Theory on the evolutionary history of lamprey metamorphosis: role of reproductive and thyroid axes

Metamorphosis is a developmental strategy used by only a small number of extant fishes and little is known about its phylogenetic development during the evolution history of this large group of vertebrates. The present report provides a putative evolutionary history of metamorphosis in the lamprey, an extant agnathan with direct descendancy from some of the oldest known vertebrates. The study reviews recent data on the role of the thyroid gland and its hormones in metamorphosis, summarizes some recent views on the evolution of the endostyle/follicular thyroid in lampreys, and provides new data on the content of two gonadotropin-releasing hormones (GnRH-I and -III) in brain during goitrogen-stimulated, precocious metamorphosis. These new data support an earlier viewpoint of a relationship between thyroid and reproductive axes during metamorphosis. It is proposed that the earliest lampreys were paedomorphic larvae and they lived in a marine environment; as such, they resembled in many ways the larvae from which the ancient protochordates, Larvacea, are derived. The iodide-concentrating efficiency of the endostyle was a critical factor in the evolution of metamorphosis and this gland was replaced by a follicular thyroid, for postmetamorphic animals needed to store iodine following their invasion of freshwater. Larval growth and postmetamorphic reproduction in freshwater became fixtures in the lamprey life cycle; a non-parasitic adult life-history type appeared later. The presence among extant lampreys of two different adult life-history types, and examples of the lability of the timing of sexual maturation in some species, imply that there has been a complex interplay between the thyroid and reproductive axes during the evolution of metamorphosis in lampreys. This proposal is consistent with what we know of interplay of these axes in extant adult lampreys and with the long-held viewpoint that thyroid function and sexual maturation are an association with an ancient history.     

Analysis of lamprey and hagfish genes reveals a complex history of gene duplications during early vertebrate evolution

It has been proposed that two events of duplication of the entire genome occurred early in vertebrate history (2R hypothesis). Several phylogenetic studies with a few gene families (mostly Hox genes and proteins from the MHC) have tried to confirm these polyploidization events. However, data from a single locus cannot explain the evolutionary history of a complete genome. To study this 2R hypothesis, we have taken advantage of the phylogenetic position of the lamprey to study the history of gene duplications in vertebrates. We selected most gene families that contain several paralogous genes in vertebrates and for which lamprey genes and an out-group are known in databases. In addition, we isolated members of the nuclear receptor superfamily in lamprey. Hagfish genes were also analyzed and found to confirm the lamprey gene analysis. Consistent with the 2R hypothesis, the phylogenetic analysis of 33 selected gene families, dispersed through the whole genome, revealed that one period of gene duplication arose before the lamprey-gnathostome split and this was followed by a second period of gene duplication after the lamprey-gnathostome split. Nevertheless, our analysis suggests that numerous gene losses and other gene-genome duplications occurred during the evolution of the vertebrate genomes. Thus, the complexity of all the paralogy groups present in vertebrates should be explained by the contribution of genome duplications (2R hypothesis), extra gene duplications, and gene losses.     

Proteins immunoreactive with antibody against a human leptin fragment are found in serum and tissues of the sea lamprey, Petromyzon marinus L

An affinity-purified, polyclonal antibody raised against a peptide corresponding to amino acids 137–156 at the carboxy terminus of human leptin (16 kD) was used to search for immunoreactive protein(s) in the lamprey, Petromyzon marinus. Immunoblots of serum from different phases of the life cycle showed the presence of a 65-kD immunoreactive protein in the larvae and all stages of metamorphosis but not in feeding juvenile and upstream migrant adults. Extracts of tissues known to store fat were also examined using the same antibody. Muscle and fat column from all phases tested (larvae, stage 2 and 4 metamorphosing animals, feeding juveniles and upstream migrants) showed 100- and 50-kD immunoreactive proteins. Extracts of nephric fold, the primary site of fat storage during metamorphosis, lacked the 100-kD protein but had the 50 kD; they also had a 16 kD immunoreactive protein not found in the other tissues. The immunoreactivity of the proteins of both serum and tissue extracts was blocked by pretreatment of the antibody with the leptin-derived antigen. The results indicate that P. marinus has proteins that share at least one epitope with mammalian leptin.     

Distribution of55Fe in juvenile adult lampreys,Petromyzon marinus L., following oral intubation of the isotope

Summary The capacity of a sanguivorous lamprey,Petromyzon marinus L., to deal with ingested iron was studied over time using autoradiography and scintillation counting of solubilized tissue samples after intubation of the oesophagus with a single dose of⁵⁵ferrous citrate. A highly efficient mechanism for absorption in the anterior intestine was recognized with 17% of the intubated radioactivity absorbed into the body after only 5 min, 66% by 3 h, and almost 80% by 21 h. Iron concentration in the epithelial cells of the anterior intestine may be a factor in restricting iron absorption during spontaneous feeding. A decline in total body radioactivity over the 15 days following iron intubation probably results from transport of the metal in the blood and release of radioiron from the mucous cells of the posterior intestine. The kidneys appear to play a smaller but still significant role in iron loss. Gradual increases in radioiron concentration (cpm g^–1 wet weight) and percent of total body radioactivity occur in the liver (2 to 26%), carcass (14 to 37%), and integument (4 to 12%) during the course of the experiment, indicating that these are the chief sites of iron storage during times of metal excess. However, eventually integument may also be a site of iron excretion. Significant fluctuations in radioiron concentration (cpm ml^–1) in whole blood during the 15 day period can be correlated with transport of the metal to sites of storage and excretion, and maybe with incorporation into haemoglobin and with erythropoietic activity. Feeding adult lampreys represent a valuable system, with both general and unique characters, for studying iron metabolism in vertebrates.     

