Extinction of endemic taxa as a direct consequence of global climate change

Monroy-Gamboa, Alina Gabriela; Cab-Sulub, Leticia; Álvarez-Castañeda, Sergio Ticul; Monroy-Gamboa, Alina Gabriela; Cab-Sulub, Leticia; Álvarez-Castañeda, Sergio Ticul

doi:10.12933/therya-22-1210

Serviços Personalizados

Journal

Artigo

Indicadores

Citado por SciELO
Acessos

Links relacionados

Similares em SciELO

Mais
Mais

Permalink

Therya

versão On-line ISSN 2007-3364

Therya vol.13 no.1 La Paz Jan. 2022 Epub 08-Abr-2022

https://doi.org/10.12933/therya-22-1210

Special contributions

Extinction of endemic taxa as a direct consequence of global climate change

Alina Gabriela Monroy-Gamboa¹

Leticia Cab-Sulub¹

Sergio Ticul Álvarez-Castañeda¹^*

^¹Centro de Investigaciones Biológicas del Noroeste, S. C. Instituto Politécnico Nacional 195, La Paz. Baja California Sur, CP. 23205, México. Email: beu_ribetzin@hotmail.com (AGM-G), lety.cs90@gmail.com (LC-S), sticul@cibnor.mx (STA-C).

Abstract:

Global climate change occurs from both natural and anthropic causes. Anthropic climate change has effects at various scales and occurs faster than the adaptation of species to these changes. Protected natural areas have been created to preserve species from the different threats facing them. Sierra La Laguna is a sky island with almost no anthropic pressure given its natural isolation; it is home to several endemic taxa, including Peromyscus truei lagunae and Sorex ornatus lagunae. This study aims to assess the possible impact of climate change on species endemic to a sky island exposed to virtually no local anthropic pressure. The Sierra La Laguna sky island, located in the southern region of the Baja California peninsula, harbors different vegetation types, including an oak-pine forest at the highest elevations and xeric vegetation at lower ones. Ecological niche models were developed under three climate change scenarios contemplating temperature rises of 1.5 °C and 4.4 °C. There are insufficient localities to make statistically robust models for mammalian species. Therefore, we used plant species typical of the oak-pine forest (Pinus cembroides lagunae, Quercus brandegeei, and Q. devia) and the rodents Peromyscus eva, that thrives in dry deciduous forests, and Chaetodipus rudinoris and C. spinatus, associated with xeric ecosystems. The models show that ecological suitability for the oak species decreases, while it is completely lost for the pine species. On the other hand, P. eva broadens its elevational range, while C. rudinoris and C. spinatus increase their ecological suitability in both area and elevation. The Sierra La Laguna sky island is an area with virtually no regional or local anthropic pressure. Nonetheless, the projections conducted under various climate change scenarios show a loss of up to 100 % of the area of climatic and elevational suitability for species characteristic of the oak-pine forest even with the minimum temperature rise of 1.5 °C. These results suggest that, under these conditions, endemic species such as P. t. lagunae and S. o. lagunae will become extinguished despite the absence of local anthropic pressures.

Keywords: Chaetodipus spinatus; Chaetodipus rudinoris; endemic; extinction; global changes; local extinctions; local conservation strategies; Peromyscus eva; protection; Sierra La Laguna

Resumen:

