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editorial
. 2025 Jun 6;63(4):450–451. doi: 10.1111/gwat.13495

Collaborative Science for Groundwater Biodiversity Conservation

Mattia Saccò 1,2,, Xander Huggins 3,4, Alejandro Martínez 5, Robert Reinecke 6
PMCID: PMC12271990  PMID: 40476347

Lost in the alarm and broader narrative on global trends of biodiversity collapse, an ecosystem is silently vanishing under our feet: groundwater. “Out‐of‐sight, out‐of‐mind” describes not only groundwater the resource, but to even greater effect, groundwater the ecosystem. That is, while groundwater is generally recognized as an invisible resource, it is rarely acknowledged or celebrated as an invisible habitat.

Depletion and quality degradation of groundwater ecosystems trigger impacts on diverse, highly specialized, and often locally endemic biota, ranging from microbes to cavefish. The extent to which groundwater ecosystems are threatened is alarming: underground biological extinction is already happening (Humphreys 2022). The full breadth of this challenge is unknown, yet the large‐scale and widespread depletion and quality degradation of groundwater would suggest that groundwater ecosystem collapse may be extensive and with concerning implications.

First, all the essential services linked to the maintenance of a well‐functioning groundwater ecosystem, such as contaminant degradation, oxygenation, and carbon turnover regulation, would be lost. Without those, groundwater quality is bound to degrade, leading to the potential proliferation of harmful viruses and bacteria. Furthermore, this impoverishment could cause detrimental cascade effects on the myriad of ecosystems that depend on groundwater, for example, rivers, lakes, grasslands, and forests. As climate change and aridification intensify, the reliance of these ecosystems on groundwater will inevitably increase, reinforcing the need for sustainable groundwater management policies and strategies (Gleeson et al. 2020).

Multiple exciting recent developments have enabled a better understanding of groundwater ecosystems. The number of species documented in subterranean groundwater‐dependent ecosystems is now almost 50,000 (Martinez et al. 2018), a number that far exceeds that of fish globally. These species deliver innumerable provisioning, regulation, and cultural ecosystem services below and above ground (Griebler and Avramov 2015). Simultaneously, the marked emergence of continental to global groundwater modeling in recent decades presents a particular opportunity to link groundwater dynamics and patterns of biodiversity with land use, climate, socioeconomic, and political change across broad contexts. In continuity with the concept of “ecohydrogeology” (Cantonati et al. 2020), we perceive a grand opportunity to better link the groundwater biology and hydrology communities and raise here the critical need to leverage such collaborations to enhance and empower groundwater ecosystem conservation and management. A handful of efforts to map terrestrial and aquatic groundwater‐dependent ecosystems have emerged over recent years (Link et al. 2023; Huggins et al. 2023a; Rohde et al. 2024; Saccò et al. 2024), yet acknowledgement of groundwater biota in hydrogeological studies remains rare, and aquifer management impacts continue to be unquantified. Likewise, thorough representation of hydrological processes is equally sparse in groundwater biology studies. Both fields have blind spots that mutual collaboration can address.

Groundwater is increasingly recognized as a resource embedded in a diverse network of systems (Huggins et al. 2023b), which include social, economic, cultural, ecological, biological, hydrological, and geological components. Broadening the “tent” of groundwater science to include the various systems and disciplinary forms of expertise that relate to groundwater could enable a more fruitful environment for this needed interdisciplinarity. Indeed, there is great potential for groundwater hydrogeologists and biologists to lead the way on this, and we pinpoint three priority areas, each followed by an actionable initiative. (1) Collaborative research—organize dedicated workshops, conference sessions, and special issues focused to nurture and facilitate collaboration between hydrologists, biologists, and conservation scientists. (2) Conservation policies—incentivize the collection of empirical subterranean ecological data to support informed, and field‐verified conservation and management actions. (3) Social awareness—establish international days to promote groundwater biodiversity issues, which could include the establishment of a World Groundwater Day, in line with existing days dedicated to rivers and lakes, or through advocating a subterranean or groundwater theme for an upcoming World Biodiversity Day.

Overall, these actions could meaningfully raise the profile of groundwater ecosystems. Advancing these actions, however, will not be trivial, and deepening the integration of hydrogeology with biology will face challenges relating to the fuzzy definition and concept of groundwater‐dependent ecosystems, the acquisition of geographically extensive data in subterranean ecosystems, and the feasibility of incorporating biological components into hydrological modeling frameworks. Yet, in a world dominated by the language and discourse of crisis, we remind ourselves and readers of the fundamentally optimistic orientation of the scientific enterprise (Paskins 2020). To protect groundwater biodiversity worldwide, now is the time to be bold and think outside of the (subterranean) blue box.

