Study site

The study was conducted in ten experimental and commercial apple orchards over two years (first year: February 2011-January 2012, second year: February 2012-January 2013). These orchards are separated from each other by 20.5 km as maximum and are located in two municipalities of Asturias: Villaviciosa (43°38′55′′ N, 5°26′08′′ W) and Nava (43°21′31′′ N, 5°30′29′′ W), which are separated by 15 km. Their surface ranged from 1 to 6 ha and their altitude from 3 to 270 m a.s.l. Apples in Asturias are mainly produced in an area characterized by an irregular topography of smooth hills and valleys, and distributed in a mosaic landscape of small agricultural plots separated by hedgerows and woodland.

The studied area has a temperate hyperoceanic climate (Rivas-Martínez & Rivas-Sáenz 2015) with abundant rainfall spread evenly along the year, and mild temperatures even in winter with low risk of frost and snowfall. Relatively high rainfall and fertile soils of Asturian meadows favor the establishment of an evergreen and dense grass coverage in orchards all the year around (Díaz-González & Fernández-Prieto 2005, Miñarro 2012). Meteorological data comprising monthly rainfall as well as temperatures and daylength in hours (Fig. 1) were registered for the area of Villaviciosa throughout the study period.

Fig. 1.

Climatic conditions in the study area. Variation of monthly temperature, rainfall and day-length during the sampling period (Year 1: February 2011-January 2012; Year 2: February 2012-January 2013).

Specimens and data collection

A total of 823 voles (401 males, 422 females) were captured. Each month, one or more orchards, depending on orchard surface area and vole density, were visited for trapping. Voles caught in a single month were grouped and analysed together. Where possible, the same orchard was not visited in two consecutive months to avoid potential alterations on population patterns due to trappings. Voles were captured with snap traps (Topcat® Andermatt Biocontrol, Switzerland) placed in galleries. Traps were activated during the day and checked twice per day for maximum of five days. Each captured specimen was assigned to a particular burrow and thus voles caught in the same trap during the same trapping session were considered as living together. Shortly after capture, body mass (BM) was registered with a precision scale to the nearest 0.5 g and voles were cryopreserved at -20 °C before necropsy. In the field work we have followed the recommendation of the Directive of the European Parliament and of the Council on the Protection of Animals Used for Scientific Purposes (Directive 2010/63/UE 2010).

Head and body length (HBL) and carcass mass (CM) of each animal were taken. In males, the position of testes (abdominal or scrotal), maximum length (TL) and maximum width (TW) of left testis, length of the left branch of seminal vesicle (SVL), and cell content of testis and epididymis tail (Gosálbez 1987) were recorded. Testicular volume (TV) was calculated as follows: TV = 4/3 π (TL/2) (TW/2)². Length variables were measured using a digital calliper to the nearest 0.01 mm (see Ventura 1993). From these characteristics the following sexual maturity states were established: immature males, individuals lacking spermatids or spermatozoids in the testis; submature males, voles with few spermatozoids and spermatids in the testis and without or with a very scarce number of spermatozoids in the epididymis; and mature males, specimens with a large amount of spermatozoids in both structures. Although spermatozoids were not quantified, the differences between mature and submature males was clear since, contrary to what happened in the latter, in mature individuals the presence of spermatozoids in epididymis and testis was homogeneous and high in the smears.

In females, the main criterion used to establish the maturity state was determined from the histological characteristics of the ovaries, which were removed and preserved in 70 % ethanol until the analysis was conducted. Four longitudinal histological sections (sections of 5 μm thick taken 150 μm apart) were performed on the left ovary. Sections were stained with hematoxylin-eosin. Other sexual parameters considered in females were: status of the vulva (closed or open), degree of development and vascularisation of the uterus, and the presence of placental scars and/or embryos (Ventura & Gosálbez 1990b). The following sexual maturity states were established: immature females, specimens without corpora lutea, closed vulva, uterus poorly developed and vascularised, without placental scars; submature females, voles without corpora lutea but with secondary follicles and/or Graafian follicles in the ovary, open vulva, uterus poorly vascularised, without placental scars or embryos; active mature females, individuals with corpora lutea, uterus completely developed and well or scarcely vascularised, showing placental scars and/or embryos, and with open vulva; inactive mature females, specimens with corpora lutea, uterus completely developed and well or scarcely vascularised, with or without placental scars, without embryos and with closed vulva. The mass of embryos was subtracted from BM of pregnant females to assess the general pattern of BM variation during the study period. Moreover, pregnant females were discarded in determining BM differences between sexes and relative age classes (Table 1) in order to prevent considering the mass gain associated to pregnancy (Nazarova & Evsikov 2008).

