L. Bekale

Effect of polymer molecular weight on chitosan-protein interaction.

We present a comprehensive study of the interactions between chitosan nanoparticles (15, 100 and 200 kDa with the same degree of deacetylation 90%) and two model proteins, i.e., bovine (BSA) and human serum albumins (HSA), with the aim of correlating chitosan molecular weight (Mw) and the binding affinity of these naturally occurring polymers to protein. The effect of chitosan on the protein secondary structure and the influence of protein complexation on the shape of chitosan nanoparticles are discussed. A combination of multiple spectroscopic methods, transmission electron microscopy (TEM) and thermodynamic analysis were used to assess the polymer-protein complex formation. Results revealed that the three chitosan nanoparticles interact with BSA to form chitosan-BSA complexes, mainly through hydrophobic contacts with the affinity order: 200>100>15 kDa. However, HSA-chitosan complexation is mainly via electrostatic interactions with the stability order: 100>200>15 kDa. Furthermore, the association between polymer and protein causes a partial protein conformational change by a major reduction of α-helix from 63% (free BSA) to 57% (chitosan-BSA) and 57% (free HSA) to 51% (chitosan-HSA). Finally, TEM micrographs clearly revealed that the binding of serum albumins with chitosan nanoparticles induces a significant change in protein morphology and the shape of the polymer.

Microscopic and thermodynamic analysis of PEG–β-lactoglobulin interaction

We report the binding of milk β-lactoglobulin (β-LG) with PEG-3000, PEG-6000 and methoxypoly(ethylene glycol) anthracene (mPEG-anthracene) in aqueous solution at pH 7.4, using multiple spectroscopic methods, thermodynamic analysis, transmission electron microscopy (TEM) and molecular modeling. Thermodynamic and spectroscopic analysis showed that polymers bind β-LG via van der Waals interactions, hydrogen bonding and hydrophobic interactions, with overall binding constants KPEG-3000–β-LG = 9.2 (±0.9) × 103 M−1, KPEG-6000–β-LG = 9.7 (±0.7) × 103 M−1 and KmPEG-anthracene–β-LG = 5.5 (±0.5) × 104 M−1. The binding affinity was mPEG-anthracene > PEG-6000 > PEG-3000. Transmission electron microscopy analysis showed significant changes in protein morphology as polymer–protein complexation occurred, with a major increase in the diameter of the protein aggregate. Modeling showed several hydrogen bonding systems between PEG and the different amino acid stabilized polymer–β-LG complexes. The free binding energy indicated that the interaction process is spontaneous at room temperature. Furthermore, mPEG-anthracene is a stronger protein binder than PEG-3000 and PEG-6000, due to its major hydrophobic characteristics.

The role of polymer size and hydrophobic end-group in PEG-protein interaction.

We investigated the interaction between polyethylene (glycol) (PEG) and human (HSA) and bovine serum albumin (BSA) in aqueous solution, using multiple spectroscopic methods and molecular modeling. The two important polymer characteristics, size and PEG hydrophobic end-group are studied in order to determine the effect of each one on PEG-protein interaction. The bindings of PEG and mPEG-anthracene with serum albumins occur via hydrophobic and H-bonding contacts with the binding affinity PEG-6000>mPEG-anthracene>PEG-3000 for BSA and EG-6000>PEG-3000>mPEG-anthracene for HSA. Modeling showed different protein binding sites are involved in PEG-BSA and PEG-HSA complexes. Several H-bonding systems between PEG and different amino acids are stabilizing polymer-protein complexes. The free binding energies of -6.48 (PEG-BSA) and -6.36 kcal/mol (PEG-HSA) showed that the interaction process is spontaneous at room temperature. Minor alterations of protein alpha-helix and beta-sheet structures were observed upon PEG complexation.

Trypsin inhibitor complexes with human and bovine serum albumins: TEM and spectroscopic analysis

We report the binding of trypsin inhibitor (TI) with human serum albumin (HSA) and bovine serum albumin (BSA) at physiological conditions, using FTIR, CD, UV-Visible spectroscopic methods and transmission electron microscopy (TEM). Structural analysis showed that trypsin inhibitor binds HSA and BSA via hydrophilic and hydrophobic contacts with overall binding constants of KTI-HSA=1.4 (±0.5)×10(4)M(-1) and KTI-BSA=1.1 (±0.4)×10(6)M(-1). Trypsin inhibitor complexation induces minor reduction of the protein α-helix and a major increase in β-sheet structure. TEM images show that trypsin inhibitor complex formation leads to the protein aggregation and fibrillation.

Structural analysis of doxorubicin-polymer conjugates.

Synthetic polymers poly(ethylene glycol) (PEG), methoxypoly (ethylene glycol) polyamidoamine (mPEG-PAMAM-G3) and polyamidoamine (PAMAM-G4) dendrimers were used for encapsulation of antibiotic drug doxorubicin (Dox) and its analogue N-(trifluoroacetyl) doxorubicin (FDox) in aqueous solution at pH 7.4. Multiple spectroscopic methods, transmission electron microscopy (TEM) and molecular modeling were used to characterize the drug binding process to synthetic polymers. Structural analysis showed that drug-polymer binding occurs via both H-bonding and hydrophobic contacts. The order of binding is PAMAM-G4>mPEG-PAMAM-G3>PEG-6000 with Dox forming more stable conjugate than FDox. Transmission electron microscopy showed significant changes in carrier morphology with major changes in the shape of the polymer aggregate as drug encapsulation occurred. Modeling also showed that drug is located in the surface and in the internal cavities of PAMAM with the free binding energy of -4.14 kcal/mol for Dox and -3.93 kcal/mol for FDox, indicating of spontaneous drug-polymer interaction at room temperature.

