Resource-use hypothesis

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The resource-use hypothesis is a macroevolutionary theory proposed by paleontologist Elisabeth S. Vrba as part of her broader Habitat Theory[1][2][3]. It posits that the degree of ecological specialization—specifically in relation to biome occupancy—influences a lineage's propensity for speciation and extinction[2][4].

Theory

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Vrba's hypothesis suggests that specialist species (those restricted to a single climate zone or biome, often termed stenobiomic) are expected to have higher rates of both speciation and extinction compared to generalist species (eurybiomic species)[1][2][5]. This is because specialists are more vulnerable to environmental changes and vicariance events[2].

Vulnerability to environmental change: Specialists, due to their narrow ecological niche, are acutely sensitive to the expansion, contraction, and fragmentation of their specific habitat caused by primary climatic cycles (such as those of the Pleistocene)[5][6]. When their resource base fragments or disappears, their populations are divided, potentially leading to rapid speciation via allopatry or, more commonly, extinction[7].

Geographic distribution and fragmentation: The hypothesis further predicts a higher frequency of specialist species in biomes that are historically prone to a high degree of contraction and fragmentation during climatic cycles[4][8]. These often correspond to zones at the extremes of global climatic gradients, such as equatorial rainforests and subtropical deserts, where shifting temperature and precipitation historically induced severe habitat fracturing[2][3][7].

Empirical studies on terrestrial mammals and other lineages have shown that the number of specialist species increases with historical regional climate fragmentation, offering support for this prediction[8]. These studies have increasingly extended the corroboration of the resource-use hypothesis beyond its initial foundation in Neogene-Quaternary African ruminants[1][7]. A key prediction —that the speciation rates of specialist species is significantly higher that in biome generalists— has been globally confirmed in several terrestrial groups, including ruminants[4], squirrels[9] and butterflies[10]. Another key prediction, stating that specialists should be more frequent than expected by chance, particularly in biomes at the extremes of the global climatic gradient, supporting the core principle that resource restriction in volatile environments drives higher specialization and turnover, has been corroborated in mammals[3][4][7][11], turtles[12] and butterflies[10]. These inter-taxonomic comparisons reinforce the view that resource-use patterns, driven by large-scale environmental change and subsequent habitat fragmentation, are a universal macroevolutionary force[13].

Relationship to other hypotheses

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The resource-use hypothesis is conceptually linked to Vrba's more widely known turnover-pulse hypothesis[6][14]. Both ideas emphasize the role of large-scale physical environmental changes (especially climate change) as the primary external driver (or pacemaker) of bursts of macroevolutionary events (i.e., synchronized extinction and speciation events, or "pulses") across multiple co-existing lineages[15]. The resource-use hypothesis provides a mechanism for how different species respond to these pulses, predicting that specialists will be the main drivers of the observed turnover[4]. This ecological mechanism is also key to explaining the pattern of change described by Punctuated Equilibrium. Punctuated Equilibrium posits that species exhibit long periods of stasis (morphological stability) interrupted by rare, rapid bursts of change associated with speciation events (cladogenesis)[16]. Vrba's work, particularly her collaboration with Stephen Jay Gould and Niles Eldredge in developing a hierarchical model of evolution, links these sudden bursts to external environmental forces[17][18]. Specifically, the resource-use hypothesis suggests that the fragmentation of a specialist's habitat during a major climatic pulse (the external trigger) drives the emergence of small, peripherally isolated populations—the very populations critical to the allopatric and peripatric speciation models underpinning Punctuated Equilibrium[2][8]. Thus, the specialists' high vulnerability to resource partitioning due to climate change provides a direct causal link between global physical events and the rapid, branching pattern of evolution observed in the fossil record[19].