A subsample of 611 specimens was classified into six classes of relative age (0-V). This subsample was formed by all immature and submature individuals, and a random selection of mature ones to balance their high number of captures. The assignation to each class was done according to the following criteria: moulting stage, sturdiness of the mastoid and the condylar processes, the separation of the angular process from the ascending branch of the mandible, and the values of the interorbital crests index (ICI), which relates the distance between the interorbital crests and the rostral length (see Ventura 1992, Ventura & Gosálbez 1992 and references therein). The approximate age intervals corresponding to these age classes are the following (see Ventura & Gosálbez 1992 and references therein): class 0, 0-3 weeks; class I, 3-6 weeks; class II, 6-10 weeks; class III, 10-14 weeks; class IV, 14-30 weeks; class V, specimens older than 30 weeks. Condylobasal length (CL) and length of upper diastema (LUD) were also measured. Cranial variables were taken only on undamaged skulls.

Data analyses

To obtain values for BM and HBL to set sexual maturity at a population level, BM₅₀ and HBL₅₀ were calculated. This approach provides the values of BM and HBL at which 50 % of specimens of the population are mature, and marks a cut-off value above which all individuals can be considered as adults (Pelikán 1972). BM₅₀ and HBL₅₀ were calculated using a probit regression model, which relates a binomial response variable (mature — non-mature) with an independent variable (BM or HBL) (Finney 1952, Pelikán 1972, Ventura & Gosálbez 1990b).

Fig. 2.

Relationship between head and body length (HBL) and body mass (BM) according to sexual state in A. scherman cantabriae. BM₅₀ and HBL₅₀ are the BM and HBL hypothetical values at which 50 % of specimens of the population are matures and mark the limit above which individuals can be considered as adults.

Significant differences in body and cranial measurements due to age class and sex were tested by a 2-way ANOVA test, followed by a Tukey's test to establish differences between age classes. Sexual differences in body and cranial measurements in each class were assessed by Student's t-tests. To determine the significance of intra-annual and inter-annual variations in BM and CM a 2-way ANOVA test was used. Intra-annual and inter-annual variation in SVL and TV were analysed by a 2-way ANCOVA test using BM as covariate. The relationships between SVL and TV, and BM and CM were determined by Pearson correlations. Partial correlations controlling for BM were used to assess the effect of temperature, rainfall and day-length on TV and SVL. Relationships between the monthly percentages of both pregnant and active mature females respect to the mean values of rainfall, temperature and day length were determined by Pearson correlations. The significance of intra- and inter-annual variations in the number of pregnant females was evaluated using Kruskal-Wallis test. Mann-Whitney U test and Bonferroni adjustment for multiple tests (α = 0.05/number of pair-wise comparisons (6) = 0.0083) were used to determine differences between maturity classes. Differences in sex ratio were assessed by chisquare test. Statistical analyses were performed using SPSS 22.0 (IBM Corp. 2013).

