Phylloerythrin: Mechanisms for cellular uptake and location, photosensitisation and spectroscopic evaluation

Enhanced efficiency of cell death by lysosome-specific photodamage

Mobilization of specific mechanisms of regulated cell death is a promising alternative to treat challenging illness such as neurodegenerative disease and cancer. The use of light to activate these mechanisms may provide a route for target-specific therapies. Two asymmetric porphyrins with opposite charges, the negatively charged TPPS2a and the positively charged CisDiMPyP were compared in terms of their properties in membrane mimics and in cells. CisDiMPyP interacts to a larger extent with model membranes and with cells than TPPS2a, due to a favorable electrostatic interaction. CisDiMPyP is also more effective than TPPS2a in damaging membranes. Surprisingly, TPPS2a is more efficient in causing photoinduced cell death. The lethal concentration on cell viability of 50% (LC50) found for TPPS2a was ~3.5 (raw data) and ~5 (considering photosensitizer incorporation) times smaller than for CisDiMPyP. CisDiMPyP damaged mainly mitochondria and triggered short-term phototoxicity by necro-apoptotic cell death. Photoexcitation of TPPS2a promotes mainly lysosomal damage leading to autophagy-associated cell death. Our data shows that an exact damage in lysosome is more effective to diminish proliferation of HeLa cells than a similar damage in mitochondria. Precisely targeting organelles and specifically triggering regulated cell death mechanisms shall help in the development of new organelle-target therapies.

Secondary plant products causing photosensitization in grazing herbivores: their structure, activity and regulation

Photosensitivity in animals is defined as a severe dermatitis that results from a heightened reactivity of skin cells and associated dermal tissues upon their exposure to sunlight, following ingestion or contact with UV reactive secondary plant products. Photosensitivity occurs in animal cells as a reaction that is mediated by a light absorbing molecule, specifically in this case a plant-produced metabolite that is heterocyclic or polyphenolic. In sensitive animals, this reaction is most severe in non-pigmented skin which has the least protection from UV or visible light exposure. Photosensitization in a biological system such as the epidermis is an oxidative or other chemical change in a molecule in response to light-induced excitation of endogenous or exogenously-delivered molecules within the tissue. Photo-oxidation can also occur in the plant itself, resulting in the generation of reactive oxygen species, free radical damage and eventual DNA degradation. Similar cellular changes occur in affected herbivores and are associated with an accumulation of photodynamic molecules in the affected dermal tissues or circulatory system of the herbivore. Recent advances in our ability to identify and detect secondary products at trace levels in the plant and surrounding environment, or in organisms that ingest plants, have provided additional evidence for the role of secondary metabolites in photosensitization of grazing herbivores. This review outlines the role of unique secondary products produced by higher plants in the animal photosensitization process, describes their chemistry and localization in the plant as well as impacts of the environment upon their production, discusses their direct and indirect effects on associated animal systems and presents several examples of well-characterized plant photosensitization in animal systems.

Hepatic photosensitization in buffaloes intoxicated by Brachiaria decumbens in Minas Gerais state, Brazil

The aim of this paper is to report the study of hepatogenous photosensitization in buffaloes during two outbreaks provoked by ingestion of Brachiaria decumbens in Minas Gerais state, Brazil. Ten young buffaloes in outbreak 1 and seven buffaloes in outbreak 2 were intoxicated by B. decumbens. Nine clinically healthy buffaloes raised under the same conditions as the sick animals served as the control group. All animals were subjected to clinical examination, and serum was collected to measure gamma-glutamyl transferase (GGT), aspartate aminotransferase (AST), direct bilirubin (DB), indirect bilirubin (IB) and total bilirubin (TB) as indicators of liver function and urea and creatinine as indicators of renal function. Histopathology of liver fragments from five different animals was carried out. During the outbreaks and every two months for one year, samples of grass from paddocks where the animals got sick were collected for quantitative evaluation of the saponin protodioscin, combined with observations of pasture characteristics and daily rainfall. Clinical signs included apathy, weight loss, restlessness, scar retraction of the ears and intense itching at the skin lesions, mainly on the rump, the tail head, neck and hindlimbs, similar to the signs observed in other ruminants. Only the GGT enzyme presented significantly different (P < 0.01) serum levels between intoxicated animals (n = 17) and healthy animals (n = 9), indicating liver damage in buffaloes bred in B. decumbens pastures. Microscopy of the liver showed foamy macrophages and lesions of liver disease associated with the presence of crystals in the bile ducts, which have also been found in sheep and cattle poisoned by grasses of the genus Brachiaria. During the outbreaks, protodioscin levels were higher than 3%, and shortly after, these levels were reduced to less than 0.80%, suggesting a hepatic injury etiology. The outbreaks took place at the beginning of the rainy season, and there was a positive correlation between saponin and the amount of rainfall, as well as between saponin and the amount of green leaves in the pasture. These findings indicate that the grass was more toxic in this period. This is the first report of photosensitization by B. decumbens in buffalo.

