Reproductive and morphological condition of wild mink (Mustela vison) and river otters (Lutra canadensis) in relation to chlorinated hydrocarbon contamination.

We assessed chlorinated hydrocarbon contamination of mink and river otters on the Columbia and Fraser River systems of northwestern North America, in relation to morphological measures of condition. We obtained carcasses of mink and river otters from commercial trappers during the winters 1994-1995 and 1995-1996. Necropsies included evaluation of the following biological parameters: sex, body mass and length, age, thymus, heart, liver, lung, spleen, pancreas, kidney, gonad, omentum, adrenal gland and baculum masses, baculum length, and stomach contents. Livers were analyzed, individually or in pools, for residues of organochlorine (OC) pesticides, polychlorinated biphenyls (PCBs), dibenzo-p-dioxins, and dibenzofurans. Contaminant levels were relatively low compared to those documented in other North American populations, although they ranged higher than those detected during an earlier survey (1990-1992) of these regional populations. Body condition varied slightly among collection regions, but showed no relationship with contaminant burden. Mink from the upper Fraser River had less fat stores and also had some of the lowest OC contamination levels observed. Similarly, a few individuals with enlarged livers and kidneys had low contaminant levels. Although a few individual animals with gross abnormalities of reproductive systems did not show high levels of contamination, there was a significant negative correlation between total PCB concentrations (as Aroclor 1260) and baculum length in juvenile mink (r = 0.707; p = 0.033; n = 8). The association of juvenile baculum length with eventual reproductive success is unknown, but further characterization of reproductive organ morphology and relationship to contaminants should be undertaken in a larger subset of these populations.

Fraser River systems ofnorthwestern North America, in relation to morphological measures ofcondition. We obtained camusses of mink and river otters from commercial tpers during the winters 1994-1995 and 1995-1996. Necropsies induded evaluation of the following biological parameter: s, body mass and length, age, thymus, hea, lvr, lung, spleen, pancreas, kidney, gonad, omentum, adrenal gland and baculum masses, baculum length, and stomach contents. Lirs were analyzwd, individually or in pools, for residues of ornohlore (OC) psides, pochlorinated biphenyls (PCBs), dibenzp.dioxins, and dibenzofirns. Containant levels wee rdaively low compared to those docmented in other North American populations, although they ranged higher than those deected during an ealier survey (1990-1992) of these regional populations. Body condition varied slighty among collection regions, but showed no ration ip h co inant burden. Mink from the upper Fraser River had less fat stores and also had some of the lowest OC c levels observed Similarly, a few individual with enlawged lives and Idneys had low contmint levels.
Although a few individual animal with gross abnormalities of reproductive did not show high levls of contaimtion, there was a sinificant nega correlaton between total PCB concentrations (as Arodor 1260) and baculum lngth in juvenile mink (r = 0.707; p = 0.033; n = 8). The ion of juvenile baculum length with eetual reproductive success is unknown, but fiuther characterization of reproductive organ morphology and relationship to contaminants should be undertaken in a larger subset of these populations. Iey uwn& baculum, mink, organocllorines, otter, polclorinated biphenyls. Eniron HealtPmn 107: 141-147 (1999). [Online 13January 1999] htt:/Iehpnetl.niehs.nih.gov/docs/l999/107p141-147harding/abstra~html The sensitivity of mink (Mustela vison) to polychlorinated biphenyls (PCBs) was identified in the early 1970s when reproductive failure of ranch mink was attributed to a diet of contaminated Great Lakes fish (1)(2)(3). Further studies in which adult ranch mink were fed PCB-contaminated fish from Saginaw Bay, Lake Huron, showed a dose-response relationship between PCB concentration in food and reproductive failures, measured as reduced litter sizes, increased kit mortality, and reduced average kit weight (4). Declines of European otter (Lutra lutra) populations (5)(6)(7) and North American mink populations (8,91 have been tentatively linked to elevated environmental PCB concentrations. Recent laboratory studies have examined mechanisms by which aryl hydrocarbon receptor (AhR) agonists such as 2,3,7,8-TCDD (dioxin) can alter sexual maturation and reproduction in various mammalian species (10). Results include a variety of feminizing effects in male offspring and less pronounced effects on female reproductive systems (11). Those studies suggest that, for example, feminizing effects of TCDD and other compounds may be discernible in field-exposed individuals.
