Furthermore, plant proteins and peptides with in vitro cytotoxic

Furthermore, plant proteins and peptides with in vitro cytotoxic activity and anticancer properties on human cancer cell lines have also been reported [20], [21], [22], [23], [24] and [25]. We have previously reported the

induction after infection and the cytotoxic activity of potato aspartic proteases (StAPs) toward plant pathogens [26], [27] and [28]. Our results show that potato aspartic proteases (StAPs) and their swaposin domain (StAsp-PSI) are proteins with cytotoxic activity which involves plasma membrane destabilization. The ability of these proteins to produce cell death varies with the cellular type [28], [29] and [30]. We have demonstrated that the lack of hemolytic and cytotoxic activities on human lymphocytes Dabrafenib molecular weight of StAsp-PSI/StAPs is attributed to the presence of cholesterol in these cell membrane types [29] and [31]. These results open a new perspective to test these proteins as possible candidates to develop new drugs that would be active against microbes but not against mammalian cells and considerer these proteins as conceptually promising agent in infectious diseases and cancer therapy. The covalent attachment

of polyethylene glycol (PEG) chains (PEGylation) to therapeutic selleck chemicals llc peptides and proteins has become one of the most useful pharmaceutical techniques developed thus far to provide functional bioconjugates with improved therapeutic properties over their unmodified counterparts [32] and [33]. PEGylation,

indeed, has been proposed as a method for optimizing pharmacokinetic and pharmacodynamic properties of therapeutic small Y-27632 2HCl drug molecules, peptides and proteins [34]. The modification leads to an increase in molecular size and steric hindrance, changes in conformation and electrostatic binding properties. This results in the reduction of renal ultrafiltration, the masking of proteolytic and immunogenic sites and the shielding from proteolytic enzymes, antibodies or antigen processing cells [34], [35] and [36]. This strategy can prolong the plasma circulating half-life, augment the in vivo stability [34], [37], [38], [39] and [40], and diminish the phagocytosis and immunogenicity of peptides and proteins [36], [41], [42] and [43]. Due to these benefits, PEGylation plays an increasingly important role in the production of enhanced peptide and protein delivery systems [44]. There are few works in which PEGylation is used to improve plant proteins therapeutic potential, reducing their immunogenic behavior and extending the permanence of the injected drugs in the body. Examples of this include histaminase from Lathyrus sativus shoots for alternative treatment of histamine-mediated affections [45]; α-momorcharin and momordica anti-HIV protein derived from Momordica charantia L.

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