Hostname: page-component-8448b6f56d-c4f8m Total loading time: 0 Render date: 2024-04-18T23:46:46.000Z Has data issue: false hasContentIssue false
  • English
  • Français

Setting conservation priorities for the Moroccan herpetofauna: the utility of regional red lists

Published online by Cambridge University Press:  14 October 2010

Juan M. Pleguezuelos ,
José C. Brito ,
Soumía Fahd ,
Mónica Feriche ,
José A. Mateo ,
Gregorio Moreno-Rueda ,
Ricardo Reques  and
Xavier Santos
Juan M. Pleguezuelos*
Affiliation:
Departamento de Biología Animal, Facultad de Ciencias, Universidad de Granada, E-18071 Granada, Spain.
José C. Brito
Affiliation:
CIBIO, Instituto de Ciências Agrárias Vairao, Vairao, Portugal
Soumía Fahd
Affiliation:
Département de Biologie, Faculté des Sciences, Université Abdelmalek Essaddi, Tetuan, Morocco
Mónica Feriche
Affiliation:
Departamento de Biología Animal, Facultad de Ciencias, Universidad de Granada, E-18071 Granada, Spain.
José A. Mateo
Affiliation:
Lagartario La Gomera, Valle Gran Rey—La Gomera (S/C Tenerife), Spain
Gregorio Moreno-Rueda
Affiliation:
Departamento de Biología Animal, Facultad de Ciencias, Universidad de Granada, E-18071 Granada, Spain.
Ricardo Reques
Affiliation:
Estación Biológica de Doñana, CSIC, Seville, Spain
Xavier Santos
Affiliation:
Departament de Biologia Animal, Universitat de Barcelona, Spain
*
Departamento de Biología Animal, Facultad de Ciencias, Universidad de Granada, E-18071 Granada, Spain. E-mail juanple@ugr.es
Rights & Permissions [Opens in a new window]

Abstract

We assess the national conservation status of the amphibians and reptiles of Morocco by applying the IUCN Red List Criteria at the national level and assess its utility as a planning tool to establish regional priorities for conservation. We rely on the accessory data accompanying regional red lists, mainly distribution range and habitats used by, and threats affecting, species of conservation concern. We also correlated some natural history traits to examine the nature and causes of the risk of extinction. With 13 species of amphibians (31% regionally threatened) and 99 species of reptiles (14% regionally threatened), Morocco is one of the Mediterranean countries with the highest diversity of herpetofauna, mainly because of the high percentage of endemism (amphibians 31%, reptiles 24%). The relative frequencies of threatened species were found to be contingent on both taxonomic group and habitat. The overwhelming importance of the threats of small range and number of habitats used by species is different from the threats to the same species at the global level; this demonstrates the usefulness of national or regional analyses of conservation status for setting conservation priorities. The importance of regional assessment derives from the fact that the boundaries set for conservation management are mainly political rather than biogeographical.

Keywords

AmphibiansconservationcrocodilesMoroccoherpetofaunaRed Listregional red listsreptiles
Type
Methods and tools
Information
Oryx , Volume 44 , Issue 4 , October 2010 , pp. 501 - 508
Copyright
Copyright © Fauna & Flora International 2010

Introduction

The conservation status of species is one of the most widely used indicators for assessing an ecosystem’s wealth (Butchart et al., Reference Butchart, Akcakaya, Kennedy and Hilton-Taylor2006), and the IUCN Red List of Threatened Species (IUCN, 2010b) is widely recognized as the most comprehensive way to evaluate conservation status (Rodrigues et al., Reference Rodrigues, Pilgrim, Lamoreux, Hoffmann and Brooks2006; Miller et al., Reference Miller, Rodríguez, Aniskowicz-Fowler, Bambaradeniya, Boles and Eaton2007). The Red List, although with several limitations (Possingham et al., Reference Possingham, Andelman, Burgman, Medellin, Master and Keith2002), has become an increasingly powerful tool in setting priorities for the allocation of effort and funds for biodiversity conservation (Trousdale & Gregory, Reference Trousdale and Gregory2004). In addition, the Red List Criteria (IUCN, 2008), although designed to be applied at a global scale, have inspired several authorities to apply the procedure nationally (Pinchera & Boitani, Reference Pinchera and Boitani1997; Eaton et al., Reference Eaton, Gregory, Noble, Robinson, Hughes and Procter2005). Assessment for national red lists could be useful because it provides the global Red List with valuable local information (Gärdenfors et al., Reference Gärdenfors, Hilton-Taylor, Mace and Rodríguez2001), it is vital to conservation globally (Rodríguez et al., Reference Rodríguez, Ashenfelter, Rojas-Suárez, Garcia-Fernández, Suárez and Dobson2000), and the use of standardized criteria, adapted from the IUCN Red List Criteria, offers the possibility of universally comparable assessments (Miller et al., Reference Miller, Rodríguez, Aniskowicz-Fowler, Bambaradeniya, Boles and Eaton2007). Despite the interest in constructing regional red lists, however, there has been limited testing of this application (Gärdenfors, Reference Gärdenfors2001) or of the comparison between lists at the national and global levels (but see Milner-Gulland et al., Reference Milner-Gulland, Kreuzberg-Mukhina, Grebot, Ling, Bykova and Abdusalamov2006). Because of lack of staff or funds assessment of the national conservation status of plants and animals has failed, particularly in developing countries (Ascher & Healy, Reference Ascher and Healy1990). However, some of these countries harbour the most important biodiversity hotspots (Myers et al., Reference Myers, Mittermeier, Mittermeier, da Fonseca and Kent2000) and, because of socio-economic constraints, have many threatened species (Hoffmann, Reference Hoffmann2004).

