soil respiration but slows down recovery from perturbations. Ecosphere 11: e03308.

Veresoglou SD, Rillig MC. 2018 Research experience modifies how participants profit from journal clubs in academia. Journal of Biological Education 53:327-332.

研究兴趣Research Interests (three)

1. How mycorrhizal propagules vary in space

The research was carried out as part of the DFG funded (I was the sole PI) project Metacorrhiza which addressed dispersal constraints in the arbuscular mycorrhizal distribution. There was a preliminary study using historic data in forests in the NW Germany and then a combination of two controlled and two field (in the same area) experiment that got published. We observed that availability of arbuscular propagules induced functional (i.e. colonization) differences but not changes in the mycorrhizal communities,

Importance: Understanding spatial constrains in arbuscular mycorrhiza can answer why we observe limitations in mycorrhizal potential in agriculture but also give informative advise on ways to afforestate areas.

Representative publications:

Veresoglou SD, Wulf M. Rillig MC. 2017 Facilitation between woody and herbaceous plants that associate with arbuscular mycorrhizal fungi in temperate European forests. Ecology and Evolution 7: 1181-1189.

Grünfeld L, Wulf M, Rillig MC, Manntschke A, Veresoglou SD. 2020 Neighbours of arbuscular-mycorrhiza associating trees are colonized more extensively by arbuscular mycorrhizal fungi than their conspecifics in ectomycorrhiza dominated stands. New Phytologist 227: 10-13.

Grünfeld L, Mola M, Wulf M, Hempel S, Veresoglou SD. 2021. Disentangling the relative importance of spatio-temporal parameters and host specificity in shaping arbuscular mycorrhizal fungus communities in a temperate forest. Mycorrhiza 31: 589-591.

Veresoglou SD, Grünfeld L, Mola M. 2021. Micro-landscape dependent changes in arbuscular mycorrhizal fungal community structure. Applied Sciences 11: 5297

Grünfeld L, Skias G, Rillig MC, Veresoglou SD. 2022. Arbuscular mycorrhizal root colonization depends on the spatial distribution of the host plants. Mycorrhiza doi:  10.1007/s00572-022-01087-0

2. How arbuscular mycorrhiza modifies the cycling of N in terrestrial ecosystems

The project addressed interactions of arbuscular mycorrhiza and nitrogen cycling microbes. We were able to show that arbuscular mycorrhiza slows down nitrification through competing with ammonia oxidizing bacteria for soil ammonium and that it nevertheless increases the potential of soils to denitrify.

Importance: Nitrified ammonium in soils either through leaching from agricultural field which presents a major environmental hassle or incomplete denitrificaiton producing nitrous oxide is undesirable. We address the possibility that these two phenomena (nitrification and incomplete denitrification) can be mitigated through a specific organic agricultural technique, managing the fields for indigenous mycorrhizal communities.

Veresoglou SD, Verbruggen E, Makarova O, Mansour I, Sen R, Rillig MC. 2019 Arbuscular mycorrhizal fungi alter the community structure of ammonia oxidizers at high fertility via competition for soil NH 4 + . Microbial Ecology 78 : 147-158.

Okiobe ST, Augustin J, Mansour I, Veresoglou SD. 2019 Disentangling direct and indirect effects of mycorrhiza on nitrous oxide activity and denitrification. Soil Biology and Biochemistry 134 : 142-151.

Okiobe ST, Rillig MC, Mola M, Augustin J, Parolly G, Veresoglou SD . 2020 Arbuscular mycorrhiza has little influence on N 2 O potential emissions compared to plant diversity in experimental plant communities. FEMS Microbiology Ecology 96 : fiz208

Okiobe ST, Pirhofer-Walzl K, Leifheit EF, Rillig MC, Veresoglou SD. 2022. Proximal and distal mechanisms through which arbuscular mycorrhizal associations alter terrestrial denitrification. Plant and Soil 476: 315–336.

3. Research syntheses

This is a collection of high visibility large-scale syntheses projects addressing the role of mycorrhiza on the functioning of ecosystems. We proposed two hypotheses, the Sun Worshipper hypothesis (which we partially tested with data from China; Veresoglou et al. 2019 Journal of Ecology) and the Evolutionary Bet-Hedging hypothesis as well as the proportion that mycorrizal associating plants compete more to each other than with weakly associating mycorrhizal plants.

