28S and 18S rDNA sequences support the monophyly of lampreys and hagfishes.

Resolving the interrelationships of three major extant lineages of vertebrates (hagfishes, lampreys, and gnathostomes) is a particularly important issue in evolution, because the basal resolution critically influences our understanding of primitive vertebrate characters. A consensus has emerged over the last 20 years that lampreys are the sister group to the gnathostomes and the hagfishes represent an ancient, basal lineage. This hypothesis has essentially displaced the classical hypothesis of monophyly of the cyclostomes (lampreys plus hagfishes). To test these hypotheses, we compared nearly complete ribosomal DNA sequences from each of these major lineages, as well as those from a cephalochordate and a urochordate, which represent a paraphyletic outgroup for assessing the basal vertebrate relationships. For this comparison, 92%-99% complete 28S rDNA sequences were obtained from the lancelet Branchiostoma floridae, the hagfish Eptatretus stouti, the lamprey Petromyzon marinus, and cartilaginous fishes Hydrolagus colliei and Squalus acanthias and were then analyzed with previously reported 28S and 18S rDNA sequences from other chordates. We conducted conventional (nonparametric) bootstrap analyses, under maximum-likelihood, parsimony, and minimum-evolution (using LogDet distances) criteria, of both 28S and 18S rDNA sequences considered separately and combined. All these analyses provide moderate to very strong support for the monophyly of the cyclostomes. Furthermore, the currently accepted hypothesis of a lamprey-gnathostome clade is moderately rejected by the Kishino-Hasegawa test (P = 0.099) and resoundingly rejected by parametric bootstrap tests (P < 0.01) in favor of monophyly of living cyclostomes. Another significant finding is that the hagfish E. stouti has the longest 28S rDNA gene known in any organism (> 5,200 nt).

Categorization of the mitochondria-rich cells in the gill epithelium of the freshwater phases in the life cycle of lampreys

The distribution and ultrastructure of the mitochondria-rich (MR) cells in the gills of larval (ammocoetes) and adult lampreys (Petromyzon marinus and Geotria australis) have been studied. One type of MR cell, which is found only in ammocoetes, occurs in groups on and between gill lamellae. Freeze-fracture replicas show that the apical membrane of this ammocoete MR cell contains globular particles. The second type of MR cell, which is present in both ammocoetes and adults in freshwater, is located between lamellae and at the base of the filament. This cell usually occurs singly and is typically intercalated between ammocoete MR cells in larval lampreys and between pavement cells and pavement and chloride cells in adult lampreys. It contains rod-shaped particles in either the apical membrane (subtype A) or, far less frequently, the lateral membrane (subtype B) and in membranes of cytoplasmic vesicles and tubules. These features characterize this intercalated MR cell as a member of a group of MR cells that are also found in urinary epithelia of tetrapods and the amphibian epidermis, where they are involved in H+ and HCO3- secretion. Because this type of MR cell disappears when the young adult lamprey enters the sea and reappears immediately after the fully grown adult re-enters freshwater on its spawning run, it is presumably essential for osmoregulation in freshwater. On the basis of electrophysiological studies on frog skin, it is proposed that the subtype A of the branchial intercalated MR cell of lampreys provides the driving force for the Na+ uptake by active H+ secretion. By analogy with urinary epithelia, the subtype B cells may exchange Cl- for HCO3-.

Toxicant extraction efficiency and branchial NaCl fluxes in lampreys exposed to Kepone.

Freshwater fish (larval lampreys Petromyzon marinus) occupied plastic tubes and ventilated aqueous solutions (around 1.0 mg/L) of the organochlorine pesticide Kepone at 13 degrees C. The efficiency with which Kepone was extracted from solution during a single pass through the pharynx, and the effect of Kepone on fluxes of Na+ and Cl- across the gills were measured. The efficiency with which lampreys extracted Kepone from local tap water averaged 55-66%, confirmed by measuring Kepone accumulation within the lampreys (as 14C-equivalents), using a mass-balance approach. The extraction efficiency matches predictions based on studies using teleosts. Extraction efficiencies declined slowly throughout the exposure period and related inversely to ventilatory rates. In ion-flux measurements, Kepone produced a 40% decline in the rate of influx of Cl- across the pharynx. Effluxes of Na+ and Cl- were not affected, nor was influx of Na+. These latter findings are difficult to reconciliate with accepted theories of Kepone's toxic action; they may relate to the fact that lampreys are unusually tolerant to Kepone poisoning.

Gill ultrastructure of the Pacific hagfish Eptatretus stouti.

At the gross anatomical level, hagfish gills show unusual features not seen in any other fish gills. Our study was undertaken to determine if peculiarities also characterize the microscopic anatomy and ultrastructure of hagfish gills. To the contrary, branchial respiratory lamellae of Pacific hagfish were found to resemble the lamellae of lampreys, elasmobranchs, and teleosts, often down to the finest subcellular details. As in other fish, hagfish lamellae are lined by epithelium containing pavement cells with organelles indicative of a secretory function, basal cells showing undifferentiated cell features, and branchial ionocytes. The ionocytes are identical to chloride cells of teleosts in cytostructure, distribution, and abundance. There are pillar and marginal capillaries in hagfish gill lamellae. Pillar cells contain bundles of 5-nm microfilaments, and they associate with collagen columns as in other fish. Hagfish pillar cells do exhibit odd features, however: They cluster (groups of up to nine were seen), and their extracellular collagen columns are rarer than in other fish gills (averaging only two columns per three pillar cells). Other special features of hagfish gills are the following: lipid droplets and smooth endoplasmic reticulum are well developed in all cell types; pavement cells secrete a lipomucous product (stains with periodic acid-Schiff, Alcian blue, and Sudan black B); and goblet cells are absent. The presence of "chloride cells" in hagfish is puzzling, as hagfish body fluids are iso-osmotic to seawater and there is no need to osmoregulate for sodium chloride; the ionocytes contain carbonic anhydrase, suggesting a function in acid/base regulation.

Ultrastructure of a complex epithelial system: the pharyngeal lining of the larval lamprey Petromyzon marinus.

Electron microscopy shows that the pharyngeal lining of the larval lamprey Petromyzon marinus is a structurally complex epithelial system that can be separated into eight epithelial types: gill lamellar, gill interlamellar, goblet cell, protective, terminal (taste) bud, preciliated, ciliated in tracts, and ciliated in grooves. Furthermore, these epithelial types encompass at least sixteen different cell types based on ultrastructure and, in some cases, correlative histochemistry (PAS, Alcian blue). Common to nearly all the epithelial types are basal cells and intermediate cells. These two cell types are seen as undifferentiated. Among mature cells, structural specialization as proceeded in three directions: 1) elaboration of mitochondria, probably related to molecular transport (ion-uptake cells, chloride cells); 2) ciliogenesis (preciliated and ciliated cell types); and 3) production of mucous secretory granules (mucous-platelet cells, goblet cells, superficial protective cells, columnar mucous cells, "cobblestone" cells, and marginal and dark cells in the terminal buds). Many of the functions of the cell types relate to the process of suspension feeding in this animal.