El cambio climático global existe de manera natural y el antrópico. El antrópico afecta a diferentes escalas y se produce de una manera más acelerada que la adaptación de las especies a estos cambios. Se han creado áreas naturales protegidas para preservar a las especies de las diferentes amenazas a las que están expuestas. La Sierra La Laguna es una isla del cielo, que gracias a su aislamiento natural tiene una presión antrópica casi nula; alberga varios taxa endémicos, incluyendo Peromyscus truei lagunae y Sorex ornatus lagunae. El objetivo de este estudio es evaluar la posible afectación del cambio climático a especies endémicas de una isla del cielo en la que prácticamente no existen presiones antrópicas locales. La isla del cielo de Sierra La Laguna, al sur de la península de Baja California, posee diferentes tipos de vegetación. En las elevaciones más altas está el bosque de encino-pino y con vegetaciones más xéricas al inferior. Se realizaron modelos de nicho ecológico con tres escenarios de cambio climático con incrementos de temperatura de 1.5 °C y 4.4 °C. No se cuentan con localidades suficientes para realizar modelos estadísticamente robustos de las especies de mamíferos, por lo que se usaron especies vegetales características del bosque (Pinus cembroides lagunae, Quercus brandegeei y Q. devia), así como a los roedores Peromyscus eva de la selva baja caducifolia y a Chaetodipus rudinoris y C. spinatus que están asociadas a ecosistemas xéricos. Los modelos muestran que la idoneidad ecológica para los encinos disminuye mientras que el pino la pierde por completo. P. eva disminuye en área pero incrementa altitudinalmente. C. rudinoris y C. spinatus aumentan en área y altitud su idoneidad ecológica. La isla del cielo Sierra La Laguna es un área con prácticamente nula presión antrópica regional y local, a pesar de esto, con las proyecciones realizadas bajo escenarios de cambio climático se muestra una pérdida hasta del 100 % del área de idoneidad climática y altitudinal aún con el incremento mínimo de temperatura de 1.5 °C para especies características del bosque de encino-pino. Los resultados sugieren que bajo estas condiciones especies endémicas como P. t. lagunae y S. o. lagunae se extinguirán a pesar de no tener presiones antrópicas locales.

Introduction

Climate changes have occurred constantly throughout Earth’s history (^{Zalasiewicz and Williams 2021}). However, it has been recognized that anthropic climate has been the main driver of species extinctions over the past 100 years (^{Cahill et al. 2013}) because ecosystems are being severely transformed and threatened, with impacts reaching the global scale. Deforestation, changes in land use, and extraction of certain species are among the factors causing the greatest impact on biodiversity loss (^{Ochoa-Ochoa and Ríos-Muñoz 2019}). Anthropic climate change is likely to compound and exacerbate these factors.

The main effects of climate change are rising ambient temperature and changes in humidity and dryness (^{IPCC 2021}). The global rise in temperature has unavoidable effects at global, regional, and local scales that occur at a faster rate than the capacity of species for physiological adaptation, thus affecting variations in population dynamics, behavior, and ecological interactions, leading to changes in their geographic distributions (^{Elith and Leathwick 2009}1; ^{Ackerly et al. 2010}; ^{Aguado and Escalante 2015}). Protecting the remaining primary forests, especially those with high carbon capture, has been suggested as a natural approach to controlling climate change and preventing biodiversity loss (^{Griscom et al. 2017}).

Local stressors, mainly derived from the ever-growing human population, have led to changes in forest cover and land use. As a result, primary or secondary vegetation has been converted into extensive crop fields, pastures dedicated to intensive livestock raising, and human settlements (Mas and ^{Flamenco 2011}). Urban areas are also undergoing expansion, most often with no planning or structure. This phenomenon is causing damage to biodiversity, hydrological systems, and ecosystems due to the growing demand for services, construction of roads and airports, urban development, and water extraction for human consumption, among others (^{Grimm et al. 2008}).

The term “protect” (to cover or shield from injury or destruction; to defend, guard; ^{Merriam-Webster 1961}) is frequently mentioned and has been adopted in the conservation field. In 2015, a group of world leaders agreed on an agenda for sustainable development, with the protection of the Earth included as one of the goals (^{CDB 2018}). Aiming to meet the objective of “protection” against the different anthropic pressures, México has created a system of Protected Natural Areas (PNAs) covering 11.14 % of the country (^{Conanp 2019}). This system harbors different ecosystems with their respective assemblages of flora and fauna. In many cases, PNAs were created to protect species endemic to the region or the country that are in some risk category (^{Bezaury-Creel and Gutiérrez-Carbonell 2009}).