Fluorescence spectra and measurement of phylloerythrin (phytoporphyrin) in plasma from clinically healthy sheep, goats, cattle and horses

AIM

To measure the background concentration of phylloerythrin in plasma from clinically healthy sheep, goats, cattle and horses on pasture.

METHODS

Blood samples were taken from 34 sheep of the Dala breed, 20 female Norwegian dairy goats, 35 Norwegian Red cows and 34 horses of different breeds. All animals were grazing green pasture when blood samples were taken. Blood samples were collected from each of four clinically healthy newborn lambs, goats, calves and foals, and pooled into one sample per species. Plasma samples were analysed for phylloerythrin by fluorescence spectroscopy, using a Perkin-Elmer LS-50B luminescence spectrometer equipped with a red-sensitive photomultiplier. The fluorescence spectra of phylloerythrin in plasma from the adult ruminants were compared with those in plasma from the neonatal ruminants, to which a known concentration of phylloerythrin had been added.

RESULTS

Plasma obtained from the adult ruminants had spectral characteristics similar to those of phylloerythrin, namely weak emission peaks at 650 and 711 nm, when excited at 425 nm. Emission spectra obtained from plasma from the neonatal ruminants showed no fluorescence at these wavelengths. On average, 0.012 (SD 0.004), 0.06 (SD 0.04), and 0.05 (SD 0.03) micromol/l phylloerythrin were present in plasma samples from the sheep, goats, and cattle, respectively. The fluorescence spectra of plasma from the newborn foals were similar to spectra of plasma from adult horses, with weak emission at 669 nm.

CONCLUSION

Small concentrations of phylloerythrin were detected in plasma from clinically healthy sheep, goats and cattle, but none could be detected in plasma from clinically healthy horses.

Measurement of phylloerythrin (phytoporphyrin) in plasma or serum and skin from sheep photosensitised after ingestion of Narthecium ossifragum

AIM

To establish a method for measuring phylloerythrin in plasma or serum and skin from lambs photosensitised after ingestion of the plant, Narthecium ossifragum, which induces an hepatogenous photosensitisation similar to the disease known as facial eczema in sheep.

METHODS

For two successive summers, lambs were grazed on uncultivated pastures containing N. ossifragum. Clinical photosensitisation was deemed to have occurred when symptoms such as restlessness, scratching, oedema and reddening of the skin were observed. Sixteen lambs that exhibited signs of photosensitisation were included in this study in the first year and five in the following year. A total of 16 clinically healthy lambs served as controls. Fluorescence emission and excitation spectra of phylloerythrin were measured in plasma or serum samples from the 21 photosensitised and 16 non-photosensitised lambs. In the first year of the study, skin samples were collected post mortem from the ear, lip, neck, nose, leg, belly, udder, back, vulva and perineal region, from all photosensitised and from seven non-photosensitised lambs, and examined by fixing them between two glass plates (each of 1 mm thickness) and placing them at a fixed angle in front of a fluorescence spectrofluorometer.

RESULTS

All plasma or serum samples obtained from the photosensitised lambs exhibited strong phylloerythrin-like fluorescence of identical spectra; maximum fluorescence was at 650 and 711 nm, and maximum excitation at 425 nm. Emission spectra obtained from plasma or sera from non-photosensitised sheep grazing the same N. ossifragum-containing pastures exhibited either no or only minor fluorescence. Phylloerythrin concentration in plasma or serum exceeded 0.3 microg/ml before clinical photosensitisation occurred, whereas the concentration in samples from clinically healthy lambs was <0.05 microg/ml. Fluorescence from skin samples from the photosensitised lambs showed emission peaks at 650, 670 and 711 nm, whereas the phylloerythrin emission peaks at 650 and 711 nm were not observed in skin from clinically healthy lambs.