The conservation status of the amphibians and reptiles of the Mediterranean Basin has been assessed at the global level (Cox et al., Reference Cox, Chanson and Stuart2006) but the herpetofauna of Morocco exhibit some characteristics that merit particular attention. Compared to other Mediterranean countries Morocco has a high diversity of terrestrial reptile species, the highest percentage of endemic reptile species, and the highest number of European relict reptile species. Morocco also harbours centres of diversity of some reptile genera (Acanthodactylus, Chalcides and Blanus).

The primary function of the IUCN Red List is to assess the extinction risk of species globally (IUCN, 2008). The data presented in the Red List include information collected to support the assessments (distribution and habitats of, and threats to, the taxa assessed), and this information provides a baseline for setting conservation priorities (Rodrigues et al., Reference Rodrigues, Pilgrim, Lamoreux, Hoffmann and Brooks2006). Using this information for summarizing biological characteristics of species at risk, key habitats for conservation, and more generalized threats, would address one of the shortfalls of the IUCN Red List, which is its lack of suitability for setting recovery actions for the greatest number of species and habitats (Noss, Reference Noss2000). Analyses within the geopolitical limits of a country are useful (Czech & Krausman, Reference Czech and Krausman1997) because most conservation decisions and budgets are planned independently by country (Rodrigues & Gaston, Reference Rodrigues and Gaston2002; Samways, Reference Samways2003).

We explored the data gathered during the process of performing a national red list of the amphibians and reptiles of Morocco to determine (1) the extinction risk of Moroccan amphibians and reptiles at the national level, and to identify (2) the groups facing the highest extinction risk, (3) the habitats that hold the most threatened species, (4) the most significant threats, and (5) the relationships between the threatened status of species and their natural history. We also sought to establish whether threatened Moroccan species share some of the traits reported to predict species vulnerability (Webb et al., Reference Webb, Brook and Shine2002). This analysis will assist conservation planning in Morocco and provide information about two groups of terrestrial vertebrates frequently neglected in conservation policy and consistently underrepresented in networks of protected areas (Milner-Gulland et al., Reference Milner-Gulland, Kreuzberg-Mukhina, Grebot, Ling, Bykova and Abdusalamov2006).

Methods

We assessed the conservation status of the 13 amphibian species and 101 reptile species (99 extant plus two Regionally Extinct) known to occur in Morocco (Western Sahara included; total area 710,850 km2). The initial species list was compiled from two distribution atlases that cover the area entirely (Bons & Geniez, Reference Bons and Geniez1996) or partially (Geniez et al., Reference Geniez, Mateo, Geniez and Pether2004), although we considered recent changes in taxonomy (Appendix 1). The complete list of species is presented in Appendix 2. Reptiles, a paraphyletic group, is considered here in its traditional sense. To evaluate extinction risk we used the Red List Criteria (IUCN, 2008) and followed the guidelines for its application at the regional level (IUCN, 2003). These guidelines are established (Gärdenfors, Reference Gärdenfors2001; Gärdenfors et al., Reference Gärdenfors, Hilton-Taylor, Mace and Rodríguez2001; Miller et al., Reference Miller, Rodríguez, Aniskowicz-Fowler, Bambaradeniya, Boles and Eaton2007) and rely on three premises: (1) if the taxon is endemic to the region or if the regional population of a species to be assessed is isolated from conspecific populations outside the region, the criteria must be used without modification; (2) if the population within the region could undergo a ‘rescue effect’ from populations outside the region, the resulting category must be downgraded; (3) if the population within the region is a demographic sink and the extra-regional source is expected to decrease or cannot perform a rescue effect, the extinction risk of the regional population may be upgraded. In Appendix 2 we followed the Habitats Authority File and the Threats Type Authority File of the IUCN (IUCN, 2010a). A species is considered Threatened when it appeared listed in one of the IUCN categories of Vulnerable, Endangered or Critically Endangered, according to the criteria of Population Reduction (A), Geographic Range (B), Small Population Size and Decline (C) and Very Small or Restricted Population (D; IUCN, 2008).

For a regional assessment it is important to consider the proportion of the global distribution that occurs within the region (IUCN, 2003), and this was estimated for Morocco from Cox et al. (Reference Cox, Chanson and Stuart2006) using the geographical information system ArcView v. 3.2 (ESRI, Redlands, USA; Appendix 2). We relied where possible on published information but also on our experience researching amphibians and reptiles in Morocco during the past 2 decades (Pearman, Reference Pearman2001). The distribution of the main habitats in Morocco was obtained from 14 months (1999–2000) of 1-km resolution data acquired by the VEGETATION sensor of the SPOT 4 satellite, delivered as multichannel daily mosaics (GLC, 2003).We made statistical comparisons (with χ2 tests) of the frequencies of categories, habitats and threats between Morocco and the Mediterranean Basin only for reptiles because of the small sample size for amphibians. Because of unbalanced sample size, expected frequencies were adjusted to the lesser sample size of the Moroccan fauna. To examine any potential relationship between natural history traits and threatened status we were constrained to those few traits available: (1) distribution breadth, assessed by the number of 1 : 50,000 Moroccan topographic sheets with a record of presence in Bons & Geniez (Reference Bons and Geniez1996), corrected with Geniez et al. (Reference Geniez, Mateo, Geniez and Pether2004); (2) number of IUCN minor habitats (the second level for habitat type in the Habitats Authority File of the IUCN; see Appendix 2); (3) body size, measured as the average snout–vent length for adults of the largest sex; (4) reproductive output, measured as mean annual number of eggs or newborn.