Worldwide, the vast majority of PNAs are affected by anthropic pressures at three levels (global, regional, and local), so that assessing the effects of climate change on particular species is a complex task. General and specific pressures act in synergy where the individual effect of each of the different stressors cannot be clearly identified. In Baja California Sur, Sierra La Laguna has an unique condition worldwide for being part of a sky island - an isolated area hosting different types of ecosystems along an elevational gradient (^{Osborne et al. 2019}). It faces little anthropic disturbance: it has no access roads to the middle and upper parts, it is located in an area with very low human population density, there are no productive activities associated with the mountain range, and any human activities carried out in the area are minimal and low-impact. The oak-pine forest located at the highest elevations can only be reached on foot and with controlled access. The mountain range is home to several endemic taxa, such as the reptiles Elgaria paucicarinata and Xantusia vigilis; the birds Hylocharis xantusii, Melanerpes formicivorus, Pipilo maculatus magnirostris, Sitta carolinensis, and Vireo victoriae; and the mammals Peromyscus truei lagunae and Sorex ornatus lagunae (^{Álvarez-Cárdenas et al. 1988}; ^{Rodríguez-Estrella 1988}; ^{Cortés-Calva 2012}; ^{Segura-Trujillo et al. 2012}). Despite these favorable features, global climate change may affect some taxa that are endemic to this PNA. The objective of this study is to assess the potential impact of climate change on taxa endemic to this sky island exposed to virtually no local anthropic pressures.

Materials and Methods

Study area. The Sierra La Laguna Biosphere Reserve is located in the southern region of the Baja California peninsula, in the state of Baja California Sur, between the municipalities of La Paz and Los Cabos. This reserve is unique in its type for being part of a sky island due to its natural isolation, with a maximum elevation of 2,080 meters (Figure 1). The low human population density in the region presents virtually no anthropic pressure, making this region an ideal model of ecosystem protection. This sky island harbors various vegetation types, including arid ecosystems such as dry deciduous forest and crassicaule shrubland at lower areas of the mountain range and oak-pine forests at higher elevations.

To assess the effects of global temperature rise at the local level, we applied ecological niche models to make projections for climate change scenarios considering different temperature rise levels. Historically, P. t. lagunae and S. o. lagunae are found in the oak-pine forest. Given their inaccessible and restricted habitat, there are very few records with unique localities (4 and 5, respectively, separated by less than one km between them); therefore, these two species were not candidates for use in ecological niche models because the models would not be statistically robust, they have to be considered a cluster of localities (^{Pawar et al. 2007}). Instead, we used the tree species Pinus cembroides lagunae, Quercus brandegeei, and Q. devia, which are typical of the oak-pine forest in Sierra La Laguna. Also included were Peromyscus eva, a rodent species that inhabits lower elevations associated with the dry deciduous forest, and Chaetodipus rudinoris and C. spinatus, representative of arid ecosystems. These mammal species were used as references to examine their potential elevational displacement due to global climate change.

Figure 1 Geographic location of the sky island Sierra La Laguna, Baja California Sur, México. Light gray represents the Baja California peninsula. Medium gray represents the Cabo region. Dark gray represents Sierra La Laguna sky island.

The ecological niche models were developed using the Maximum Entropy (MaxEnt) algorithm in R (^{R Development Core Team 2020}) for the present time using climatic variables from the Digital Climate Atlas of Mexico on a 250-meter scale (http://uniatmos.atmosfera.unam.mx/ACDM/servmapas). We used r < 0.80 to avoid collinearity and correlation (^{Dormann et al. 2013}). The best models were selected based on good performance (< 10 % omission rate; ^{Peterson et al. 2011}), lowest value of the Akaike’s Information Criterion corrected for small sample size (AICc), and a ROC < 0.05 (^{Peterson et al. 2011}). These were projected using three general circulation models: HadGEM2-ES (^{Jones et al. 2011}), CCSM4 (^{Vertenstein et al. 2016}), and MPI-ESM-LR (^{Giorgetta et al. 2013}) considering a minimum global temperature rise of 1.5 °C and a maximum of 4.4 °C (for details of the modeling methodology, refer to ^{Monroy-Gamboa et al. 2021}).

Results

To assess the status of mammal species, two different analyses were conducted. The first included the associated plant species that define the oak-pine forest, i. e., Pinus cembroides, Quercus brandegeei, and Q. devia. The second was based on the fact that the temperature rise will lead to a forest desertification process with a shift toward xeric species.

