M. Szekerke scite author profile

The biodistribution has been examined in mice of a range of synthetic branched polypeptides which are based on a polylysine backbone but which differ in ionic charge, side-chain structure, and molecular size. Polycationic polypeptides, regardless of their size or primary structure at the branches, were cleared rapidly from the circulation, the liver being the major site of clearance. Polypeptides with glutamic acid in the side chain, which would be amphoteric under physiological conditions, showed a significantly prolonged blood survival, and this was seen with polypeptides in the range of molecular weights of 46,000 up to 213,000. Such polypeptides provide a useful system with which to investigate the effect of structural parameters on the pharmacokinetic properties of carrier molecules and would allow the selection of candidate carriers for a variety of uses.

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Investigation of drug-protein interactions and the drug-carrier concept by the use of branched polypeptides as model systems. Synthesis and characterization of the model peptides

Hudecz

Szekerke

1980

Collect. Czech. Chem. Commun.

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Synthesis of branched polypeptides with a new design of variations in surface topography is described. The side chains of the poly(Lys-(DL-Alam)) were elongated by single amino acids (L-Tyr, L-Glu, L-His, L-Leu, L-Pro, L-Phe) or short polymers (L-, D-Glu, L-Tyr, L-, D-, DL-Lys). Single amino acids were coupled, via the azide, active ester or N-carboxy anhydride method, oligomers were grafted by the polymerisation of N-carboxy anhydride derivatives. The resulting polypeptides were characterised by amino acid analysis, identification of the N-terminal residue of the chain ends, determination of the sedimentation coefficient and molecular weight estimation, based on sedimentation experiments and thin layer gel chromatography.

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Carrier Design: New Generation of Polycationic Branched Polypeptides Containing OH Groups with Prolonged Blood Survival and Diminished in Vitro Cytotoxicity

et al. 1999

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For the construction of macromolecule-drug conjugates, it is important to provide rational basis to the selection of proper carrier. With respect to the importance of the side-chain structure and charge of the branched polypeptides in biological properties, we have prepared a new class of branched polypeptides with single or multiple hydroxyl groups and studied their solution conformation, in vitro cytotoxicity, biodistribution, and immunoreactivity. For comparative studies, polypeptides were designed to contain serine at various positions of the side chains, varying also the number. Ser was attached to the end of oligo(DL-Ala) side chains grafted to polylysine resulting polypeptides with the general formula poly[Lys(Ser(i)-DL-Ala(m))], (SAK). Ser was also coupled directly to the polylysine backbone poly[Lys(Ser(i))] (S(i)K) and then elongated by polymerization of N-carboxy-DL-Ala anhydride resulting poly[Lys(DL-Ala(m)-Ser(i))] (ASK). An additional polymer was also prepared, but instead of the oligo(DL-Ala) branches, oligo(DL-Ser) side chains were introduced (poly[Lys(DL-Ser(m))], SK). The presence of hydroxyl groups resulted in compounds with improved of water solubility. CD spectra of polypeptides showed significant differences correlating with the position and numbers of Ser residues in the side chains. Under physiological conditions, polycationic polypeptides assumed ordered secondary structure (S(i)K and LSK) or partially unordered conformation (SK, SAK, and ASK). Data of selected polymers demonstrate that these polycationic compounds are essentially nontoxic in vitro on normal rat liver or mouse spleen cells and have no cytostatic effect on mouse colorectal carcinoma C26 cells. The blood clearance and biodistribution of these derivatives were greatly dependent on the position and number of Ser residues in the branches and possess a rather extended blood survival in mice. Polypeptides were taken up predominantly by the liver and kidney (S(i)K, LSK, and ASK) or kidney and lung (SK and SAK). The best survival in the blood was found with SAK, representing the first polycationic branched polypeptide, which show extended blood clearance. The relative position of Ser residue had also a marked influence on the immunogenicity of polypeptides. The characteristics of the antibody response to polypeptide containing Ser at the end of the branches (SAK) or adjacent to the polylysine backbone (ASK) was also dependent on the genetic background of the mouse strains. We also found that these compounds have no effect on to the SRBC-specific humoral immune response, indicating the lack of nonspecific immunostimulatory potential. In conclusion, these studies suggest that synthetic branched polypeptides with Ser can be considered as candidates for constructing suitable conjugates for drug/epitope delivery. It is not only due to the presence of hydroxyl group to be used for oxime chemistry but also to their beneficial biological features.

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M. Szekerke

Carrier design: Synthesis and conformational studies of poly (L-lysine) based branched polypeptides with hydroxyl groups in the side chains

Branched Polypeptides with a Poly(L-Lysine) Backbone: Synthesis, Conformation, and Immunomodulation

Carrier design: biodistribution of branched polypeptides with a poly(L-lysine) backbone

Investigation of drug-protein interactions and the drug-carrier concept by the use of branched polypeptides as model systems. Synthesis and characterization of the model peptides

Carrier Design: New Generation of Polycationic Branched Polypeptides Containing OH Groups with Prolonged Blood Survival and Diminished in Vitro Cytotoxicity

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