Body and skull size variation

In general, mean HBL and BM were similar for males and females, and increased progressively with relative age class (HBL: F_{5, 605} = 548.01, p < 0.001; BM: F_{5, 494} = 370.91, p < 0.001; Table 1). Only HBL was affected by the interaction of sex and age classes (F_{5, 605} = 3.12, p < 0.01): class I, males (mean = 100.9 mm), females (97.3 mm); class V, males (134.9 mm), females (137.6 mm). Cranial dimensions also varied significantly with age class (CL: F_{5, 511} = 566.32, p < 0.001; LUD: F_{5, 539} = 573.22, p < 0.001; ICI: F_{5, 536} = 529.63, p < 0.001; Table 1). Significant differences between sexes were detected for CL (F_{5, 511} = 8.00, p < 0.01) and LUD (F_{5, 539} = 11.61, p < 0.01), with males showing significantly higher values than females in classes IV (CL: males = 32.5 mm, females = 32.1 mm; LUD: males = 11.8 mm, females = 11.6 mm) and V (CL: males = 33.6 mm, females = 33.1 mm; LUD: males = 12.2 mm, females = 11.9 mm). Body mass and CM were correlated significantly in both sexes (males: r = 0.967, p < 0.001; females: r = 0.957, p < 0.001); since mean values for both variables showed similar interannual and intra-annual variation patterns (results concerning CM are not shown).

Fig. 3.

Relationship between body mass (BM) and sexual maturity state in both sexes in A. scherman cantabriae throughout the study period.

Table 1.

Body and cranial measurements according to relative age classes in A. scherman cantabriae. (HBL: head and body length, BM: body mass, CL: condylobasal length, LUD: length of upper diastema, ICI: interorbital crests index, M: male, F: female. *p < 0.05; **p < 0.01; n.s.: not significant).

Table 2.

Number of captured specimens of A. scherman cantabriae according to sex, sexual maturity state and age class. For each sex and age class, the percentage of individuals corresponding to each sexual state is indicated in brackets.

Reproduction in males

In our sample, males with a BM below 48 g were immature or submature, and above 77 g all males were mature (Fig. 2). Males with a HBL below 111 mm were immature or submature, and above 134 mm all males were mature. Submature specimens were detected above 25 g BM and 87 mm HBL. Males could be considered as mature with a BM (BM₅₀) over 64.9 g and a HBL (HBL₅₀) over 122.8 mm (Fig. 2).

All males belonging to class 0 were immature, and males of class I immature or, in a lower percentage, submature (Table 2). Most submature individuals corresponded to classes II (43.9 %) and III (46.3 %), although the youngest mature male corresponded to age class II. All class IV and V males were mature, although some specimens (16.5 %) had few spermatozoids in testis and epididymis.

Testicular volume was positively correlated with SVL (r = 0.805, p < 0.001). Mean values of TV and SVL for mature specimens with few spermatozoids did not differ significantly from the values corresponding to mature males in any month of both years (Mann-Whitney U test with Bonferroni adjustment; p > 0.0083, in all cases). Mature males with few spermatozoids were not detected in spring of the first year, and spring and summer of the second year (Fig. 3).

Fig. 4.

Estimated marginal means of the testis volume (TV) and seminal vesicle length (SVL) using body mass as covariate in mature specimens of A. scherman cantabriae throughout the study period.

Fig. 5.

Variation of the population structure of mature females belonging to age classes IV and V according to sexual activity state in A. scherman cantabriae during the study period.

Fig. 6.

Monthly variation (mean ± SE) of male and female body mass (BM) in mature specimens belonging to age classes IV and V in A. scherman cantabriae during the study period.

Using BM as a covariate, TV and SVL in mature males showed significant intra-annual variations (TV: F_{11, 283} = 3.19, p < 0.001; SVL: F_{11, 284}= 4.03, p < 0.001; Fig. 4). Significant inter-annual differences were found in SVL (F_1,284= 11.71, p < 0.01) but not in TV (F_1,283 = 0.07, p = 0.787; Fig. 4). A significant interaction was detected between month and year both in TV and SVL (TV: F_{11, 283} = 3.08, p < 0.01; SVL: F_{11, 284} = 3.85, p < 0.001). Estimated marginal means of TV in mature males (Fig. 4) showed maximum values in spring of both years, and decreased till August (first year) or November (second year). Estimated marginal means of SVL (Fig. 4) did not show a clear inter-annual variation pattern. Partial correlations controlled by BM were significant between TV and day-length (r = 0.126, p < 0.05), whereas temperature (r = 0.006, p = 0.920) and rainfall (r = -0.003, p = 0.955) did not show a significant relationship with TV. Partial correlation between SVL and day-length, and between the former variable and temperature were significant (r = 0.190, p < 0.01; r = 0.144, p < 0.05; respectively). Rainfall did not correlate significantly with SVL (r = -0.051, p = 0.390).