The principal objective of this study was to evaluate possible relationships between tissue levels of contaminants and measurements of certain organs, particularly reproductive organs. Given the presence of several organochlorine (OC) pesticides, polychlorinated dibenzo-p-dioxins (PCDDs) and dibenzofurans (PCDFs), and PCBs in pooled liver samples of mink and river otters (Lutra canadensis) previously collected by Elliott et al. (12), those species were again collected from trappers during the 1994-1995 and 1995-1996 winter seasons along the reaches of both the Fraser and Columbia river systems in British Columbia. Collections were also extended to the Kootenay River, a tributary of the Columbia, and the lower Fraser River. Hepatic chlorinated hydrocarbon concentrations were assessed, along with several biological parameters. Biological characterization induded sex, age, body mass and length, organ condition indices, baculum size in males, and stomach content analysis. Results from analysis of the same animals for heavy metals are being published elsewhere (13).

Materials and Methods
Sample collection. Skinned mink and river otter carcasses were collected from commercial trappers during the winters of 1994-1995 (November-March) and 1995-1996 (November-January). Traplines were located on the Fraser River near Prince George and Chilliwack, British Columbia, Canada; on the Kootenay River near Creston and Cranbrook, British Columbia, on the Slocan River (a tributary to the Kootenay River); and on the Columbia River between Revelstoke and Trail, British Columbia. In the Fraser Valley, a suburban/rural environment near the terminus of the Fraser River, mink and otters were obtained from licensed trappers without commercial traplines, and who were permitted to remove nuisance animals. Specific collection locales are indicated in Figure 1. Over the two seasons, a total of 26 mink and 32 river otters were collected on the three river systems. Six of the mink were not subjected to the same chemical and biological measurements described below, but are induded in the data sets regarding sex and age ratios.
Trappers were provided with collection kits to ensure consistent and adequate quality of tissue storage. Collection kits consisted of aluminum foil, garbage bags, labels for recording the date and location of collection and the sex of the trapped specimen, and detailed instructions on collection handling and storage. Skinned carcasses were frozen before shipment by air to the laboratory.
Necropsies. All mink and otters collected in the winter of 1995-1996, as well as otters collected the previous winter on the Kootenay River, were thawed and a gross necropsy performed by a veterinarian (C.RS.). The carcasses (without pelts) were sexed and weighed, and total length (nose to tip of tail) and tail length were measured. After external examination for gross abnormalities (including a count of toes), each carcass was dissected to assess organ condition and internal structure. One upper and one lower canine tooth were removed for dental cementum analysis of age (14,15); unfortunately, some of the otter teeth were damaged during extraction, so that ages were not obtained for all animals. Thymus, heart, lung, liver, spleen, pancreas, gonads, kidney, omentum, and adrenal glands were excised with hexane-washed knife and forceps, weighed, and examined for gross pathology. Livers were placed in hexane-washed jars and frozen for chemical analysis as described below. Stomach contents were assessed on a superficial level (e.g., if fish scales were encountered, they were not identified to genus or species level). In males, the baculum was excised, deaned with a digestive enzyme and also by hand to remove all adhering tissues, and then air-dried for several months. Cleaned and dried bacula were weighed (mass) with an electronic balance and measured (length) with an electronic micrometer. Some animals were received with heads missing, so that there was some variability in sample size for the numerous data sets.
Analysis ofhepatic organochlorine contamination. Excised livers from mink and river otters were analyzed at the Pacific Environmental Science Centre, Environment Canada (North Vancouver, BC) for chlorinated organic compounds. The organic contaminants included the pesticides aldrin, dieldrin, endosulfan, endrin, heptachlor, heptachlor epoxide, p,p'-DDD, pp'-DDE, pp'-DDT, and PCBs.