We compared natural history traits between threatened and non-threatened species with a Mann–Whitney U-test. To test for an association between threatened status and these predictor variables we used a generalized linear model (GLM) with a binomial distribution of errors (threatened vs non-threatened) linked to a logit function. To eliminate variables without significant effects we selected the best models using the Akaike information criterion (AIC: Burnham & Anderson, Reference Burnham and Anderson2004). As species with common ancestry are not independent, a control for phylogeny is advisable (Pagel & Harvey, Reference Pagel and Harvey1988) but the absence of phylogenies for many of the groups considered precluded an analysis by contrasts, and therefore we performed the same analysis with genus and family as statistical units (Pagel & Harvey, Reference Pagel and Harvey1988). This procedure would diminish the error because of the non-independence of the statistical units, and similar results across the taxonomic levels would suggest that they were not confounded by phylogeny.

Results

Our proposed national red list of the amphibians and reptiles of Morocco indicates that 30.8% of the 13 amphibian species and 13.9% of the 101 reptile species are threatened (Table 1, Appendix 2). Two reptile species are Regionally Extinct. Of the reptiles, 25.0% of the continental chelonians, 12.1% of the saurians, 18.5% of the snakes and none of the amphisbaenians are threatened (Table 1). The percentage endemism of Moroccan amphibians and reptiles is 30.7 and 23.8%, respectively. Of the reptile family Scincidae (with 18 species in Morocco) 33.3% are threatened and 50% endemic. All threatened species of amphibians were categorized by criteria B (geographic range) of the Red List Criteria, and for reptiles 10 of the 14 threatened species were categorized by criteria B, two by criteria A (reduction in population size) and two by criteria D (population size or area of occupancy; Appendix 2). Criteria B was used for the evaluation of 78% of the threatened species.

Comparing threatened species at the Moroccan and global scales, three amphibian species were categorized at higher risk at the regional scale, and none at lower risk, and 12 reptile species were categorized at higher risk, and three at lower risk (Appendix 2). The frequency of threat categories of reptiles differed significantly between the two geographical scales (, P < 0.001; Table 1).

Table 1 Summary of our national red list assessment of the amphibians and reptiles of Morocco, and the number of endemic species in each group, with a summary of the global status of the amphibians and reptiles of the Mediterranean Basin (from Cox et al., Reference Cox, Chanson and Stuart2006) and, for reptiles only, χ2 tests between the total numbers in each category in Morocco and the Mediterranean Basin.

1 RE, Regionally Extinct; EX, Extinct; CR, Critically Endangered; EN, Endangered; VU, Vulnerable; NT, Near Threatened; DD, Data Deficient; LC, Least Concern; **, P < 0.01

Amphibians occur in most major habitats in Morocco, and threatened species are notably present in savannah and desert habitats (Table 2). Reptiles occur in all major habitats, and there is no difference in occurrence between threatened and non-threatened species (, P = 0.98; Table 2). There is no correlation between the number of non-threatened and threatened species and habitat area (r s < 0.22 for both comparisons). The habitats in which threatened reptiles most frequently occur are scrublands and grasslands (Table 2). Threatened amphibians occur on average in fewer minor habitat types (mean = 5.0 ± SD 2.9, n = 4) than non-threatened species (mean = 13.1 ± SD 5.7, n = 9; U-test, Z = 2.08, P < 0.05), and the same is true for reptiles (mean = 3.2 ± SD 1.8, n = 14 vs mean = 5.3 ± SD 3.2, n = 87; U-test, Z = 2.44, P = 0.01; Appendix 2).

Table 2 The numbers of threatened and non-threatened species of amphibians and reptiles (with column-wise percentages in parentheses) that occur in each habitat type in Morocco (considering only major habitats from the Habitat Authority File of the IUCN, 2010b), χ2 tests between the numbers of threatened and non-threatened reptile species that occur in these habitats in Morocco (all differences are non-significant), and the area of these major habitats in Morocco, taken from the Global Land Cover 2000 Project (GLCP; see Methods). As the GLCP did not identify exactly the same habitats as the Habitat Authority File the following pairs of major habitats in the Habitat Authority File were combined for the calculation of area: grassland + savannah, desert + coastline, wetlands + artificial aquatic.

The most pervasive threats to amphibians in Morocco are habitat loss and degradation, affecting 100% of the threatened species and 69% of all species (Table 3). The primary causes of habitat loss are shifts in agricultural practices and groundwater extraction.

Table 3 Number of threatened and non-threatened amphibian species in Morocco (this study) and the Mediterranean Basin (global Red List assessment, from Cox et al., Reference Cox, Chanson and Stuart2006) affected by major threats (from the Threats Type Authority File of the IUCN; IUCN, 2010b). Note that species assessed overall as not falling into one of the IUCN threat categories may still, nevertheless, be subject to some threats.

The most pervasive threats to Moroccan reptiles are the intrinsic factors of the species, affecting 100% of the threatened species, followed by habitat loss, accidental mortality and harvesting (hunting/gathering; Table 4). The main intrinsic factors that place reptiles at risk of extinction are restricted range, low density and limited dispersal capacity. The main causes of habitat loss are the increasing surface area devoted to modern agriculture. Harvesting threatens reptile species in Morocco, mostly snakes, because of collection for traditional medicine and entertainment. Different sets of threats affected Moroccan and Mediterranean reptiles considering either all species (, P < 0.001) or only threatened species (, P < 0.001). Intrinsic factors have more impact on Moroccan than on Mediterranean reptiles, and Moroccan reptiles are less affected by habitat loss, invasive species, human disturbance and pollution (Table 4).