Importance: We explore here large scale patterns on mycorrhiza that can answer some evolutionary (e.g. bet-hedging) or global (e.g. latitudinal gradients) questions that arise from empirical research.

Veresoglou SD, Chen BD, Fischer MM, Helgason T, Mamolos AP, Rillig MC, Roldán A, Johnson D. 2019 Latitudinal constraints in responsiveness of plants to arbuscular mycorrhiza: The ‘sun-worshipper’ hypothesis. New Phytologist 224 : 552-556

Veresoglou SD, Liu L, Xu T, Rillig MC, Wang M, Wang J, Chen Y, Hu Y, Hao Z, Chen BD. 2019 Biogeographical constraints in Glomeromycotinan distribution across forest habitats in China. Journal of Ecology 107 : 684-695.

Veresoglou SD, Rillig MC, Johnson D. 2018 Responsiveness of plants to mycorrhiza regulates coexistence. Journal of Ecology 106 :1864-1875.

Veresoglou SD, Johnson D, Mola M, Yang G, Rillig MC. 2022. Evolutionary bet-hedging in arbuscular mycorrhiza associating angiosperms. New Phytologist 233: 1987-1987.

Veresoglou SD, Yang G, Mola M, Manntschke A, Mating M, Forstreuter M, Rillig MC. 2020. Excluding arbuscular mycorrhiza lowers variability in soil respiration but slows down recovery from perturbations. Ecosphere 11: e03308.

教育经历 Education

2005-2010:：PhD “The impact of arbuscular mycorrhizal fungi on N cycling related rhizosphere microbial community structure and function”,

2005-2009：Manchester Metropolitan University (supervisors Dr Robin Sen – Manchester Metropolitan University, Dr Liz Shaw – University of Reading).

1998-2004:Diploma (300 ECTS – equivalent to an MSc) in Forestry and Natural Environment, Aristotle University of Thessaloniki, 1998 – 2004.

工作经历 Work Experience

2021/10 -至今:  Associate Professor at Sun Yat-Sen University.

2019/05 - 2020/04:  Postdoc position, ERC project “Gradual Chance” led by Matthias C Rillig. The position was offered as a means of me finishing my two DFG projects given that the regulations in Germany do not allow renewals of house positions to people with over six year post-PhD experience.

Skills gained: theoretical modelling skills. The main task was to adapt MacArthur’s model of resource subdivision to address how expectations fro global change differ when we model gradual changes such as global warming as abrupt.

2014/05 - 2019/04: Junior Group Leader (Freie Universität Berlin, Plant Ecology)

Skills gained: teaching to an BSc and MSc level. Regularly applying for grants and managing a small group of motivated people.

2012/05 - 2014/04: Marie Curie Fellow (Freie Universität Berlin – advisor Matthias C Rillig)

Skills gained: proposing and executing a long term (i.e. here 2 years) research plan. Producing research reports.

2010/10 – 2012/04:  Guest Researcher (Freie Universität Berlin – advisor Matthias C Rillig)

Skills gained: engaging into research in a collaborative environment. Scientific writing.

2007/09 – 2010/01: Assistant demonstrator parallel to my PhD (Manchester Metropolitan University)

Skills gained: engaging with undergraduate students. Communicating research to other scholars.

I am also currently a member of Berlin-Brandenburg Institute of Advance Biodiversity Research and I am affiliated as an independent contractor with Aristotle University of Thessaloniki.

【EDITORIAL SERVICE AND REFEREEING】

Editor Plant and Soil (consulting editor 2016-2020; section editor 2021-至今)

Editor ISME Journal (2020-至今)

Editor Soil Ecology Letters (2019-至今)

Reviewer of over 220 papers in 50+ international journals (publons ID attached).