Reproduction in females

Females with a BM below 42 g were immature or submature, and all individuals above 80 g were mature (Fig. 2). Specimens with a HBL below 96 mm were immature or submature, and above 127.5 mm all individuals were mature. The submature specimens were detected with BMs above 29 g and HBLs of 96 mm. Females with BMs and HBLs higher than 59.9 g and above 121.9 mm, respectively, could be considered mature (BM₅₀ and HBL₅₀ respectively) (Fig. 2). In classes 0, I and II most females were immature (Table 2). The youngest mature female corresponded to class II. Submature females corresponded mostly to classes II and III, and all females of classes IV and V were mature.

Active mature females and/or pregnant females were found in all months of the study period (Fig. 5). No significant inter-annual (Kruskal-Wallis H′ = 0.104, p = 0.748) and intra-annual (Kruskal-Wallis H′ = 18.341, p = 0.074) differences in the number of pregnant females were found. These females appeared in all months except January 2013 (mature females: n = 8). Between April and November of the first year, pregnant females constituted more than 25 % of mature females. However, the occurrence of pregnant females in second year was more irregular (Fig. 5), with maximums in March (61.5 %) and November (58.3 %). Monthly percentages of both pregnant and mature active females were not significantly correlated with the monthly mean values of rainfall (r = -0.380, p = 0.067; r = -0.326, p = 0.120; respectively), temperature (r = 0.215, p = 0.314; r = 0.322, p = 0.125; respectively) or day length (r = 0.207, p = 0.331; r = 0.343, p = 0.101; respectively); likewise, there were neither significant correlations when the month before the month of capture was considered: rainfall (r = 0.220, p = 0.313; r = 0.415, p = 0.062; respectively), temperature (r = 0.160, p = 0.467; r = 0.012, p = 0.958; respectively), day length (r = 0.374, p = 0.079; r = 0.231, p = 0.288; respectively).

Body mass variation

Mean variation of BM in mature male specimens belonging to classes IV and V (Fig. 6) showed significant intra- (F_11,253 = 4.64, p < 0.001) and interannual differences (F_11,253 = 3.17, p < 0.01). The BM means of these males were also affected by the monthyear interaction (F_11,253 = 3.17, p < 0.01). Conversely, mean variations in BM of adult females (classes IV and V, Fig. 6) were not significant neither intra-(F_{11, 266} = 1.67, p = 0.081) nor inter-annually (F_{1, 266} = 1.07, p = 0.302). Mean BM of classes IV and V did not differ significantly between sexes (t = -1 .85, df = 517, p = 0.064). Mean BM values of both sexes showed relative higher values in June of the first year and May of the second year (Fig. 6).

Fig. 7.

Variation of the population structure according to relative age classes in A. scherman cantabriae throughout the study period.

Fig. 8.

Variation of population structure of immature, submature and mature specimens belonging to age classes 0-III in A. scherman cantabriae during the study period.

Population structure

Total sex ratio (401 males, 423 females) was not significantly different from 0.5 (χ2 = 0.43, p = 0.512). For each age class (class I: 0.97, class II: 1.14, class III: 0.88, classes IV-V: 0.93) the sex ratio was also not significantly different from that value (χ2 test, p > 0.05 in all cases). The presence in all months of specimens from class 0 or I revealed that births occurred steadily (Fig. 7), whereby, immature specimens of both sexes were captured continuously during both years (Fig. 8). Submature or mature specimens belonging to classes I, II and/or III were detected in all months, with maximums in May (72.7 %), August (72.2 %) and November (77.3 %) of the first year and with a more regular presence between February and December of the second year (Fig. 8). The percentage of captured mature individuals of classes II and III decreased in winter of both years (Fig. 8). At least 45 % of captured voles in each month belonged to classes IV and V (Fig. 7).

