Biodegradable Biliverdin Nanoparticles for Efficient Photoacoustic Imaging.

Photoacoustic imaging has emerged as a promising imaging platform with a high tissue penetration depth. However, biodegradable nanoparticles, especially those for photoacoustic imaging, are rare and limited to a few polymeric agents. The development of such nanoparticles holds great promise for clinically translatable diagnostic imaging with high biocompatibility. Metabolically digestible and inherently photoacoustic imaging probes can be developed from nanoprecipitation of biliverdin, a naturally occurring heme-based pigment. The synthesis of nanoparticles composed of a biliverdin network, cross-linked with a bifunctional amine linker, is achieved where spectral tuning relies on the choice of reaction media. Nanoparticles synthesized in water or water containing sodium chloride exhibit higher absorbance and lower fluorescence compared to nanoparticles synthesized in 2-(N-morpholino)ethanesulfonic acid buffer. All nanoparticles display high absorbance at 365 and 680 nm. Excitation at near-infrared wavelengths leads to a strong photoacoustic signal, while excitation with ultraviolet wavelengths results in fluorescence emission. In vivo photoacoustic imaging experiments in mice demonstrated that the nanoparticles accumulate in lymph nodes, highlighting their potential utility as photoacoustic agents for sentinel lymph node detection. The biotransformation of these agents was studied using mass spectroscopy, and they were found to be completely biodegraded in the presence of biliverdin reductase, a ubiquitous enzyme found in the body. Degradation of these particles was also confirmed in vivo. Thus, the nanoparticles developed here are a promising platform for biocompatible biological imaging due to their inherent photoacoustic and fluorescent properties as well as their complete metabolic digestion.

Three bilindione isomers: synthesis, characterization and reactivity of biliverdin analogs.

Linear tetrapyrrole is the core structure of light-sensitive native cofactors such as phycocyanobilin, phytochromobilin and bile pigments, which attracts increasing attention in biomimetic chemistry, photochemistry and coordination chemistry. To decipher the relationship between structures and functions, in this work, we firstly reported the synthesis, isolation and characterization of three bilindione isomers (ZZZ, syn, syn, syn 1, EZE, syn, syn, anti 2 and EZE, anti, syn, anti 3) bearing meso-pentafluorophenyl groups. The structures were confirmed by X-ray diffraction and 2-D NMR spectroscopes. More importantly, the interconversion between three isomers under heating and light irradiation was investigated, and isomer 3 was found to be transformed to 1 and 2 more easily, which is in line with the results of DFT calculation. This work provides important insights for understanding the relationship between structures and functions and would be important to further construct metal complexes based on linear tetrapyrrole ligands, which are complementary to well-studied the cyclic analogs such as porphyrin and corroles.

Alkyl peroxides reveal the ring opening mechanism of verdoheme catalyzed by heme oxygenase.

Heme oxygenase (HO) catalyzes heme catabolism through three successive oxygenation steps where the substrate heme itself activates O2. Although a rate-determining step of the HO catalysis is considered as third oxygenation, the verdoheme degradation mechanism has been the least understood in the HO catalysis. In order to discriminate three possible pathways proposed for the verdoheme ring-opening, we have examined reactions of the verdoheme-HO-1 complex with alkyl peroxides, namely MeOOH. Under reducing conditions, the MeOOH reaction afforded two novel products whose absorption spectra are similar to but slightly different from that of biliverdin. HPLC, ESI-MS, and NMR analysis show that these products are 1- and 19-methoxy-deoxy-biliverdins. The addition of a methoxy group at one end of the linear tetrapyrrole unambiguously indicates transient formation of the Fe-OOMe intermediate and rearrangement of its terminal methoxy group to the alpha-pyrrole carbon. The corresponding OH transfer of the Fe-OOH species is highly probable in the H2O2-dependent verdoheme degradation and is likely to be the case in the O2-dependent reaction catalyzed by HO as well.

In vitro permeability and metabolic stability of bile pigments and the effects of hydrophilic and lipophilic modification of biliverdin.

Bile pigments, including bilirubin and biliverdin are tetrapyrrolic, dicarboxylic acids capable of forming conjugates at their propionic acid groups via ester or amide bonds. They possess substantial antioxidant and anti-mutagenic activities and therefore their intestinal absorption might influence the development of cardiovascular disease and cancer. The aim of this study was to investigate whether altering the physico-chemical properties of bile pigments would improve their permeability in an in vitro assay of absorption. Native and synthetically modified bile pigments were tested for gastrointestinal permeability and metabolic stability using the Caco-2 cell line. In addition, a gross measure of their toxic effects was tested in a red blood cell co-incubation assay. The apparent permeability of unconjugated bilirubin (1), bilirubin ditaurate (2) and biliverdin (3) through Caco-2 cell monolayers was determined to be 10.4+/-1.2x10(-7), 35.2+/-3.4x10(-7) and 37.0+/-1.6x10(-7) cm/s (mean+/-SD), respectively, while biliverdin diglucosamine (4), and biliverdin dioctylamine (5) were impermeable. Unconjugated bilirubin, biliverdin, bilirubin ditaurate and biliverdin diglucosamine did not decompose when incubated in Caco-2 cell homogenates, whereas biliverdin dioctylamine decomposed over time. Only unconjugated bilirubin showed toxicity towards red blood cells (> or = 1000 microM), an effect that was abolished by the addition of 40 g/L serum albumin. The data presented here suggest that bile pigments are absorbed across the Caco-2 cell monolayer and that conjugation of biliverdin to hydrophilic or lipophilic moieties decreases their absorption and can reduce their metabolic stability. In summary, exogenous bilirubin and biliverdin supplements could be absorbed across the intestinal epithelium in vivo and potentially increase circulating concentrations of these antioxidant compounds.

