Roland von Fellenberg

The role of neutrophil chemotactic cytokines in the pathogenesis of equine chronic obstructive pulmonary disease (COPD).

Chronic obstructive pulmonary disease (COPD) is defined as a chronic obstructive inflammatory disease affecting the small airways associated with hay dust exposure (Lowell, F.C., 1964. Observation on heaves. An asthma like syndrome in the horse, J. Allergy 35, 322-330). The disease corresponds histopathologically to a chronic bronchiolitis (Gerber, H., 1973. Chronic pulmonary disease in the horse, Equine Vet. J. 5, 26-33; Winder, N.C., Grünig, G., Hermann, M., Howald, B., von Fellenberg, R., 1989. Comparison of respiratory secretion cytology and pulmonary histology in horses, J. Vet. Med., A36, 32-38) and is mainly characterized by the presence of neutrophil granulocytes in the small bronchioles. Around 12-50% of all horses in Europe and the northern United States suffer from this disease (Mc Pherson, E.A., Lawson, G.H.K., Murphy, J.R., Nicholson, J.M., Fraser, J.A., Breeze, R.G., Pirie, H.M., 1978. Chronic obstructive pulmonary disease (COPD): Identification of affected horses, Eq. Vet. J. 10, 47-53; Larson, V.L., Busch, R.H., 1985. Equine tracheobronchial lavage: Comparison of lavage cytologic features in horses with chronic obstructive pulmonary disease, Am. J. Vet. Res., 46, 144-146; Bracher, V., von Fellenberg, R., Winder, N.C., Grünig, G., 1991. An investigation of the incidence of chronic obstructive pulmonary disease (COPD) in random populations of swiss horses, Equine Vet. J. 23, 136-141). The number of neutrophils in the bronchoalveolar lavage (BAL) and in tracheobronchial secretions (TBS) correlates with the severity of the disease. The present study is focused on the mechanisms which lead to the infiltration of neutrophil granulocytes in the lung of horses. We found that: (1). A strong chemotactic activity in the BAL fluid is associated with high levels of dust exposition. (2). In vitro stimulated alveolar macrophages have impaired phagocytosis efficiency and secrete two chemo-attractants specific for neutrophil granulocytes: Interleukin-8 (IL-8) (Wuyts, A., Proost, P., Put, W., Lenaerts, J.-P., Paemen, L., van Damme, J., 1994. Leucocyte recruitment by monocyte chemotactic proteins (MCPs) secreted by human phagocytes, J. Immunol. Meth. 174, 237-247) and macrophage inflammatory protein-2 (MIP-2) (Wolpe, S.D., Sherry, B., Juers, D., Davatelis, G. Yurt, R.W., Cerami, A., Identification and characterisation of macrophage inflammatory protein-2, Proc. Natl. Acad. Sci. USA 86, 612-616; Tekamp-Olson, P., Gallegos, C., Bauer, D., 1990. Cloning and characterisation of cDNAs for murine macrophage inflammatory protein-2 and its human homologues, J. Exp. Med., 172, 911-927; Driscoll, K.E., 1994. Macrophage inflammatory proteins: Biology and role in pulmonary inflammation. Exp. Lung Res., 20, 473-490). This is associated with the appearance of chemotactic activity in the supernatant. These data confirmed our working hypothesis that bronchiolar neutrophilia may be the consequence of a (over)stimulation of pulmonary macrophages leading to expression of cytokines chemotactic for neutrophil granulocytes.

Effect of lysozyme or modified lysozyme fragments on DNA and RNA synthesis and membrane permeability of Escherichia coli.

Previously we have shown that chicken egg white lysozyme, an efficient bactericidal agent, affects both gram-positive and gram-negative bacteria independently of its muramidase activity. More recently we reported that the digestion of lysozyme by clostripain yielded a pentadecapeptide, IVSDGNGMNAWVAWR (amino acid 98-112 of chicken egg white lysozyme), with moderate bactericidal activity but without muramidase activity. On the basis of this amino acid sequence three polypeptides, in which asparagine 106 was replaced by arginine (IVSDGNGMRAWVAWR, RAWVAWR, RWVAWR), were synthesized which showed to be strongly bactericidal. To elucidate the mechanisms of action of lysozyme and of the modified antimicrobial polypeptides Escherichia coli strain ML-35p was used. It is an ideal organism to study the outer and the inner membrane permeabilization since it is cryptic for periplasmic beta-lactamase and cytoplasmic beta-galactosidase unless the outer or inner membrane becomes damaged. For the first time we present evidence that lysozyme inhibits DNA and RNA synthesis and in contrast to the present view is able to damage the outer membrane of Escherichia coli. Blockage of macromolecular synthesis, outer membrane damage and inner membrane permeabilization bring about bacterial death. Ultrastructural studies indicate that lysozyme does not affect bacterial morphology but impairs stability of the organism. The bactericidal polypeptides derived from lysozyme block at first the synthesis of DNA and RNA which is followed by an increase of the outer membrane permeabilization causing the bacterial death. Inner membrane permeabilization, caused by RAWVAWR and RWVAWR, follows after the blockage of macromolecular synthesis and outer membrane damage, indicating that inner membrane permeabilization is not the deadly event. Escherichia coli bacteria killed by the substituted bactericidal polypeptides appeared, by electron microscopy, with a condensed cytoplasm and undulated bacterial membrane. So the action of lysozyme and its derived peptides is not identical.