Livers were homogenized, acetoneextracted, and partitioned with 2% NaCl. Extracts were then treated, as necessary, with florisil, concentrated sulfuric acid, activated copper, and/or mercury to remove interferences. Glass columns prepared with glass wool, 2% deactivated florisil, and heat-treated sodium sulfate were washed with 50 ml hexane. A 2-ml sample extract was loaded, and the first and second fractions were eluted with 35nml hexane and 150 ml 1:1 hexane/dichloromethane (DCM), respectively. The first fraction contained PCBs, p,p'-DDE, aldrin, and heptachlor, and the second fraction contained the remainder of the pesticides. Fractions were roto-evaporated, and then quantitated using a HP-5890 series II high resolution gas chromatograph with electron capture detection (Hewlett-Packard, Cupertino, CA). Method blanks were induded with each run, and 20% of the samples were split and analyzed as g duplicates. Discrepancies of greater than 20% among duplicates were not acceptable. External 0.1-and 1.0-pg/g PCB standards were analyzed twice during each sample run. Instrument calibration was completed at three concentrations using pesticide mixture and Aroclor 1260 standards. Average recoveries were 89%, with coefficients of variation of 1.4-12.7%. Minimum detection limits were 0.01 pg/g for PCBs and 0.002 jg/g for pesticides. All concentrations discussed in the text were expressed on a wet weight basis. Otters' livers were also pooled by region and analyzed at Zenon Analytical (Burnaby, BC) using high-resolution gas chromatography/mass spectrometry (GC/MS) for PCDDs, PCDFs, and co-planar PCBs (16). Those data are induded in the Appendix.
Statistical evaluation. Biological data collected from necropsies of mink and river otters were grouped by collection region and river to permit statistical interpretation. In all cases, tests for normality and homogeneity of variances were completed, and transformations were deemed unnecessary. Organ condition or somatic indices were calculated for kidney, liver, and spleen by dividing the organ mass by a corrected total body mass and multiplying by 100. The corrected body mass was derived by subtracting the kidney, liver, and spleen masses from the total skinned carcass mass. Organ somatic indices were compared within sexes among regions using analyses of variance (ANOVA). Organ masses were also compared using the more conservative analyses of covariance (ANCOVA), with total body mass as the covariate. Where a significant difference in organ mass or somatic index was seen among regions, an unplanned multiple comparison using Tukey's honestly significant difference test (17) was conducted. Gross body measures (length and mass) were also submitted to ANOVA, grouped according to sex and region, but without consideration of age differences. When significant differences among regions were found, an ANCOVA was conducted with age as the covariate. Analyses of covariance were also conducted on adrenal, omentum, testes, and baculum masses and baculum length, with total body mass as the covariate. All tests were performed with SYS-TAT 5.0 (18).
We tested several biological parameters for associations with each other and with contaminant body burdens using Pearson correlation matrices. Correlations were assessed for significance using a Bonferroni adjustment when more than two associations were being evaluated simultaneously. Occasionally, an association between just two variables was retested separately, in which case a Bonferroni adjustment of the probability value was not necessary.

Results
Twenty-six mink and 32 river otters were collected over the course of the two winter seasons. Sex ratios for the captured mink and otters were dominated by males; 73% of mink and 59% of otters collected were males (Table 1). In addition, of those individuals whose ages could be determined, the majority captured had been born within the year (i.e., juveniles). In the subsample of animals with determined ages, 74% of mink and 42% of otters were juveniles. Sample sizes were too small to compare sex or age ratios among study areas.
Hepatic chlorinated hydrocarbon contamination. Most mink livers, which were all collected along the Fraser River, contained detectable concentrations of PCBs and DDT-related compounds (r-DDT, primarily p,p'-DDE), and several also contained dieldrin ( Table 2). Most otter livers from the Kootenay, Columbia, and lower Fraser Rivers contained detectable concentrations of PCBs, p,p'-DDE, and heptachlor epoxide ( Table 3). None of the otters from the upper Fraser had detectable p,p'-DDE and only one had detectable PCBs; four animals had detectable heptachlor epoxide concentrations.
A subset of the animals collected was also analyzed for PCDDs, PCDFs, and non-ortho PCB congeners; those results are compiled in the Appendix along with some previously published data. Concentrations of 2,3,7,8-TCDD and -TCDF were low (<5 pg/g) in all samples. The pattern of higher chlorinated PCDDs and PCDFs varied among sites, with the pools from the lower Fraser valley having much higher relative concentrations of octaCDD and 1,2,3,6,7,8-hexaCDD and higher chlorinated PCDFs than other sites.
TCCD toxic equivalents (TEQs) were calculated using the data in the Appendix, based on international toxic equivalence factors (TEFs) (19,20). The highest concentrations were found in an otter pool from the lower Fraser River (27 pg/g), followed by a pool from the lower Columbia River (20 pg/g) (Fig. 2).