Stereoselectivity of each of the three steps of the heme oxygenase reaction: hemin to meso-hydroxyhemin, meso-hydroxyhemin to verdoheme, and verdoheme to biliverdin.

Heme oxygenase catalyzes the regiospecific oxidation of hemin to biliverdin IXalpha with concomitant liberation of CO and iron by three sequential monooxygenase reactions. The alpha-regioselectivity of heme oxygenase has been thought to result from the regioselective oxygenation of the heme alpha-meso position at the first step, which leads to the reaction pathway via meso-hydroxyheme IXalpha and verdoheme IXalpha intermediates. However, recent reports concerning heme oxygenase forming biliverdin isomers other than biliverdin IXalpha raise a question whether heme oxygenase can degrade meso-hydroxyhemin and isomers other than the alpha-isomers. In this paper, we investigated the stereoselectivity of each of the two reaction steps from meso-hydroxyhemin to verdoheme and verdoheme to biliverdin by using a truncated form of rat heme oxygenase-1 and the chemically synthesized four isomers of meso-hydroxyhemin and verdoheme. Heme oxygenase-1 converted all four isomers of meso-hydroxyhemin to the corresponding isomers of verdoheme. In contrast, only verdoheme IXalpha was converted to the corresponding biliverdin IXalpha. We conclude that the third step, but not the second, is stereoselective for the alpha-isomer substrate. The present findings on regioselectivities of the second and the third steps have been discussed on the basis of the oxygen activation mechanisms of these steps.

Enantioselective syntheses of (13)C-labeled (2R)- and (2S)-phytochromobilin dimethyl ester.

(2R)- and (2S)-phytochromobilin dimethyl ester have been prepared in enantiomerically pure form, specifically (13)C-labeled at C(10) or C(15).

Synthesis, chromatographic purification, and analysis of isomers of biliverdin IX and bilirubin IX.

Neutral solvent systems were developed to isolate the alpha, beta, gamma, and delta isomers of biliverdin IX dimethyl ester by TLC. The individual free acids of biliverdin IX were obtained by saponification of the corresponding dimethyl esters. The bilirubin IX isomers were prepared by reducing the corresponding biliverdin IX isomers with NaBH3CN. Starting from a pure biliverdin IX dimethyl ester, the corresponding free acid of biliverdin IX or bilirubin IX was available within 3-4 h. Preparation of spectrally pure bile pigment required final TLC on acid-cleaned neutral TLC plates. The absorption spectra of the free acids and dimethyl esters of biliverdin IX in methanol showed a broad band at about 650 nm and a sharp band at about 375 nm. The long-wave-length band was extremely sensitive to the presence of strong acid. A 10-fold molar excess of HCl caused a 35- to 50-nm shift of the absorption maximum to longer wavelengths and near doubling of the maximum absorption. The molar absorption coefficients of biliverdins were identical for each free acid and dimethyl ester pair. In each case, Beer's law was followed in both methanol and acidified methanol. Methanol also proved to be a suitable solvent for spectroscopic determination of the non-alpha isomers of bilirubin IX. The wavelength of maximum absorption and molar absorption coefficient of each dipyrrolic ethyl anthranilate azo pigment derived from the various bilirubin IX isomers are also reported.

Preparation and properties of crystalline biliverdin IX alpha. Simple methods for preparing isomerically homogeneous biliverdin and [14C[biliverdin by using 2,3-dichloro-5,6-dicyanobenzoquinone.

Amorphous isomerically pure biliverdin IX alpha is readily prepared in more than 70% yield by dehydrogenation of bilirubin with 2,3-dichloro-5,6-dicyanobenzoquinone in dimethyl sulphoxide under carefully controlled conditions. Crystalline biliverdin IX alpha and amorphous [14C]biliverdin can be obtained similarly in more than 40+ yield. The pure crystalline pigment was characterized by elemental analysis, methylation, chemical and enzymic reduction to bilirubin, i.r.- and u.v.-visible-absorption spectroscopy, n.m.r. spectroscopy and field-desorption mass spectrometry, and its solubility was determined. Under certain conditions, dehydrogenation, gave biliverdin contaminated with III alpha and XIII alpha isomers as a result of disproporationation of bilirubin. Formation of non-IX alpha isomers depends on the concentrations of the reagents and the order in which they are mixed, and occurs under neutral anaerobic conditions. Free-radical reactions probably are responsible, suggesting that the first step in the deydrogenation of bilirubin with 2,3-dichloro-5,6-dicyanobenzoquinone in dimethyl sulphoxide is formation of a bilirubin cation radical, rather than hydride ion abstraction.

Synthesis of biliverdin and bilirubin 1-O-acyl-beta-D-glucopyranuronic acids.

Biliverdin and bilirubin mono- and di-beta-glucuronides were prepared by nucleophilic substitution of the 1-O-mesyl derivative of alpha-ethoxyethyl-protected glucuronic acid (compound II) with the tetrabutylammonium salts of biliverdin and bilirubin. Removal of the acetal-protecting groups by mild acid treatment yielded biliverdin glucuronides, which were reduced to bilirubin glucuronides. Depending on reaction conditions the pure beta-anomers or mixtures highly enriched in the beta-anomers were obtained. The biliverdin and bilirubin glucuronides were identical with pigments derived from bile. They were characterized as the IX alpha isomers and the beta-anomers by alkaline hydrolysis, n.m.r. spectroscopy, hydrolysis with beta-glucuronidase and conversion into dipyrrolic azopigments. Model reactions of the 1-O-mesylate (II) with other nucleophiles also were performed, i.e. the acetate anion and various alcohols.