X-gal is an
analog of
lactose, and therefore may be hydrolyzed by the
β-galactosidase enzyme which cleaves the β-
glycosidic bond in -lactose. X-gal, when cleaved by β-galactosidase, yields galactose and 5-bromo-4-chloro-3-hydroxyindole -
1. The latter then spontaneously dimerizes and is oxidized into 5,5'-dibromo-4,4'-dichloro-
indigo -
2, an intensely blue product which is insoluble. X-gal itself is colorless, so the presence of blue-colored product may therefore be used as a test for the presence of active β-galactosidase. This also allows for bacterial β-galactosidase (so called
lacZ ) to be used as a
reporter in various applications. Similarly, Xαgal is used as a reporter compound for
α-galactosidase (e.g. Mel1 in yeast).
Reaction Cloning In
gene cloning, X-gal is used as a visual indication of whether a cell expresses a functional
β-galactosidase enzyme in a technique called
blue/white screening. This method of screening is a convenient way of distinguishing a successful cloning product from other unsuccessful ones. The blue/white screening method relies on the principle of α-complementation of the β-galactosidase gene, where a fragment of the
lacZ gene (lacZα) in the plasmid can complement another mutant
lacZ gene (lacZΔM15) in the cell. Both genes by themselves produce non-functional peptides, however, when expressed together, as when a plasmid containing
lacZα is transformed into a
lacZΔM15 cells, they form a functional β-galactosidase. The presence of an active β-galactosidase may be detected when cells are grown in plates containing X-gal, the blue-colored product precipitated within cells resulted in the characteristic blue colonies. However, the multiple cloning site, where a gene of interest may be ligated into the plasmid vector, is located within the
lacZα gene. Successful ligation therefore disrupts the
lacZα gene, α-complementation is therefore also disrupted and no functional β-galactosidase can form, resulting in white colonies. Cells containing successfully ligated insert can then be easily identified by its white coloration from the unsuccessful blue ones. Example of cloning vectors used for this test are
pUC19,
pBluescript, pGem-T Vectors, and it also requires the use of specific
E. coli host strains such as DH5α which carries the mutant
lacZΔM15 gene. Often, the plate containing X-Gal also contains IPTG (isopropyl β--1-thiogalactopyranoside). IPTG is a chemical structure analogue of lactose. However, IPTG cannot be hydrolyzed by β-galactosidase. IPTG is used as an inducer that binds to lac repressor releasing the DNA and allowing transcription. The presence of IPTG in the agar plate therefore increases the synthesis of β-galactosidase.
Variants X-gal has a number of variants, which are similar molecules with slight differences serving mainly to produce colors other than blue as a signal.
Protein-protein interactions In
two-hybrid analysis, β-galactosidase may be used as a reporter to identify proteins that interact with each other. In this method, genome libraries may be screened for protein interaction using yeast or bacterial system. Where there is a successful interaction between proteins being screened, it will result to the binding of an activation domain to a promoter. If the promoter is linked to a
lacZ gene, the production of β-galactosidase, which results in the formation of blue-pigmented colonies in the presence of X-gal, will therefore indicate a successful interaction between proteins. This technique may be limited to screening libraries of size of less than around 106. The successful cleavage of X-gal also creates a noticeably foul odor due to the volatilization of
indole. ==See also==