Reviewer of two grant proposals for the Czech academy of Sciences, one for the National Science center in Poland, two for Deutsche Forschungsgemeinschaft and one for the Dutch Research Council

所获奖励 Awards

2023:  Inclusion in the Stanford University Top 2 Scientists List. Rank: 86678 in citations globally with self-citations excluded. 中山大学319位学者入选“2023全球前2%顶尖科学家”榜单！ (Press release at SYSU): https://mp.weixin.qq.com/s/kx9y7ISUP-bjuiuDNS8Cw  

2021: 2021 Best Editorial Board Member Award (ISME Journal)

2012/05: Marie Curie Fellowship, Grant agreement number 300298.

2005/06: Chloros Trust PhD fellowship

承担课题 Grants

2023: NSFC 年度国家自然科学基金面上项目项目 MycoDisp: Implications of connectance of mycorrhizal habitats for the functioning of ecosystems. 600,000 RMB

2022: NSFC 外国优秀青年学者研究基金项目project Arbuscular mycorrhizae: a land of promise for mitigating terrestrial N2O emissions. 800,000 RMB

2017: Deutsche Forschungsgemeinschaft project "Metacorrhiza" (sole PI) €175,477. The project explores community dynamics of Glomeromycotan fungi (arbuscular mycorrhizal mutualism).

2017: Deutsche Forschungsgemeinschaft project "LandUseSAC" (sole PI) €235,790. The project aims at generating better estimates of community metrics of the microbiome of the plots at Biodiversity Exploratories

2014: Dahlem Centre of Plant Sciences (DCPS, Berlin, http://www.dcps.fu berlin.de/) funding (€3000) for the project "Null models of abundance data in plant community ecology” (Area: Plant and Environment"". I was the sole PI

2012: Marie Curie award (Grant agreement number 300298) under the supervision of Matthias C. Rilig (€167,390)

2011: Dahlem Centre of Plant Sciences (DCPS, Berlin, http://www.dcps.fu berlin.de/) funding (€10,000) for the pilot study “Multidiversity-multifunctionality”. seven PIs including myself

2005:  Chloros Trust PhD studentship (€38,400)