Table 4 Number of threatened and non-threatened reptile species in Morocco (this study), with χ2 testsFootnote 1 of differences in frequencies, and the Mediterranean Basin (global Red List assessment, from Cox et al., Reference Cox, Chanson and Stuart2006) affected by major threats (from the Threats Type Authority File of the IUCN; IUCN, 2010b), and χ2 testsFootnote 1 between between Morocco and the Mediterranean Basin for frequencies of all species and threatened species. Species assessed overall as not falling into one of the IUCN threat categories may still, nevertheless, be subject to some threats.

1ns, non-significant; *P < 0.05; **P < 0.01; ***P < 0.001

Threatened reptile species have, on average, a more restricted distribution (presence in 9.7 ± SD 11.1 topographic sheets; n = 14) than non-threatened species (58.0 ± SD 55.2, n = 85; Z = 4.3, P < 0.001) and use fewer minor habitats. There is no difference in body size (317.1 ± SD 325.6 mm snout–vent length vs 224.9 ± SD 276.4 mm snout–vent length; Z = 1.39, P = 0.2) or reproductive output (8.4 ± SD 6.6 eggs or newborn vs 8.3 ± SD 5.8 eggs or newborn; Z = 0.03, P = 0.97) between threatened and non-threatened species. In the GLMs distribution range was not included as a predictor variable because it was frequently used as a criterion to evaluate the conservation status and its inclusion would therefore be tautological. Four models were statistically significant, all of them including the number of habitats. The best model included number of habitats and body size but the effect of body size was not significant (Wald statistic = 2.78, P = 0.10). The second best model only included the number of habitats but the AIC value increased only marginally (Table 5). The same results were obtained at the genus and family levels (the latter was non-significant, probably because of small sample size; Table 5). These results suggest that the number of habitats in which a species occurs is an important predictor of the conservation status of reptiles.

Table 5 List of the best GLMs, after 200 replications, of the influence of natural history traits at the levels of species, genus and family (the predictors) on threatened status (the dependent variable). Predictors at the species level are: body size, expressed as mean snout–vent length (mm) of the largest sex; habitat, number of minor habitats used by the species; output, mean annual reproductive output of the species (number of eggs or newborn). Predictor variables at the genus and family levels are the means of the scores of these variables at the species and genus levels, respectively. Variables with a significant effect are in bold. For more details, see Methods section.

Discussion

The number of amphibian species in Morocco is low but similar to other African countries north of the Sahara (Schleich et al., Reference Schleich, Kästle and Kabish1996). However, the species richness of Moroccan reptiles is one of the highest amongst the countries of the Mediterranean Basin and similar to that of larger countries such as Algeria and Egypt. A number of reasons account for this and the presence of the highest mountains in North Africa (the High Atlas rises to 4,167 m) is one of the most important. Morocco is traversed by four mountain ranges (from north to south, the Riff, Middle Atlas, High Atlas and Anti-Atlas); the two northernmost are refuges for relict species of European origin and all harbour species endemic to the mountains. As a result, endemism amongst Moroccan reptiles is high for a country embedded in a large continent, and is comparable to that observed on islands. Globally, highlands have been identified as important areas of vertebrate diversity (Rahbek & Graves, Reference Rahbek and Graves2001). Other factors that contribute to the high species richness in Morocco are the former connection of north-west Africa with Europe, through what is now the Strait of Gibraltar, the Saharan habitats in the south, and the Macaronesian coastal corridor of the Western Sahara through which some Sahelian species reach the south-west of the country.

The percentage of Moroccan amphibians that are regionally threatened is higher than that of Mediterranean amphibians that are globally threatened (25.5%; Cox et al., Reference Cox, Chanson and Stuart2006) but approximately the same as the overall percentage of globally threatened amphibians (32.5%; Stuart et al., Reference Stuart, Chanson, Cox, Young, Rodrigues, Fischman and Waller2004). The percentage of Moroccan reptiles that are regionally threatened is similar to that of Mediterranean reptiles that are globally threatened (12.3%; Cox et al., Reference Cox, Chanson and Stuart2006), suggesting that the overall conservation status of the Moroccan reptile fauna is similar to that observed in the Mediterranean Basin.

Species of the family Scincidae, however, are particularly at risk, and this family includes the only species in Morocco on the brink of extinction. Regionally some amphibian and reptile species are in a category of greater extinction risk, and some reptiles are in a category of lower risk, compared to globally. In regional red list assessments it is usual for some species to fall into a category of higher extinction risk compared to the IUCN Red List (Keller et al., Reference Keller, Zbinden, Schmid and Volet2005); widely distributed and globally abundant species can be regionally restricted and subject to a demographic sink without the possibility of extra-regional populations to perform a rescue effect (Eaton et al., Reference Eaton, Gregory, Noble, Robinson, Hughes and Procter2005). A lower category of extinction risk at a regional level is less common (IUCN, 2003).

With respect to habitat use, some threatened amphibians occur in desert and savannah. We were unable to measure habitat areas within protected areas because of the lack of accurate maps but according to data in the Executive Program for Protected Areas in Morocco (Ministère de l’Agriculture, 1994) these two habitats are not well represented in the current network of protected areas. Arid habitats in the south of Morocco (scrubland, desert and savannah) are key habitats for threatened amphibians and reptiles and are conservation priorities. These areas have been neglected in demarcation of protected areas, perhaps because of the low biodiversity of endothermic vertebrates or game species there (Milner-Gulland et al., Reference Milner-Gulland, Kreuzberg-Mukhina, Grebot, Ling, Bykova and Abdusalamov2006). A good example of such areas are the small dune fields throughout the Taffilat region (i.e. Erg Chebbi), which have a high diversity of reptiles but are threatened by off-road recreational driving and construction of tourism facilities.

