User:Trivas47/Biotin carboxyl carrier protein

The biotin carboxyl carrier protein (BCCP) is a Acetyl CoA subunit that allows for Acetyl CoA to be catalyzed and converted to malonyl-CoA. More specifically, BCCP catalyzes the carboxylation of the carrier protein to form an intermediate. Then the carboxyl group is transferred by the transcacrboxylase to form the malonyl-CoA. This conversion is an essential step in the biosynthesis of fatty acids.

The biosynthesis of fatty acids in plants, such as triacylglycerol, is vital to the plant's overall health because it allows for accumulation of seed oil. The biosynthesis that is catalyzed by BCCP usually takes place in the chloroplast of plant cells. The biosynthesis performed by the BCCP protein allows for the transfer of CO2 within active sites of the cell.

The biotin carboxyl carrier protein carries approximately 1 mol of biotin per 22,000 g of protein.

There is not much research on BCCPs at the moment. However, a recent study on plant genomics found that Brassica BCCPs might play a key role in abiotic and biotic stress responses. Meaning that these proteins may be relaying messages to the rest of the plant body after it has been exposed to extreme conditions that disrupt the plant's homeostasis. \\

Structure

The first report of the BCCP structure was made by biochemists F. K. Athappilly and W. A. Hendrickson in 1995. It can be thought of as a long β-hairpin structure, with four pairs of antiparallel β-strands that wrap around a central hydrophobic core. The biotinylation motif Met-Lys-Met is located at the tip of the β-hairpin structure. Rotations around the CαCβ bond of this Lys residue contribute to the swinging-arm model. The connection to the rest of the enzyme at the N-terminus of BCCP core is located at the opposite end of the structure from the biotin moiety. Rotations around this region contribute to the swinging-domain model, and the N1′ atom of biotin is ~ 40 Å from this pivot point. This gives a range of ~ 80 Å for the swinging-domain model, and the BC–CT active site distances observed so far are between 40 and 80 Å. In addition, the linker before the BCCP core in the holoenzyme could also be flexible, which would give further reach for the biotin N1′ atom.

The structures of biotin-accepting domains from E. coli BCCP-87 and the 1.3S subunit of P. shermanii TC were determined by both X-ray crystallography and nuclear magnetic resonance studies. (Athappilly and Hendrickson, 1995; Roberts et al., 1999; Reddy et al., 1998). These produced essentially the same structures that are structurally related to the lipoyl domains of 2-oxo acid dehydrogenase multienzyme complexes (Brocklehurst and Perham, 1993; Dardel et al., 1993), which similarly undergo an analogous post-translational modification. These domains form a flattened β-barrel structure comprising two four-stranded β-sheets with the N- and C-terminal residues close together at one end of the structure. At the other end of the molecule, the biotinyl- or lipoyl-accepting lysine resides on a highly exposed, tight hairpin loop between β4 and β5 strands. The structure of the domain is stabilized by a core of hydrophobic residues, which are important structural determinants. Conserved glycine residues occupy β-turns linking the β-strands.