References

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  1. ^ a b c Vrba, Elisabeth (1987). "Ecology in relation to speciation rates: Some case histories of Miocene-recent mammal clades". Evolutionary Ecology. 1 (4): 283–300. Bibcode:1987EvEco...1..283V. doi:10.1007/BF02071554.
  2. ^ a b c d e f Vrba, Elisabeth S. (1992). "Mammals as a key to evolutionary theory". Journal of Mammalogy. 73 (1): 1–28. doi:10.2307/1381862. JSTOR 1381862.
  3. ^ a b c Hernández Fernández, Manuel; Pelegrin, Jonathan S.; Gómez Cano, Ana R.; García Yelo, Blanca A.; Moreno Bofarull, Ana; Sánchez-Fontela, Noelia; Rodríguez-Ruiz, Claudia; Ramiro Camacho, Alejandro; Domingo, Laura; Menéndez, Iris; Martín-Perea, David M.; Bazán, Carla M.; Alcalde, Gema M.; Domingo, M. Soledad; Luna, Belén; Peinado Cortés, María del Mar; Arias, Antón; González Couturier, Gabriela; Márquez Villena, Ana; Anaya, Noelia; Blanco, Fernando; Galli, Emilia; Gamboa, Sara; Quesada, Álvaro; Sanz-Pérez, Dánae; Varela, Sara; Cantalapiedra, Juan L. (2022). "Macroevolution and climate changes: A global multi-family test supports the resource-use hypothesis in terrestrial mammals". Historical Biology. 34 (8): 1471–1479. Bibcode:2022HBio...34.1471H. doi:10.1080/08912963.2022.2042807.
  4. ^ a b c d e Cantalapiedra, Juan L.; Hernández Fernández, Manuel; Morales, Jorge (2011). "Biomic specialization and speciation rates in ruminants (Cetartiodactyla, Mammalia): a test of the resource-use hypothesis at the global scale". PLOS ONE. 6 (12) e28749. Bibcode:2011PLoSO...628749C. doi:10.1371/journal.pone.0028749.
  5. ^ a b Vrba, Elisabeth (1985). "Environment and evolution: alternative causes of the temporal distribution of evolutionary events". South African Journal of Science. 81 (5): 229–236.
  6. ^ a b Vrba, Elisabeth (1993). "The pulse that produced us". Natural History. 102 (5): 47–51.
  7. ^ a b c d Hernández Fernández, Vrba; Vrba, Elisabeth (2005). "Macroevolutionary processes and biomic specialization: testing the resource-use hypothesis". Evolutionary Ecology. 19: 199–219. doi:10.1007/s10682-004-8152-7.x (inactive 17 December 2025).{{cite journal}}: CS1 maint: DOI inactive as of December 2025 (link)
  8. ^ a b c Gamboa, Sara; Galván, Sofía; Varela, Sara (2011). "Vrba was right: Historical climatic fragmentation, and not current climate, explains mammal biogeography". Historical Biology. 30 (5) e17339. doi:10.1111/gcb.17339.
  9. ^ Menéndez, Iris; Gómez Cano, Ana R.; Cantalapiedra, Juan L.; Peláez-Campomanes, Pablo; Álvarez-Sierra, María A.; Hernández Fernández, Manuel (2021). "A multi-layered approach to the diversification of squirrels". Mammal Review. 5 (1): 66–81. Bibcode:2021MamRv..51...66M. doi:10.1111/mam.12215.
  10. ^ a b Gamboa, Sara; Condamine, Fabian L.; Cantalapiedra, Juan L.; Varela, Sara; Pelegrin, Jonathan S.; Menéndez, Iris; Blanco, Fernando; Hernández Fernández, Manuel (2021). "A phylogenetic study to assess the link between biome specialization and diversification in swallowtail butterflies". Global Change Biology. 28 (20): 5901–5913. doi:10.1111/gcb.16344. PMID 35838418.
  11. ^ Moreno Bofarull, Ana; Arias Royo, Antón; Hernández Fernández, Manuel; Ortiz-Jaureguizar, Edgardo; Morales, Jorge (2008). "Influence of continental history on the ecological specialization and macroevolutionary processes in the mammalian assemblage of South America: Differences between small and large mammals". BMC Evolutionary Biology. 8 (1) 97. Bibcode:2008BMCEE...8...97B. doi:10.1186/1471-2148-8-97. PMC 2330041. PMID 18366786.
  12. ^ Thomas, Juan S.; Gamboa, Sara; Hernández Fernández, Manuel; Morillo, Oscar; Pelegrin, Jonathan S. (2024). "Macroevolutionary processes in turtles (Testudines): a view from biomic specialization and historical climatic changes". Frontiers in Ecology and Evolution. 12 (20) 1474500. Bibcode:2024FrEEv..1274500T. doi:10.3389/fevo.2024.1474500.
  13. ^ Gamboa, Sara; Galván, Sofía; Sobral, Mar; Hernández Fernández, Manuel; Varela, Sara (2025). "The division of food space among mammalian species on biomes". Ecography. 2025 (10) e07660. Bibcode:2025Ecogr202507660G. doi:10.1002/ecog.07660.
  14. ^ Vrba, Elisabeth (1993). "Turnover-Pulses, The Red Queen, and Related Topics" (PDF). American Journal of Science. 293: 418–452. Bibcode:1993AmJS..293..418V. doi:10.2475/ajs.293.A.418.
  15. ^ Vrba, Elisabeth S. (1995). "On the connections between paleoclimate and evolution". In Vrba, E.S.; Denton, G.H.; Partridge, T.C.; Burkle, L.H. (eds.). Paleoclimate and Evolution with emphasis on Human Origins. New Haven, CT: Yale University Press. pp. 24–45.
  16. ^ Eldredge, N.; Gould, S.J. (1972). "Punctuated equilibria: An alternative to phyletic gradualism". In Schopf, T.J.M. (ed.). Models in Paleobiology. San Francisco, CA: Freeman Cooper. pp. 82–115.
  17. ^ Vrba, Elisabeth S. (1980). "Evolution, species and fossils: how does life evolve?". South African Journal of Science. 76: 61–84.
  18. ^ Vrba, Elisabeth S.; Gould, Stephen J. (2005). "The hierarchical expansion of sorting and selection: Sorting and selection cannot be equated". Paleobiology. 12 (2): 217–228. doi:10.1017/S0094837300013671.
  19. ^ Gómez Cano, Ana R.; Cantalapiedra, Juan L.; Mesa, Aurora; Moreno Bofarull, Ana; Hernández Fernández, Manuel (2011). "Global climate changes drive ecological specialization of mammal faunas: Trends in rodent assemblages from the Iberian Plio-Pleistocene". BMC Evolutionary Biology. 13 (5) 94. doi:10.1186/1471-2148-13-94. PMID 23627696.