Natural protease inhibitors: qualitative and quantitative assay by fibrinogen-agarose electrophoresis.

An electrophoretic procedure for the qualitative and quantitative assay of protein protease inhibitors is reported. This assay is particularly suited for investigations of crude biological materials when specific antisera are not available. The supporting medium consists of agarose into which denatured fibrinogen is incorporated as the substrate for proteases. The processing then is divided into two steps: (1) electrophoretic resolution of the inhibitor containing material and (2) detection of the inhibitor bands through their protease inhibiting activity. The inhibitor position is thus made visible as a colored band of denatured fibrinogen which has escaped digestion by protease. By electrophoretic separation of multiple copies of a sample of biological fluid followed by soaking each of them in the solution of a distinct protease, the enzyme specificity of a particular inhibitor band can easily be established. The bands can in selected cases be quantitated accurately by densitometry and the inhibitor activity thus determined using a reference serum calibrated with Trasylol as a standard. The activity of alpha-1-protease inhibitor in healthy horses is reported.

Fractionation and partial characterization of α-1-protease isoinhibitors of horse

The principal α-1-protease inhibitor of horse was fractionated by classical methods and analysed with a modified fibrinogen-agarose gel electrophoretic method of high sensitivity and resolving power. Starting with an electrophoretically homogeneous inhibitor in unfractionated serum, two isoinhibitor bands became apparent after fractionation with (NH4)2SO4 and DEAE-cellulose DE-52 ion-exchange chromatography. The isoinhibitors differed in electrophoretic migration and in the elution pattern from Sephadex G-100 gel filtration, but possessed identical antigenic determinants and enzyme specificity. The slower migrating isoinhibitor with an apparent molecular weight of 90 000 could be highly purified. In contrast the faster moving isoinhibitor (molecular weight 65 000) could not be completely freed from a contaminating α-2-protease inhibitor. The formation of the two isoinhibitors is discussed considering conformational changes analogous to phenomena observed with α-2-macroglobulin, or dimer formation in combination with altered conformations. The isoinhibitors described here are new additions to the different heterogeneities which exist in α-1-protease inhibitors in horse. They also supplement the different heterogeneities which exist among the α-1-protease inhibitors of mammals.

Design of synthetic bactericidal peptides derived from the bactericidal domain P18–39 of aprotinin

A bactericidal domain, P(18-39), of the proteinase inhibitor aprotinin, possesses the structural feature of two antiparallel beta-sheets connected by a short turn. In order to understand the structural requirements for antibacterial activity, two peptides, each having the sequence corresponding to a single beta-sheet structure of P(18-39), were synthesized and their antibacterial properties investigated. One peptide, P(18-28), with the sequence IIRYFYNAKAG, was active against almost all the bacterial strains investigated. However, the bactericidal activity of P(18-28) was reduced compared to the parent molecule, P(18-39). The other peptide, P(29-39), with the sequence LCQTFVYGGCR, was only weakly bactericidal against Pseudomonas aeruginosa. A peptide, P(18-26), devoid of the C-terminus dipeptide Ala-Gly of P(18-28), retained the bactericidal activity of P(18-28) against most of the bacterial strains investigated. Only Klebsiella pneumoniae, P. aeruginosa and Staphylococcus aureus were resistant to P(18-26). Replacement of lysine 26 by arginine in P(18-26) (IIRYFYNAR) improved the bactericidal activity. The retropeptide, RANYFYRII, retained the antibacterial activity of IIRYFYNAR toward Gram-negative bacteria, but it was less active against Gram-positive bacteria. The random peptide, IANRIYRYF, was as bactericidal as IIRYFYNAR. Moreover, the random peptide possessed, in contrast to IIRYFYNAR, a strong antifungal activity against Candida albicans. Elimination of the N-hydrophobic terminal Ile-Ile from P(18-26) (RYFYNAK) strongly reduced the bactericidal potency of the peptide. Attaching the hydrophobic peptide, FFVAP, to the C-terminal of P(18-26) (IIRYFYNAKFFVAP) increased the bactericidal potency of the peptides considerably. We concluded that the order of the amino acids in the sequence of the peptides is not, per se, a critical feature for bactericidal activity. Hydrophobic interaction between peptide and bacterial membrane is probably the most important feature involved in the bactericidal mechanism of the antibiotic peptides.