Most of the generalist amphibian and reptile species of Morocco are not threatened. A broad pattern of habitat use is considered an important characteristic in determining the ability of species to remain in an area following diverse human impacts (Santos et al., Reference Santos, Brito, Pleguezuelos and Llorente2007; see Attum et al., Reference Attum, Eason, Cobbs and Baha El Din2006, for a particular case). The link between conservation concern and habitat specialization of the herpetofauna of Morocco, however, derives from the fact that many of the threatened species occupy marginal habitats, especially those at the southern or northern limits of their distribution. Conservation of the diversity of the herpetofauna of Morocco requires identification of these marginal habitats, especially in the wet mountain habitats in the north and subtropical Macaronesian scrublands in the south.

The distribution of threatened species can be determined at any scale by an interaction between the biological mechanisms promoting species diversity and the mechanisms (mostly anthropogenic) eroding that diversity (Orme et al., Reference Orme, Davies, Burgess, Eigenbrod, Pickup and Olson2005). The major threat to Moroccan amphibians is habitat loss and degradation, and this is also the most pervasive threat to biodiversity generally (Baillie et al., Reference Baillie, Hilton-Taylor and Stuart2004). In Morocco many wetlands have been lost through drainage (Ramdani et al., Reference Ramdani, Flower, Elkhiati, Kraïem, Fathi, Birks and Patrick2001), with implications for amphibians, which have poor dispersal ability. For reptiles it is the species’ intrinsic factors that result in a high percentage being of conservation concern, suggesting that humans have few negative influences on their conservation. The restricted range of some species is the most pervasive threat factor for threatened reptiles, contrary to that observed in the wider Mediterranean Basin (Cox et al., Reference Cox, Chanson and Stuart2006). The number of habitats in which these species occur is probably a surrogate for a variable not included in the model, species’ range. This is not the spurious result of analysing a large country without comprehensive data for species’ chorology but the consequence of a significant portion of the diversity comprising species at the limit of their ecological requirements and distribution (Gaston, Reference Gaston2003). Morocco, because of its geographical position, contains faunal elements of both the Aethiopic and Palaearctic but some of the species are represented only by scattered and/or small populations. This is the main reason that the number of habitats and restricted range are of overwhelming importance as intrinsic factors threatening many Moroccan reptiles.

Although assignation of a high risk status to species at the edge of their range could be a shortcoming of regional red lists when assessing mobile vertebrates such as birds (Eaton et al., Reference Eaton, Gregory, Noble, Robinson, Hughes and Procter2005), we believe that this is not the case for reptile populations at the edge of their range because of their lower capacity for dispersal. Unlike amphibians, harvesting, persecution and human disturbance have an impact on reptiles, especially on some of the venomous snake species sought for snake charming and traditional medicine.

We believe this regional red list for Moroccan herpetofauna has more predictive power than the IUCN Red List in priority ranking for national conservation action, providing data for prioritizing habitats and areas for conservation (Rodrigues et al., Reference Rodrigues, Pilgrim, Lamoreux, Hoffmann and Brooks2006). Because of its high endemism Morocco makes a disproportionately large contribution to the diversity of the herpetofauna of the Mediterranean Basin. The reptiles of Morocco are also relatively well conserved compared to other Western Mediterranean countries for which this group has been assessed nationally, such as Spain (Pleguezuelos et al., Reference Pleguezuelos, Márquez and Lizana2002) and Portugal (Cabral, Reference Cabral2005). The regional conservation assessment of Moroccan amphibians and reptiles was different from the assessment of the same species at the global level at the rank of habitats that harbour threatened species and the major threats affecting these species. Although national boundaries are often irrelevant to populations, our national assessment indicates the usefulness of regional red list analyses for detecting conservation priorities in smaller regions (IUCN, 2003). Our results also demonstrate that the current network of protected areas in Morocco does not appear to fulfil the conservation requirements of the country’s threatened amphibians and reptiles.

Acknowledgements

We thank the many people who helped in the field. During the development of this study JCB had a contract from Fundaçao para a Ciência e Tecnologia (Portugal), and GMR was funded for a postdoctoral fellowship by the Spanish government.

Appendices

The appendices for this article are available online at http://journals.cambridge.org

Biographical sketches

The authors come from seven research institutions and three countries, including Morocco. During the last 10 years they have collaborated 0n projects on the ecology, phylogeography and conservation biology of western Mediterranean amphibians and reptiles. The authors have extensive expertise in the distribution and ecology of the herpetofauna of Morocco, having organized and participated in at least 20 scientific expeditions in the country. Some of the authors have participated in red listing analyses at global or regional levels. Collaboratively, the authors seek to investigate the threats to the herpetofauna and improve the conservation of these species in Morocco.