Acknowledgment

The authors warmly thank colleagues, friends, and partners for insightful and constructive feedback. M.S. acknowledges support from the School of Molecular and Life Sciences at Curtin University, and the BHP‐Curtin alliance within the framework of the “eDNA for Global Environment Studies (eDGES)” programme. A.M. was supported by P.R.I.N. 2022 project “ANCHIALOS” (2022LLNF3N), funded by the Ministry of Universities and Research (Italy).

Data Availability Statement

Data sharing is not applicable to this article as no new data were created or analyzed in this study.

References

  1. Cantonati, M. , Stevens L.E., Segadelli S., Springer A.E., Goldscheider N., Celico F., Filippini M., Ogata K., and Gargini A.. 2020. Ecohydrogeology: The interdisciplinary convergence needed to improve the study and stewardship of springs and other groundwater‐dependent habitats, biota, and ecosystems. Ecological Indicators 110: 105803. [Google Scholar]
  2. Gleeson, T. , Cuthbert M., Ferguson G., and Perrone D.. 2020. Global groundwater sustainability, resources, and systems in the Anthropocene. Annual Review of Earth and Planetary Sciences 48, no. 1: 431–463. [Google Scholar]
  3. Griebler, C. , and Avramov M.. 2015. Groundwater ecosystem services: A review. Freshwater Science 34, no. 1: 355–367. [Google Scholar]
  4. Huggins, X. , Gleeson T., Serrano D., Zipper S., Jehn F., Rohde M.M., Abell R., Vigerstol K., and Hartmann A.. 2023a. Overlooked risks and opportunities in groundwatersheds of the world's protected areas. Nature Sustainability 6, no. 7: 855–864. [Google Scholar]
  5. Huggins, X. , Gleeson T., Castilla‐Rho J., Holley C., Re V., and Famiglietti J.S.. 2023b. Groundwater connections and sustainability in social‐ecological systems. Groundwater 61, no. 4: 463–478. [DOI] [PubMed] [Google Scholar]
  6. Humphreys, W.F. 2022. Community extinction: The groundwater (stygo‐) fauna of Curaçao, Netherlands Antilles. Hydrobiologia 849, no. 21: 4605–4611. [Google Scholar]
  7. Link, A. , El‐Hokayem L., Usman M., Conrad C., Reinecke R., Berger M., Wada Y., Coroama V., and Finkbeiner M.. 2023. Groundwater‐dependent ecosystems at risk–global hotspot analysis and implications. Environmental Research Letters 18, no. 9: 094026. [Google Scholar]
  8. Martinez, A. , Anicic N., Calvaruso S., Sanchez N., Puppieni L., Sforzi T., Zaupa S., Alvarez F., Brankovits D., Gąsiorowski L., and Gerovasileiou V.. 2018. A new insight into the stygofauna mundi: Assembling a global dataset for aquatic fauna in subterranean environments. In ARPHA Conference Abstracts, vol. 1, e29514. Pensoft Publishers.
  9. Paskins, M. 2020. History of science and its utopian reconstructions. Studies in History and Philosophy of Science Part A 81: 82–95. [DOI] [PubMed] [Google Scholar]
  10. Rohde, M.M. , Albano C.M., Huggins X., Klausmeyer K.R., Morton C., Sharman A., Zaveri E., Saito L., Freed Z., Howard J.K., Job N., Richter H., Toderich K., Rodella A.‐S., Gleeson T., Huntington J., Chandanpurkar H.A., Purdy A.J., Famiglietti J.S., Singer M.B., Roberts D.A., Caylor K., and Stella J.C.. 2024. Groundwater‐dependent ecosystem map exposes global dryland protection needs. Nature 632, no. 8023: 101–107. [DOI] [PMC free article] [PubMed] [Google Scholar]
  11. Saccò, M. , Mammola S., Altermatt F., Alther R., Bolpagni R., Brancelj A., Brankovits D., Fišer C., Gerovasileiou V., Griebler C., Guareschi S., Hose G.C., Korbel K., Lictevout E., Malard F., Martínez A., Niemiller M.L., Robertson A., Tanalgo K.C., Bichuette M.E., Borko S., Brad T., Campbell M.A., Cardoso P., Celico F., Cooper S.J.B., Culver D., Di Lorenzo T., Galassi D.M.P., Guzik M.T., Hartland A., Humphreys W.F., Lopes Ferreira R., Lunghi E., Nizzoli D., Perina G., Raghavan R., Richards Z., Reboleira A.S.P.S., Rohde M.M., Sánchez Fernández D., Schmidt S.I., van der Heyde M., Weaver L., White N.E., Zagmajster M., Hogg I., Ruhi A., Gagnon M.M., Allentoft M.E., and Reinecke R.. 2024. Groundwater is a hidden global keystone ecosystem. Global Change Biology 30, no. 1: e17066. [DOI] [PubMed] [Google Scholar]

Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Data Availability Statement

Data sharing is not applicable to this article as no new data were created or analyzed in this study.

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