CONCLUSION

Plasma concentrations of phylloerythrin in healthy sheep were <0.05 microg/ml. Clinical signs of photosensitisation were not observed until the concentration of phylloerythrin in plasma exceeded 0.3 microg/ml. This is the first reported spectroscopic method for analysis of phylloerythrin and the only one which does not involve exposure of the analyst to hazardous chemicals. It has the additional benefit of distinguishing between hepatogenous and primary photosensitisation.

Detection of singlet oxygen in blood serum samples of clinically healthy lambs and lambs suffering from alveld disease

Alveld is a disease in lambs of domestic sheep (Ovis aries L.), characterized by a combination of photosensitivity and liver damage. Generation of singlet oxygen play a major role in phototoxicity reactions. The compound phylloerythrin (phytoporphyrin) is so far assumed to be the main photodynamic agent in hepatogenous photosensitivity diseases in sheep. Phylloerythrin is a potent photosensitizer and an efficient source of singlet oxygen. The compound accumulates in the peripheral circualtion upon liver damage. Liver dysfunction is also likely to cause an increase in the blood level of bilirubin. Formation of singlet oxygen by bilirubin is reported. In the present work the photosensitizing potential of serum has been measured and related to the bilirubin- and phylloerythrin levels in lambs suffering from alveld and in clinically healthy controls. The singlet oxygen level of the serum was taken as a measure of the photosensitizing potential. The observed singlet oxygen values in serum from alveld lambs were significantly higher than the corresponding values observed in clinically healthy control lambs. This indicates that the serum of the alveld lambs contains an elevated concentration of photosensitizer. The singlet oxygen level was not correlated to the concentration of bilirubin or phylloerythrin. The results indicate that the photosensitizing mechanism is quite complex and may involve other sensitizer(s) than phylloerythrin.

In vitro and in vivo photosensitization by protoporphyrins possessing different lipophilicities and vertical localization in the membrane

Photodynamic therapy (PDT) is being evaluated in clinical trials for treatment of various oncologic and ophthalmic diseases. The main cause for cell inactivation and retardation of tumor growth after photoactivation of sensitizers is very short-lived singlet oxygen molecules that are produced and have limited diffusion distances. In this paper we show that the extent of biological damage can be modulated by using protoporphyrin, which was modified to increase its lipophilicity, and which also places the tetrapyrrole core deeper within the membrane by the carboxylate groups being anchored at the lipid:water interface. The uptake of the parent molecule (PPIX) and its diheptanoic acid analogue (PPIXC6) by WiDR and CT26 cells was investigated by fluorescence microscopy and by fluorescence intensity from the cells. The uptake of PPIXC6 increased almost linearly with incubation length for over 24 h, whereas for PPIX only 1 h was needed to reach maximal intracellular concentration. Fluorescence microscopy of both cell lines indicated that both drugs were distributed diffusely in the plasma membrane and cytoplasm, but remained outside the nucleus. The efficiency of in vitro inactivation of WiDr and CT26 cells increased with the length of the alkylcarboxylic chain. Tumors in mice that were treated with PPIX-PDT grew more slowly than control tumors. However, tumors that were given PPIXC6 followed by light exposure showed a significant delay in their growth.

Peripheral and axial substitution of phthalocyanines with solketal groups: synthesis and in vitro evaluation for photodynamic therapy

Phthalocyanines (Pcs) are a class of photosensitizers (PSs) with a strong tendency to aggregate in aqueous environment, which has a negative influence on their photosensitizing ability in photodynamic therapy. Pcs with either peripheral or axial solketal substituents, that is, ZnPc(sol)8 and Si(sol)2Pc, respectively, were synthesized and their tendency to aggregate as well as their photodynamic properties in 14C and B16F10 cell lines were evaluated. The results were compared to more hydrophilic silicon Pcs, that is, Si(PEG750)2Pc and Pc4. The order of cellular uptake was Pc4 > ZnPc(sol)8 > Si(PEG750)2Pc > Si(sol2)Pc. In contrast, Si(sol2)Pc showed the highest photocytotoxicity, while ZnPc(sol)8 did not show any photocytotoxicity up to a concentration of 10 microM in both cell types. UV/vis spectroscopy showed that Si(sol)2Pc is less prone to aggregation than ZnPc(sol)8, which can explain the lack of photoactivity of the latter. Si(sol)2Pc was predominantly located in lipid droplets, whereas Si(PEG750)2Pc was homogeneously distributed in the cytosol, which is probably the main cause of their difference in photoactivity. The very high photodynamic efficacy of Si(sol)2Pc makes this PS an interesting candidate for future studies.

