The molecular basis of the coloration mechanism in lobster shell: β-Crustacyanin at 3.2-Å resolution

Cianci, Michele; Rizkallah, P.J.; Ołczak, Andrzej; Raftery, James; Chayen, Naomi E.; Zagalsky, P.F.; Helliwell, John R.

doi:10.1073/pnas.152088999

Cited by 184 publications

(256 citation statements)

References 32 publications

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“…It was proposed that α-crustacyanin consists of two groups of homologous proteins (CRTC, containing apoproteins C 1 , C 2 and A 1 , and CRTA, containing apoproteins A 2 and A 3 ) [43]. Cianci et al 2002 further reported the structural basis of the bathochromic shift and binding behavior based on subunits A 1 and A 3 of curstacyanin protein and several different perturbations of the carotenoid molecules [44].…”

Section: Invertebrate Carotenoid-binding Proteinsmentioning

confidence: 99%

“…The absorption spectrum of the carotenoid astaxanthin along with the β-crustacyanins displays a bathochromic shift of 100 nm (λ max = 580 nm [40]. It was proposed that extension of conjugation by coplanarization of the β-ionone rings with the polyene chain and polarization resulting from hydrogen bonding at the C(4) and C(4′) keto groups of astaxanthin may be mainly responsible for the bathochromic shift [30,44].…”

Section: Invertebrate Carotenoid-binding Proteinsmentioning

confidence: 99%

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Vertebrate and invertebrate carotenoid-binding proteins

Bhosale

Bernstein

2007

Archives of Biochemistry and Biophysics

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In invertebrates and vertebrates, carotenoids are ubiquitous colorants, antioxidants, and provitamin A compounds that must be absorbed from dietary sources and transported to target tissues where they are taken up and stabilized to perform their physiological functions. These processes occur in a specific and regulated manner mediated by high-affinity carotenoid-binding proteins. In this minireview, we examine the published literature on carotenoid-binding proteins in vertebrate and invertebrate systems, and we report our initial purification and characterization of a novel luteinbinding protein isolated from liver of Japanese quail (Coturnix japonica).

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Section: Invertebrate Carotenoid-binding Proteinsmentioning

confidence: 99%

Section: Invertebrate Carotenoid-binding Proteinsmentioning

confidence: 99%

Vertebrate and invertebrate carotenoid-binding proteins

Bhosale

Bernstein

2007

Archives of Biochemistry and Biophysics

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“…A paradigm for a modular assembly of carotenoid-containing subunits into distinct holoproteins occurs in crustacyanin, isolated from lobster carapace. Various combinations of five b-crustacyanin subunits (each 20 kDa) combine to form dimers in which two carotenoids span the interface [31].…”

Section: The Red Carotenoid Proteinmentioning

confidence: 99%

Water-soluble carotenoid proteins of cyanobacteria

Kerfeld¹

2004

Archives of Biochemistry and Biophysics

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In photosynthetic organisms, carotenoids function in light harvesting and in photoprotection. In cyanobacteria, there have been numerous reports of proteins that bind exclusively carotenoids. Perhaps the best characterized of these proteins are the 35 kDa water-soluble orange carotenoid proteins (OCPs). Structural, biochemical, and genomic data on the OCP and its paralogs are gradually revealing how these proteins function in photoprotection.

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“…For example, carotenoprotein crustacyanin, a well studied blue pigment from the lobster shell, contains orange carotenoid astaxanthin, which demonstrates a strong bathochromic shift due to noncovalent binding to a protein of lipocalin family (2).…”

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confidence: 99%

New Class of Blue Animal Pigments Based on Frizzled and Kringle Protein Domains

Bulina

Lukyanov

Yampolsky

et al. 2004

Journal of Biological Chemistry

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The nature of coloration in many marine animals remains poorly investigated. Here we studied the blue pigment of a scyfoid jellyfish Rhizostoma pulmo and determined it to be a soluble extracellular 30-kDa chromoprotein with a complex absorption spectrum peaking at 420, 588, and 624 nm. Furthermore, we cloned the corresponding cDNA and confirmed its identity by immunoblotting and mass spectrometry experiments. The chromoprotein, named rpulFKz1, consists of two domains, a Frizzled cysteine-rich domain and a Kringle domain, inserted into one another. Generally, Frizzleds are members of a basic Wnt signal transduction pathway investigated intensely with regard to development and cancerogenesis. Kringles are autonomous structural domains found throughout the blood clotting and fibrinolytic proteins. Neither Frizzled and Kringle domains association with any type of coloration nor Kringle intrusion into Frizzled sequence was ever observed. Thus, rpulFKz1 represents a new class of animal pigments, whose chromogenic group remains undetermined. The striking homology between a chromoprotein and members of the signal transduction pathway provides a novel node in the evolution track of growth factor-mediated morphogenesis compounds.Pigments in nature play important roles ranging from camouflage coloration and sunscreen to visual reception and participation in biochemical pathways (1). Considering the spectral diversity of pigment-based coloration in animals one can conclude that blue pigments occur relatively rare (as a rule blue coloration results from light diffraction or scattering rather than the presence of a blue pigment). At least partially this fact is explained by an inevitably more complex structure of blue pigments compared to yellow-reds. To appear blue a compound must contain an extended and usually highly polarized system of the conjugated -electrons.In many organisms blue coloration is achieved by combining a chromophore with a specific apoprotein, which organizes the chromophore and provides red-shift upon binding. For example, carotenoprotein crustacyanin, a well studied blue pigment from the lobster shell, contains orange carotenoid astaxanthin, which demonstrates a strong bathochromic shift due to noncovalent binding to a protein of lipocalin family (2).Several known types of protein-based animal pigments can be distinguished: carotenoproteins (including rhodopsins, where carotenoids feature an unusual covalent bond to apoprotein), heme-, flavin-, or metal-containing proteins, pterins, melanins, ommochromes (1), and members of the green fluorescent protein (GFP) 1 family (3). Each type is characterized by specific chromogenic groups and protein sequences.In the present work we studied the blue pigment of the scyfoid jellyfish Rhizostoma pulmo. We anticipated to find either a carotenoprotein (being the most widely spread pigment class (1)) or GFP-like chromoprotein (as many fluorescent and colored GFP-like proteins were found earlier in Cnidaria (3)). However, this work revealed a new class of pigments base...

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The molecular basis of the coloration mechanism in lobster shell: β-Crustacyanin at 3.2-Å resolution

Cited by 184 publications

References 32 publications

Vertebrate and invertebrate carotenoid-binding proteins

Vertebrate and invertebrate carotenoid-binding proteins

Water-soluble carotenoid proteins of cyanobacteria

New Class of Blue Animal Pigments Based on Frizzled and Kringle Protein Domains

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