Brassicasterol

Brassicasterol
Ball-and-stick model of brassicasterol
Names
IUPAC name
24-methyl cholest-5,22-dien-3β-ol
Other names
brassicasterol
(3β,22E)-ergosta-5,22-dien-3-ol
24β-methylcholesta-5,22-dien-3 beta-ol
ergosta-5,22-dien-3β-ol
Identifiers
3D model (JSmol)
ChemSpider
ECHA InfoCard 100.006.807
UNII
Properties
C28H46O
Molar mass 398.68 g·mol−1
Appearance White solid
Melting point 150 to 151 °C (302 to 304 °F; 423 to 424 K)
Hazards
Flash point Non-flammable
Related compounds
Related Sterols
cholesterol
β-sitosterol
campesterol
stigmasterol
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
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Infobox references

Brassicasterol (24-methyl cholest-5,22-dien-3β-ol) is a 28-carbon sterol synthesised by several unicellular algae (phytoplankton) and some terrestrial plants, e.g., oilseed rape. This compound has frequently been used as a biomarker for the presence of (marine) algal matter in the environment.

Chemical properties

Solubility

Brassicasterol has a low water solubility and, as a consequence, a high octanol – water partition coefficient. This means that, in most environmental systems, brassicasterol will be associated with the solid phase.

Degradation

In anaerobic sediments and soils, brassicasterol is stable for many hundreds of years, enabling it to be used as an indicator of past algal production (see below).

Chemical analysis

Since the molecule has a hydroxyl (-OH) group, it is frequently bound to other lipids including glycerols; most analytical methods, therefore, utilise a strong alkali (KOH or NaOH) to saponify the ester linkages. Typical extraction solvents include 6% KOH in methanol. The free sterols are then separated from the polar lipids by partitioning into a less polar solvent (e.g, hexane). Prior to analysis, the hydroxyl group is frequently derivatised with BSTFA (bis-trimethyl silyl trifluoroacetamide) to replace the hydrogen with the less exchangeable trimethylsilyl (TMS) group. Instrumental analysis is frequently conducted on gas chromatograph (GC) with either a flame ionisation detector (FID) or mass spectrometer (MS). The mass spectrum for the TMS ether of brassicasterol can be seen in the figure.

Formation and occurrences

It can be found in Mirabilis jalapa.[1]

Algal sources

Brassicasterol is formed in plants from the isoprenoid squalene through campesterol as an intermediate. A list of the algae in which brassicasterol has been identified is shown below together with approximate composition.[2]

Sterol content of selected dinoflagellates (as percentage). Data from Volkman, 1986
Species A B C D E F G H others
Gonyaulax spp10000000000
Peridinium foliaceum10000000000
Peridinium foliaceum 80200000000
Gonyaulax diegensis390000002932
Pyrocystis lunula76602100015
Gonyaulax polygramma36109700047
Gymnodinium wilczeki263903510000
Glenodinium hallii85000042000
Noctiluca milaris01157306014
Gymnodinium simplex00005300047
Prorocentrum cordatum70005063025
A = cholesterol
B = campesterol
C = sitosterol
D = 22-dehydrocholesterol ((22E)-cholesta-5,22-dien-3β-ol)
E = brassicasterol
F = stigmasterol
G = 24-methylene cholesterol
H = fucosterol

Use as a tracer for marine algae

The principal source of brassicasterol in the environment is from marine algae. Its relatively high concentration and stability allows it to be used in the assessment of the origin of organic matter in samples, especially sediments.

Brassicasterol / cholesterol ratio

The concentration of brassicasterol in a core sample from Loch Striven, Scotland. Highest values may be seen in the top sections of the sediment, which decrease with depth. However, the cholesterol behaves in a similar manner, and the ratio brassicasterol/cholesterol is fairly uniform at all depths, indicating either a comparable degradation rate with no change in source or different degradation rates and a change in source.

Multivariate analysis

Multivariate statistical analyses such as principal component analysis of a range of lipid biomarkers (e.g., other sterols, fatty acids, and fatty alcohols) enable identification of compounds that have similar origins or behaviour. An example can be seen in the loadings plot for sediment samples from the Mawddach Estuary, Wales.


The location of brassicasterol in this figure (shown in red) indicates that the distribution of this compound is similar to that of the short-chain fatty acids and alcohols, which are known to be of marine origin. The terrestrially derived biomarkers such as β-sitosterol are on the opposite side of the figure and are mutually exclusive.

References

  1. Constituents of Mirabilis jalapa. Siddiqui S., Siddiqui B.S., Adil Q. and Begum S., Fitoterapia, 1990, Volume 61, No. 5, page 471 (abstract)
  2. Data from a review by Volkman, 1986
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