Morphology of the pancreas of some species belonging to the genera Phelsuma and Gecko (family Gekkonidae): evidence of apoptotic process during the seasonal cycle

Does the pancreas of gekkotans differentiate similarly? Developmental structural and 3D studies of the mourning gecko (Lepidodactylus lugubris) and the leopard gecko (Eublepharis macularius)

This study investigated the pancreas differentiation of two species of gekkotan families-the mourning gecko Lepidodactylus lugubris (Gekkonidae) and the leopard gecko Eublepharis macularius (Eublepharidae)-based on two-dimensional (2D) histological samples and three-dimensional (3D) reconstructions of the position of the pancreatic buds and the surrounding organs. The results showed that at the moment of egg laying, the pancreas of L. lugubris is composed of three distinct primordia: one dorsal and two ventral. The dorsal primordium differentiates earlier than either ventral primordium. The right ventral primordium is more prominent and distinctive, starting to form earlier than the left one. Moreover, at this time, the pancreas of the leopard gecko is composed of the dorsal and right ventral primordium and the duct of the left ventral primordium. It means that the leopard gecko's left primordium is a transitional structure. These results indicate that the early development of the gekkotan pancreas is species specific. The pancreatic buds of the leopard and mourning gecko initially enter the duodenum by separate outlets, similar to the pancreas of other vertebrates. The pancreatic buds (3 of the mourning gecko and 2 of the leopard gecko) fuse quickly and form an embryonic pancreas. After that, the structure of this organ changes. After fusion, the pancreas of both gekkotans comprises four parts: the head of the pancreas (central region) and three lobes: upper, splenic, and lower. This organ develops gradually and is very well distinguished at hatching time. In both gekkotan species, cystic, hepatic, and pancreatic ducts enter the duodenum within the papilla. During gekkotan pancreas differentiation, the connection between the common bile duct and the dorsal pancreatic duct is associated with intestinal rotation, similar to other vertebrates.

Reptiles in Space Missions: Results and Perspectives

Reptiles are a rare model object for space research. However, some reptile species demonstrate effective adaptation to spaceflight conditions. The main scope of this review is a comparative analysis of reptile experimental exposure in weightlessness, demonstrating the advantages and shortcomings of this model. The description of the known reptile experiments using turtles and geckos in the space and parabolic flight experiments is provided. Behavior, skeletal bones (morphology, histology, and X-ray microtomography), internal organs, and the nervous system (morphology, histology, and immunohistochemistry) are studied in the spaceflight experiments to date, while molecular and physiological results are restricted. Therefore, the results are discussed in the scope of molecular data collected from mammalian (mainly rodents) specimens and cell cultures in the parabolic and orbital flights and simulated microgravity. The published data are compared with the results of the gecko model studies after the 12–44.5-day spaceflights with special reference to the unique peculiarities of the gecko model for the orbital experiments. The complex study of thick-toed geckos after three spaceflights, in which all geckos survived and demonstrated effective adaptation to spaceflight conditions, was performed. However, future investigations are needed to study molecular mechanisms of gecko adaptation in space.

Molecular identification of single hormone-encoding proglucagon cDNA isoforms from squamates and their abundant expression

Among ectothermic reptiles, the order Squamata has adapted most successfully to the terrestrial environment. However, the physiological background of this success remains unknown. Since the regulation of energy metabolism provides an important insight into terrestrial adaption by ectothermic animals, we focused on proglucagon-derived peptides (PGDPs). In the process of cloning proglucagon mRNA in geckos, we identified several novel proglucagon (PG) cDNA isoforms. They were tissue-specifically and strongly expressed in the pancreas and small intestine of the geckos, suggesting their biological relevance. Therefore, in order to clarify whether these novel cDNA isoforms are phylogenetically conserved, we performed the additional molecular characterization of proglucagon cDNAs from several representative species of the Squamata and Testudine clade and examined the expression of proglucagon mRNAs in the small intestine and pancreas. In the present study, a total of 7 proglucagon cDNA isoforms were identified and divided into two groups (Classes A and B) based on the 3'-UTR sequence of each isoform. The longest isoform of each group (named PG-A₁ and PG-B₁, respectively) had the same molecular characteristics as those previously reported from chickens and reptiles, namely, PG-A and PG-B. Other 5 isoforms were novel-type cDNAs, and were the products of exon skipping (named PG-A₂, PG-A_2s, PG-B₂, PG-B_2s, and PG-B₃). Some of these isoforms coded for only one peptide hormone (GLP-1 or GLP-2). This is the first identification of single hormone-encoding proglucagon cDNAs in vertebrates. Moreover, an expression analysis of these isoforms revealed that single hormone-encoding proglucagon mRNAs were predominantly expressed with tissue and lineage specificities in the reptile clade. Collectively, the present results suggest an independent regulatory system for GLP-1 and GLP-2 secretion and indicate the plasticity of proglucagon genes in expressing different isoforms in different tissues in Squamata. These results also provide insights into the plastic energy metabolic system of Squamata in accordance with various habitats in the terrestrial environment, supporting their successful prosperity.

