Ultrastructural localization of hair keratin homologs in the claw of the lizard Anolis carolinensis

The claw of lizards is largely composed of beta‐keratins, also referred to as keratin‐associated beta‐proteins. Recently, we have reported that the genome of the lizard Anolis carolinensis contains alpha keratin genes homologous to hair keratins typical of hairs and claws of mammals. Molecular and immunohistochemical studies demonstrated that two hair keratin homologs named hard acid keratin 1 (HA1) and hard basic keratin 1 (HB1) are expressed in keratinocytes forming the claws of A. carolinensis. Here, we extended the immunocytochemical localization of the novel reptilian keratins to the ultrastructural level. After sectioning, claws were subjected to immunogold labeling using antibodies against HA1, HB1, and, for comparison, beta‐keratins. Electron microscopy showed that the randomly organized network of tonofilaments in basal and suprabasal keratinocytes becomes organized in long and parallel bundles of keratin in precorneous layers, resembling cortical cells of hairs. Entering the cornified part of the claw, the elongated corneous cells fuse and accumulate corneous material. HA1 and HB1 are absent in the basal layer and lower spinosus layers of the claw and are expressed in the upper and precorneous layers, including the elongating corneocytes. The labeling for alpha‐keratin was loosely associated with filament structures forming the fibrous framework of the claws. The ultrastructural distribution pattern of hard alpha‐keratins resembled that of beta‐keratins, which is compatible with the hypothesis of an interaction during claw morphogenesis. The data on the ultrastructural localization of hair keratin homologs facilitate a comparison of lizard claws and mammalian hard epidermal appendages containing hair keratins. J. Morphol., 2011. © 2010 Wiley‐Liss, Inc.     

Compensatory testicular hypertrophy in the lizard Anolis carolinensis

In reproductively responsive, male Anolis carolinensis undergoing artificially induced testicular recrudescence, unilateral orchidectomy of the left testis produced compensatory hypertrophy of the remaining testis. Testosterone inhibited this compensatory testicular hypertrophy on a weight basis, but did not reduce the rate of spermatogenic development. These results suggest that there is a mechanism of testosterone feedback in Anolis carolinensis that controls gonadotropin secretion during the recrudescent phase. In reproductively thermorefractory lizards, unilateral orchidectomy had no effect on the remaining testis. Administration of exogenous follicle-stimulating hormone to refractory animals increased testicular weight and stage of spermatogenic development. Sensitivity to gonadotropin, as well as failure of unilateral orchidectomy to produce compensatory hypertrophy in refractory male anoles, suggests that the control of the refractory period in A. carolinensis results from physiological mechanisms in the pituitary gland or brain rather than in the testis.     

Estrogen localization in the brain of the lizard, Anolis carolinensis (1)

Estrogen induces reproductive behavior in lizards by acting on specific areas of the brain. Neural areas that selectively concentrate radioactivity after 3-h-estradiol administration were mapped using thawmount autoradiography. Major accumulations of hormone-concentrating cells occur in the medial preoptic area, basal hypothalamus, amygdala (n. vetromedialis telencephali) and in and around the torus semicircularis. Numerous smaller accumulations are also described and the topographical distribution is compared with that of avian and mammalian species.     

Sperm transfer and storage in the lizard,Anolis carolinensis

The relationship of the hemipenis to the cloaca in copula and sperm storage and transport in the female oviduct were studied in Anolis carolinensis using light and scanning electron microscopy. During copulation, the hemipenis does not penetrate beyond the cloaca, but the two apical openings of the bifurcate sulcus spermaticus appose the openings of the oviducts from the cloaca. Sperm enter the sperm storage tubules between 2 and 6 hr after insemination and small amounts of sperm reach the infundibulum 6 to 24 hr following mating. Sperm storage tubules are embedded in the wall of the utero-vaginal transition, and are formed by the folding and fusion of the oviducal epithelium. The importance of the hemipenile-cloacal relationship and the role of sperm storage in the life history of A. carolinensis are discussed.     

