Bullous pemphigoid: serum antibody titre and antigen specificity.

2 antigens have been identified as possible targets for autoantibody depositions in bullous pemphigoid: a 230-kD protein (BP230) and a 180-kD protein (BP180). We studied the relationship of these 2 antigens with the immunofluorescence determined serum antibody titre: 2 groups of bullous pemphigoid patients were selected on the basis of immunoblot-determined antibody specificity. One group (13 patients) had antibody specificity for BP230 and not for BP180, while the other group (9 patients) had antibody specificity for BP180 and not for BP230. The immunofluorescence titres of the circulating antibodies determined on monkey oesophagus substrate displayed, for the BP230-specific group, a mean of 1:1102. The maximal observed titre was 1:5120. The mean titre in the BP180-specific group was only 1:29, with a highest titre of only 1:160. This result suggests that in routine indirect immunofluorescence of bullous pemphigoid sera, the contribution of the BP180-specific antibodies to the total anti-epidermal basement membrane zone antibody titre is relatively much lower than that of the BP230-specific antibodies. Thus, at high dilutions, only the BP230-specific antibodies contribute to the overall indirect immunfluorescence titre.

Protease activities in the spicule venom of Euproctis caterpillars.

The spicule venoms of Euproctis chrysorrhoea and Euproctis subflava were investigated for their capacity to hydrolyze chromogenic tripeptide substrates with selective affinities for various serine proteases. Seven substrates were assayed with affinities for trypsin and thrombin, trypsin and urokinase, serine proteases, chymotrypsin, glandular kallikrein, plasma kallikrein and plasmin. Venom material has a broad spectrum of affinities for the substrates with relative high plasma kallikrein activities. In E. chrysorrhoea venom, trypsin-like activities predominated, whereas E. subflava venom hydrolyzed, in preference, substrates with an affinity for chymotrypsin. The venoms were fractionated on Sephadex G-100, leading to three fractions, all having serine protease activity. The ratios of substrate specificities were markedly different, indicating that in both caterpillar venom preparations at least two separate serine proteases are present. In addition, in human plasma, inhibitor activity could be detected to the kallikrein activity of E. chrysorrhoea, but not of E. subflava. The trypsin-like activity was not inhibited by human plasma. These and earlier studies warrant the assumption that serine proteases, particularly kallikrein, are major factors in the elicitation of clinical symptoms observed after contact with caterpillar spicules.