First evidence of the tooth eruption sequence of the upper jaw in Hyaenodon (Hyaenodontidae,Mammalia) and new information on the ontogenetic development of its dentition

Juvenile material with the main focus on the upper jaw of the fossil predator Hyaenodon was evaluated to study the tooth eruption sequence and to examine the ontogeny of its dentition in detail. The comparison in size of milk to permanent teeth indicates a growth rate of 12–16 % in Hyaenodon. The thin section of a deciduous canine of a North American taxon shows four dental rings. Based on the knowledge of recent carnivores, this implies an age of 3–4 years in the last stage of tooth eruption and thus a long juvenile phase. The mandibles ascertained the most recent established tooth eruption sequence for North American and European species. For the first time ever, juvenile material from Asia is documented and interpreted. This study likewise shows a difference in the sequence of the upper jaw: the first upper premolar erupts before the first upper molar in North American species, whereas the European taxa show an earlier eruption of the first upper molar. This fact further confirms the divergence between the Hyaenodon lineages from North America and Europe.     

Time course of pump inhibition by ouabain in amphibian epithelia

Inhibition by ouabain of rheogenic Na⁺ transport across the basolateral membranes of frog skin is found to be manifest within 3–4 min. This rate of pump inhibition is not different from the rate of diffusion through extracellular tissue layers between the serosal bath and the actual site of action, i.e., the epithelial cell layers. It is concluded that the well-known slow time course of decrease in transepithelial current flow is due ionic redistribution and conductance changes of the epithelial membranes secondary to pump inhibition.     

Microelectrode studies of potential difference responses to changes in stromal K+ in bullfrog cornea

The effects of changing stromal K+ were studied using microelectrodes in an in vitro preparation of frog cornea. The intracellular potential (V0) responded in two opposite ways under short-circuit conditions: (1) depolarization (normal response) when stromal K+ was increased from 4 to 20 or to 79 mM, about 30 mV per 10-fold K+ concn. change; (2) a hyperpolarization (anomalous response) of 10 mV maximum when stromal K+ was increased from 0 to 4 mM. The increase from 4 to 20 or 79 mM decreased or even reversed the short-circuit current (Isc). The transepithelial conductance (gt) increased when K+ was increased to 79 mM but no change occurred in the apical membrane fractional resistance (fRo). Increase of stromal K+ from 0 to 4 mM increased Isc and minimally changed gt and fRo. Ouabain (10(-3) M) abolished the anomalous responses, that is, the increases in V0 and Isc when stromal K+ was increased from 0 to 4 mM. These results are interpreted in terms of two K+ conductive pathways in the basolateral membrane of the corneal epithelium, a Nernstian conductance and an electrogenic (Na+ + K+)-ATPase pump transporting more Na+ than K+ ions per cycle. The normal or anomalous potential difference responses to changes in stromal K+ appear to depend on the relative resistance of the two pathways at the time stromal K+ is changed.     

Molecular effects of nitrosamine toxicity.

Nitrosamines are toxic chemical compounds found low in quantity, but widespread in the environment. This work investigated the kinetics of chemical reaction of activated nitrosamines with various organic substrates. The mechanism by which nitrosamines react demonstrates possible pathways in which the toxicity is expressed. Once activated nitrosamines are very reactive. Chemical compounds which can act as nucleophilic substrates may be alkylated by the activated nitrosamines. A broad category of chemical compounds are shown to be suitable substrates for nitrosamine induced alkylation. This large category of substrates suggests a substantial potential for toxic activity in vivo. By investigating the reaction kinetics of activated nitrosamines a greater understanding of their toxic effects may be possible.     

Molecular cloning of the mouse 46-kDa mannose 6-phosphate receptor (MPR 46).