Identification of an aprotinin antiviral domain

Digestion of the proteinase inhibitor aprotinin, by clostripain, a cysteine proteinase, yielded five oligopeptide fragments. Two fragments exhibited both antiviral and antibacterial activities, two fragments only antiviral activity, and one fragment showed no antimicrobial activity. One of the former oligopeptides showed antiviral activity against human herpes simplex virus type 1 and bovine parainfluenza virus type 3. It consisted of the hexapeptide Y‐F‐Y‐N‐A‐K corresponding to amino acids 21–26 of intact aprotinin. An identical synthetic peptide had the same antiviral spectrum as the natural hexapeptide, exhibited no antibacterial activity, and was also devoid of trypsin inhibiting activity. Intact aprotinin, in contrast, is ineffective against human herpes simplex virus 1 and bovine parainfluenza virus 3 but possesses antibacterial properties against several bacterial species [(1992) J. Appl. Bact. 72, 180–187].

Horse α-1 protease inhibitors: Relationship between the slow (S) and fast (F) isoforms

Horse alpha-1 protease isoinhibitors were isolated in a highly purified form using individually designed fractionation procedures. The isoinhibitors, running in agarose gel electrophoresis at pH 8.6 as two distinct bands, were designated S alpha-1 and F alpha-1. The molecular relationships between S alpha-1 and F alpha-1 were investigated by using classical electrophoretic and immunoelectrophoretic methods. No differences between the inhibitors were revealed with respect to their antiproteolytic activity, determined by fibrinogen agarose gel electrophoresis assays. No immunological differences between the isoforms were detected. These observations, together with others reported in this paper, suggest that the two isoinhibitors are probably the monomeric and dimeric form of the same molecule.

Resistance of horse α1-proteinase inhibitor to perchloric acid denaturation and a simplified purification procedure resulting therefrom

Addition of perchloric acid (6.4% w/v final concentration) to horse alpha 1-proteinase inhibitor or to horse plasma neither precipitated nor inactivated alpha 1-proteinase inhibitor. None of the isoinhibitors of alpha 1-proteinase inhibitor was altered by dilute perchloric acid. This unexpected behavior led to a simplified procedure for the purification of horse alpha 1-proteinase inhibitor, consisting of removal of the bulk of plasma proteins, by perchloric acid precipitation and by gel filtration on Sephadex G-75 and G-200. The resulting preparations of alpha 1-proteinase inhibitor were immunogenically pure. The simplified purification procedure permitted the immunochemical comparison of the isoinhibitors of alpha 1-proteinase inhibitor, which proved to be immunologically identical.

Identification of the second α-2-antiprotease of equine serum as antithrombin III

Abstract 1. 1. The α-2-protease inhibitor, of 65,000 daltons molecular weight, described by several authors in horse plasma and also present as a contaminant in α-1-isoinhibitor isolates previously described by us (Pellegrini & von Fellenberg (1980) Biochim. biophys. Acta 616 , 351–361) has now been isolated to purity and identified as antithrombin III. 2. 2. The inhibitor is composed of a single polypeptide chain as judged by SDS polyacrylamide gel electrophoresis. 3. 3. The inhibitor was effective only against trypsin and thrombin. 4. 4. Serological cross-reaction existed between the inhibitor and the antiserum to human antithrombin III . 5. 5. An antiserum to our isolate, however, did not react with human antithrombin III . 6. 6. This confirms the results reported by Kurachi et al . (1976, Biochemistry 15 , 368–372).

Isolation and characterization of two new low-molecular-weight protein proteinase inhibitors from the granule-rich fraction of equine neutrophilic granulocytes

A new species of protein proteinase inhibitors was detected in the granule-rich fraction of equine neutrophilic granulocytes. Five isoinhibitors were identified with a narrow enzyme specificity towards two microbial proteinases, e.g., proteinase K and subtilisin. Two isoinhibitors were purified and partially characterized. They had an Mr of 11,300 and 7400, respectively, and were resistant to perchloric acid and heat treatment at 100 degrees C for 20 min. The inhibitors retained their activity over a broad range of pH (1-9 and 1-12, respectively). The possible biological function of this species of protein proteinase inhibitors as defensins (= endogenous antibiotics) is tentatively discussed.