The livestock photosensitizer, phytoporphyrin (phylloerythrin), is a substrate of the ATP-binding cassette transporter ABCG2

Hepatogenous photosensitization occurs in livestock following damage to the liver or biliary apparatus that results in impaired excretion of phytoporphyrin (phylloerythrin), a photosensitizer. Based on earlier observations that porphyrin-based photosensitizers are substrates of the ATP-binding cassette transporter ABCG2, we examined the ability of the hepatic transporters ABCB1 (P-glycoprotein) and ABCG2 to transport phytoporphyrin. Transport of phytoporphyrin was blocked by the ABCG2-specific inhibitor fumitremorgin C (FTC) in human embryonic kidney cells transfected with full length human ABCG2, while no transport by cells transfected with human ABCB1 was noted. FTC-inhibited transport of phytoporphyrin was also demonstrated in ABCG2-expressing LLC-PK1 pig kidney cells, consistent with the idea that the pig orthologue, like human ABCG2, transports the photosensitizer. ABCG2 expression was confirmed by immunohistochemistry in the hepatocytes of cow, pig and sheep livers. We conclude that phytoporphyrin is a substrate for ABCG2 and that the transporter is likely responsible for its biliary excretion.

Spectrofluorometric analysis of phylloerythrin (phytoporphyrin) in plasma and tissues from sheep suffering from facial eczema

AIMS

To study the increase in phylloerythrin concentration in plasma and the disposition of phylloerythrin in skin and other tissues of sheep in which the hepatogenous photosensitisation,facial eczema, had been experimentally induced by dosing with the mycotoxin, sporidesmin. Spectroscopic differences between plasma and skin measurements of animals kept inside and outside after dosing were also studied in order to establish whether phylloerythrin undergoes photodegradation when exposed to sunlight.

METHODS

Twenty-six Romney x Polled Dorset (25-30 kg)weaned female lambs were purchased from a commercial flock in the Waikato region, New Zealand. Twenty-two of these lambs were dosed with 0.25 mg sporidesmin/kg liveweight on each of two consecutive days (Days -1 and 0); the remaining four lambs served as controls. Both sporidesmin-dosed lambs and controls were randomly divided into two penned groups, one group housed inside in a darkened room and the others outside, exposed to natural sunlight. The lambs were fed green lucerne pellets and lucerne chaff ad libitum for 10 days prior to dosing and until Day 12 after the first dose; thereafter, all the lambs were fed fresh, cut grass (mainly ryegrass) ad libitum, until the end of the experimental period on Day 26. Plasma samples collected on Days -2, 7, 10, 12, 14, 17, 20 and 25were analysed for gamma glutamyltransferase (GGT) activity, bilirubin concentration, and the fluorescence spectrum of phylloerythrin. Spectrofluorometric analysis of phylloerythrin in skin was performed in vivo on the same days, using an external fiber-optic probe.

RESULTS

Eight of 11 lambs (73%) kept outside after sporidesmin dosing became photosensitised during the experimental period. None of the sporidesmin-dosed animals kept inside showed clinical signs of photosensitisation. The GGT activity in plasma increased exponentially during the experimental period in all sporidesmin-dosed animals until it reached a plateau. All plasma obtained from sporidesmin-dosed sheep had spectral characteristics similar to those of phylloerythrin, namely a peak in the excitation spectrum at 422 nm and strong emission band at 650 (SE 1) and 709 (SE 1) nm. The fluorescence under excitation at 422 nm of phylloerythrin added to plasma from control lambs had identical peaks. Emission spectra obtained from plasma from healthy sheep without addition of phylloerythrin showed either no fluorescence or minor fluorescence at around 671 nm. Fluorescence in skin of sporidesmin-dosed animals had similar spectra to that in plasma. The appearance of the phylloerythrin-like spectra occurred 2-3 days later in the skin than in plasma, and phylloerythrin in sunlight-exposed skin did not suffer photodegradation during the course of the study.

CONCLUSION

Plasma concentrations of phylloerythrin in healthy sheep were <0.1 micromol/l, and clinical signs of photosensitisation were not evident until concentrations exceeded 0.3 micromol/l. Plasma concentrations of phylloerythrin rose as high as 4.9 micromol/l in some animals. The concentration of phylloerythrin in skin began increasing 2-3 days later than that in blood. Hepatogenous photosensitisation can be diagnosed by analysis of plasma phylloerythrin concentrations using a spectroscopic method.