Footnotes

This paper contains supplementary material that can be found online at http://journals.cambridge.org

*

Also at: KLIVV, Österreischische Academie der Wissenschaften, Vienna, Austria

References

Arnold, E.N., Arribas, O. & Carranza, S. (2007) Systematics of the Palaearctic and oriental lizard tribe Lacertini (Squamata: Lacertidae: Lacertinae) with descriptions of eight new genera. Zootaxa, 1430, 1–86.CrossRefGoogle Scholar
Arntzen, J.W. & García-Paris, M. (1995) Morphological and allozyme studies of midwife toads (genus Alytes), including the description of two new taxa from Spain. Contributions to Zoology, 65, 5–34.Google Scholar
Ascher, W. & Healy, R. (1990) Natural Resource Policy-making in Developing Countries. Duke University Press, Durham, USA.Google Scholar
Attum, O., Eason, P., Cobbs, G. & Baha El Din, S.M. (2006) Response of a desert lizard community to habitat degradation: do ideas about habitat specialists/generalists hold? Biological Conservation, 133, 52–62.CrossRefGoogle Scholar
Baillie, J.E.M., Hilton-Taylor, C. & Stuart, S.N. (eds) (2004) 2004 IUCN Red List of Threatened Species. A Global Species Assessment. IUCN, Gland, Switzerland, and Cambridge, UK.Google Scholar
Barata, M., Harris, D.J. & Castilho, R. (2008) Comparative phylogeography of north-west African Natrix maura (Serpentes: Colubridae) inferred from mtDNA sequences. African Zoology, 43, 1–7.CrossRefGoogle Scholar
Böhme, W., Schmitz, G. & Messer, J. (1989) Erster Nachweis der Gattung Telescopus für dier Schlangenfauna Marokkos. Salamandra, 25, 3–76.Google Scholar
Bons, J. & Geniez, P. (1996) Amphibiens et Reptiles du Maroc. Asociación Herpetológica Española, Barcelona, Spain.Google Scholar
Burnham, K.P. & Anderson, D.R. (2004) Multimodel inference: understanding AIC and BIC in model selection. Sociological Methods & Research, 33, 261–304.CrossRefGoogle Scholar
Butchart, S.H.M., Akcakaya, H.R., Kennedy, E. & Hilton-Taylor, C. (2006) Biodiversity indicators based on trends in conservation status: strengths of the IUCN Red List Index. Conservation Biology, 20, 579–581.CrossRefGoogle ScholarPubMed
Cabral, M.J. (2005) Livro Vermelho dos Vertebrados de Portugal. Instituo de Conservacao de Natureza, Lisbon, Portugal.Google Scholar
Caputo, V. & Mellado, J. (1992) A new species of Chalcides (Reptilia: Scincidae) from north-eastern Morocco. Bolletino Zoologia, 59, 335–342.CrossRefGoogle Scholar
Carranza, S. & Arnold, E.N. (2006) Systematics, biogeography, and evolution of Hemidactylus geckos (Reptilia: Gekkonidae) elucidated using mitochondrial DNA sequences. Molecular Phylogenetics and Evolution, 38, 531–545.CrossRefGoogle ScholarPubMed
Carranza, S., Arnold, E.N., Geniez, P., Roca, J. & Mateo, J.A. (2008) Radiation, multiple dispersal and parallelism in the skinks, Chalcides and Sphenops (Squamata: Scincidae), with comments on Scincus and Scincopus and the age of the Sahara Desert. Molecular Phylogenetics and Evolution, 46, 1071–1094.CrossRefGoogle ScholarPubMed
Carranza, S., Arnold, E.N., Mateo, J.A. & Geniez, P. (2002) Relationships and evolution of the North African geckos, Geckonia and Tarentola (Reptilia: Gekkonidae), based on mitochondrial and nuclear DNA sequences. Molecular Phylogenetics and Evolution, 23, 244–256.CrossRefGoogle ScholarPubMed
Carranza, S., Arnold, E.N., Wade, E. & Fahd, S. (2004) Phylogeography of the false smooth snakes, Macroprotodon (Serpentes, Colubridae): mitochondrial DNA sequences show European populations arrived recently from Northwest Africa. Molecular Phylogenetics and Evolution, 33, 523–532.CrossRefGoogle ScholarPubMed
Cox, N., Chanson, J. & Stuart, S. (compilers) (2006) The Status and Distribution of Reptiles and Amphibians of the Mediterranean Basin. IUCN, Gland, Switzerland.CrossRefGoogle Scholar
Czech, B. & Krausman, P.R. (1997) Distribution and causation of species endangerment in the United States. Science, 277, 1116–1117.CrossRefGoogle Scholar
Eaton, M.A., Gregory, R.D., Noble, D.G., Robinson, J.A., Hughes, J., Procter, D. et al. (2005) Regional IUCN red listing: the process as applied to birds in the United Kingdom. Conservation Biology, 19, 1557–1570.CrossRefGoogle Scholar
Frost, D.R., Grant, T., Faivovich, J., Bain, R.H., Haas, A., Haddad, C.F.B. et al. (2006) The amphibian tree of life. Bulletin American Museum of Natural History, 297, 1–370.CrossRefGoogle Scholar
Gärdenfors, U. (2001) Classifying threatened species at national versus global level. Trends in Ecology & Evolution, 16, 511–516.CrossRefGoogle Scholar
Gärdenfors, U., Hilton-Taylor, C., Mace, G.M. & Rodríguez, J.P. (2001) The application of IUCN Red List Criteria at regional levels. Conservation Biology, 15, 1206–1212.CrossRefGoogle Scholar
Gaston, K.J. (2003) The Structure and Dynamics of Geographic Ranges. Oxford University Press, Oxford, UK.CrossRefGoogle Scholar
Geniez, P., Mateo, J.A., Geniez, M. & Pether, J. (2004) The Amphibians and Reptiles of the Western Sahara. Chimaira, Frankfurt and Main, Germany.Google Scholar
GLC (Global Land Cover) (2003) The Global Land Cover for the Year 2000. Http://www-gvm.jrc.it/glc2000/defaultGLC2000.htm [accessed 30 September 2008].Google Scholar
Guicking, D., Joger, U. & Wink, M. (2008) Molecular phylogeography of the viperine snake Natrix maura (Serpentes: Colubridae): evidence for strong intraspecific differentiation. Organisms Diversity & Evolution, 8, 130–145.CrossRefGoogle Scholar
Hahn, D.E. & Wallach, V. (1998) Comments on the systematics of Old World Leptotyphlops (Serpentes: Leptotyphlopidae), with description of a new species. Hamadryad, 23, 50–62.Google Scholar
Hoffmann, J.P. (2004) Social and environmental influences of endangered species: a cross-national study. Sociological Perspectives, 47, 79–107.CrossRefGoogle Scholar
IUCN (2003) Guidelines for Application of IUCN Criteria at Regional Levels (v. 3.0). IUCN Species Survival Commission, IUCN, Gland, Switzerland.Google Scholar
IUCN (2008) Guidelines for using the IUCN Red List Categories and Criteria (Version 7.0). IUCN, Gland, Switzerland.Google Scholar
IUCN (2010a) The Habitats Authority File and the Threats Type Authority File. Http://www.iucn.org/about/work/programmes/species/red_list/resources/technical_documents/authority_files/ [accessed 22 May 2010].Google Scholar