Localization of amylin-like immunoreactivity in the striped velvet gecko pancreas

Immunohistochemical techniques were employed to investigate the distribution of amylin-like immunoreactive cells in the pancreas of gecko Homopholis fasciata. Four types of endocrine cells were distinguished: insulin immunoreactive (B cells), pancreatic polypeptide immunoreactive (PP cells), glucagon and pancreatic polypeptide immunoreactive (A/PP cells) and somatostatin immunoreactive cells (D cells). Pancreatic islets contained B, A/PP and D cells, whereas extrainsular regions contained B, D and PP cells. In the pancreatic islets, amylin-like immunoreactive cells corresponded to B cells, but not to A/PP or D cells. In the extrainsular regions, amylin-like immunoreactive cells corresponded to either B or PP cells. Amylin secreted from intrainsular B cells may regulate pancreatic hormone secretion in an autocrine and/or a paracrine fashion. On the other hand, amylin secreted from extrainsular PP and B cells, and/or intrainsular B cells may participate in the modulation of calcium homoeostasis in an endocrine fashion.

Molecular characterization of insulin from squamate reptiles reveals sequence diversity and possible adaptive evolution

The Squamata are the most adaptive and prosperous group among ectothermic amniotes, reptiles, due to their species-richness and geographically wide habitat. Although the molecular mechanisms underlying their prosperity remain largely unknown, unique features have been reported from hormones that regulate energy metabolism. Insulin, a central anabolic hormone, is one such hormone, as its roles and effectiveness in regulation of blood glucose levels remain to be examined in squamates. In the present study, cDNAs coding for insulin were isolated from multiple species that represent various groups of squamates. The deduced amino acid sequences showed a high degree of divergence, with four lineages showing obviously higher number of amino acid substitutions than most of vertebrates, from teleosts to mammals. Among 18 sites presented to comprise the two receptor binding surfaces (one with 12 sites and the other with 6 sites), substitutions were observed in 13 sites. Among them was the substitution of HisB10, which results in the loss of the ability to hexamerize. Furthermore, three of these substitutions were reported to increase mitogenicity in human analogues. These substitutions were also reported from insulin of hystricomorph rodents and agnathan fishes, whose mitogenic potency have been shown to be increased. The estimated value of the non-synonymous-to-synonymous substitution ratio (ω) for the Squamata clade was larger than those of the other reptiles and aves. Even higher values were estimated for several lineages among squamates. These results, together with the regulatory mechanisms of digestion and nutrient assimilation in squamates, suggested a possible adaptive process through the molecular evolution of squamate INS. Further studies on the roles of insulin, in relation to the physiological and ecological traits of squamate species, will provide an insight into the molecular mechanisms that have led to the adaptivity and prosperity of squamates.

Comparative Pancreatic Pathology

Spontaneous pathologies of the pancreas are important causes of morbidity and mortality in some veterinary species and rare in others. As in human beings, the pancreas of most domestic and exotic animals is a composite organ with both endocrine and exocrine functions. The similarities between structure and function of porcine, canine, and human pancreata are such that the pig and dog serve as valuable models in basic and translational studies, most recently for efforts aimed at modeling pancreatitis and diabetes, developing functional and sustainable replacement of endocrine functions, and in imaging and manipulation studies.

This article will provide a brief review of spontaneous veterinary diseases and their underlying mechanisms and the morphological features that reflect these alterations. Several species- or breed-specific conditions and the effects of selected systemic diseases on the pancreas are also discussed. The contributions to our knowledge of pancreatic physiology and pathology by small mammal (rodent) and engineered animal models and the in-depth mechanisms homologous to those in the human pancreas are covered in other sections of this article.