Low molecular weight angiotensin I converting enzyme from rat lung

Generation of a 90 000 molecular weight fragment from human plasma angiotensin-I-converting enzyme by enzymatic or alkaline hydrolysis

A catalytically active Mr 90 000 fragment was generated from native Mr 140 000 human plasma angiotensin-I-converting enzyme after treatment with reagents that induced a perturbation of the native tertiary conformation. Treatment of converting enzyme with 6 M urea produced an aggregation of molecules that was susceptible to proteolysis by either trypsin, chymotrypsin or Staphylococcus aureus V8 proteinase to generate the Mr 90 000 converting enzyme. Also, 1 M ammonium hydroxide, pH 11.3, or 0.01 M sodium hydroxide, pH 11.3, cleaved converting enzyme to the Mr 90 000 fragment. Degradation was not an autocatalytic phenomenon, since it was not prevented by inhibition of converting enzyme with EDTA. The enzymatically mediated, but not the alkaline mediated, cleavage was inhibited by specific converting enzyme inhibitors captopril and Merck L-154,826. This suggests that captopril and Merck L-154,826 can prevent converting-enzyme degradation by preserving a conformation that does not have sites exposed to proteolytic enzymes. This conformation may mimic the native conformation which is quite resistant to serine proteinases.

Rabbit pulmonary angiotensin-converting enzyme: the NH2-terminal fragment with enzymatic activity and its formation from the native enzyme by NH4OH treatment

The NH2-terminal sequence of 22 residues of rabbit lung angiotensin-converting enzyme has been determined as (NH2)Thr-Leu-Asp-Pro-Gly-Leu-Leu-Pro-Gly-Asp-Phe-Ala -Ala-Asp-Asn-Ala-Gly-Ala-Arg-Leu-Phe-Ala-. In the course of purification of the enzyme for structural analysis a protein of Mr = 82,000 with angiotensin-converting activity was separated from the major fraction containing the native enzyme (Mr = 140,000). This low-molecular-weight enzyme catalyzed the hydrolysis of the synthetic substrate Hip-His-Leu at a rate 23% of that with the native enzyme, and exhibited a similar Km value as well as behaviors towards various effectors of angiotensin-converting enzyme. Edman degradation of both the native and the 82K enzymes revealed that they contain identical amino acid sequences from the NH2-termini. This result and those of peptide mapping and carbohydrate and amino acid analyses indicate that the 82K enzyme is a fragment derived from the NH2-terminal portion of the native enzyme, and hence contains its catalytic site. Evidence has been obtained indicating that the active fragment was formed from the native enzyme during its elution from the antibody-affinity column with NH4OH: on treatment of the native enzyme (140K Mr) with 1 N NH4OH at room temperature, a cleavage occurred and two proteins with Mr = 82K and Mr = 62K were obtained. The 82K Mr fragment was found to be enzymatically active and to contain the same NH2-terminal sequence as the native enzyme. The other fragment (62K Mr) was devoid of the activity and was shown to derive from the COOH-terminal portion of the native enzyme by the peptide mapping and terminal analyses. Cleavage of a peptide bond with NH4OH is unusual and appears to be specific for the native angiotensin-converting enzyme from rabbit lung.

Methods for microcarrier culture of bovine pulmonary artery endothelial cells avoiding the use of enzymes

Enzymes situated along the luminal surface of pulmonary endothelial cells interact with circulating solutes, notably with vasoactive substances, to regulate the hormonal composition of systemic arterial blood. However, it is becoming clear that the range and complexity of reactions occurring at or near the surface of endothelial cells are greater than previously recognized. In addition, evidence indicates that the quality of cell cultures used to define specific endothelial functions must be carefully controlled, together with development of improved understanding of the effects of long-term culture on pulmonary endothelial cells. We have developed new techniques for the culture of pulmonary endothelial cells which avoid exposure to proteolytic enzymes at both the isolation step and during subculture. A combination of mechanical harvest and culture on microcarrier beads has provided a system for the long-term, large-scale culture of pulmonary endothelial cells, features which to a large extent determine the scope of biochemical studies which can be undertaken.