RESUMO
Keratinized tissues, including whiskers, are ideal for acquiring a record of physiological parameters. Most tissues provide a snapshot of physiological status; however, whiskers may support longitudinal sampling for reproductive and stress-related hormones, if hormones are incorporated as whiskers grow and concentrations change with physiological state. Whiskers from female Steller sea lions (Eumetopias jubatus) and northern fur seals (Callorhinus ursinus) were serially sectioned and pulverized and steroid hormones were extracted. Standard methods were used to validate enzyme immunoassay kits for cortisol, progesterone, 17ß-estradiol and testosterone. All hormones were measurable in whisker segments from both species with progesterone concentrations showing cyclical patterns, which appear to signify previous pregnancies or luteal phases. Yearly progesterone concentrations were greater in years a pup was produced compared with years when no pup was observed. Free-ranging female Steller sea lions had reproductive rates between 0 and 1.0 (0.53 ± 0.33, n = 12) using a yearly progesterone concentration of 30 pg/mg or greater to classify a reproductive year as producing a pup and below 30 pg/mg as non-reproductive. Cortisol concentrations were greater near the root and rapidly declined, lacking any obvious patterns, throughout the rest of the whisker. Progesterone and testosterone concentrations were able to help determine sex of unknown individuals. Immunohistochemistry revealed that steroid hormones most likely do not leach out of whiskers based on the deposition patterns of progesterone and cortisol being present throughout the whisker length. Overall, measuring steroid hormones in whiskers can reveal individual reproductive histories over multiple years in sea lions and fur seals. Cyclical patterns of δ15N were useful for identifying periods of up to ~10 years of growth within whiskers, and measuring both stable isotopes and hormones may be useful for differentiating periods of active gestation from diapause and potentially track multi-year reproductive histories of female otariids.
RESUMO
Vibrissae or follicle-sinus complexes (F-SCs) are highly developed mammalian sensory structures. These blood-filled sinuses are richly innervated and possess novel mechanoreceptors. Although much is known regarding the function of F-SCs in terrestrial mammals, much less is known regarding marine carnivores such as pinnipeds. Pinnipeds possess the largest, most highly innervated vibrissae of any mammal. One such pinniped is the California sea lion, which are generalist marine predators that rely heavily upon tactile discrimination capabilities. Psychophysical studies demonstrate that haptic tactile discrimination using F-SCs is exceptionally sensitive. However, our knowledge of the structure and function of F-SCs in otariids is limited. Our objectives were to investigate the innervation and microstructure of F-SCs across the mystacial vibrissal field and infer function from haptic performance studies in California sea lions. Innervation and microstructure of vibrissae differed considerably compared to similar data available for phocids. Total innervation of mystacial vibrissae was estimated to be 86,042 axons. Investigations of innervation density and investment of microvibrissae versus macrovibrissae demonstrated a significantly increased axon density per F-SC in medial microvibrissal regions compared to lateral macrovibrissae, which supports psychophysical data and somatotopic organization of the central nervous system involved with tactile discrimination capability. Innervation increased from medial microvibrissae (705 ± 125 axons/F-SC) to lateral macrovibrissae (1,447 ± 154) as well as from dorsal (541 ± 60) to ventral (1,493 ± 327) vibrissal regions. These data provide a more complete picture of the sensory ecology of this important aquatic mammalian lineage; the specialization of peripheral sensory structures, central nervous structures with demonstrated enhanced haptic capabilities behaviorally has likely led to the ecological success of California sea lions.