Glucosylceramide in the androgen-responsive kidney of the lizard Anolis carolinensis

During the spring breeding season of the American chameleon, Anolis carolinensis, elevated levels of glucosylceramides which contain hydroxy fatty acids are produced in the kidneys of males but not females. Hyperproduction of this glycolipid is also induced by testosterone. The testosterone-induced hypertrophy of epithelial cells in the proximal tubules of the mouse kidney seems an analogous phenomenon and an elevated concentration of specific glycolipids in the male mouse kidney has been previously demonstrated. Thus the formation of renal glycolipids in response to testosterone may be a widespread feature in vertebrates.     

Incubation temperature modifies neonatal thermoregulation in the lizard Anolis carolinensis

The thermal environment experienced during embryonic development can profoundly affect the phenotype, and potentially the fitness, of ectothermic animals. We examined the effect of incubation temperature on the thermal preferences of juveniles in the oviparous lizard, Anolis carolinensis. Temperature preference trials were conducted in a laboratory thermal gradient within 48 hr of hatching and after 22-27 days of maintenance in a common laboratory environment. Incubation temperature had a significant effect on the upper limit of the interquartile range (IQR) of temperatures selected by A. carolinensis within the first 2 days after hatching. Between the first and second trials, the IQR of selected temperatures decreased significantly and both the lower limit of the IQR and the median selected temperature increased significantly. This, along with a significant incubation temperature by time interaction in the upper limit of the IQR, resulted in a pattern of convergence in thermoregulation among treatment groups. The initial differences in selected temperatures, as well as the shift in selected temperatures between first and second trials, demonstrate plasticity in temperature selection. As a previous study failed to find environmentally induced plasticity in temperature selection in adult A. carolinensis, this study suggests that this type of plasticity is exclusive to the period of neonatal development.     

Chromatophores and color change in the lizard,Anolis carolinensis

Summary The skin of the lizard, Anolis carolinensis, changes rapidly from bright green to a dark brown color in response to melanophore stimulating hormone (MSH). Chromatophores responsible for color changes of the skin are xanthophores which lie just beneath the basal lamina containing pterinosomes and carotenoid vesicles. Iridophores lying immediately below the xanthophores contain regularly arranged rows of reflecting platelets. Melanophores containing melanosomes are present immediately below the iridophores. The ultrastructural features of these chromatophores and their pigmentary organelles are described. The color of Anolis skin is determined by the position of the melanosomes within the melanophores which is regulated by MSH and other hormones such as norepinephrine. Skins are green when melanosomes are located in a perinuclear position within melanophores. In response to MSH, they migrate into the terminal processes of the melanophores which overlie the xanthophores above, thus effectively preventing light penetration to the iridophores below, resulting in skins becoming brown. The structural and functional characteristics of Anolis chromatophores are compared to the dermal chromatophore unit of the frog.This study was supported in part by GB-8347 from the National Science Foundation.Contribution No. 244, Department of Biology, Wayne State University.The authors are indebted to Dr. Joseph T. Bagnara for his encouragement during the study and to Dr. Wayne Ferris for his advice and the use of his electron microscope laboratory.     

Thermoregulatory function of the parietal eye in the lizard Anolis carolinensis

Summary Animals were acclimitized to a daily cycle of 15–25°C and a photoperiod of LD 12:12. Parietalectomized animals in an experimental thermal gradient (15°C–40°C, LD 12:12) selected significantly higher temperatures than controls at all hours of the day except from 0800–1200. These results suggest that the lizard parapineal plays a direct role in thermoregulation in addition to the indirect function as an illuminometer.     

