Anti-Trypanosoma brucei activity of nonprimate zoo sera.

Constitutive anti-Trypanosoma brucei subsp. brucei S 427 clone 1 and 22 activities were evaluated in sera from 22 species of nonprimate mammals. The sera fell into 5 categories. Sera from Cape buffalo, giraffe, and greater kudu showed a concentration-dependent inhibition of replication of the 2 clones of organisms, which was dependent on the presence of xanthine oxidase. Sera from warthog and springbok also severely limited trypanosome replication but lacked xanthine oxidase. Their antitrypanosome activity was inactivated by heating at 56 C for 30 min but not affected by absorbing with trypanosomes at 4 C. Sera from lion and leopard showed a concentration-dependent inhibition of the growth of T. brucei S427 clone 1 organisms, but not clone 22 organisms. These sera lacked xanthine oxidase. Their anti-T. brucei S 427 clone 1 activity was inactivated by heating at 56 C for 30 min but not removed by absorbing with trypanosomes. Serum from Grant's gazelle prevented replication of both T. brucei clones, lacked xanthine oxidase, and was not affected by heating at 56 C. Sera from waterbuck, Thompson's gazelle, sitatunga, Cape hartebeeste, gerenuk, Grant's zebra, cow, several cat, cougar, bobcat, and domestic cat were fully supportive of trypanosome replication irrespective of concentration tested up to a maximum of 48% v/v in culture medium. Sera from different individuals of the same mammal species had similar effects on trypanosomes, and samples collected from the same individual at different times also had similar activities indicating species-specific stable expression, or lack thereof, of constitutive serum antitrypanosome components.

The trypanocidal Cape buffalo serum protein is xanthine oxidase.

Plasma and serum from Cape buffalo (Syncerus caffer) kill bloodstream stages of all species of African trypanosomes in vitro. The trypanocidal serum component was isolated by sequential chromatography on hydroxylapatite, protein A-G, Mono Q, and Superose 12. The purified trypanocidal protein had a molecular mass of 150 kDa, and activity correlated with the presence of a 146-kDa polypeptide detected upon reducing sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Amino acid sequences of three peptide fragments of the 146-kDa reduced polypeptide, ligand affinity and immunoaffinity chromatography of the native protein, and sensitivity to pharmacological inhibitors, identified the trypanocidal material as xanthine oxidase (EC 1.1.3.22). Trypanocidal activity resulted in the inhibition of trypanosome glycolysis and was due to H2O2 produced during catabolism of extracellular xanthine and hypoxanthine by the purine catabolic enzyme.

Structural basis of the induction of unscheduled DNA synthesis in rat hepatocytes.

The structural basis of the induction of unscheduled DNA synthesis (UDS) in isolated rat hepatocytes was studied with CASE, an expert system. The analysis identified a number of structural determinants associated with the induction of UDS. These structures accounted for 97.3% of the activity of the chemicals in the database. Further analyses indicated that the concordance between prediction and experimentally determined UDS of molecules not in the learning set is > 82%. A comparison of predictions of UDS and mutagenicity in Salmonella indicated that there is a dichotomy between these activities. The basis of this lack of coincidence remains to be elucidated.

The mechanism of antler casting in the fallow deer.

The process by which antlers are detached from their pedicles was examined histologically in fallow deer castrated in the autumn to induce precocious casting. Osteoclastic erosion across an abscission line between the dead bone of the antler and the living bone of the pedicle was found to be responsible for the separation of the 2. As early as 3 days after castration, osteoclasts and associated lacunae were present on the sides of the pedicle bone. These were then found in progressively deeper locations, by 2 weeks extending across the entire width of the pedicle. Concomitant with the centripetal spread of osteoclasts was the enlargement of Haversian canals, the surfaces of which became lined with osteoclasts. These widening vascular channels within the bone were filled with connective tissue, which in precasting stages formed a mesodermal pad about 1 mm thick. In later stages, a circumferential cleft was excavated beneath the antler burr, and connective tissues from the surrounding pedicle skin invaded the space between the antler and pedicle. After casting, the ingrowing integumental tissues fused with the mesodermal tissues derived from the vascular channels of the pedicle to give rise to an incipient antler bud beneath the scab. The ingrowth of epidermis capable of de novo hair follicle formation gave rise to the future velvet skin that envelops the elongating antler.

Schwann cell proliferation following lysolecithin-induced demyelination.

Schwann cell division, meticulously regulated throughout development, occurs at an extremely low level in normal adult nerves. Loss of the myelin sheath in disease results in active proliferation of Schwann cells. The dividing cells are usually thought to be the Schwann cells of the demylinated fibres and their daughters. In this study we asked if other populations of Schwann cells might also divide following focal monophasic demyelination, and if the proliferating Schwann cells would be found only in the foci of demyelination. [3H]thymidine incorporation was examined by autoradiography at intervals after topical application of lysolecithin (lysophosphatidyl choline) to rat sciatic nerves. The postlabelling intervals were set to identify premitotic cells, cells shortly after mitosis (perimitotic cells) and postmitotic cells, as well as to provide cumulative labelling over 3 days. The affected nerves had three distinct zones. The first was a zone of nearly complete demyelination immediately beneath the perineurium. The subjacent zone was normal morphologically except for numerous supernumerary Schwann cells, displacement of some Schwann cell perikarya, ultrastructural changes in a few myelinated fibres, and rare demyelinated and remyelinated fibres. The third zone, beneath the first two, was normal. In the focus of demyelination there were large numbers of Schwann cells in S phase on days 4 and 6. These cells included premyelinating Schwann cells that were contacting or ensheathing demyelinated axons or collateral axonal sprouts. The subjacent region also contained dividing Schwann cells, most of which were Schwann cells of unmyelinated Remak fibres. In addition, occasional Schwann cells of thickly myelinated fibres (fibres that had not previously undergone demyelination) were labelled by the premitotic schedule; most of these fibres had morphological abnormalities in the Schwann cell perikaryon or myelin sheath. In many, the perikaryon of the Schwann cell was beginning to separate from the rest of the Schwann cell cytoplasm and the myelin sheath. These changes suggested that these fibres were destined to undergo subsequent demyelination, a hypothesis supported by the absence of any normal myelinated fibres with labelled Schwann cell nuclei in nerves removed 1 week after labelling. Thus, this model provided no evidence for division by Schwann cells that continued to maintain myelin sheaths. Taken together, these results suggest that there is a 'surround' of Schwann cell proliferation around foci of demyelination; in this surround multiple populations of Schwann cells are recruited to proliferate, including Schwann cells of intact unmyelinated fibres. Structurally normal unmyelinated fibres appear to provide an unexpected source of new Schwann cells in nerve disease.