学术论著 Peer-Reviewed Articles

1. Veresoglou SD, Xi J, Penuelas J. 2024 Mechanisms of coexistence: Exploring species sorting and character displacement in woody plants to alleviate belowground competition. Ecology Letters doi: 10.1111/ele.14489.
2. Xi J, Li GC, Wang M, Veresoglou SD. 2024 Leaf area predicts conspecific spatial aggregation of woody species. Global Ecology and Biogeography doi: 10.1111igeb.13887.
3. Veresoglou SD, Begum N. 2024. Dose-response curves: the next frontier in plant ecology. Trends in Plant Science doi: 10.10164tplants.2024.03.018. 
4. Camenzing T, Aguilar Trigueros C, Hempel 5, Lehmann A, Bielcik M, Andrade-Linares DR, Bergmann J, dela Cruz J, Cawronski J, Golubeva P, Haslwimmer H, Lartey L, Leifheit E, Maass S, Marhan S, Pinek L, Powell JR, Roy J, Veresoglou SD, Wang D, Wulf A, Zheng W, Rillig MC. 2024. Towards establishing a fungal economics spectrum in soil saprobic fungi. Nature Communications 15: 3321.
5. Cui N, Veresoglou SD, Tian Y, Guo R, Zhang L, Jiang L, Kang F, Yuan W, Hou D, Shi L, Guo J, Sun M, Zhang T. 2024. Arbuscular mycorrhizal fungi offset NH 3 emissions in temperate meadow soil under simulated warming and nitrogen deposition. Journal of Environmental Management 354: 120239. 
6. Chen J, li GC, Lee TM, Veresoglou SD. Can conservation tillage and reduced irrigation promote sustainability in agroecosystems through lowering nitrous oxide emissions? A synthesis. Plant and Soil 499: 427-438. 
7. Veresoglou SD, Agathokleous E. 2023. Pertinent challenges in mycorrhizal ecopreneurship for sustainable food production. Sustainable Horizons 8: 100064.
8. Wang M, Chen J, Lee TM, Xi J, Veresoglou SD. 2023 Context dependent plant responses to arbuscular mycorrhiza mainly reflect biotic experimental settings. New Phytologist 240: 13-16. 
9. Aguilar-Trigueros, CA, Krah FS, Cornwell WK, Zanne AE, Abrego N, Anderson IC, Andrew C, Baldrian P, Bässler C, Bissett A, Chaudhary VB, Chen BD, Chen Y, Delgado-Baquerizo M, Deveautour C, Egidi E,  Flores-Moreno H, Golan J, Heilmann-Clausen J, Hempel S, Hu Y, Kauserud H, Kivlin S, Kohout P, Lammel DR, Maestre FT, Pringle A, Purhonen J, Singh BK, Veresoglou SD, Vetrovsky T, Zhang HY, Rillig MC, Powell JR. 2023. Symbiotic status alters fungal eco-evolutionary offspring trajectories. Ecology Letters 26: 1523-1534
10. Veresoglou SD, Johnson D. 2023. Species-area relationships in microbial-mediated mutualisms. Trends in Microbiology. 31: 1111-1117. 
11. Veresoglou SD, Chen J 2023 A perspective on greenhouse gas emission studies integrating arbuscular mycorrhiza. Pedosphere 34: 525-529. 
12. Grunfeld L, Skias G, Rillig MC, Veresoglou SD. 2022. Arbuscular mycorrhizal root colonization depends on the spatial distribution of the host plants. Mycorrhiza 32: 387-395.
13. Okiobe ST, Pirhofer-Walzl K, Leifheit EF, Rillg MC, Veresoglou SD. 2022. Proximal and distal mechanisms through which arbuscular mycorrhizal associations alter terrestrial denitrification. Plant and Soil 476: 315-336.
14. Veresoglou SD et al. 2022 No tillage outperforms conventional tillage under arid conditions and following fertilization. Soil Ecology Letters 5: 137-141.
15. Veresoglou SD, Guolin Li, Junjiang Chen David Johnson. 2022. Direction of plant-soil feedback determines plant responses to drought. Global Change Biology 28: 3995-3997.
16. Veresoglou SD, Johnson D, Mola M, Yang G, Rillig MC. 2022. Evolutionary bet-hedging in arbuscular mycorrhiza associating angiosperms. New Phytologist 233: 1987-1987.
17. de Castro F, Adl SM, Allesina S, Bardgett RD, Bolger T, Dazell J, Emmerson M, Fleming T, Garlaschelli D, Grilli J, Hannula SE, de Vries F, Lindo Z, Maule A, Öpik M, Rillig MC, Veresoglou SD, Wall DH, Caruso T. 2021. Local stability properties of complex, species rich soil food webs with functional block structure. Ecology and Evolution 11: 16070-16081.