Control of the pars intermedia of the lizard,Anolis carolinensis

Summary The capacity of colour change in intact lizards and in animals with a transected hypophysial stalk was studied during extended periods. It was concluded that, with certain exceptions, the skin colour of the lizards gives information on the circulating levels of MSH, and thereby on the function of the pars intermedia.After transection of the hypophysial stalk, three phases of chromatic behaviour were recognised. During Phase I, which lasted for about 6 days (average), dark skin was retained irrespective of the colour of the background (= high MSH levels), whereas Phase II (19 days) was characterised by the inability of the animals to become brown (= low MSH levels). A gradual recovery toward normal adaptive capacity was seen during Phase III.In the disconnected neuro-intermediate lobe, aldehyde fuchsin (AF)-positive material in the rostral region rapidly clumped and disappeared within a few days. In the caudal portion, the stainability and the varicose arrangement of fibres were retained longer, but disappeared within approximately 14 days after the operation. Proximal to the lesion, the preoptic system exhibited a marked increase in stainability with AF, starting in the median eminence and progressing in a retrograde direction toward the peptidergic nuclei.Revascularisation of the disconnected neuro-intermediate lobe occurred during the first few days. A reinnervation of AF-fibres across the transected area into the neural lobe was observed during Phase III in most animals, but AF-fibres did not reoccupy the entire lobe. In association with an outgrowth of capillaries, the regenerating fibres formed new neural lobules. This regenerative process was accompanied by an increase in blood supply from the primary plexus of the median eminence to the neuro-intermediate lobe.Supported by grants from the Swedish Natural Science Research Council and the Royal Physiographic Society of LundThe authors are indebted to Mrs. Ingrid Hallberg and Mrs. Kirsten Thörneby for valuable technical assistance and skillful attention to the animals and to Miss Inger Norling for photographic aid     

Control of the pars intermedia of the lizard,Anolis carolinensis

Summary The ultrastructure of the intermediate lobe of the hypophysis was studied in Anolis carolinensis with the use of a threefold aldehyde fixative. Lizards with a brown skin were selected. The possibility of two types of secretory cells is discussed; neither cell type is innervated. Type I cells are rarely found and contain dense granules approximately 0.3 m in diameter; Type II cells vary widely in secretory activity. Most of the Type II cells contain a large number of dense secretory granules (up to about 1.3 m in diameter) almost filling the cytoplasm. Rough endoplasmic reticulum (RER), Golgi apparatus and mitochondria are poorly developed. Only some of these cells show signs suggesting a high secretory activity, namely a well developed RER, Golgi apparatus and numerous mitochondria. In these cells the RER sometimes forms large intracisternal droplets (up to 7 m in diameter). Two of the animals exhibited a more uniform, high secretory activity. Large (about 2 m in diameter), pale vacuoles, probably of extracellular character, were found mostly in the vicinity of the perivascular septum. Their role in the release of MSH is discussed. The present data, which are discussed with reference to earlier findings (Forbes, 1972), form the morphological basis for an experimental study on regulation of MSH release (Larsson et al., 1979).Supported by grants from the Swedish Natural Science Research Council (to P. Meurling) and the Royal Physiographic Society of LundThe authors are indebted to Mrs. Ingrid Hallberg, Mrs. Kirsten Thörneby and Mrs. Lena Sandell for valuable technical assistance and to Miss Inger Norling for photographic aid     

Control of the pars intermedia of the lizard,Anolis carolinensis

Summary The distribution of the tracer substance horseradish peroxidase (HRP, Mw 40,000) in the neuro-intermediate lobe of the lizard, Anolis carolinensis, was studied at various time intervals (13 min to 24 h) after vascular injection. HRP rapidly entered the extracellular lumen of the neural lobe, but did not penetrate into the third ventricle. The tracer was found in micropinocytotic vesicles (MPVs) of ependymal cells within 13 min after injection. The number of cellular inclusions containing HRP increased during the period of observation (24 h). The tracer was sparsely taken up by aminergic and peptidergic nerve terminals of the external layer. After transection of the hypophysial stalk, numerous dense, labelled droplets were found in the peptidergic terminals, and the number of labelled inclusions in ependymal cells increased.MPVs were frequently found in extensions of stellate cells of the intermediate lobe, and endocytotic vacuoles (EVs) developed especially in the perikaryon. HRP was also found in large cisternae of the secretory cells, appearing predominantly towards the perivascular septum (PVS). These cisternae were found to communicate with the extracellular lumen, probably representing a system of the extracellular space extending into the secretory cell. After transection of the hypophysial stalk, there was an increase in the number of small EVs in secretory cells of the intermediate lobe.The results are discussed in terms of MSH-release regulation and possible participation of the extracellular lumen, glial and stellate cells in the transport of regulating factors and secretory material.Supported by grants from the Swedish Natural Science Research Council (to Dr. Patrick Meurling) and the Royal Physiographic Society of LundThe author is indebted to Mrs. Lena Sandell and Miss Inger Norling for excellent technical assistance and photographic aid; and to Dr. Rolf Libelius and Dr. Ingmar Lundquist for generous advice and stimulating discussions concerning the tracer technique     

