Interaction of hidrophilic porphyrins and extracellular hemoglobin with biomimetic models of biological membranes / Interação de porfirinas hidrofílicas e de hemoglobina extracelular com modelos biomiméticos de membrana biológica

AUTOR(ES)
DATA DE PUBLICAÇÃO

2008

RESUMO

In the first part of this work interactions of the cationic meso tetrakis (4-N-methilpyridil) porphyrin (TMPyP) and meso-tetrakis (4-sulfonatophenyl) porphyrin (TPPS4) in the free base forms with membrane model systems (ionic micelles, mixed micelles and phospholipids vesicles) in aqueous solutions, have been investigated by optical absorption, resonance light scattering (RLS), fluorescence and SAXS (Small Angle X-Ray Scattering). The best-fit SAXS curves were obtained assuming for cetyltrimethylammonium chloride (CTAC) micelle a prolate ellipsoidal shape in the absence and upon incorporation of 2-10 mM TPPS4. SAXS results show that the presence of TPPS4 impacts on micellar hydrophobic core, leading to a micellar reassembling into smaller micelles. SAXS data analysis demonstrated a prolate ellipsoidal shape for sodium dodecyl sulfate (SDS) micelles; no significant changes in shape and size were observed for SDS-TMPyP co-micelles. Moreover, the ionization coefficient, α, decreases with the increase of the porphyrin concentration, suggesting the "screening" of the anionic charge of SDS by the cationic porphyrin. These results are consistent with optical absorption, fluorescence and RLS spectroscopies data, allowing to conclude that neutral surfactants present a smaller interaction with the cationic porphyrin as compared with ionic surfactants. Fluorescence quenching of TPPS4 and TMPyP is studied in aqueous solution and upon addition of micelles of SDS, CTAC, N-hexadecyl-N,N-dimethyl-3-ammonio-1- propanesulfonate (HPS) and t-octylphenoxypolyethoxyethanol (Triton X-100). Potassium iodide (KI) was used as quencher. Steady-state Stern-Volmer plots were best fitted by a quadratic equation, including dynamic (KD) and static (KS) quenching. KS was significantly smaller than KD. For TMPyP quenching results are consistent with reported binding constants: a significant reduction of quenching takes place for SDS, a moderate reduction is observed for HPS and almost no change is seen for Triton X-100. For CTAC-TPPS4 system an enhancement of quenching was observed as compared to pure buffer. This is probably associated to accumulation of iodide at the cationic micellar interface. The attraction between CTAC headgroups and I-, and repulsion between SDS and I-, enhances and reduces the fluorescence quenching, respectively, of porphyrins located at the micellar interface. The small quenching of TPPS4 in Triton X-100 is consistent with strong binding as reported in the literature. Anionic TPPS4 and cationic TMPyP in the presence of low concentrations of the surfactants CTAC and SDS, respectively, showed formation of aggregates, monitored by optical absorption, fluorescence and resonance light scattering intensity (RLS). The addition of nonionic surfactant, Triton X-100, reduced the effect of aggregation monitored by the various techniques used in the present work. Therefore, under conditions for the maximum of aggregate formation (porphyrin-surfactant), apparently, the CTAC: TX-100 ratio equal to 40:60 and SDS:TX-100 ratio equal to 80:20 are not sufficient to eliminate aggregation, despite the significant decrease of the quenching effect of fluorescence and of the light scattering intensity. The interaction of TMPyP with 1-Palmitoyl-2-Oleoyl-sn- Glycero-3-Phosphocholine (POPC), 1-Palmitoyl-2-Oleoyl-sn-Glycero-3-[Phospho-rac-(1- glycerol)] (POPG) and the mixture POPC+POPG is predominantly due to the electrostatic contribution. The increase of the negative charge, due to addition of POPG, favors the interaction of vesicles with the cationic porphyrin. On the second part of this work the effects of three surfactants upon the oligomeric structure of the giant extracellular hemoglobin of Glossoscolex paulistus (HbGp) in the oxy - form was studied. The use of SDS, CTAC and HPS has allowed to differentiate the effects of opposite headgroup charges on the oligomeric structure dissociation and hemoglobin autoxidation. Furthermore, the interaction of HPS with HbGp was clearly less intense than the interaction of this hemoglobin with cationic (CTAC) and anionic (SDS) surfactants. Probably, this lower interaction with HPS is due to the lower electrostatic attraction between the HPS surfactant and the protein surface ionic sites when compared to the electrostatic interaction between HbGp and cationic and anionic surfactants. Spectroscopic data are discussed and compared with the literature in order to improve the understanding of hemoglobin-surfactant interaction as well as the acid isoelectric point (pI) influence of the giant extracellular hemoglobins on its structure-activity relationship. HbGp samples were studied by dynamic light scattering (DLS). In the pH from range 6.0 to 8.0, HbGp is stable and a monodisperse size distribution with a z-average hydrodynamic diameter (Dh) of 27±1 nm is observed. More alkaline pH (pH>9.0) induced an irreversible dissociation process, resulting in smaller Dh of 10±1 nm. Dh decrease suggests a complete hemoglobin dissociation. At pH 9.0 the dissociation kinetics is slow, taking a minimum of 24 h to be completed. Dissociation rate constants progressively increase at higher pH. Melting curves for HbGp showed oligomeric dissociation and protein denaturation as a function of pH. Autoxidation and dissociation processes are intimately related, so that oligomeric protein dissociation promotes the increase of autoxidation rate and vice-versa.

ASSUNTO(S)

vesículas de fosfolipídios saxs espectroscopia ótica hemoglobins phospholipidis vesicles porfirinas porphyrins dls optical spectroscopies micelas saxs hemoglobina dls micelles

ACESSO AO ARTIGO

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