The result of the modeling of P. c. lagunae, Q. brandegeei, and Q. devia showed a decrease in the area with climatic suitability under the three projected scenarios, except for Q. devia with the general circulation model HadGEM2-ES; with an increase of 4 °C the model showed a minimum increment (2.28 km²) in the surface (Figure 2; Table 1). Both the optimistic and pessimistic climate-change scenarios predicted the total disappearance of climatic suitability for the endemic population of P. c. lagunae, a species that is characteristic of the forest at higher elevations. The models for Peromyscus eva, associated with the dry deciduous forest, showed a loss of between 18 % and 21 % of the climatically suitable area (Figure 2; Table 1). The models for Chaetodipus rudinoris and C. spinatus, strongly associated with the xeric habitats in the lower part of the mountain range, showed a broadening of their elevational range between 108 to 682 and 1,295 m, respectively, and an expansion of the area with climatic suitability (Figure 2; Table 1). Both results indirectly show the reduction of the forest and the mammal species associated with it, which can be considered a collapse of the forest due to desertification.

Table 1 Area, in km2, presenting suitable climatic conditions for the species inhabiting the Sierra La Laguna sky island, currently and under three general circulation models as climatic change scenarios assuming minimum and maximum temperature rises of 1.5 ºC and 4.4 ºC, respectively.

	Current	Climate change
		1.5° C			4.4° C
		CCSM4	HadGEM2-ES	MPI-ESM-LR	CCSM4	HadGEM2-ES	MPI-ESM-LR
Pinus cembroides lagunae	693.25	0.00	0.00	0.00	0.00	0.00	0.00
Quercus brandegeei	1,390.78	1,306.57	1,389.51	1,187.66	1,268.23	874.52	977.51
Quercus devia	1,378.36	614.23	1,130.76	743.40	303.86	1,380.64	1,052.88
Chaetodipus rudinoris	0.00	236.76	428.70	50.62	829.87	820.41	78.85
Chaetodipus spinatus	86.61	1,302.89	1,392.54	651.03	1,392.54	1,392.54	903.14
Peromyscus eva	1,345.34	1,050.28	1,098.43	1,097.39	1,095.74	1,096.99	1,099.00
Sky island	1,392.54
Protected area	1,124.50

General circulation models: CCSM4 (^{Vertenstein et al. 2016}), HadGEM2-ES (^{Jones et al. 2011}), and MPI-ESM-LR (^{Giorgetta et al. 2013}).

Discussion

In the Sierra La Laguna Biosphere Reserve, there are no vehicle roads to reach the oak-pine forest; a private road reaches up to an elevation of 1,220 meters but allows no access to the public. Public vehicular accesses are located at the foothills of the mountain range up to 620 masl. The forest can only be accessed by walking through five specific points: La Burrera, San Dionisio, La Zorra, La Victoria, and San Pedro del Frijolar, through paths running across approximately 900 meters of elevation with very steep slopes. There are three points controlled by park rangers: two in the accesses most frequently used by visitors (La Burrera and San Dionisio) and a third at the destination site, the park ranger’s hut (^{Conanp 2015}).

The only regular visitors to the reserve are park rangers and forest fire brigades; property and land owners visit the reserve occasionally to conduct monitoring and surveillance activities in the areas granted to them. In some seasons of the year, small groups of visitors register with park rangers; the activities and camping sites are restricted by PNA regulations that visitors meet. Sierra La Laguna is an area where the extraction of forest materials is prohibited, including dead wood, so there is neither tree cutting nor firewood collection. Also, there are no human settlements above ~600 masl, except for the forest station in La Laguna (for forest guards) and a hut owned by the Centro de Investigaciones Biológicas del Noroeste at Palo Extraño. Both facilities are for temporary use only and are reached by walking an average time of six and eight hours, respectively. Most of the human settlements within the reserve (around 65) are located between 400 and 600 masl and are single-family houses, with a very low percentage of permanent households. Most of these rural households are registered as inhabited (^{INEGI 2020}).

Figure 2 Area and elevations with suitable climatic conditions for characteristic species of the sky island of Sierra La Laguna under climatic change scenarios. Rows show the increments of temperature and columns the general circulation models used in each case. The area representing the sky island is shown with a black outline, where the three characteristic species of trees (Pinus cembroides lagunae, Quercus brandegeei, and Q. devia) are currently distributed. Gray represents the suitable climatic area with climatic change scenarios for Q. brandegeei. Black represents the suitable climatic area with climatic change scenarios for two species: Q. brandegeei and Q. devia. Pinus cembroides lagunae is missing because this species lost its climatic suitability in all the climatic change scenarios).

