Curculin

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Curculin

A curculin homodimer. From PDB 2DPF.
Identifiers
Symbol CURC_CURLA
PDB 2PDF (RCSB PDB PDBe PDBj) More Structures
UniProt P19667

Curculin is a sweet protein that was discovered and isolated in 1990 from the fruit of Curculigo latifolia (Hypoxidaceae),[1] a plant from Malaysia. Like miraculin, curculin exhibits taste-modifying activity; however, unlike miraculin, it also exhibits a sweet taste by itself. After consumption of curculin, water and sour solutions taste sweet. The plant is referred to locally as 'Lumbah'.

Protein structure

The active form of curculin is a heterodimer consisting of two monomeric units connected through two disulfide bridges. The mature monomers each consist of a sequence of 114 amino acids, weighing 12.5 kDa (curculin 1) and 12.7 kDa (curculin 2), respectively. While each of the two isoforms is capable of forming a homodimer, these do not possess the sweet taste nor the taste-modifying activity of the heterodimeric form. [2] To avoid confusion, the heterodimeric form is sometimes referred to as "neoculin".

SIGNAL (22): MAAKFLLTIL VTFAAVASLG MA
       1-50: DNVLLSGQTL HADHSLQAGA YTLTIQNKCN LVKYQNGRQI WASNTDRRGS
     51-100: GCRLTLLSDG NLVIYDHNNN DVWGSACWGD NGKYALVLQK DGRFVIYGPV
    101-114: LWSLGPNGCR RVNG
PROPEP (22): GITVAKDSTE PQHEDIKMVI NN

Amino acid sequence of sweet protein curculin adapted from Swiss-Prot biological database of protein sequences.[3]

Sweetness properties

Curculin is considered to be a high-intensity sweetener, with a reported relative sweetness of 430-2070 times sweeter than sucrose on a weight basis.[1][4][5]

A sweet taste, equivalent to a 6.8% or 12% sucrose solution, was observed after holding curculin in the mouth in combination with clear water or acidified water (citric acid), respectively. The sweet taste lasts for 5 minutes with water and 10 minutes with an acidic solution.[1]
Sweetness was also observed with other acids such as ascorbic acid (vitamin C)[6] and acetic acid.

The taste-modifying activity of curculin is reduced in the presence of ions with two positive charges (such as Ca2+ and Mg2+) in neutral pH solutions, although these ions have no effect in acidic solutions. In the same way, monovalent ions (such as Na+ and Cl) have no effect in solutions with either neutral or acidic pH.[1][5]

Although the "sweet-inducing" mechanism is unknown, it is believed that one active site of curculin strongly binds to the taste receptor membranes while a second active site fits into the sweet receptor site. The latter site is thought to be responsible for the induction of sweetness. Presence of Ca2+ and/or Mg2+, water and acids tune the binding of the active site of curculin to the receptor site and therefore modify perceived sweetness.[5]

As a sweetener

Like most proteins, curculin is susceptible to heat. At a temperature of 50 °C (122 °F) the protein starts to degrade and lose its "sweet-tasting" and "taste-modifying" properties, so it is not a good candidate for use in hot or processed foods. However, below this temperature both properties of curculin are unaffected in basic and acidic solutions,[5] so it has potential for use in fresh foods and as a table-top sweetener.

Because curculin is not widely found in nature, efforts are underway to produce a recombinant form of the protein. In 1997, curculin was expressed in E. coli and yeast, but the recombinant protein did not exhibit "sweet-tasting" or "taste-modifying" activity.[7] However, a 2004 study obtained a recombinant curculin, expressed in E. coli, exhibiting "taste-modifying" and "sweet-tasting" properties. [2]

In addition to challenges related to commercial production of the protein, there are many regulatory and legal issues remaining to be resolved before it can be marketed as a sweetener. Curculin currently has no legal status in European Union and United States. However it is approved in Japan as a harmless additive, according to the List of Existing Food Additives established by the Ministry of Health and Welfare (English publication by JETRO).

See also

References

  1. 1.0 1.1 1.2 1.3 Yamashita H, Theerasilp S, Aiuchi T, Nakaya K, Nakamura Y, Kurihara Y (September 1990). "Purification and complete amino acid sequence of a new type of sweet protein taste-modifying activity, curculin". J. Biol. Chem. 265 (26): 15770–5. PMID 2394746. 
  2. 2.0 2.1 Suzuki, M; Kurimoto, E; Nirasawa, S; Masuda, Y; Hori, K; Kurihara, Y; Shimba, N; Kawai, M; Suzuki, E; Kato, K (August 2004). "Recombinant curculin heterodimer exhibits taste-modifying and sweet-tasting activities". FEBS Letters 573 (1–3): 135–8. doi:10.1016/j.febslet.2004.07.073. PMID 15327988. 
  3. UniProtKB/Swiss-Prot database entry #P19667
  4. Kurihara Y (1992). "Characteristics of antisweet substances, sweet proteins, and sweetness-inducing proteins". Crit Rev Food Sci Nutr 32 (3): 231–52. doi:10.1080/10408399209527598. PMID 1418601. 
  5. 5.0 5.1 5.2 5.3 Yamashita H, Akabane T, Kurihara Y (April 1995). "Activity and stability of a new sweet protein with taste-modifying action, curculin". Chem. Senses 20 (2): 239–43. doi:10.1093/chemse/20.2.239. PMID 7583017. 
  6. Y Kurihara, H Kohno, M Kato, K Ikeda and M Miyake. Protein curuculin and application of the same. US5242693 A. 1993.
  7. Kurihara, Y. and Nirasawa, S. Structures and activities of sweetness-inducing substances (miraculin, curculin, strogin) and the heat-stable sweet protein, mabinlin. Foods and Food Ingredients Journal of Japan 1997, 67-74.
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