IUCN/SSC Otter Specialist Group Bulletin

©IUCN/SCC Otter Specialist Group

Volume 28 Issue 2 Pages 62 - 118 (October 2011)

Citation: Cousins, L., Tansley, D. and Hepburn, L. (2011). Investigation into the Dietary Habits of the Eurasian Otter (Lutra lutra) in the County of Essex . IUCN Otter Spec. Group Bull. 28 (2): 76 - 83

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Investigation into the Dietary Habits of the Eurasian Otter (Lutra lutra) in the County of Essex

Leslie Cousins1, D. Tansley2 and L. Hepburn1

1Department of Biological Sciences, University of Essex, Wivenhoe Park, Colchester.CO4 3SQ. e-mail: lcousi@essex.ac.uk
2Essex Wildlife Trust, Abbots Hall Farm, Great Wigborough, Colchester. CO5 7RZ

Leslie Cousins.  Click for larger image D. Tansley.  Click for larger image L. Hepburn.  Click for larger image
Received 12th July 2011, accepted 29th October 2011
Abstract: Monitoring throughout the county of Essex has shown annual widening of otter distribution. There is, however, room for expansion and some areas remain un-colonised. This paper reports a snapshot study of spraints collected from within the areas of known distribution, providing additional insight on a growing population. Prey remains were identified to family level and data used to calculate trophic breadths over the range of stream orders. Investigative comparisons were used to detect changes in diet with stream order. Further consideration was given to the importance of crayfish predation (e.g. the signal crayfish Pacifastacus leniusculus).Within the sample (n= 54) from four stream orders (Strahler 2-5), fish occurred most frequently (67%). Other groups included; invertebrates 20%, birds 7% and mammals 6%. Crayfish comprised 4% of the sample. There were no significant differences between Trophic Niche Breadth and stream order (H*=2.73, P>0.05), a finding strengthened by subsequent statistical analysis of the data. Dietary composition was consistent within the range and period studied. Extended research could determine seasonal variation and the extent to which available prey assemblage limits distribution against wider environmental and biological variables. .
Keywords: distribution, trophic niche breadth, Strahler classification, predation
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The Eurasian otter (Lutra lutra) population in the county of Essex and East Anglia is experiencing growth and becoming re-established after regional extinction (Mason and MacDonald 2003).

Historically, the otter was common throughout Britain (Stephens 1957). However, by the early 1960’s hunt returns where showing a sharp reduction in numbers (Chanin and Jefferies 1978).In response to growing conservation concern a series of national surveys were instigated (Hewer 1974, Lenton et al., 1980).The second national survey reported an absence of otter signs in Essex (Strachan et al., 1990). The decline and eventual disappearance of otters was attributed to the effects of persistent toxic pollutants compounded by habitat destruction and direct persecution (Macdonald and Mason 1983; Mason and Macdonald, 1986; Mason, 1989; Strachan and Jefferies, 1996; Jefferies and Hanson, 2000). Environmental pollutants identified as harmful to otters included; organochlorine pesticides; heavy metals and polychlorinated biphenyls (PCBs).

Re-colonisation was facilitated by the efforts of multiple agencies combined within the Joint Otter Group and other agencies working to reverse environmental degradation. Habitat restoration and targeted re-introductions successfully re-established a small yet viable population (Jefferies et al.,1986, 2000). A survey in 1991 (Strachan and Jefferies, 1996), identified the presence of field signs indicating otter usage. Successive surveys have consistently shown increases in the extent to which the species uses local water courses (Tansley, 2008, 2009, 2011). Annual monitoring of the Essex population is tracking progress, which is essential, as the population has yet to reach carrying capacity and still has potential to expand (Crawford, 2010). This study aims to complement survey distribution data with additional information, through dietary analysis, on how a growing otter population uses available resources.