There are no agricultural activities associated with the forest. Also, there is no goat or sheep farming, and bovine cattle farming is minimal; some feral farm animals have been recorded, which have escaped from extensive cattle raising carried out in the ranches located at lower elevations.

Results of our niche models show that the plant species typical of the oak-pine forest will face a decrease in their areas of optimal climatic conditions under temperature rises of 1.5 °C and 4.4 °C, projected from the three general circulation models. In all scenarios, Pinus cembroides lagunae loses the climatic suitability conditions that allow it to survive. The results of the model for Pinus show a reduction of its areas with optimal climatic conditions. This means that the expected recruitment of Pinus will be lower than its mortality rate, leading to a negative demographic trend; thus, the total number of Pinus individuals would decline gradually through time, leading to the increasing isolation of mature individuals until their ultimate disappearance. Although the models for Q. devia and Q. brandegeei suggest areas with climatic suitability for the different temperature-rise scenarios, the increase in global temperature will affect these species by reducing the area climatically suitable for their survival and reproduction. The results generally project that, in the short term, the vegetation will evolve from an oak-pine forest to an oak forest and then will entirely disappear. The historical records of Peromyscus truei lagunae and Sorex ornatus lagunae associate these species with sites where P. c. lagunae and Q. devia predominate (^{Woloszyn 1985}). However, there is a high probability that these two tree species will lack the conditions of climatic suitability allowing them to survive if temperature rises as much as 1.5 °C and 4.4 °C; therefore, the species associated with them will certainly be highly affected.

It has been shown that suitable climatic conditions for xeric species will expand in area, reaching elevations where more temperate conditions currently exist (^{Monroy-Gamboa et al. 2021}), so P. eva may populate the area where P. t. lagunae currently thrives.

The analysis of species associated with desert ecosystems shows an expansion of the area of distribution and elevational range, so the overall modeling suggests the replacement of forest species by species with xeric characteristics. Chaetodipus rudinoris and C. spinatus, species that are characteristic and closely associated with the desert, broaden their potential elevational range because niche models project the expansion of areas with xeric climates; this implies that these species will gradually colonize higher elevations and replace the species that inhabit current forests.

Worldwide, the five years with the highest temperatures since 1990 have been recorded from 2015, with 2020 being the year with the second-highest temperature. Indeed, temperature has increased by 1.25 °C, i. e., we have nearly reached the 1.5 °C rise that was formerly projected to occur not before 2050 (^{Ripple et al. 2021}); it has now been envisaged that limiting the temperature rise to even 2 °C will be an unattainable goal (^{IPCC 2021}). These facts, combined with the virtually absent local anthropic influence on the environment and the results of boreal plant species showing a collapse and the expansion of xeric mammals, allow hypothesizing that forest mammals such as S. o. lagunae and P. t. lagunae are undergoing an apparently irreversible local extinction process directly resulting from a climate change effect that causes variations in environmental parameters. In the present case, these will not be favorable for the oak-pine forest and will likely cause its extinction in the short term.

The results obtained indicate that even for an area characterized by restricted access and with low or no anthropogenic impact, the 1.5 °C and 4.4 °C temperature-rise scenarios will directly impact the oak-pine forest. Changes in the forest as a vegetation type will have an immediate impact on the associated fauna. The results of our analyses point to the possibility of local extinctions of P. t. lagunae and S. o. lagunae, mammal populations that are endemic to this sky island associated with different historical and climatic processes in the Baja California peninsula. The changes in climate that previously occurred historically have been of lower intensity and over longer periods of time, allowing these species to survive. By contrast, the current climate change is occurring faster than the capacity of these species to adapt; seemingly, the current rise in temperature driven by anthropic causes will inevitably lead to the local extinction of these species.

Acknowledgments

AGM-G thanks the Comisión Nacional de Ciencia y Tecnología (CONACyT) for the post-doctoral fellowship at the Centro de Investigaciones Biológicas del Noroeste, S.C. (CVU 206047). LC-S thanks CONACyT for the doctoral fellowship (337421). M. E. Sánchez-Salazar translated the manuscript into English.