IUCN (2010b) The IUCN Red List of Threatened Species. Http://www.iucnredlist.org/ [accessed 22 May 2010].Google Scholar
Joger, U. (1991) A molecular phylogeny of agamid lizards. Copeia, 1991, 616–622.CrossRefGoogle Scholar
Keller, V., Zbinden, N., Schmid, H. & Volet, B. (2005) A case study in applying the IUCN regional guidelines for national red lists and justifications for their modification. Conservation Biology, 19, 1827–1834.CrossRefGoogle Scholar
Lenk, P., Joger, U. & Wink, M. (2001) Phylogenetic relationships among European ratsnakes of the genus Elaphe Fitzinger based on mitochondrial DNA. Amphibia–Reptilia, 22, 329–339.CrossRefGoogle Scholar
Macey, J.R., Jas, I.I., Larson, A., Tuniyev, B.S., Orlov, N. & Papenfuss, T.J. (1999) Molecular phylogenetics, tRNA evolution, and historical biogeography in anguid lizards and related taxonomic families. Molecular Phylogenetics and Evolution, 12, 250–272.CrossRefGoogle ScholarPubMed
Miller, R.M., Rodríguez, J.P., Aniskowicz-Fowler, T., Bambaradeniya, C., Boles, R., Eaton, M.A. et al. (2007) National threatened species listing based on IUCN criteria and regional guidelines: current status and future perspective. Conservation Biology, 21, 684–696.CrossRefGoogle Scholar
Milner-Gulland, E.J., Kreuzberg-Mukhina, E., Grebot, B., Ling, S., Bykova, E., Abdusalamov, I. et al. (2006) Application of IUCN red listing criteria at the regional and national levels: a case study from Central Asia. Biodiversity and Conservation, 15, 1873–1886.CrossRefGoogle Scholar
Ministère de l’Agriculture (1994) Plan Directeur des Aires protégées. Unpublished Report. Ministère de l’Agriculture, Rabat, Morocco.Google Scholar
Myers, N., Mittermeier, R.A., Mittermeier, C.C., da Fonseca, G.A. & Kent, J. (2000) Biodiversity hotspots for conservation priorities. Nature, 403, 853–858.CrossRefGoogle ScholarPubMed
Nagy, Z.T., Lawson, R., Joger, U. & Wink, M. (2004) Molecular systematics of racers, whipsnakes and relatives (Reptilia: Colubridae) using mitochondrial and nuclear markers. Journal of Zoological Systematics and Evolutionary Research, 42, 223–233.CrossRefGoogle Scholar
Noss, R.F. (2000) High-risk ecosystems as foci for conservation biodiversity and ecological integrity in ecological risk assessments. Environmental Science Policy, 3, 321–332.CrossRefGoogle Scholar
Orme, C.D.L., Davies, R.G., Burgess, M., Eigenbrod, F., Pickup, N., Olson, V.A. et al. (2005) Global hotspots of species richness are not congruent with endemism or threat. Nature, 436, 1016–1019.CrossRefGoogle ScholarPubMed
Pagel, M. & Harvey, P.H. (1988) Recent developments in the analysis of comparative data. Quarterly Review of Biology, 63, 413–440.CrossRefGoogle ScholarPubMed
Pearman, P.B. (2001) Conservation value of independently evolving units: sacred cow or testable hypothesis? Conservation Biology, 15, 780–783.CrossRefGoogle Scholar
Pinchera, F. & Boitani, L. (1997) Application to the terrestrial vertebrates of Italy of a system proposed by IUCN for a new classification of national Red List categories. Biodiversity and Conservation, 6, 959–978.CrossRefGoogle Scholar
Pleguezuelos, J.M., Márquez, R. & Lizana, M. (eds) (2002) Atlas y Libro Rojo de los Anfibios y Reptiles de España. Asociación Herpetológica Española–Ministerio de Medio Ambiente, Madrid, Spain.Google Scholar
Possingham, H.P., Andelman, S.J., Burgman, M.A., Medellin, R.A., Master, L.L. & Keith, D.A. (2002) Limits to the use of threatened species lists. Trends in Ecology & Evolution, 17, 503–507.CrossRefGoogle Scholar
Rahbek, C. & Graves, G.R. (2001) Multiscale assessment of patterns of avian species richness. Proceedings of the National Academy of Sciences of the USA, 98, 4534–4539.CrossRefGoogle ScholarPubMed
Ramdani, M., Flower, R.J., Elkhiati, N., Kraïem, M.M., Fathi, A.A., Birks, H.H. & Patrick, S.T. (2001) North African wetland lakes: characterization of nine sites included in the CASSARINA Project. Aquatic Ecology, 35, 1386–2588.Google Scholar
Rodrigues, A.S.L. & Gaston, K.J. (2002) Rarity and conservation planning across geopolitical units. Conservation Biology, 16, 674–682.CrossRefGoogle Scholar
Rodrigues, A.S.L., Pilgrim, J.D., Lamoreux, J.F., Hoffmann, M. & Brooks, T.M. (2006) The value of the IUCN Red List for conservation. Trends in Ecology & Evolution, 21, 71–76.CrossRefGoogle ScholarPubMed
Rodríguez, J.P., Ashenfelter, G., Rojas-Suárez, F., Garcia-Fernández, J.J., Suárez, L. & Dobson, A.P. (2000) Local data are vital to worldwide conservation. Nature, 403, 241.CrossRefGoogle ScholarPubMed
Samways, M.J. (2003) Marginality and national red listing of species. Biodiversity and Conservation, 12, 2523–2525.CrossRefGoogle Scholar
Santos, X., Brito, J.C., Pleguezuelos, J.M. & Llorente, G.A. (2007) Comparing Filippi and Luiselli’s 2000 method with a cartographic approach to assess the conservation status of secretive species: the case of the Iberian snake-fauna. Amphibia–Reptilia, 28, 17–23.CrossRefGoogle Scholar
Schleich, H., Kästle, W. & Kabish, K. (1996) Amphibians and Reptiles of North Africa. Koelz, Koenigstein, Germany.Google Scholar
Stuart, S.N., Chanson, J.S., Cox, N.A., Young, B.E., Rodrigues, A.S.L., Fischman, D.L. & Waller, R.W. (2004) Status and trends of amphibian declines and extinction worldwide. Science, 306, 1783–1786.CrossRefGoogle ScholarPubMed
Trousdale, W. & Gregory, R. (2004) Property evaluation and biodiversity conservation: decision support for making hard choices. Ecological Economics, 48, 279–291.CrossRefGoogle Scholar
Webb, J.K., Brook, B.W. & Shine, R. (2002) What make a species vulnerable to extinction? Comparative life-history traits of two sympatric snakes. Ecological Research, 17, 59–67.CrossRefGoogle Scholar
Weisrock, D.W., Papenfuss, T.J., Macey, J.R., Litvinvhuk, S.N., Polymeri, R., Ugurtas, I.H. et al. (2006) A molecular assessment of phylogenetic relationships and lineage accumulation rates within the family Salamandridae (Amphibia, Caudata). Molecular Phylogenetics and Evolution, 41, 368–383.CrossRefGoogle ScholarPubMed
Zangari, F., Cimmaruta, R. & Nascetti, G. (2006) Genetic relationships of the western Mediterranean painted frogs based on allozymes and mitochondrial markers: evolutionary and taxonomic inferences (Amphibia, Anura, Discoglossidae). Biological Journal of the Linnean Society, 87, 515–536.Google Scholar
Figure 0

