Porphyrin depth in lipid bilayers as determined by iodide and parallax fluorescence quenching methods and its effect on photosensitizing efficiency.

Photosensitization by porphyrins and other tetrapyrrole chromophores is used in biology and medicine to kill cells. This light-triggered generation of singlet oxygen is used to eradicate cancer cells in a process dubbed "photodynamic therapy," or PDT. Most photosensitizers are of amphiphilic character and they partition into cellular lipid membranes. The photodamage that they inflict to the host cell is mainly localized in membrane proteins. This photosensitized damage must occur in competition with the rapid diffusion of singlet oxygen through the lipid phase and its escape into the aqueous phase. In this article we show that the extent of damage can be modulated by employing modified hemato- and protoporphyrins, which have alkyl spacers of varying lengths between the tetrapyrrole ring and the carboxylate groups that are anchored at the lipid/water interface. The chromophore part of the molecule, and the point of generation of singlet oxygen, is thus located at a deeper position in the bilayer. The photosensitization efficiency was measured with 9,10-dimethylanthracene, a fluorescent chemical target for singlet oxygen. The vertical insertion of the sensitizers was assessed by two fluorescence-quenching techniques: by iodide ions that come from the aqueous phase; and by spin-probe-labeled phospholipids, that are incorporated into the bilayer, using the parallax method. These methods also show that temperature has a small effect on the depth when the membrane is in the liquid phase. However, when the bilayer undergoes a phase transition to the solid gel phase, the porphyrins are extruded toward the water interface as the temperature is lowered. These results, together with a previous publication in this journal, represent a unique and precedental case where the vertical location of a small molecule in a membrane has an effect on its membranal activity.

[1]  R. Pandey Recent advances in photodynamic therapy , 2000 .

[2]  F. Wilkinson,et al.  Rate constants for the decay and reactions of the lowest electronically excited singlet state of molecular oxygen in solution , 1981 .

[3]  E. London,et al.  Parallax method for direct measurement of membrane penetration depth utilizing fluorescence quenching by spin-labeled phospholipids. , 1987, Biochemistry.

[4]  Nancy L Oleinick,et al.  The role of apoptosis in response to photodynamic therapy: what, where, why, and how , 2002, Photochemical & photobiological sciences : Official journal of the European Photochemistry Association and the European Society for Photobiology.

[5]  G. Feigenson,et al.  Fluorescence quenching in model membranes An analysis of the local phospholipid environments of diphenylhexatriene and gramicidin A , 1981 .

[6]  T. Dougherty An update on photodynamic therapy applications. , 2002, Journal of clinical laser medicine & surgery.

[7]  T. Dougherty Photodynamic therapy. , 1993, Photochemistry and photobiology.

[8]  Y. Usui DETERMINATION OF QUANTUM YIELD OF SINGLET OXYGEN FORMATION BY PHOTOSENSITIZATION , 1973 .

[9]  F. Goñi,et al.  Fluorescence quenching at interfaces and the permeation of acrylamide and iodide across phospholipid bilayers , 1993, FEBS letters.

[10]  Reinhard Schmidt,et al.  Physical Mechanisms of Generation and Deactivation of Singlet Oxygen , 2003 .

[11]  J. Moan,et al.  On the diffusion length of singlet oxygen in cells and tissues , 1990 .

[12]  M. Reed,et al.  The History of Photodetection and Photodynamic Therapy¶ , 2001, Photochemistry and photobiology.

[13]  W. E. Ford,et al.  CHLOROPHYLL PHOTOSENSITIZED ELECTRON TRANSFER IN PHOSPHOLIPID BILAYER VESICLE SYSTEMS: EFFECTS OF CHOLESTEROL ON RADICAL YIELDS AND KINETIC PARAMETERS * , 1984 .

[14]  T. Dubbelman,et al.  Photodynamic treatment of yeast cells with the dye toluidine blue: all-or-none loss of plasma membrane barrier properties. , 1992, Biochimica et biophysica acta.

[15]  London,et al.  Location of diphenylhexatriene (DPH) and its derivatives within membranes: comparison of different fluorescence quenching analyses of membrane depth , 1998, Biochemistry.

[16]  M. DeRosa Photosensitized singlet oxygen and its applications , 2002 .

[17]  J. Vanderkooi,et al.  Oxygen diffusion in biological and artificial membranes determined by the fluorochrome pyrene , 1975, The Journal of general physiology.

[18]  G. Miotto,et al.  Photosensitization with zinc (II) phthalocyanine as a switch in the decision between apoptosis and necrosis. , 2001, Cancer research.

[19]  E. London,et al.  Anchoring of tryptophan and tyrosine analogs at the hydrocarbon-polar boundary in model membrane vesicles: parallax analysis of fluorescence quenching induced by nitroxide-labeled phospholipids. , 1995, Biochemistry.

[20]  Y. Barenholz,et al.  Organization and dynamics of pyrene and pyrene lipids in intact lipid bilayers. Photo-induced charge transfer processes. , 1991, Biophysical journal.