AIM AND OBJECTIVES

Aim
To determine the diet and feeding habits of L. lutra across the county of Essex

Specific Objectives

  • To produce a map communicating the distribution of collected samples in relation to the known distribution of this species.
  • To identify all prey species to family level.
  • To determine the relative contributions of each family to otter diet in relation to distribution.
  • To compare trophic breadth indices to identify geographical patterns in relation to stream order.
  • To determine the importance of invasive crayfish species to otter diet.
METHODS AND MATERIALS

Essex is a low-lying county in eastern England. The largest of the counties rivers and tributaries included in this study are; the Stour, Colne, Chelmer and Roding. Spraint samples (n=54) were collected during the spring and summer of 2010 from field locations known to have been previously used by otters (Figure 1, Tansley, 2009). Samples were wrapped in aluminium foil, sealed in plastic sample bags, tagged and stored frozen.

Map of Essex showing rivers, known otter occupation and sample sites.  There are few sites or known distribution in the south of the county
Figure 1. The county of Essex incorporating the known otter distribution as 2009 (triangles) and the sites where samples of spraints where collected in 2010 (circles). Figure produced as an overlay to Crown Copyright © Ordnance Survey Licence number 100025798.
(click for larger version)

Stream order was allocated to each sample using the system described by Strahler (1952). Streams originating from source were allocated the first order. In this system an nth order stream always flows downstream from the confluence of two (n-1)th order streams.

Samples were oven dried at 60 °C for 12-24 hours until completely desiccated, then carefully crumbled by hand to separate undigested prey remains. Once separated identification of prey remains to family level was aided by published keys (Conroy et al., 2005, Teerink 1991, Day 1966). Binocular Leica Zoom 2000 and Nikon 104 microscopes were used for analysis. The bulk percentage dry weight of prey items was estimated by eye (Wise et al., 1981). Data gathered were used to calculate the percentage (%) frequency occurrence of prey groups (P=number of spraints containing X / total number of spraints x 100).

The relative (R) percentage (%) frequency of occurrence for each prey group(R = occurrence of X / number of groups x 100). Trophic niche breadth (TNB) for each observation using TNB=1/RΣpi2 Levins’ index (Feinsinger et al., 1981). Where pi is the estimated proportion of prey type within each sample and R is the total number of prey types observed. Using descriptive statistics, homoscedasity was assessed for each group before and after various transformations. Despite transformation, neither normality nor homoscedasity were achieved. Therefore, analysis of data required the use of the Kruskal-Wallis (H) test between trophic niche breadth (TNB) and stream order. Additionally, the Spearman’s test was used to look for correlation between ranked TNB and stream order.

A contingency table was constructed to calculate expected values enabling a chi squared (Χ2) test of association between stream order and prey groups. Arcsine transformed frequencies of prey families were compared between stream orders using the paired t-test. The statistical analyses of data were performed using SPSS software.

RESULTS

Spraints (n=54) were collected from rivers of the orders; two to five (Figure 1). Six of the samples (11%) came from second order streams. Third order streams contributed the highest proportion of 20 samples (37%). Seventeen samples were taken from streams of the fourth order (31%). The remaining eleven samples (20%) where collected from fifth order streams. The dry weight of spraints ranged from 0.34g to 7.91g, mean 2.046g (SE 0.195).


Table 1: Families and Common names of prey items extracted from otter spraint (n=54) collected from the county of Essex 2010

Prey Group Family Common name Percentage (%)
 frequency
 
Fish Cyprinidae carp 35
Percidae perch 9
Cottidae stone loach 14
Cobitdae bullhead 15
Gasterosteidae stickleback 4
Esocidae pike 11
Salmonidae trout 2
Anguillidae eel 7
Invertebrate Odonata dragon fly 6
Gammaridae shrimp 5
Astercidae crayfish 6
Tricoptera caddis fly 1
Bird Ralliform moorhen 4
Anseriform duck 2
Colombiform pigeon 2
Mammal
 
Leporidae rabbit 2

Otters predated animals from four groups comprised of eight families of fish, four families of invertebrate, three families of bird and one family of mammal (Table 1). Percent frequency occurrence values of prey families within each stream order (Figure 2) provided a description of predation within each stream order, these values were used to calculate related trophic niche breadths (Figure 3). The distribution of TNB values within each group was skewed. Second order streams had a median value of 0.1. The median TNB value of third order streams was 0.09. In the group of fourth order streams, the distribution was highly skewed and had a median of 0.07. Within the fifth order group of samples the TNB median was 0.08.