Distribution of arginine vasotocin in the brain of the lizard Anolis carolinensis

Summary The distribution of immunoreactive arginine vasotocin (AVT-ir) was determined in the brain of the lizard Anolis carolinensis. Cells and fibers containing AVT-ir were found in the medial septal region, lamina terminalis, lateral forebrain bundle, preoptic area, supraoptic nucleus, anterior hypothalamus, paraventricular nucleus, periventricular nucleus, arcuate nucleus, and ventromedial nucleus of the thalamus. Occasional AVT-ir cells were found in the interpeduncular nucleus. Fibers containing AVT-ir were found in the cortex, around the olfactory ventricle, in the diagonal band of Broca, amygdala area, dorsal ventricular ridge, striatum, nucleus accumbens, septum, ventromedial hypothalamus, lateral hypothalamus, medial forebrain bundle, median eminence, pars nervosa, nucleus of the solitary tract, locus coeruleus, cerebellar cortex (granular layer), dorsal part of the nucleus of the lateral lemniscus, substantia nigra, and myelencephalon. The intensity of AVT-ir staining was, in general, greater in males than in females. Comparison of AVT-ir distribution in A. carolinensis with those previously published for other reptilian species revealed species-specific differences in distribution of AVT.     

Control of the pars intermedia of the lizard,Anolis carolinensis

Summary Morphological changes in the disconnected neuro-intermediate lobe were studied in the lizard, Anolis carolinensis from the 2nd to the 14th post-operative day using a threefold aldehyde fixative (Rodríguez, 1969). Two phases of colour change capacity were exhibited: Phase I started immediately after the transection, lasted for 6 days (mean) and was characterised by an excessive MSH release (brown skin). This phase proceeded gradually into Phase II, designated by an interruption of the MSH release (green skin).The degenerative processes and final elimination of neurons in the disconnected neural lobe propagate in a rostro-caudal direction from the transected area. The aminergic fibres (Type II) disappear within 2 days postoperatively, whereas the degeneration continues for more than 10 days in the peptidergic fibres (Type III, IV and V). The glia cells (ependyma and pituicytes) serve as very active macrophages, engulfing fragments of axons already affected by autolysis and transferring them into glial lysosomes. No apparent morphological changes occur in the shift from Phase I to II.The great majority of the secretory cells of the intermediate lobe are not affected by degenerative processes and appear to be markedly activated by the stalk transection. They exhibit numerous mitochondria, well-developed Golgi complexes forming numerous Golgi vesicles and extensive parallel cisternae of the rough endoplasmic reticulum, sometimes forming large intracisternal droplets (7 m in diameter). Numerous pale vacuoles are seen, especially toward the intact capillaries, suggesting their coupling to the MSH release by extension of the active membrane area toward the perivascular septum. The number of these vacuoles is very markedly reduced in Phase II (no release), whereas the formation of new granules seems to proceed in early stages. The interruption of the MSH release implies a successive refilling of gradually growing secretory granules and a concomitant reduction in the development of the synthetic apparatus. Mechanisms probably involved in the control of the synthesis and release of MSH are discussed.Supported by grants from the Swedish Natural Science Research Council (to P. Meurling) and the Royal Physiographic Society of LundThe authors are indebted to Mrs. Lena Sandell, Mrs. Ingrid Hallberg and Mrs. Kirsten Thörneby for technical assistance and skillful attention of the animals and to Miss Inger Norling for photographic aid.