A cDNA clone for the mouse 46-kDa mannose 6-phosphate receptor (MPR 46) was isolated from an embryonic mouse cDNA library. Its single open reading frame codes for a protein of 278 residues. It shows an over-all amino-acid identity of 93% with the human receptor. Nine non-conservative amino-acid exchanges are found in the luminal domain, one non-conservative exchange of hydrophobic amino acids is in the transmembrane domain, while the cytoplasmic receptor tails are identical. All five potential N-glycosylation sites are conserved as well as amino acids that are important for ligand binding (Arg 137 and His 131) and disulfide pairing (Cys 32 and 78, Cys 132 and Cys 167, Cys 145 and Cys 179). The absolute identity in the cytoplasmic MPR 46 tail suggests the importance of this amino-acid sequence for the intracellular routing of the MPR 46.     

Increased (23R)-hydroxylase activity in patients suffering from cerebrotendinous xanthomatosis, resulting in (23R)-hydroxylation of bile acids

Patients suffering from cerebrotendinous xanthomatosis, an inborn error of metabolism in bile acid synthesis, excrete excessive amounts of 23-hydroxylated bile alcohols, 23-norcholic acid and 23-hydroxycholic acid into urine. In this study the configuration of this excreted 23-hydroxycholic acid was established as (23R)-hydroxycholic acid. Urine samples of two treated patients, receiving chenodeoxycholic acid, were investigated to see whether this administered bile acid was partly converted into 23-hydroxychenodeoxycholic acid. One patient was treated with ursodeoxycholic acid for 1 month and subsequently with chenodeoxycholic acid, and the urinary excretion of both (23R)-hydroxychenodeoxycholic acid and (23R)-hydroxyursodeoxycholic acid were followed. Indeed, all three patients excreted (23R)-hydroxylated chenodeoxycholic acid during oral treatment with chenodeoxycholic acid, and the patient treated with ursodeoxycholic acid excreted (23R)-hydroxylated ursodeoxycholic acid. During treatment with chenodeoxycholic acid the excretion of (23R)-hydroxychenodeoxycholic acid increases at first and later on decreases markedly. These findings suggest increased (23R)-hydroxylase activity in patients suffering from cerebrotendinous xanthomatosis, acting both on endogenously synthesized bile alcohols and on exogenously administered bile acids; during continuation of chenodeoxycholic acid treatment in an effective dose (750 mg/day) this enzyme activity gradually disappears.     

Genetic variation of an acid phosphatase (Acp-2) in the laboratory rat: Possible homology with mouse AP-1 and human ACP2

A genetic locus controlling the electrophoretic mobility of an acid phosphatase in the rat (Rattus norvegicus) is described. The locus, designed Acp-2, is not expressed in erythrocytes but is expressed in all other tissues studied. The product of Acp-2 hydrolyzes a wide variety of phosphate monoesters and is inhibited by l(+)-tartaric acid. Inbred rat strains have fixed either allele Acp-2^a or allele Acp-2^b. Codominant expression is observed in the respective F₁ hybrids. Backcross progenies revealed the expected 1:1 segregation ratio. Possible loose linkage was found between the Acp-2 and the Pep-3 gene loci at a recombination frequency of 0.36±0.06.Supported by the Deutsche Forschungsgemeinschaft (Grant Be 352/15) and by a grant from the Alexander-von-Humboldt-Stiftung (VB2-FLF).     

Trimethyloxonium modification of single batrachotoxin-activated sodium channels in planar bilayers. Changes in unit conductance and in block by saxitoxin and calcium

Single batrachotoxin-activated sodium channels from rat brain were modified by trimethyloxonium (TMO) after incorporation in planar lipid bilayers. TMO modification eliminated saxitoxin (STX) sensitivity, reduced the single channel conductance by 37%, and reduced calcium block of inward sodium currents. These effects always occurred concomitantly, in an all-or-none fashion. Calcium and STX protected sodium channels from TMO modification with potencies similar to their affinities for block. Calcium inhibited STX binding to rat brain membrane vesicles and relieved toxin block of channels in bilayers, apparently by competing with STX for the toxin binding site. These results suggest that toxins, permeant cations, and blocking cations can interact with a common site on the sodium channel near the extracellular surface. It is likely that permeant cations transiently bind to this superficial site, as the first of several steps in passing inward through the channel.