8 and 16 0 kDa presumably represent VP11–145 fragments since they

8 and 16.0 kDa presumably represent VP11–145 fragments since they closely match the predicted mass and differ by about the same mass (0.2 kDa) as both VP1 peaks. The peak at 18.8 kDa closest matches fragments VP21–167. This complete cleavage OSI-744 after VP1 residue 145 and partial cleavage after VP2 residue 167 is further confirmed by the

presence of peaks at 34.7 and 40.4 kDa that can be explained by the presence of a disulfide bond between part of the VP1 and VP2 molecules. The peaks at 5239 and 6193 Da match closely with fragments VP1155–200 and VP1146–200, respectively. Furthermore, this interpretation is consistent with the previously observed cleavage after VP1 residue 145 and suggests partial cleavage after VP1 residue 154. Two further peaks at 5267 and 6221 Da differ by 28 Da from these two peaks, suggesting that they represent variants of these fragments. Although the peaks of low height at 5447 and 6395 Da match closest to fragments VP1158–204 (5460 Da) and VP1110–169 (6392 Da), respectively, this interpretation is not consistent with VP1 cleavages occurring after residues 145 and 200. Since these Afatinib peaks differ by about the same mass (208 and 202 Da, respectively) from the peaks at 5239 and 6193 Da and have the same relative height as these peaks, it is more likely that

they represent another variant of these fragments. The closest matching fragments of the peaks at 5039 and 5993 Da (see Table 1) are not consistent with cleavages occurring after VP1 residues 145 and 154. As a result the identity of these peaks is uncertain. We next analysed the proteolytic stability of FMDV O1 Manisa antigen by SELDI-TOF-MS in an accelerated stability study by incubation of the antigen at 35 °C for 2 weeks. The height of the VP1 peaks gradually decreased during this

2-week Oxygenase incubation period whereas the height of the VP2 peak remained constant (Fig. 4a–d). Two peaks of low height at about 22.2 and 22.4 kDa appear upon prolonged incubation at 35 °C (Fig. 4a–d), which could represent VP1 degradation products. Further degradation products were not observed. Incubation of the antigen at 4 °C for 2 weeks did not reveal such VP1 degradation (cf. Fig. 4a and e). We next analysed FMDV O1 Manisa antigen after addition of the adjuvant, a double oil emulsion, by SELDI-TOF-MS using immunocapture with the VP1 specific VHH M8. The relative height of the VP4 peak as compared to the VP2 or VP1–VP2 dimer peak did not vary before or after emulsification (cf. Fig. 5a and b). The ratio between the VP4 and VP2 peak height is 70/7.9 (8.9) before emulsification and 30/3.6 (8.4) after emulsification. This indicates that equal amounts of VP4 remained associated with FMDV virions after emulsification. The heights of the spectral peaks representing VP1, VP2, VP4 and VP1–VP2 dimers in DOE vaccine (Fig. 5b) were somewhat reduced as compared to the profiles obtained with the antigen before emulsification (Fig. 5a).

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