1% formic acid gradient Data were acquired in dara-dependent mod

1% formic acid gradient. Data were acquired in dara-dependent mode (DDA), and multiple charged peptides ions (+2, +3 and +4) were automatically mass selected and dissociated in MS/MS experiments. Flow was set for 600 nL/min, nanoflow capillary voltage of 3.5 kV, block temperature of 100 °C, and cone voltage of 100 V. The MS/MS spectra acquired were processed using Proteinlynx v. 2.0 software (Waters, Milford, USA) and the generated PKL files were used to perform database searches using Selleck PCI 32765 a in house license for MASCOT software v. 2.2 (Matrix Science, London,

UK). The non-redundant NCBI database was used for search the data. Search parameters allowed a maximum of one missed cleavage, the carbamidomethylation PD0332991 purchase of cysteine, the possible oxidation of methionine, peptide tolerance of 0.3 Da, and MS/MS tolerance of 0.2 Da. The significance threshold was set at p < 0.05, and identification required that each protein contained at least one peptide with an expected value <0.05. Data were manually checked for validation. In order to visualize and document the presence of labelled vicilins by microscopy from larvae, adults and eggs, fresh portions were mounted on glass slides and visualized using

a laser Confocal microscope (Leica DMI6000 B Microscope). Vicilin–FITC complexes were detected by confocal microscopy in the genitalia of virgin males as soon as they emerged from the artificial seeds (Fig. 1A–C). When vicilin–FITC fed males were mated to control virgin females, the fluorescence could be seen in the genitalia within minutes after the copulation (Fig. 1D–F). The vicilin–FITC complex could be traced from the distal parts of the female genitalia to the 3-mercaptopyruvate sulfurtransferase ovarioles (Fig. 2). Tracing the fluorescence, we could see that the vicilin–FITC complex was incorporated in the forming chorion of the oöcytes (Fig. 2D–F). When females were allowed to lay their eggs, the fluorescence in

the laid eggs was clearly visible under confocal microscopy (Fig. 3A–C and supplementary material 1). In order to determine the fate of the vicilin–FITC complex after oviposition, we followed the embryonic development in the eggs laid by fertilized females until the eclosion of the neonatal larvae. In this case, both males and females were fed a diet containing the vicilin–FITC complex during the larval period. We can see in Fig. 4 that only 3 days after oviposition it is possible to distinguish the segments of the embryo inside the egg (Fig. 4D). Throughout the fourth and fifth days after oviposition it is possible to see that the embryo eroded part of the egg shell (Fig. 4E–H and supplementary material 2). At the sixth day after oviposition, the newly hatched larvae start eating a circular window from the floor of the egg shell before eclosion (Fig. 4I and J). After the eclosion, a fluorescent egg shell was left behind, where it was also possible to see a fluorescent deposit close to the egg pore (Fig. 4K and L).

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