Four graphs showing the relative prey composition on watercourses of different orders fromj 2nd to 4th order.  Click for larger version
Figure 2. Relative percent (%) frequency of prey families within the diet of otters from four orders of stream. Cyprinidae (Cyp), Percidae (Perc), Cottidae (Cot), Cobitidae (Cob), Gasterosteidae (Gast), Esocidae (Esoc), Salmonidae (Salm), Anguillidae (Ang), Odonata (Odon), Gammaridae (Gam), Astercidae (Ast), Tricoptera (Tri), Ralliform (Ral), Anseriform (Ans), Colombiform (Col), Leporidae (Lep).
(click for larger version)
Graph showing trophic niche breadth on streams of different order; the higher the order, the wider the niche. Click for larger version.
Figure 3. The Trophic Niche Breadth of otter diet as determined from spraints collected from four orders of stream within the county of Essex.
(click for larger version)

Comparison of these data could not separate populations, there being no significant difference between trophic niche breadths and stream order, H* =2.73, P>0.05. There was no correlation between ranked niche breadth data and stream order (rS = -0.116, P>0.05). Prey occurrence data was tested for association with stream orders and none were found, e.g. the number of occurrences of Cyprinidae fish families within spraints were not significantly different between either of the stream orders investigated, χ23= 5.41, P<0.05.

A comparison of the, arcsine transformed, proportion of each prey type found no significant differences (P>0.05) in distribution among stream orders (Table 2).


Table 2: Comparisons of the proportion of different prey types consumed in streams of increasing magnitude, n = 19.

Catagories t-values
2nd Order 3rd Order 4th Order 5th Order
Whole Sample 0.721 (NS)

0.706 (NS)

0.823 (NS)

1.049 (NS)

2nd Order

0.535 (NS)

0.134 (NS)

0.092 (NS)

3rd Order

0.863 (NS)

0.652 (NS)

4th Order

0.116 (NS)


NS = not significant.
DISCUSSION

The frequency occurrence of prey within the diet of the Essex population was congruent with previous studies of eutrophic systems (e.g. Weir and Bannister, 1973, 1977; Jarman, 1979; Woodroffe, 1994), and consistent with evolutionary adaptation. In this study fish were the most frequently taken food items, 67%. In terms of volume, fish may contribute a larger proportion of diet than has been measured here. Due to problems associated with bulk estimations (Carss and Nelson, 1998) no attempt had been made to estimate the volume of fish eaten, whole or part.

Insects and crustaceans featured regularly in the diet (19.9%). Consistent occurrence across stream orders suggests invertebrates are an important dietary component to this population. Carss and Parkinson (1996) have described how well fed, captive otters actively pursue and consume aquatic insects. The benefit and importance of invertebrates to the diet of otters is considered by Taylor et al. (2010).

Otters are considered beneficial as a source of biological control of invasive crayfish species (Reeve, 2004). In this study crayfish occurred in 4% of the sample. Crayfish predation is identified by the presence of carapace or other cuticle fragments within spraints. This method is limited by providing only presence or likely absence of occurrence and not volumetric data. To fully understand habits, a longer study would be needed to identify spatial and seasonal variations in crayfish predation.

Birds and mammals were an infrequent, though regular, feature in the diet of the Essex population (bird 7.4%, mammal 5.5%). The families predated (e.g. Ralliform, Anserform and Leporidae) were those otters are most likely to encounter, and the infrequency suggests predation is opportunistic.

Amphibians area group of potential prey known to feature within the diet of otters (e.g. Clavero et al., 2003). The absence of amphibian prey from the sample could be due to the timing and habitat focus of sample collection. Observations have shown that otters feed on amphibians during the spawning season in early spring (Mason and Macdonald, 1986; Weber, 1990). This study focused on river habitats, excluding standing waters that are preferred breeding sites for frogs, toads and newts (Baker et al., 2011).