Morphological characterization. Reproductive tract abnormalities were seen in a few   male mink and otters. In one mink and one otter, a testicle had not descended into the scrotum, but was instead located in the inguinal canal; the otter was also missing a kidney on the same side as the undescended testicle. In two mink, no testes or bacula were found. Another otter was missing one testicle and had an underdeveloped second testicle. No abnormalities were seen in the reproductive tracts of the females. Of the two female mink and four female otters known to be of breeding age, only one otter was pregnant. She carried two fetuses measuring 6 cm from crown to rump and weighing 9.9 and 10.5 g. The corpora lutea were not counted in other females, so it is not known whether they had undergone copulation and successful ovulation that year.
Three mink showed other lesions not associated with reproductive organs. One male mink had a healed umbilical infection with some associated abdominal adhesions. Another mink had a thickened, scarred area  on the mucosa of its stomach, and a third had an enlarged, hemorrhagic mesenteric lymph node. There were no significant differences in average testes mass, baculum length, or baculum mass in male mink or river otters from the various collection regions (Table 4). There appeared to be an association between baculum size and age (juveniles vs. yearlings) in both species, but correlations were only significant in mink (mass and age: r = 0.805, p = 0.024; length and age: r = 0.774, p = 0.047). There were several strong correlations among the various reproductive organ sizes. Male mink average testes mass was significantly correlated with total body mass (juveniles: r = 0.987, p<O.001; all males: r = 0.813, p = 0.008), and baculum leng th and mass were correlated with each other (all males: r= 0.785, p = 0.015). In male otters, total body mass, average testes mass, and baculum length were all significantly associated with each other; Pearson correlations ranged from 0.696 to 0.927, with associated Bonferroni-adjusted probabilities of 0.05-0.001. Baculum mass was associated with average testes mass (r = 0.927, p<0.001) and baculum length (r= 0.866, p = 0.001), but not total body mass.
The morphological condition of sampled animals showed few differences among collection regions. Although there was a substantial amount of variability in extent of subcutaneous and intraabdominal fat deposits among animals, none showed signs of severe emaciation, such as atrophy of fat. Seven of the nine mink collected from the upper Fraser River had empty stomachs, were significantly lighter (p = 0.011, males only), and had significantly less omentum tissue (p = 0.027) than counterparts from the lower reaches of the river. However, signs of emaciation were not present. In addition, male otters from the lower Fraser had larger livers than otters from the upper Columbia River (p = 0.012), and male mink from the Kootenay had larger livers and kidneys than mink from the Fraser River (p = 0.008 and p = 0.04, respectively). No mass differences in adrenal tissue were 2.0 ± 0.02 tion (Fig. 3), and there was no association 94.7 ± 2.1 6.6 ± 0.6 between PCBs and age. There were no other 100.5 ± 0.5 6.5 ± 0.2 significant associations between hepatic OC Is.
pesticide or PCB concentrations and liver, Volume 107, Number 2, February 1999 * Environmental Health Perspectives kidney, spleen, adrenal, omentum, or testes masses in mink, nor any organ size in otters. Most of the contaminant information was obtained on composite samples of otters, and direct comparisons with biological parameters cannot be made.

Discussion
Hepatic concentrations of chlorinated hydrocarbon contaminants in mink and otters collected in British Columbia ranged slightly higher than mean levels determined from the same regions during a 1990-1991 survey; however, they were about an order of magnitude less than samples from the lower reaches of the Columbia River (12) and from other North American populations (21). Although higher or equivalent to maximum means recorded previously for our study areas, international TEQ values of 27 pg/g wet weight in otter livers from the lower Fraser River and 20 pg/g in otter livers from the lower Columbia are below those considered to cause effects on reproduction of ranch mink. Leonards et al. (22) calculated critical body residues of 160-200 pg TEQs/g wet weight for litter size and kit survival effects in mink. The PCB concentration reported by Jensen et al. (23) to reduce reproductive success in female mink by 50% (50 mg/kg liver weight) was still twofold higher than the most contaminated female otter in our study (24 mg/kg liver weight). The pattern of relatively elevated concentrations of octaCDD and other higher chlorinated PCDDs and PCL)Fs, particularly in the otter pools from the lower Fraser Valley, probably indicates the heavy use of chlorophenolic biocides used for many years by the forest industry in that area. Eggs of ospreys (Pandion haliaetus) collected in other areas of the Fraser River basin had particularly high concentrations of octaCDD (up to 7,000 pg/g in a single egg) and other higher chlorinated PCDDs and PCDFs, which correlated significantly with pentachlorophenol concentrations (24).