18. Grünfeld L, Mola M, Wulf M, Hempel S, Veresoglou SD. 2021. Disentangling the relative importance of spatio-temporal parameters and host specificity in shaping arbuscular mycorrhizal fungus communities in a temperate forest. Mycorrhiza 31: 589-591.
19. Wei X, Hu Y, Cai G, Yao H, Ye J, Sun Q, Veresoglou SD, Yaying L, Zhu Z, Guggenberger G, Chen C.B., Su Y.R., Li Y, Wu J, Ge T. 2021. Organic phosphorus availability shapes the diversity of phoD-harboring bacteria in agricultural soil. Soil Biology and Biochemistry 161: 108364.
20. Lammel DR, Nüsslein K, Cerri CEP, Veresoglou SD, Rillig MC. 2021. Soil biota shift with land use change from pristine rainforest and Savannah (Cerrado) to agriculture in southern Amazonia. Molecular Ecology 30: 4899-4912
21. Veresoglou SD, Grünfeld L, Mola M. 2021. Micro-landscape dependent changes in arbuscular mycorrhizal fungal community structure. Applied Sciences 11: 5297.
22. Yang G, Zhang Y, Yang X, Liu N, Rillig MC, Veresoglou SD, Wagg C. 2021. Mycorrhizal suppression and phosphorus addition influence the stability of plant community composition and function in a temperate steppe. Oikos 130: 354-365.
23. Yang G, Roy J, Veresoglou SD, Rillig MC. 2021. Soil biodiversity enhances the persistence of legumes under climate change. New Phytologist 229: 2945-2956.
24. Rillig MC, Bielcik M, Chaudhary VB, Grünfeld L, Maaß S, Mansour I, Ryo M, Veresoglou SD. 2020. Ten simple rules for increased lab resilience. PLoS Computational Biology 16: e1008313.
25. Agathokleous E, Feng ZZ, Oksanen E, Sicard P, Wang Q, Saitanis CJ, Araminiene V, Blande JD, Hayes F, Calatayud V, Domingos M, Veresoglou SD, Peñuelas J, Wardle, DA, De Marco A, Li ZZ, Harmens H, Yuan XY, Vitale M, Paoletti E. 2020. Ozone affects plant, insect, and soil microbial communities: A threat to terrestrial ecosystems and biodiversity. Science Advances 6: eabc1176
26. Veresoglou SD, Yang G, Mola M, Manntschke A, Mating M, Forstreuter M, Rillig MC. 2020. Excluding arbuscular mycorrhiza lowers variability in soil respiration but slows down recovery from perturbations. Ecosphere 11: e03308.
27. Serlet AJ, López Moreira GA, Zolezzi G, Wharton G, Hölker F, Gurnell AM, Tockner K, Bertoldi W, Bruno MC, Jähnig S, Lewandowski J, Monaghan MT, Rillig MC, Rogato M, Toffolon M, Veresoglou SD, Zarfl C. 2020 SMART Research: Towards interdisciplinary river science in Europe. Frontiers in Environmental Science 8: 63
28. Rillig MC, Aguilar-Trigueros CA, Anderson I, Antonovics J, Ballhausen MB, Bergmann J, Bielcik M, Chaudhary VB, Deveautour C, Grünfeld L, Hempel S, Lakovic M, Lammel D, Lehmann A, Lehmann J, Leifheit E, Liang Y, Li E, Lozano Y, Manntschke A, Mansour I, Oviatt P, Pinek L, Powell JR, Roy J, Ryo M, Sosa-Hernandez M, Veresoglou SD . Wang DW, Yang G, Zhang H. 2020 Myristate and the ecology of AM fungi: significance, opportunities, applications and challenges. New Phytologist 227: 1610-1614.
29. Okiobe ST, Rillig MC, Mola M, Augustin J, Parolly G, Veresoglou SD. 2020 Arbuscular mycorrhiza has little influence on N 2 O potential emissions compared to plant diversity in experimental plant communities. FEMS Microbiology Ecology 96 : fiz208
30. Grünfeld L, Wulf M, Rillig MC, Manntschke A, Veresoglou SD. 2020 Neighbours of arbuscular-mycorrhiza associating trees are colonized more extensively by arbuscular mycorrhizal fungi than their conspecifics in ectomycorrhiza dominated stands. New Phytologist 227: 10-13.
31. Morris EK, Fletcher R, Veresoglou SD. 2020 Effective methods of biofumigation: a meta-analysis. Plant and Soil 446: 379-393.
32. Veresoglou SD, Chen BD, Fischer MM, Helgason T, Mamolos AP, Rillig MC, Roldán A, Johnson D. 2019 Latitudinal constraints in responsiveness of plants to arbuscular mycorrhiza: The ‘sun-worshipper’ hypothesis. New Phytologist 224: 552-556.