A total of 120 family groups were captured. Couples formed by adults individuals were observed in 42 cases (35 %), 33.3 % of them with pregnant females (n = 14). The number of captured couples with offspring was 59 (49.2 %), formed by one to five juveniles. The immature voles captured in each burrow mostly belonged to the same relative age class. Indeed, most immature specimens (93.6 %) corresponded to age class 0, I, and II, although some specimen of age class III were captured occasionally with mature couples (6.4 %). Occasionally, groups of more than two adults belonging to class IV and/or V were detected, mostly in May (42.1 %): one male-two females (n = 8), two males-one female (n = 6), two males-two females (n = 5). Of these associations, a pregnant female was observed in a group formed by two males-one female and in five groups of one male-two females. Furthermore, both females were pregnant in a group of one male-two females and in three groups of two males-two females.

Implications for management

Apple orchards in Asturias are located in relatively small plots (70 % are smaller than 2 ha) immersed in a mosaic landscape with high densities of seminatural habitat (hedgerows and woodlands) and a topography with smooth hills and valleys, leading to a closed landscape. It has been hypothesized that such setting might modulate multiannual fluctuations in abundance of fossorial water voles directly by slowing dispersion and indirectly by the presence of specialist and generalist predators (Giraudoux et al. 1997, Fichet-Calvet et al. 2000, Foltête et al. 2009, Berthier et al. 2013). Anyway, although no studies on population dynamics has been conducted and thus there is not periodic data on vole density, some population outbreaks have been observed at a local scale in Asturias (Miñarro, pers. observ.). In such situations of tree-damage threat vole control is faced without coordinate actions among farmers and according to their perception of risk.

Population control of this species in Asturias has so far mainly been achieved by manually placing rodenticide baits or snap-traps at burrow entrances. Until now, farmers increase control activity in winter in order to eliminate adults before the hypothetical breeding season, which was expected to start in spring. Thus, farmers would reduce population increase. However, our results show a continuous breeding regardless of season which suggests that population control could be performed along the whole year. This does not mean extending the use of rodenticides throughout the year but that control effort does not need to be seasonal as it used to be. It is well known that increasing the poison input in the agroecosystem enhances the risk for wildlife (Coeurdassier et al. 2014, Montaz et al. 2014). For that reason, sustainable control management strategies should preferably be taken into account instead of poisoning practices which are maintained over time.

As control measures of direct application, trapping beyond the death of the mature couple might lead to increase control effectiveness since some offspring could remain in the burrow. It is worthwhile to keep in mind that we found up to seven specimens in a burrow. Furthermore, a continuous trapping might suppose a decrease of the body condition in females remaining in the burrow, which in turn might have negative consequences on her reproductive success (Somoano et al. 2016). On the other hand, dispersion in fossorial water voles is done aboveground by juvenile specimens (Saucy & Schneiter 1998, Saucy 2002). Installing fences can be useful to avoid invasions by dispersal specimens (see details in Walther & Fuelling 2010). Farmers should maintain these fences surrounding apple orchards continuously as young mature specimens appear throughout the year and could thus disperse at any time. Uncoordinated control actions by farmers involve potential colonization movements of juveniles from source demes (without or scarce control) to nearby sink plots (with continuous removal of voles).

The enforcement of other sustainable control management strategies, such as frequent mowing (Morilhat et al. 2007, Jacob 2008), livestock grazing (Defaut et al. 2009) or the use of repellents (Fischer et al. 2013) can be suitable strategies to maintain fossorial water voles under physiological stress, which in turns might induce a decline in their population densities (Charbonnel et al. 2008). However, the effectiveness of these control strategies is frequently assessed by the relative abundance of voles (e.g. Morilhat et al. 2007, Jacob 2008, Delattre & Giraudoux 2009), without going into the underlying cause. The information obtained for this population can be used to assess direct consequences of control strategies on the reproductive biology of fossorial water voles, such as changes in population structure (Cerqueira et al. 2006), growth delaying (Stoddart 1971, Zejda 1991, Moorhouse et al. 2008) or delays in the onset of reproduction (Yakovleva et al. 1997).