Biliverdin

Biliverdin
Identifiers
114-25-0 YesY
3D model (Jmol) Interactive image
ChEBI CHEBI:17033 YesY
ChEMBL ChEMBL455477 YesY
ChemSpider 10628548 YesY
ECHA InfoCard 100.003.675
MeSH Biliverdin
PubChem 251
Properties
C33H34N4O6
Molar mass 582.646
Melting point > 300 °C
Hazards
Main hazards Irritant
Safety data sheet Sigma-Aldrich
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
YesY verify (what is YesYN ?)
Infobox references

Biliverdin is a green tetrapyrrolic bile pigment, and is a product of heme catabolism.[1][2] It is the pigment responsible for a greenish color sometimes seen in bruises.[2]

Metabolism

Heme metabolism

Biliverdin results from the breakdown of the heme moiety of hemoglobin in erythrocytes. Macrophages break down senescent erythrocytes and break the heme down into biliverdin, which normally rapidly reduces to free bilirubin.[1][3] Biliverdin is seen briefly in some bruises as a green color. In bruises, its breakdown into bilirubin leads to a yellowish color.[2]

Role in disease

Biliverdin has been found in excess in the blood of humans suffering from hepatic diseases. Jaundice is caused by the accumulation of biliverdin or bilirubin (or both) in the circulatory system and tissues.[1] Jaundiced skin and sclera (whites of the eyes) are characteristic of liver failure.

Role in treatment of disease

While typically regarded as a mere waste product of heme breakdown, evidence that suggests that biliverdin — and other bile pigments — has a physiological role in humans has been mounting.[4][5]

Bile pigments such as biliverdin possess significant anti-mutagenic and antioxidant properties and therefore may fulfil a useful physiological function.[5] Biliverdin and bilirubin have been shown to be potent scavengers of peroxyl radicals.[4][5] They have also been shown to inhibit the effects of polycyclic aromatic hydrocarbons, heterocyclic amines, and oxidants — all of which are mutagens. Some studies have found that people with higher concentration levels of bilirubin and biliverdin in their bodies have a lower frequency of cancer and cardiovascular disease.[4] It has been suggested that biliverdin — as well as many other tetrapyrrolic pigments — may function as an HIV-1 protease inhibitor[6] as well as having beneficial effects in asthma[5] though further research is needed to confirm these results. There are currently no practical implications for using biliverdin in the treatment of any disease.

In non-human animals

Biliverdin is an important pigment component in avian egg shells, especially blue and green shells. There is a significantly higher concentration of biliverdin in blue egg shells than in brown egg shells. Research has shown that the biliverdin of egg shells is produced from the shell gland, rather than from the breakdown of erythrocytes in the blood stream, though there is no evidence that the sources of the material are neither tetrapyrroles nor free haem from the blood plasma.

Along with its presence in avian egg shells, other studies have also shown that biliverdin is present in the blue-green blood of many marine fish, the blood of tobacco hornworm, the wings of moth and butterfly, the serum and eggs of frogs, and the placenta of dogs.[7] In the garfish (Belone belone) and related species, the bones are bright green because of biliverdin.

Biliverdin is also present in the green blood, muscles, bones, and mucosal lining of skinks of the genus Prasinohaema, found in New Guinea, and in a number of other reptiles, in particular arboreal snakes, and members of the Varanidae. It is uncertain whether this presence of biliverdin is an ecological or physiological adaptation of any kind, but green blood that gives terrestrial animals a green color seems to occur nearly exclusively in species that inhabit green vegetation, which is highly suggestive at the least. It has been suggested that accumulation of biliverdin might deter harmful infection by Plasmodium malaria parasites, though no statistically significant correlation has been established.[8] The Cambodian frog, Chiromantis samkosensis also exhibits this character along with turquoise bones.[9]

In fluorescence imaging

Fluorescent proteins visualize the cell cycle progression. IFP2.0-hGem(1/110) fluorescence is shown in green and highlights the S/G2/M phases. smURFP-hCdtI(30/120) fluorescence is shown in red and highlights the G0/G1 phases.

In a complex with reengineered bacterial phytochrome, biliverdin has been employed as an IR-emitting chromophore for in vivo imaging.[10][11] In contrast to fluorescent proteins which form their chromophore through posttranslational modifications of the polypeptide chain, phytochromes bind an external ligand (in this case, biliverdin), and successful imaging of the first bacteriophytochrome-based probe required addition of the exogenous biliverdin.[10] Recent studies demonstrated that bacteriophytochrome-based fluorescent proteins with high affinity to biliverdin can be imaged in vivo utilizing endogenous ligand only and, thus, with the same ease as the conventional fluorescent proteins.[11] Advent of the second and further generations of the biliverdin-binding bacteriophytochrome-based probes should broaden the possibilities for the non-invasive in vivo imaging.