Stanniocalcin-like immunoreactivity in the corpuscles of Stannius of the bowfin Amia calva L.

Summary We used an antiserum against salmon stanniocalcin in an immunohistochemical, immunocytochemical, and Western blot analysis of bowfin (Amia calva) corpuscles of stannius. The bowfin is one of two extant holostean species with ancient ancestral links to modern-day bony fishes. The corpuscles of Stannius (white corpuscles) of the bowfin were scattered throughout much of the kidney among the adrenocortical homolog (yellow corpuscles) but could be distinguished from the adrenocortical homolog by their positive staining with both the periodic acid-Schiff reaction and a salmon stanniocalcin antiserum. Immunoreactivity was confined to cytoplamic granules and was absent when the antiserum was blocked with salmon stanniocalcin or with a crude extract of bowfin corpuscles of Stannius. When bowfin corpuscle-of-Stannius extracts were subjected to sodium dodecyl sulphate electrophoresis and Western blot analysis, two closely spaced bands were evident (43–45 kDa). Staining of both bands was abolished by pre-absorption of the antiserum with salmon stanniocalcin. In comparison to salmon stanniocalcin, the reputed bowfin hormone migrated faster in gels, suggesting a smaller apparent size. The purification of bowfin stanniocalcin should yield important new information regarding the evolution of this unique calcium-regulating hormone.     

Relocalization of membrane enzymes accompanies biliary atresia in lamprey liver

Summary Light- and electron-microscopic histochemical procedures were used to show the distribution of the membrane-bound enzymes alkaline phosphatase (Alp), adenosine triphosphatase (ATPase), and 5-nucleotidase (5-nuc) in the livers of lamprey, Petromyzon marinus, throughout the life cycle. In larvae, the three enzymes are located at the biliary pole on the canalicular membranes of microvilli. At metamorphosis the enzymes become localized at all lateral cell surfaces of hepatocytes as bile canaliculi degenerate in the programmed regression of the entire biliary tree. This latter pattern of enzyme distribution persists during the parasitic adult phase but no activity is evident in individuals in the spawning migration. As the timing of the relocalization of enzymatic activity correlates well with a build-up of bile products and iron during metamorphosis, it is suggested that the lateral surface may be the new site for transport of these products.Supported by NSERC of Canada grant no. A5945 to J.H.Y.     

Intracellular distribution of iron (and associated elements) in various cell types of larvae and juveniles of the sea lamprey (Petromyzon marinus)

The intracellular distribution of iron and other elements was examined in various cell types in larvae and juveniles of the sea lamprey (Petromyzon marinus) using transmission electron microscopy and energy dispersive x-ray microanalysis. The objective was to establish whether there are cell-type specific relationships between iron and other elements in the iron-rich organs and tissues (adipose tissue, opisthonephric kidneys, dorsal integument, fat column, liver, and posterior intestine) of these two life cycle periods. Iron was localized within either dense bodies (presumptive lysosomes, siderosomes) or in the cytoplasmic matrix of many cell types where it was viewed as haemosiderin/ferritin and ferritin, respectively. Presumptive lysosomes of adipocytes of the nephric folds, dorsal integument, and fat column possessed iron and sulphur and this elemental association was also prevalent in the epithelia of the larval proximal tubules and in the posterior intestine and epidermis of both life periods. Macrophages of the larval haemopoietic tissue (posterior intestine) and of the juvenile opisthonephros, which were described as melanomacrophages because of their granules, possessed iron, sulphur, and calcium. This elemental association was also noted in the presumptive lysosomes of the iron-loaded hepatocytes of the juvenile liver while no elements could be detected in these cells in the larval organ. The variations and similarities in elemental associations between the cell types in each life period and at different life periods is discussed in the context of specific cell functions related to the prevention of iron toxicity. These functions are sequestration of iron and storage as the less toxic haemosiderin (larval adipocytes, macrophages, juvenile hepatocytes) or as part of a process of elimination of excesses of this metal (posterior intestine, dorsal epidermal cells). Due to its unique ability to deal with copious amounts of iron at all periods of the life cycle, the lamprey serves as an important model for studies of iron loading in vertebrates.     

Distribution of ferric iron in larval lampreys, Petromyzon marinus L

The distribution and abundance of ferric iron in larval lampreys (Petromyzon marinus L.) were investigated using light microscopy and the Prussian blue stain. Animals from various watersheds contained different concentrations of iron, although the sites of deposition were the same for all animals. A major portion of iron is within adipose tissue, while the liver, and cartilage contain predominantly low to trace amounts of iron, respectively. Iron is associated with fibrous connective tissue in several places in the body, and this association may have particular significance in the inner ear. Iron is also located in cells of the meninges. The presence of iron in the epithelial cells of the posterior intestine may reflect elimination of the metal through the extrusion of iron-loaded cells into the intestinal lumen. Iron within mucous cells of the epidermis, suggest elimination of iron during mucous secretion. Iron-loaded cells of bipolar shape are also present in the epidermis, but are particularly prominent around the branchiopore. Low concentrations of iron are observed within in melanin-containing macrophages (melano-macrophages) in regions of iron absorption, erythrophagocytosis, and haemopoiesis. High levels of iron in the epithelia and lumina of pronephric tubules are concomitant with degeneration of this organ. These data are evidence of the wide spread distribution of iron in lamprey tissues and additional evidence for the potential value of lampreys for the study of iron metabolism in vertebrates.