Beata Prabucka

Purification and partial characteristic of a major gliadin-degrading cysteine endopeptidase from germinating triticale seeds

The endopeptidase of the highest electrophoretic mobility was the main endopeptidase hydrolyzing gliadin in the endosperm of germinated triticale (X Triticosecale Wittm.) grains after three days of imbibition. Activity of this endopeptidase, named EP8 starts to be detectable after two days of imbibition. The appearance of its activity in the endosperm on a second day of imbibition may suggest that EP8 is synthesized in aleurone during germination and/or secreted into the starchy endosperm as an inactive polypeptide during grains development and then activated. EP8 was isolated from the endosperm of germinating triticale seeds and purified 257-fold using ammonium sulphate, ion exchange chromatography on DEAE Sepharose CL-6B and gel filtration on Sephadex G-100. The enzyme was totally inhibited by E-64—class-specific cysteine proteinases inhibitor and activated by thiol compounds. Molecular weight estimated by SDS-PAGE was 39.5 kDa. The optimum pH for the hydrolysis of gliadin was 4.2 and for hemoglobin 5.2. High activity of EP8 against wheat gliadin in vitro suggests that this cysteine endopeptidase plays a major role in the mobilization of storage proteins in the endosperm of germinating triticale grains.

The participation of phytocystatin TrcC-4 in the activity regulation of EP8, the main prolamin degrading cysteine endopeptidase in triticale seeds

Phytocystatins (PCs) are protein inhibitors of endogenous plant endopeptidases and exogenous pathogen proteinases. We have previously described the protein inhibitor TrcC-4, which is probably involved in the control of protein degradation during triticale seeds germination. The occurrence of the LARFAVXEHN motif supports the TrcC-4 designation as a PC. In this paper TrcC-4 was expressed in Escherichia coli using the pET28 expression vector. TrcC-4(6×His) was purified by affinity chromatography with a single step of purification. Western blot analysis showed the presence of TrcC-4 in both developing and germinating triticale seeds. TrcC-4 protein level was higher both in scutellum of germinating seeds and in developing grains of the triticale cultivar more resistant to pre-harvest sprouting (Zorro) than in a less resistant one (Disco). Furthermore it was demonstrated that the activity of EP8, cysteine endopeptidase responsible for the mass hydrolysis of prolamin during germination, is inhibited by TrcC-4(6×His), as confirmed by native PAGE with gliadin as a substrate. These results suggest that phytocystatin TrcC-4 controls the activity of cysteine endopeptidases involved in germination and, thus, is potentially involved in pre-harvest sprouting.

Endogenous Action of Cysteine Endopeptidase and Three Carboxypeptidases on Triticale Prolamins

ABSTRACT Quantitative and qualitative changes occurring in the prolamin fraction in the starchy endosperm of triticale grains were analyzed by SDS-PAGE on consecutive days of germination. The most intensive hydrolysis of prolamins was observed after the second day of the process. The high molecular weight fractions of prolamins were degraded with the highest rate. Endopeptidase EP8 was capable of hydrolyzing all fractions of prolamins isolated from dry triticale grains, but the high molecular weight fractions were the most rapidly degraded by the enzyme. Carboxypeptidases I, II, and III isolated from triticale grains hydrolyzed prolamins proteolytically modified by endopeptidase EP8, whereas intact prolamins were degraded slightly. Differences in the activity of the studied carboxypeptidases against crude prolamins indicate that carboxypeptidase II may be involved in the initiation of the hydrolysis process and, together with carboxypeptidases I and III, participates in the later stages of degradation of ...

Endopeptidases of Triticale Seeds

The changes in endopeptidase activity in different parts of germinating triticale cv. Malno were investigated. Haemoglobin, gliadin, azocasein and azoalbumin were used as substrates. During the first day of germination the activity of haemoglobin hydrolyzing endopeptidases predominated while after the second day, mainly in the endosperm, a rapid increase in endopeptidases activity preferring gliadin hydrolysis was observed. In all the investigated tissues azocaseinolytic activities increased with the successive days of germination. Similar changes were observed using azoalbumin with one exception: in the embryo axis this activity decreased with the progression of germination. Separation of endopeptidases on the DEAE Sepharose CL-6B reveals three activity peaks in extract from dry seeds and four peaks in extract from 3 d germinated seeds. The obtained peaks differed in substrate specificity and in sensitivities to class-specific inhibitors.

Carboxypeptidases of germinating triticale grains

Presence of five carboxypeptidases was found in endosperm of germinating triticale grains, while two of them in scutellum. Changes of their activities during four days of germination suggest that carboxypeptidase II plays an important role at initial stage of germination, while carboxypeptidases I and III - at subsequent stages of the process. High activity of carboxypeptidase II both in scutellum and endosperm of dry grains accompanied by its decrease during germination, and on the other hand, the appearance of carboxypeptidases I and III activities at the 2nd and 3rd day of the process seems to confirm such functions of these enzymes. Experiments with GA3 indicated that carboxypeptidase I was synthesized in scutellum, and carboxypeptidase III — in aleurone layer. Carboxypeptidases I and II cleave N-CBZ-Phe-Ala, and carboxypeptidase III — N-CBZ-Ala-Met and N-CBZ-Ala-Phe as substrates with the highest rate.

Structural and functional characterization of the triticale (x Triticosecale Wittm.) phytocystatin TrcC-8 and its dimerization-dependent inhibitory activity

Phytocystatins are a group of proteins with significant potential to regulate activities of cysteine proteinases of native and pest/pathogen origins. The two-domain triticale (x Triticosecale Wittm.) phytocystatin TrcC-8 was characterized in this study. This protein belongs to the second group of phytocystatins and contains all the conserved sequences and motifs as well as both N-terminal (CY) and C-terminal (CY-L) domains that are characteristic of phytocystatins with the C-terminal extension. We demonstrated that TrcC-8 forms stable dimers with a significantly reduced inhibitory activity against papain compared to the activity of monomers, indicating the regulatory nature of the oligomerization. Moreover, according to our research, only the N-terminal domain possesses the ability to form dimers, indicating that this part of TrcC-8 is involved in the dimerization of the full-length protein. Homology modelling of TrcC-8 strongly suggests distinct specificities for the CY and CY-L domains, confirmed in experiments with inhibition of the papain. Our results suggest that the CY domain of TrcC-8 may, although markedly weakly and suboptimally, interact with papain in an analogous mode to tarocystatin, while the CY-L domain of TrcC-8 has distinct specificity than tarocystatin.