[21]  M. C. Feiters,et al.  UV-VIS, FLUORESCENCE, AND EPR STUDIES OF PORPHYRINS IN BILAYERS OF DIOCTADECYLDIMETHYLAMMONIUM SURFACTANTS , 1994 .

[22]  Meir Shinitzky,et al.  Physiology of membrane fluidity , 1984 .

[23]  M. Kępczyński,et al.  Interaction of Dicarboxylic Metalloporphyrins with Liposomes. The Effect of pH on Membrane Binding Revisited ¶ , 2002, Photochemistry and photobiology.

[24]  D. Brown,et al.  On the origin of sphingolipid/cholesterol-rich detergent-insoluble cell membranes: physiological concentrations of cholesterol and sphingolipid induce formation of a detergent-insoluble, liquid-ordered lipid phase in model membranes. , 1997, Biochemistry.

[25]  S J Singer,et al.  Membrane fluidity and cellular functions. , 1975, Advances in experimental medicine and biology.

[26]  E. London,et al.  Extension of the parallax analysis of membrane penetration depth to the polar region of model membranes: use of fluorescence quenching by a spin-label attached to the phospholipid polar headgroup. , 1993, Biochemistry.

[27]  A. Moor,et al.  Signaling pathways in cell death and survival after photodynamic therapy. , 2000, Journal of photochemistry and photobiology. B, Biology.

[28]  M. Shinitzky,et al.  Vertical displacement of membrane proteins mediated by changes in microviscosity. , 1976, Proceedings of the National Academy of Sciences of the United States of America.

[29]  E. Corey,et al.  A Study of the Peroxidation of Organic Compounds by Externally Generated Singlet Oxygen Molecules , 1964 .

[30]  R. Cundall,et al.  Fluorescence lifetime and quenching studies on some interesting diphenylhexatriene membrane probes , 1983 .

[31]  W.Phillip Helman,et al.  Rate Constants for the Decay and Reactions of the Lowest Electronically Excited Singlet State of Molecular Oxygen in Solution. An Expanded and Revised Compilation , 1995 .

[32]  Thomas J. Dougherty,et al.  Basic principles of photodynamic therapy , 2001 .

[33]  R. D. Kaiser,et al.  Determination of the depth of BODIPY probes in model membranes by parallax analysis of fluorescence quenching. , 1998, Biochimica et biophysica acta.

[34]  Benjamin Ehrenberg,et al.  Do Liposome-binding Constants of Porphyrins Correlate with Their Measured and Predicted Partitioning Between Octanol and Water?¶ , 2002, Photochemistry and photobiology.

[35]  J Moan,et al.  Lysosomes and Microtubules as Targets for Photochemotherapy of Cancer , 1997, Photochemistry and photobiology.

[36]  Z. Malik,et al.  Electric depolarization of photosensitized cells: lipid vs. protein alterations. , 1993, Biochimica et biophysica acta.

[37]  E. London,et al.  The location of fluorescence probes with charged groups in model membranes. , 1998, Biochimica et biophysica acta.

[38]  R. Bonnett Progress with heterocyclic photosensitizers for the photodynamic therapy (PDT) of tumours , 2002 .

[39]  B. Ehrenberg,et al.  Liposome binding constants and singlet oxygen quantum yields of hypericin, tetrahydroxy helianthrone and their derivatives: studies in organic solutions and in liposomes. , 2000, Journal of photochemistry and photobiology. B, Biology.

[40]  G. Feigenson Fluorescence quenching in model membranes. , 1982, Biophysical journal.

[41]  G. Jori,et al.  PORPHYRIN‐LIPOSOME INTERACTIONS: INFLUENCE OF THE PHYSICO‐CHEMICAL PROPERTIES OF THE PHOSPHOLIPID BILAYER , 1988, Photochemistry and photobiology.

[42]  D. Kessel,et al.  Intracellular sites of photodamage as a factor in apoptotic cell death , 2001 .

[43]  Benjamin Ehrenberg,et al.  The depth of porphyrin in a membrane and the membrane's physical properties affect the photosensitizing efficiency. , 2002, Biophysical journal.

[44]  B. Ehrenberg,et al.  SINGLET OXYGEN GENERATION BY PORPHYRINS AND THE KINETICS OF 9,10‐DIMETHYLANTHRACENE PHOTOSENSITIZATION IN LIPOSOMES , 1993, Photochemistry and photobiology.

[45]  B. Ehrenberg,et al.  Kinetics and Yield of Singlet Oxygen Photosensitized by Hypericin in Organic and Biological Media , 1998, Photochemistry and photobiology.

[46]  Roger Guilard,et al.  The porphyrin handbook , 2002 .

[47]  C. M. Allen,et al.  Current status of phthalocyanines in the photodynamic therapy of cancer , 2001 .

[48]  B. Ehrenberg Assessment of the partitioning of probes to membranes by spectroscopic titration. , 1992, Journal of photochemistry and photobiology. B, Biology.

[49]  A. Kleinfeld,et al.  Interaction of fluorescence quenchers with the n-(9-anthroyloxy) fatty acid membrane probes , 1983 .