Targeted conjugation of breast anticancer drug tamoxifen and its metabolites with synthetic polymers

Conjugation of antitumor drug tamoxifen and its metabolites, 4-hydroxytamxifen and ednoxifen with synthetic polymers poly(ethylene glycol) (PEG), methoxypoly (ethylene glycol) polyamidoamine (mPEG-PAMAM-G3) and polyamidoamine (PAMAM-G4) dendrimers was studied in aqueous solution at pH 7.4. Multiple spectroscopic methods, transmission electron microscopy (TEM) and molecular modeling were used to characterize the drug binding process to synthetic polymers. Structural analysis showed that drug-polymer binding occurs via both H-bonding and hydrophobic contacts. The order of binding is PAMAM-G4>mPEG-PAMAM-G3>PEG-6000 with 4-hydroxttamoxifen forming more stable conjugate than tamoxifen and endoxifen. Transmission electron microscopy showed significant changes in carrier morphology with major changes in the shape of the polymer aggregate as drug encapsulation occurred. Modeling also showed that drug is located in the surface and in the internal cavities of PAMAM with the free binding energy of -3.79 for tamoxifen, -3.70 for 4-hydroxytamoxifen and -3.69kcal/mol for endoxifen, indicating of spontaneous drug-polymer interaction at room temperature.

Transporting testosterone and its dimers by serum proteins.

A substantial part of steroids is bound to serum proteins in vivo. We report the association of testosterone and it aliphatic dimer (alip) and aromatic dimer (arom) with human serum albumin (HSA) and bovine serum albumin (BSA) in aqueous solution at physiological pH. Multiple spectroscopic methods, transmission electron microscopy (TEM) and molecular modeling were used to characterize steroid-protein binding and protein aggregation process. Spectroscopic analysis showed that steroids bind protein via hydrophobic, hydrophilic and H-bonding interactions. HSA forms more stable complexes than BSA. The binding affinity of steroid-protein adducts is testosterone>dimer-aromatic>dimer-aliphatic. Transmission electron microscopy showed major changes in protein morphology as steroid-protein complexation occurred with increase in the diameter of the protein aggregate indicating encapsulation of steroids by serum proteins. Modeling showed the presence of H-bonding stabilized testosterone-protein complexes with the free binding energy of -12.95 for HSA and -11.55 kcal/mol for BSA, indicating that the interaction process is spontaneous at room temperature. Steroid complexation induced more perturbations of BSA conformation than HSA.

Encapsulation of testosterone and its aliphatic and aromatic dimers by milk beta-lactoglobulin

The encapsulation of testosterone and it aliphatic dimer (alip) and aromatic dimer (arom) with milk β-lactoglobulin (β-LG) was studied in aqueous solution at pH 7.4. Multiple spectroscopic methods, transmission electron microscopy (TEM) and molecular modeling were used to characterize testosterone-β-LG binding and protein aggregation process. Spectroscopic analysis showed that steroids bind β-LG via hydrophobic and H-bonding interactions with overall binding constants K test-β-LG = 5.6 (± 0.6) × 10(4)M(-1), K test-dimeralip-β-LG = 4.8 (± 0.5) × 10(3)M(-1) and K test-dimer-arom-β-LG = 2.9 (± 0.4) × 10(4)M(-1). The binding affinity was testosterone > testosterone dimer-aromatic > testosterone dimer-aliphatic. Transmission electron microscopy showed major changes in protein morphology as testosterone-protein complexation occurred with increase in the diameter of the protein aggregate indicating encapsulation of steroids by β-LG. Modeling showed the presence of H-bonding stabilized testosterone-β-LG complexes with the free binding energy of -9.82 Kcal/mol indicating that the interaction process is spontaneous at room temperature.

Conjugation of steroids with PAMAM nanoparticles

We studied the binding process between polyamidoamine PAMAN-G4 dendrimer and testosterone and its aliphatic (alip) and aromatic (arom) dimers in aqueous solution at pH 7.4. Multiple spectroscopic methods, transmission electron microscopy (TEM) and molecular modeling were used to characterize the steroid binding process to PAMAM-G4 nanoparticles. Thermodynamic parameters ΔS, ΔH and ΔG showed steroid-PAMAM bindings occur via hydrophobic, H-bonding and van der Waals contacts. The binding affinity is testosterone>testosterone-aromatic dimer>testosterone-aliphatic dimer. Transmission electron microscopy showed significant changes in carrier morphology with major changes in the diameter of the polymer aggregate as steroid encapsulation occurred. Modeling also showed that testosterone is located in the interior cavity of PAMAM with the free binding energy of -9.36 kcal/mol, indicating of spontaneous steroid-polymer interaction at room temperature.