Literature Cited

Ackerly, D. D., et al. 2010. The geography of climate change: implications for conservation biogeography. Diversity and Distributions 16:476-487. [ Links ]

Aguado, O., and T. Escalante. 2015. Cambios en los patrones de endemismo de los mamíferos terrestres de México por el calentamiento global. Revista Mexicana de Biodiversidad 86:99-110. [ Links ]

Álvarez-Cárdenas, S., P. Galina-Tessaro, A. González-Romero, and A. Ortega-Rubio. 1988. Herpetofauna. Pp. 167-184, in La Sierra de La Laguna de Baja California Sur (Arriaga, L., and A. Ortega, eds.). Centro de Investigaciones Biológicas del Noroeste, S. C. La Paz, México. [ Links ]

Bezaury-Creel, J. D., and D. Gutiérrez-Carbonell. 2009. Áreas naturales protegidas y desarrollo social en México. Pp. 385-431, in Capital natural de México. Vol. II: Estado de conservación y tendencias de cambio (Dirzo, R., R. González, and I. March, coords.). Comisión Nacional para el Conocimiento y Uso de la Biodiversidad. Distrito Federal, México. [ Links ]

Cahill, A. E., et al. 2013. How does climate change cause extinction? Proceedings of the Royal Society B: Biological Sciences 280:20121890. [ Links ]

Convenio sobre la Diversidad Biológica (CDB). 2018. La diversidad biológica y la Agenda 2030 para el Desarrollo Sostenible. Nota técnica. Convenio sobre la Diversidad Biológica, Organización de las Naciones Unidas para la Alimentación y la Agricultura, Banco Mundial, Programa de las Naciones Unidas para el Medio Ambiente. Québec, Canadá. [ Links ]

Comisión Nacional de Áreas Naturales Protegidas (Conanp). 2015. Programa de uso público de la Reserva de la Biosfera Sierra La Laguna. Comisión Nacional de áreas Naturales Protegidas. Dirección Regional Península de Baja California y Pacífico Norte. Dirección de la Reserva de la Biosfera Sierra La Laguna. Baja California Sur, México. [ Links ]

Comisión Nacional de Áreas Naturales Protegidas (Conanp). 2019. Áreas Naturales Protegidas decretadas. http://sig.conanp.gob.mx/website/pagsig/datos_anp.htm Consulted on 10 June 2021. [ Links ]

Cortés-Calva, P. 2012. Importancia de la mastofauna de la Reserva de la Biosfera Sierra de La Laguna. Pp. 163-181, in Evaluación de la reserva de la Biosfera Sierra de La Laguna, Baja California Sur (Ortega-Rubio, A., M. Lagunas-Vázques, and L. F. Beltrán-Morales, eds.) Centro de Investigaciones Biológicas del Noroeste, S. C. Baja California Sur, México. [ Links ]

Dormann, C. F., et al. 2013. Collinearity: a review of methods to deal with it and a simulation study evaluating their performance. Ecography 36:27-46. [ Links ]

Elith, J., and J. R. Leathwick. 2009. Species distribution models: ecological explanation and prediction across space and time. Annual Review of Ecology, Evolution, and Systematics 40:677-697. [ Links ]

Giorgetta, M. A., et al. 2013. Climate and carbon cycle changes from 1850 to 2100 in MPI-ESM simulations for the Coupled Model Intercomparison Project phase 5. Journal of Advances in Modeling Earth Systems 5:572-597. [ Links ]

Grimm, N. B., et al. 2008. Global change and the ecology of cities. Science 319:756-760. [ Links ]

Griscom, B. W., et al. 2017. Natural climate solutions. Proceedings of the National Academy of Sciences of the United States of America 114:11645-11650. [ Links ]

Instituto Nacional de Estadística, Geografía e Información (INEGI). 2020. México en cifras. https://www.inegi.org.mx/app/areasgeograficas . Consulted on 12 June 2021. [ Links ]

Intergovernmental Panel on Climate Change (IPCC). 2021. Climate Change 2021: The physical science basis. Contribution of working group 1 to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change (Masson-Delmotte, V., et al., eds.). Cambridge University Press. Cambridge, United Kingdom. https://www.ipcc.ch/report/ar6/wg1/downloads/report/IPCC_AR6_WGI_Full_Report.pdf . Consulted on 10 August 2021. [ Links ]