A new class of fluorescent protein was evolved from a cyanobacterial (Trichodesmium erythraeum) phycobiliprotein, α-allophycocyanin, and named small ultra red fluorescent protein (smURFP) in 2016. smURFP autocatalytically self-incorporates the chromophore biliverdin without the need of an external protein, known as a lyase.[12] Jellyfish- and coral-derived fluorescent proteins require oxygen and produce a stoichiometric amount of hydrogen peroxide upon chromophore formation.[13] smURFP does not require oxygen or produce hydrogen peroxide and uses the chromophore biliverdin. smURFP has a large extinction coefficient (180,000 M−1 cm−1) and has a modest quantum yield (0.20), which makes it comparable biophysical brightness to eGFP and ~2-fold brighter than most red or far-red fluorescent proteins derived from coral. smURFP spectral properties are similar to the organic dye Cy5.[12]

See also

References

  1. 1 2 3 Boron W, Boulpaep E. Medical Physiology: a cellular and molecular approach, 2005. 984-986. Elsevier Saunders, United States. ISBN 1-4160-2328-3
  2. 1 2 3 Mosqueda L, Burnight K, Liao S (2005). "The Life Cycle of Bruises in Older Adults". Journal of the American Geriatrics Society. 53(8):1339-1343. doi:10.1111/j.1532-5415.2005.53406.x
  3. Seyfried, H; Klicpera, M; Leithner, C; Penner, E (1976). "Bilirubin metabolism (author's transl)". Wiener klinische Wochenschrift. 88 (15): 477–82. PMID 793184.
  4. 1 2 3 Bulmer, AC; Ried, K; Blanchfield, JT; Wagner, KH (2008). "The anti-mutagenic properties of bile pigments". Mutation research. 658 (1–2): 28–41. doi:10.1016/j.mrrev.2007.05.001. PMID 17602853.
  5. 1 2 3 4 Ohrui, T; Yasuda, H; Yamaya, M; Matsui, T; Sasaki, H (2003). "Transient relief of asthma symptoms during jaundice: a possible beneficial role of bilirubin". The Tohoku journal of experimental medicine. 199 (3): 193–6. doi:10.1620/tjem.199.193. PMID 12703664.
  6. McPhee, F; Caldera, PS; Bemis, GW; McDonagh, AF; Kuntz, ID; Craik, CS (1996). "Bile pigments as HIV-1 protease inhibitors and their effects on HIV-1 viral maturation and infectivity in vitro". The Biochemical Journal. 320 (Pt 2): 681–6. doi:10.1042/bj3200681. PMC 1217983Freely accessible. PMID 8973584.
  7. Fang, LS; Bada, JL (1990). "The blue-green blood plasma of marine fish". Comparative Biochemistry and Physiology B. 97 (1): 37–45. doi:10.1016/0305-0491(90)90174-R. PMID 2253479.
  8. Austin, C; Perkins, S (2006). "Parasites in a biodiversity hotspot: a survey of hematozoa and a molecular phyolgenetic analysis of plasmodium in New Guinea skinks". Journal of Parasitology. 92 (4): 770–777. doi:10.1645/GE-693R.1. PMID 16995395.
  9. Lee Grismer, L.; Thy, Neang; Chav, Thou; Holden, Jeremy (2007). "A New Species of Chiromantis Peters 1854 (Anura: Rhacophoridae) from Phnom Samkos in the Northwestern Cardamom Mountains, Cambodia". Herpetologica. 63 (3): 392–400. doi:10.1655/0018-0831(2007)63[392:ANSOCP]2.0.CO;2.
  10. 1 2 X. Shu; et al. (2009). "Mammalian expression of infrared fluorescent proteins engineered from a bacterial phytochrome". Science. 324 (5928): 804–807. doi:10.1126/science.1168683. PMC 2763207Freely accessible. PMID 19423828.
  11. 1 2 G.S.Filonov; Piatkevich, Kiryl D; Ting, Li-Min; Zhang, Jinghang; Kim, Kami; Verkhusha, Vladislav V; et al. (2011). "Bright and stable near infra-red fluorescent protein for in vivo imaging". Nat Biotechnol. 29 (8): 757–761. doi:10.1038/nbt.1918. PMC 3152693Freely accessible. PMID 21765402.
  12. 1 2 Rodriguez, Erik A.; Tran, Geraldine N.; Gross, Larry A.; Crisp, Jessica L.; Shu, Xiaokun; Lin, John Y.; Tsien, Roger Y. (2016-08-01). "A far-red fluorescent protein evolved from a cyanobacterial phycobiliprotein". Nature Methods. doi:10.1038/nmeth.3935. ISSN 1548-7105. PMID 27479328.
  13. Tsien, Roger Y. (1998-01-01). "The Green Fluorescent Protein". Annual Review of Biochemistry. 67 (1): 509–544. doi:10.1146/annurev.biochem.67.1.509. PMID 9759496.
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