Comparison of TNB and one physical attribute of habitat variability (stream order) found no significant change in diet between rivers in terms of size and discharge. This study has detailed dietary norms of the local population. As range is a function of habitat quality (Jefferies and Woodroffe, 2008), these data could provide a baseline with which to gauge the prey assemblage of water courses yet to support otters.

An extended comparison of distribution, diet and broader habitat quality (eg. the standardised River Habitats Survey, Raven et al., 1997, 1998; Fox et al., 1998) of used and un-colonised rivers could provide informative results. Indices such as the RHS collect a range of physical and biological habitat attributes, not included in this study, which may have influence over the ecology and distribution of otters.

Acknowledgements - I would like to thank the following people for all their generous help; Russell Smart for laboratory assistance, Odette Robson for help and suggestions. Stephen Wilkinson, Sue Manning, Patricia Clegg and Peter Margetts for help collecting spraint samples.

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Résumé : Enquête sur les Habitudes Alimentaires de la Loutre d’Europe (Lutra lutra) dans le Comté d'Essex
Le suivi de la Loutre dans le Comté d'Essex a montré un élargissement annuel de sa répartition. Il existe effectivement des possibilités d'expansion mais certaines zones demeurent non colonisées. Cet article rapporte l’analyse rapide d’épreintes recueillies sur les zones de répartition connue, apportant des éléments supplémentaires sur une population croissante. Les restes de proies ont été identifiés jusque la famille et les données obtenues ont permis de calculer des valeurs trophiques sur l’ensemble des tronçons du continuum fluvial. Diverses enquêtes ont été comparées afin de détecter des variations alimentaires en fonction de la situation sur le continuum fluvial (classe de courant). Un examen plus approfondi a mis l’accent sur l'importance de la prédation des écrevisses (Pacifastacus leniusculus). Au sein de l'échantillon (n=54) regroupant quatre classes de courant (Strahler 2-5), les poissons sont les plus fréquents (67%). D'autres groupes sont aussi présents; les invertébrés 20%, les oiseaux 7% et les mammifères 6%. Les écrevisses composent 4% de l'échantillon. Il n'y avait pas de différences significatives entre l’ampleur de la niche trophique et la classe de courant (H * = 2,73, P>0,05). La composition alimentaire est restée stable durant l’étude et sur l’ensemble de la zone suivie. Des recherches plus poussées permettraient d’apprécier des variations saisonnières et évaluer dans quelle mesure la disponibilité des proies limite l’expansion de l’espèce en parallèle de variables environnementales et biologiques.
Revenez au dessus

Resumen: Estudio de los Hábitos Dietarios de la Nutria Euroasiática (Lutra lutra) en el Condado de Essex
Un monitoreo que abarca el condado de Essex ha mostrado una ampliación de la distribución de la nutria. Sin embargo, espacio para expansión y algunas áreas se mantienen sin colonizar. Este artículo es resultado de un estudio acotado de fecas colectadas dentro de las áreas de distribución conocida y aporta información adicional sobre una población en crecimiento. Los restos de presas fueron identificadas al nivel de familia y los datos usados para calcular la amplitud trófica en todo el rango de órdenes de los cursos fluviales. Se usó la comparación de investigaciones para detectar cambios en la dieta según el orden del curso fluvial. Se le dio otra importancia a la predación de cangrejos (por ej. el cangrejo señal Pacifastacus leniusculus). De la muestra (n=54) de cuatro órdenes de cursos fluviales (Strahler 2-5), los peces fueron más frecuentes (67%). Otros grupos presentes fueron: invertebrados 20%, aves 7% y mamíferos 6%. Los cangrejos comprendieron el 4% de la muestra. No se hallaron diferencias significativas entre las Amplitudes de Nicho Trófico según el orden del curso fluvial (H* =2.73, P>0.05), este resultado está reforzado por posteriores análisis estadísticos de los datos. La composición dietaria fue estable dentro del área y período estudiados. Un estudio más amplio podría determinar variaciones estacionales y la medida en que el ensamble de presas disponibles limita la distribución frente a las más amplias variables ambientales y biológicas.
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