Jones, C. D. J., et al. 2011. The HadGEM2-ES implementation of CMPI5 centennial simulations. Geoscientific Model Devevelopment 4:543-570. [ Links ]

Mas, J.-F., and A. Flamenco. 2011. Modelación de los cambios de coberturas/uso del suelo en una región tropical de México. GeoTrópico 5:1-24. [ Links ]

Merriam-Webster, A. 1961. Webster’s New Practical Dictionary. G & C. Merriam Co. Publishers. Springfield, U.S.A. [ Links ]

Monroy-Gamboa, A. G., L. Cab-Sulub, M. C. Lavariega, and S. T. Álvarez-Castañeda. 2021. Modeling biodiversity changes and conservation issues in a desert sky island. Journal of Arid Environments 89:1-14. [ Links ]

Ochoa-Ochoa, L., and C. A. Ríos-Muñoz. 2019. Estimación de adecuabilidad de especies en ambientes antropizados desde el enfoque del modelo de nicho. Pp. 345-362, in Antropización: primer análisis integral (Ornelas-García, C. P., F. Álvarez, and A. L. Wegier, eds.). Red Temática de Fauna Nativa en Ambientes Antropizados - Consejo Nacional de Ciencia y Tecnología, Instituto de Biología - Universidad Nacional Autónoma de México. Ciudad de México, México. [ Links ]

Osborne, M. J., S. J. Cordova, A. C. Cameron, and T. F. Turner. 2019. Isolation by elevation: mitochondrial divergence among sky island populations of Sacramento Mountain salamander (Aneides hardii). Conservation Genetics 20:545-556. [ Links ]

Pawar, S., et al. 2007. Conservation assessment and priorization of areas in Northeast India: Priorities for amphibian and reptiles. Biological Conservation 136:346-361. [ Links ]

Peterson, A. T., et al. 2011. Ecological Niches and Geographic Distributions. Princeton University Press. New Jersey, U.S.A. [ Links ]

R Development Core Team. 2020. R: A language and environment for statistical computing. 3.6.1. R Foundation for Statistical Computing. Viena, Austria. https://www.r-project.com . Consulted on 15 February 2020. [ Links ]

Ripple, W. J., et al. 2021. World Scientists’ warning of a climate emergency 2021. BioSciencebiab 79:1-5 [ Links ]

Rodríguez-Estrella, R. 1988. Avifauna. Pp. 185-208, in La Sierra de La Laguna de Baja California Sur (Arriaga, L. , and A. Ortega, eds.). Centro de Investigaciones Biológicas del Noroeste, S. C. La Paz, México. [ Links ]

Segura-Trujillo, C., E. Aguilera-Miller, and S. T. Álvarez-Castañeda. 2012. Diversidad genética en Sierra de La Laguna, Baja California Sur, México. Pp. 221-248, in Evaluación de la Reserva de la Biosfera la Sierra La Laguna, Baja California Sur: Avances y Retos (Ortega-Rubio, A. , ed.). Centro de Investigaciones Biológicas del Noroeste. S. C. La Paz, México. [ Links ]

Vertenstein, M., et al. 2016. CCSM4.0 User’s Guide. National Center for Atmospheric Research. Colorado, U.S.A. [ Links ]

Woloszyn, D., J. C. Guemez, and B. W. Woloszyn. 1985. New locality record of La Laguna Mountain Shrew, Sorex ornatus lagunae Nelson and Goldman, 1909, in Cape Region of Baja California, Mexico. Acta Theriologica 30:157-160. [ Links ]

Zalasiewicz, J., and M. Williams. 2021. Climate change through Earth history. Pp. 49-65, in Climate change. Observed impacts on planet Earth. (Letcher T. M., ed.). Elsevier B. V. Oxford, U.K. [ Links ]

⁰Associated editor: Edward Heske

Received: August 17, 2021; Revised: October 11, 2021; Accepted: October 18, 2021

^*Corresponding author: ), sticul@cibnor.mx

This is an open-access article distributed under the terms of the Creative Commons Attribution License