33. Okiobe ST, Augustin J, Mansour I, Veresoglou SD. 2019 Disentangling direct and indirect effects of mycorrhiza on nitrous oxide activity and denitrification. Soil Biology and Biochemistry 134: 142-151.
34. Veresoglou SD, Peñuelas J. 2019 Variance in biomass-allocation fractions is explained by distribution in European trees. New Phytologist 222: 1352-1363.
35. Hu Y, Veresoglou SD, Tedersoo L, Xu T, Ge T, Chen Y, Hao Z, Su Y, Rillig MC, Chen B. 2019 Contrasting latitudinal diversity and co-occurrence patterns of soil fungi and plants in forest ecosystems. Soil Biology & Biochemistry 131: 100-110.
36. Veresoglou SD, Verbruggen E, Makarova O, Mansour I, Sen R, Rillig MC. 2018 Arbuscular mycorrhizal fungi alter the community structure of ammonia oxidizers at high fertility via competition for soil NH4+. Microbial Ecology 78: 147-158.
37. Yang G, Wagg C, Veresoglou SD, Hempel S, Rillig MC. 2018 How soil biota influence ecosystem stability. Trends in Plant Science 23: 1057-1067.
38. Veresoglou SD, Halley JM. 2018 Seed mass predicts migration lag of European trees. Annals of Forest Science 75: 86.
39. Veresoglou SD*, Liu L*, Xu T*, Rillig MC, Wang M, Wang J, Chen Y, Hu Y, Hao Z, Chen BD. 2019 Biogeographical constraints in Glomeromycotinan distribution across forest habitats in China. Journal of Ecology 107: 684-695.
40. Veresoglou SD, Rillig MC, Johnson D. 2018 Responsiveness of plants to mycorrhiza regulates coexistence. Journal of Ecology 106:1864-1875.
41. Veresoglou SD, Rillig MC. 2018 Research experience modifies how participants profit from journal clubs in academia. Journal of Biological Education 53:327-332.
42. Caruso T, Hammer E, Hempel S, Kohler J, Morris EK,Veresoglou SD, Opitz N, Wehner J, Rillig MC. 2018 Assessing soil ecosystem processes – biodiversity relationships in a nature reserve in Central Europe. Plant and Soil 423; 491-501.
43. Veresoglou SD, Wang D, Andrade-Linares DR, Hempel S, Rillig MC. 2018 Fungal decision to exploit or explore depends on growth rate. Microbial Ecology 75:289-292.
44. de Sousa NMF, Veresoglou SD, Oehl F, Rillig MC, Maia LC. 2018 Predictors of arbuscular mycorrhizal fungal communities in the Brazilian tropical dry forest. Microbial Ecology 75:447-458.
45. Chen YL, Xu ZW, Xu TL, Veresoglou SD, Yang GW, Chen BD. 2017 Nitrogen deposition and precipitation induced phylogenetic clustering of arbuscular mycorrhizal fungal communities. Soil Biology & Biochemistry 115:233-242.
46. Chen YL, Xu TL, Veresoglou SD, Hu HW, Hao ZP, Hu YJ, Liu L, Deng Y, Rillig MC, Chen BD. 2017 Plant diversity represents the prevalent determinant of soil fungal community structure across temperate grassland in northern China. Soil Biology & Biochemistry 110:12-21.
47. Veresoglou SD, Wulf M. Rillig MC. 2017 Facilitation between woody and herbaceous plants that associate with arbuscular mycorrhizal fungi in temperate European forests. Ecology and Evolution 7:1181-1189.
48. Xu T*, Veresoglou SD*, Chen Y*, Xiang D, Ondrej D, Hao Z, Liu L, Deng Y, Hu Y, Chen W, Wang J, He J, Rillig MC, Chen BD. 2016. Plant community, geographic distance and abiotic factors play different roles in predicting AMF biogeography at the regional scale in northern China. Environmental Microbiology Reports 8: 1048–1057.
49. Veresoglou SD, Anderson IC, de Sousa NMF, Hempel S. Rillig MC. 2016 Resilience of fungal communities to elevated CO2. Microbial Ecology 72: 493-495.
50. Veresoglou SD, Rillig MC, Fraser LH, Halley JM. 2016 The influence of sampled biomass on species-area relationships of grassland plants New Phytologist 211: 382-385.
51. Xiang D*, Veresoglou SD*, Rillig MC, Xu T, Li H, Hao Z, Chen BD. 2016 Relative importance of individual climatic drivers shaping arbuscular mycorrhizal fungal communities. Microbial Ecology 72: 418-427.
