Transglutaminases as tanning agents for the leather industry

This study was aimed at determining whether the protein crosslinking enzymes, transglutaminases, had the potential to be used as tanning agents, using native bovine hide and purified soluble rat tail collagen as real and model substrates, respectively. We demonstrate that transglutaminases (TGs) were capable of covalently crosslinking collagen molecules together such that on average every collagen molecule contained at least one epsilon(gamma-glutamyl)lysine crosslink. However, transglutaminase-mediated crosslinking did not affect the denaturation temperature of either native bovine hide or soluble rat tail collagens when used in isolation or together with other proteins and bifunctional diamines as crosslinking facilitators. In an initial study into the effect of TG-mediated crosslinking on the tensile strength of chrome-tanned bovine hide, such crosslinking led to a 30 per cent decrease in tensile strength. Despite a change in the gel melting point mediated by epsilon(gamma-glutamyl)lysine crosslinking, the use of transglutaminases as alternative tanning agents seems unlikely given the present data.

A comparative study of the effects of hypoxia upon isolated arterial muscle from the rat

Contractile response of rat aorta, mesenteric artery and femoral artery to noradrenaline and potassium chloride were studied under standard and hypoxic conditions and the effect of hypoxia was dependent upon both the vessel and the stimulant. Hypoxia had less effect upon contractions to potassium chloride than those to noradrenaline. The effects of hypoxia on potassium chloride induced responses in different vessels were relatively similar although responses to noradrenaline were vessel dependent. Noradrenaline induced contractions of the femoral artery were most affected by hypoxia whilst those of the mesenteric artery were least affected. Hypoxia changed the well maintained response of the femoral artery to noradrenaline to a transient form; this effect of hypoxia was not evident in the aorta or the mesenteric artery. The aorta and mesenteric artery contracted in calcium free EGTA PSS suggesting that these vessels displayed a release component. Hypoxia reduced the magnitude of this component. The effects of verapamil on noradrenaline and potassium chloride induced responses were investigated and were found to be different to those of hypoxia. Verapamil exerted a greater effect on contractions to potassium chloride than on those to noradrenaline. The effects of hypoxia on 45calcium flux were also vessel dependent. In the mesenteric and femoral arteries hypoxia increased basal 45calcium accumulation. However, the magnitude of noradrenaline stimulated 45calcium accumulation was reduced in the femoral artery and aorta but was unchanged in the mesenteric artery. The effects of hypoxia on 45calcium accumulation were similar to verapamil only in the aorta. The results provide evidence that the effects of hypoxia may arise from alterations in calcium mobilisation processes and that differences between vessels in these processes accounts for the heterogeneity between vessels in their response to hypoxia.