Although we found some abnormalities in male reproductive systems, those individuals consistently had among the lowest concentrations of chlorinated hydrocarbons for both species. Where cryptorchidism (the incomplete descent of testicles) was observed, it was probably due to genetic defects sometimes associated with this condition in domestic animals (25). In some of the cases where testicles were missing and the condition of the carcass was too poor to identify a remnant of the vas deferens, the possibility of it having been removed during skinning cannot be excluded, although we considered this unlikely. However, where abnormalities were paired, as in two otters each with one undescended testicle and either a missing kidney or a missing second testicle, genetic explanations or skinning artefacts are even less likely. In particular, missing organs are more likely to have developed during fetal development. In such cases, we would not necessarily expect a relationship between presence of abnormalities and persistent contaminants in the body, as effects on reproductive development may be more related to female parental body burden.
Recent studies have reported that in utero exposure of rats to relatively low concentrations of TCDD and related PCBs can have significant effects on development of the reproductive system of offspring, without any subsequent lactational or feeding exposure (10,11). Effects on male offspring included reductions in testis weights and fertility, and effects on females included genital abnormalities, decreases in fecundity and litter size, and increases in pup mortality. If such effects are largely a function of maternal exposure, they would not be correlated necessarily with chlorinated hydrocarbon body burden in a wild mammal that had been feeding independently for at least a few months.
Nevertheless, Henny et al. (26) recently found significant correlations between PCBs and other OC contaminants and reproductive abnormalities such as smaller testes and bacula in river otters collected from the Columbia River in Oregon. Based on average hepatic PCB concentrations (as Arodor 1260) for the Oregon otters (0.04-0.65 ppm wet weight), otters from British Columbia were within the same contaminant range for that particular PCB measure, yet they showed no association between baculum size and PCB contamination. Although it is difficult to compare biological parameters without knowing the natural regional and genetic variability, average baculum size of juvenile otters from British Columbia (8.13 cm; 2 g) was roughly equivalent to juvenile otters from the Columbia River (8.3 cm; 2.62 g) and much less than that of the juveniles that Henny et al. (26) collected from an Oregon reference population (9.52 cm; 5.82 g). It is apparent that further sampling of both exposed and reference populations is required to establish confidence in such findings for wild mustelids.
Even though contaminant body burdens were lower (on a wet weight basis), juvenile male mink from British Columbia displayed a similar correlation between hepatic PCB concentration (Aroclor 1260) and baculum length as Henny found in otters (26). This may indicate that mink are more sensitive than otters to PCB-induced reproductive effects in males, especially considering that, A, .
U 1~~~~~~~~~~1 0 0.02 GM. 6.08 Li 0.12 0.14 0.1_ 0.18 0.2 Figure 3. Relationship between total polychiorinated biphenyls (PCBs; as Aroclor 1260) and baculum length in juvenile mink collected from British Columbia, [1994][1995][1996]  evaluated testicular development in young male mink exposed to bleached kraft mill effluent in the diet and found no effects in either male or female reproductive potential at the applied concentrations. On the whole, effects on male reproductive development and integrity have not been assessed, despite the evidence of significant effects in breeding females. The association found here in juvenile males exposed to relatively low concentrations of OCs suggests that reproduction may also be affected in males. Of course, whether baculum size has any bearing on reproductive success is unknown.
We recognize that the observed association between mink baculum size and hepatic PCB contamination is based on a relatively small sample size and that such a result may be a spurious finding given the large number of correlations that were studied. The observed correlation may also be a coincidental relationship, with an effect caused more by genetic and ecological variability. Nevertheless, our findings, together with the independent report of a similar association in otters from the lower Columbia (26), suggest a need for further investigation of possible effects of PCBs on reproductive development of male mustelids.
Several of the most contaminated individuals collected in our study were females, notably otters from the lower Fraser River and the lower Columbia River. From the perspective of identifring risks of reproductive Environmental Health Perspectives * Volume 107, Number  The combined results of biological and chemical investigations presented here suggest that the mink and river otter populations using these major river systems in British Columbia do not appear physiologically or reproductively compromised because of chlorinated hydrocarbon accumulation. However, the relationship between PCBs and mink baculum size warrants further study. Also, even without postulating a link with OC contaminants, the occurrence of potentially serious developmental abnormalities in several systems (reproductive, digestive, and renal) in a relatively high proportion (about 10%) of individuals from wild populations of both species should be investigated. Finally, carcasses from commercial trapping are biased against sampling adult females, which is likely the critical component of the population impacted by contaminants. Alternative sampling methods should be considered to better survey adult and female segments of the populations.