52. Andrade-Linares DR, Veresoglou SD, Rillig MC. 2016 Temperature priming and memory in soil filamentous fungi. Fungal Ecology 21: 10-15.
53. Rillig MC, Lehmann A, Aguilar-Trigueros CA, Antonovics J, Caruso T, Hempel S, Lehmann J, Valyi K, Verbruggen E, Veresoglou SD, Powell JR.2016 Soil microbes and community coalescence. Pedobiologia59: 37-40.
54. Veresoglou SD, Halley JM, Rillig MC. 2015 Extinction risk of soil biota. Nature Communications 6: 8862.
55. Veresoglou SD. 2015 P hacking in biology: An open secret Proceedings of the National Academy of Sciences USA 112: 201512689.
56. Antonovics J, Bergmann J, Hempel S, Verbruggen E, Veresoglou S, Rillig M. 2015 The evolution of mutualism from reciprocal parasitism: more ecological clothes for the Prisoner’s Dilemma. Evolutionary Ecology 29: 627-641.
57. Rillig MC, Antonovics J, Caruso T, Lehmann A, Powell JR, Veresoglou SD, Verbruggen E. 2015 Interchange of entire communities: microbial community coalescence. Trends in Ecology and Evolution 30: 470-476.
58. Sardans J, Alonso R, Janssens I, Carnicer J, Veresoglou SD, Rillig MC, Fernandez-Martinez M, Sanders T, Peñuelas J. 2015 Foliar and soil concentrations and stoichiometry of N and P across European Pinus sylvestris forests: relationships with climate, N deposition and tree growth. Functional Ecology 30: 676-689.
59. Veresoglou SD, Rillig MC. 2015 Evidence-Based Data Analysis: Protecting the World from Bad Code? The American Statistician 69: 257.
60. Aguilar-Trigueros CA, Hempel S, Powell JR, Anderson IC, Antonovics J, Bergmann J, Cavagnaro TR, Chen BD, Hart MM, Klironomos J, Petermann JS, Verbruggen E, Veresoglou SD, Rillig MC. 2015 Branching out: towards a trait-based understanding of fungal ecology. Fungal Biology Reviews 29: 34-41.
61. Veresoglou SD, Aguilar-Trigueros CA, Mansour I, Rillig MC. 2015 Self-DNA: a blessing in disguise? New Phytologist 207: 488-490. 
62. Sardans J, Janssens IA, Alonso R, Veresoglou SD, Rillig MC, Sanders T, Carnicer, J, Filella, I, Farré-Armengol, G, Peñuelas J. 2015 Foliar elemental composition of European forest tree species associated with evolutionary traits and present environmental and competitive conditions. Global Ecology and Biogeography 24: 240-255.
63. Rillig MC, Aguilar-Trigueros CA, Bergmann J, Verbruggen E, Veresoglou SD, Lehmann A. 2015 Plant root and mycorrhizal fungal traits for understanding soil aggregation. New Phytologist 205:1385-1388.
64. Veresoglou SD, Rillig MC. 2014 Challenging cherished ideas in mycorrhizal ecology: the Baylis postulate. New Phytologist 204: 1-3.
65. Xiang D, Verbruggen E, Hu Y, Veresoglou SD, Rillig MC, Zhou W, Xu T, Li H, Hao Z, Chen Y, Chen BD. 2014 Land use influences arbuscular mycorrhizal fungal communities in the farming-pastoral ecotone of northern China. New Phytologist 204: 968-978.
66. Hu, Z, Xiang, D, Veresoglou SD, Chen F, Chen Z, Hao, Z, Zhang X, Chen B. 2014 Soil organic carbon and soil structure are driving microbial abundance and community composition across the arid and semi-arid grasslands in northern China. Soil Biology and Biogemistry 77: 51-57.
67. Veresoglou SD, Powell JR, Davison J, Lekberg Y, Rillig MC. 2014 The Leinster and Cobbold indices improve inferences of microbial diversity. Fungal Ecology 11: 1-7.
68. Veresoglou SD, Rillig MC. 2014 Do closely related plants host similar arbuscular mycorrhizal fungal communities? A meta-analysis. Plant and Soil 377: 395-406.
69. Wehner J, Powell JR, Muller LAH, Caruso T, Veresoglou SD, Hempel S, Rillig MC. 2014 Determinants of root-associated fungal communities within Asteraceae in a semiarid grassland. Journal of Ecology 102: 425-436.
70. Leifheit EF, Veresoglou SD, Lehmann A, Morris EK, Rillig MC. 2014 Multiple factors influence the role of arbuscular mycorrhizal fungi in soil aggregation - a meta-analysis. Plant and Soil 374: 523-537.
