Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:2.3.1.28 (chloramphenicol acetyltransferase)
 5,100 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The noncovalent association of transmembrane alpha-helices is a fundamental event in the folding of helical membrane proteins. In this work, a system (TOXCAT) is developed for the study of transmembrane helix-helix oligomerization in a natural membrane environment. This assay uses a chimeric construct composed of the N-terminal DNA binding domain of ToxR (a dimerization-dependent transcriptional activator) fused to a transmembrane domain (tm) of interest and a monomeric periplasmic anchor (the maltose binding protein). Association of the tms results in the ToxR-mediated activation of a reporter gene encoding chloramphenicol acetyltransferase (CAT). The level of CAT expression indicates the strength of tm association. The assay distinguishes between a known dimerizing tm and a mutant in which dimerization is disrupted. In addition, modulation of the chimera concentration shows that the dimerization exhibits concentration dependence in membranes. TOXCAT also is used to select oligomeric tms from a library of randomized sequences, demonstrating the potential of this system to reveal novel oligomerization motifs. The TOXCAT system has been used to investigate glycophorin A tm-mediated dimerization. Although the overall sensitivity of glycophorin A tm dimerization to mutagenesis is found to be similar in membranes and in detergent micelles, several significant differences exist. Mutations to polar residues, which are generally disruptive in SDS, exhibit sequence specificity in membranes, demonstrating both the limitations of detergent micelles and the wider range of application of the TOXCAT system.
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PMID:TOXCAT: a measure of transmembrane helix association in a biological membrane. 992 59

Homo- and hetero-oligomeric interactions between the transmembrane (TM) helices of integrin alpha and beta subunits may play an important role in integrin activation and clustering. As a first step to understanding these interactions, we used the TOXCAT assay to measure oligomerization of the wild-type alpha(IIb) TM helix and single-site TM domain mutants. TOXCAT measures the oligomerization of a chimeric protein containing a TM helix in the Escherichia coli inner membrane via the transcriptional activation of the gene for chloramphenicol acetyltransferase. We found the amount of chloramphenicol acetyltransferase induced by the wild-type alpha(IIb) TM helix was approximately half that induced by the strongly dimerizing TM helix of glycophorin A, confirming that the alpha(IIb) TM domain oligomerizes in biological membranes. Mutating each of the alpha(IIb) TM domain residues to either Ala, Leu, Ile, or Val revealed that a GXXXG motif mediates oligomerization. Further, we found that the residue preceding each glycine contributed to the oligomerization interface, as did the residue at position i + 4 after the second Gly of GXXXG. Thus, the sequence XXVGXXGGXXXLXX is critical for oligomerization of alpha(IIb) TM helix. These data were used to generate an atomic model of the alpha(IIb) homodimer, revealing a family of structures with right-handed crossing angles of 40 degrees to 60 degrees, consistent with a 4.0-residue periodicity, and with an interface rotated by 50 degrees relative to glycophorin A. Thus, although the alpha(IIb) TM helix makes use of the GXXXG framework, neighboring residues have evolved to engineer its dimerization interface, enabling it to subserve specific and specialized functions.
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PMID:Dimerization of the transmembrane domain of Integrin alphaIIb subunit in cell membranes. 1506 9

The cation-pi interaction is an electrostatic attraction between a positive charge and the conjugated pi electrons of an aromatic ring. These interactions are well documented in soluble proteins and can be both structurally and functionally important. Catalyzed by observations in our laboratory that an Ala- and Ile-rich two-helix transmembrane segment tended to form SDS-resistant dimers upon the incorporation of suitably located Trp residues, here we have constructed a library of related constructs to study systematically the impact of aromatic-aromatic and cation-pi interactions on tertiary structure formation within an Escherichia coli membrane. Using the TOXCAT oligomerization assay with the hydrophobic segment AIAIAIIAZAXAIIAIAIAI, where Z = A, W, Y, or F and X = A, H, R, or K in all possible combinations of cation and/or aromatic pairings, to assess the TM-TM dependent expression of the chloramphenicol acetyltransferase reporter gene, we find that cation-pi interactions, particularly between Lys and Trp, Tyr, or Phe, as well as weakly polar interactions between pairs of aromatic residues, significantly enhance the strength of oligomerization of these hydrophobic helices, in some instances forming oligomers four times stronger than the high-affinity glycophorin A dimer. The contribution of these forces to the tertiary structure formation in designed transmembrane segments suggests that similar forces may also be a significant factor in the folding and stability of native membrane proteins.
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PMID:Aromatic and cation-pi interactions enhance helix-helix association in a membrane environment. 1765 97