Table 1 Summary of our national red list assessment of the amphibians and reptiles of Morocco, and the number of endemic species in each group, with a summary of the global status of the amphibians and reptiles of the Mediterranean Basin (from Cox et al., 2006) and, for reptiles only, χ2 tests between the total numbers in each category in Morocco and the Mediterranean Basin.

Figure 1

Table 2 The numbers of threatened and non-threatened species of amphibians and reptiles (with column-wise percentages in parentheses) that occur in each habitat type in Morocco (considering only major habitats from the Habitat Authority File of the IUCN, 2010b), χ2 tests between the numbers of threatened and non-threatened reptile species that occur in these habitats in Morocco (all differences are non-significant), and the area of these major habitats in Morocco, taken from the Global Land Cover 2000 Project (GLCP; see Methods). As the GLCP did not identify exactly the same habitats as the Habitat Authority File the following pairs of major habitats in the Habitat Authority File were combined for the calculation of area: grassland + savannah, desert + coastline, wetlands + artificial aquatic.

Figure 2

Table 3 Number of threatened and non-threatened amphibian species in Morocco (this study) and the Mediterranean Basin (global Red List assessment, from Cox et al., 2006) affected by major threats (from the Threats Type Authority File of the IUCN; IUCN, 2010b). Note that species assessed overall as not falling into one of the IUCN threat categories may still, nevertheless, be subject to some threats.

Figure 3

Table 4 Number of threatened and non-threatened reptile species in Morocco (this study), with χ2 tests1 of differences in frequencies, and the Mediterranean Basin (global Red List assessment, from Cox et al., 2006) affected by major threats (from the Threats Type Authority File of the IUCN; IUCN, 2010b), and χ2 tests1 between between Morocco and the Mediterranean Basin for frequencies of all species and threatened species. Species assessed overall as not falling into one of the IUCN threat categories may still, nevertheless, be subject to some threats.

Figure 4

Table 5 List of the best GLMs, after 200 replications, of the influence of natural history traits at the levels of species, genus and family (the predictors) on threatened status (the dependent variable). Predictors at the species level are: body size, expressed as mean snout–vent length (mm) of the largest sex; habitat, number of minor habitats used by the species; output, mean annual reproductive output of the species (number of eggs or newborn). Predictor variables at the genus and family levels are the means of the scores of these variables at the species and genus levels, respectively. Variables with a significant effect are in bold. For more details, see Methods section.

Supplementary material: PDF

Pleguezuelos et al. supplementary material

Pleguezuelos et al. supplementary material 1

Download Pleguezuelos et al. supplementary material(PDF)
PDF 59.9 KB