71. Veresoglou SD, Peñuelas J, Fischer R, Rautio P, Sardans J, Merliä P, Tabakovic-Tosic M, Rillig MC. 2014 Exploring continental-scale stand health - N:P ratio relationships for European forests. New Phytologist 202: 422-430.
72. Lehmann A, Veresoglou SD, Leifheit EF, Rillig MC. 2014 Arbuscular mycorrhizal influence on Zinc nutrition in crop plants - a meta-analysis. Soil Biology and Biochemistry 69: 123-131.
73. Veresoglou SD, Rillig MC. 2013 Accounting for the adaptation deficit of non-mycorrhizal plants in experiments. Plant and Soil 366: 33-34.
74. Veresoglou SD, Caruso T, Rillig MC. 2013 Modelling the environmental and soil factors that shape the niches of two common arbuscular mycorrhizal fungal families. Plant and Soil 368: 507-518.
75. Verbruggen E*, Veresoglou SD*, Anderson IC, Caruso T, Hammer EC, Kohler J, Rillig MC. 2013 Arbuscular mycorrhizal fungi - short-term liability but long-term benefits for soil carbon storage. New Phytologist 197: 366-368.
76. Veresoglou SD, Barto EK, Menexes G, Rillig MC. 2013 Fertilization affects severity of disease caused by fungal plant pathogens. Plant Pathology 62: 961-969.
77. Veresoglou SD*, Caruso T*, Rillig MC. 2012 Metacommunities and symbiosis: hosts of challenges. Trends in Ecology and Evolution 27: 588-589.
78. Veresoglou SD, Thornton B, Menexes G, Mamolos AP, Veresoglou DS. 2012 Soil fertilization leads to a decline in between-samples variability of microbial community δ13C profiles in a grassland fertilization experiment. Plos One 7: e44203.
79. Veresoglou SD, Shaw LJ, Hooker JE, Sen R. 2012 Arbuscular mycorrhizal modulation of diazotrophic and denitrifying microbial communities in the (myco)rhizosphere of Plantago lanceolata. Soil Biology and Biochemistry 53: 78-81.
80. Veresoglou SD, Halley JM. 2012 A model that explains diversity patterns of arbuscular mycorrhizas. Ecological Modelling 231: 146-152.
81. Veresoglou SD. 2012 Arbuscular mycorrhiza prevents suppression of actual nitrification rates in the (myco) rhizosphere of Plantago lanceolata. Pedosphere 22: 137-151.
82. Veresoglou SD, Menexes G, Rillig MC. 2012 Do arbuscular mycorrhizal fungi affect the allometric partition of host plant biomass to shoots and roots? A meta-analysis of studies from 1990 - 2010. Mycorrhiza 22: 227-235.
83. Veresoglou SD, Rillig MC. 2012 Suppression of fungal and nematode plant pathogens through arbuscular mycorrhizal fungi. Biology Letters 8: 214-217.
84. Veresoglou SD, Chen BD, Rillig MC. 2012 Arbuscular mycorrhiza and soil nitrogen cycling. Soil Biology & Biochemistry 46: 53-62. 
85. Veresoglou SD, Voulgari OK, Sen R, Mamolos AP, Veresoglou DS. 2011 Effects of nitrogen and phosphorus fertilization on soil pH-plant productivity relationships in upland grasslands of Northern Greece. Pedosphere 21: 750-752.
86. Veresoglou SD, Sen R, Mamolos AP, Veresoglou DS. 2011 Plant species identity and arbuscular mycorrhizal status modulate potential nitrification rates in nitrogen-limited grassland soils. Journal of Ecology 99: 1339-1349.
87. Veresoglou SD, Mamolos AP, Thornton B, Voulgari OK, Sen R, Veresoglou DS. 2011 Medium-term fertilization of grassland plant communities masks plant species-linked effects on soil microbial community structure. Plant and Soil 344: 187-196.
88. Veresoglou SD, Shaw LJ, Sen R. 2011 Glomus intraradices and Gigaspora margarita arbuscular mycorrhizal associations differentially affect nitrogen and potassium nutrition of Plantago lanceolata in a low fertility dune soil. Plant and Soil 340: 481-490.
89. Veresoglou SD, Menexes G. 2010 Impact of inoculation with Azospirillum spp. on growth properties and seed yield of wheat: a meta-analysis of studies in the ISI Web of Science from 1981 to 2008. Plant and Soil 337: 469-480.