Functional and structural characterisation of RimL from Bacillus cereus, a new Nα-acetyltransferase of ribosomal proteins that was wrongly assigned as an aminoglycosyltransferase.

Enzymes of the GNAT (GCN5-relate N-acetyltransferases) superfamily are important regulators of cell growth and development. They are functionally diverse and share low amino acid sequence identity, making functional annotation difficult. In this study, we report the function and structure of a new ribosomal enzyme, Nα-acetyl transferase from Bacillus cereus (RimLBC), a protein that was previously wrongly annotated as an aminoglycosyltransferase. Firstly, extensive comparative amino acid sequence analyses suggested RimLBC belongs to a cluster of proteins mediating acetylation of the ribosomal protein L7/L12. To assess if this was the case, several well established substrates of aminoglycosyltransferases were screened. The results of these studies did not support an aminoglycoside acetylating function for RimLBC. To gain further insight into RimLBC biological role, a series of studies that included MALDI-TOF, isothermal titration calorimetry, NMR, X-ray protein crystallography, and site-directed mutagenesis confirmed RimLBC affinity for Acetyl-CoA and that the ribosomal protein L7/L12 is a substrate of RimLBC. Last, we advance a mechanistic model of RimLBC mode of recognition of its protein substrates. Taken together, our studies confirmed RimLBC as a new ribosomal Nα-acetyltransferase and provide structural and functional insights into substrate recognition by Nα-acetyltransferases and protein acetylation in bacteria.

The conserved N-terminal region of the mitotic checkpoint protein BUBR1: a putative TPR motif of high surface activity.

BUBR1, a key component of the mitotic spindle checkpoint, is a multidomain protein kinase that is activated in response to kinetochore tension. Although BUB1 and BUBR1 play an important role in cell division, very little is known about their structural characteristics. We show that the conserved N-terminal region of BUBR1, comprising residues 1-204, is a globular domain of high alpha-helical content ( approximately 60%), stable in the pH range 4-9 and probably organized as a tetratricopeptide motif repeat (TPR), most closely resembling residues 16-181 of protein phosphatase 5. Because the latter presents a continuous amphipathic groove and is regulated by binding certain fatty acids, we compared the properties of BUBR1(1-204) and TPR-PP5(16-181) at air/water interfaces and found that both proteins exhibited a similar surface activity and formed stable, rigid monolayers. The deletion of a region that probably comprises several alpha-helices of BUBR1 indicates that long-range interactions are essential for the stability of the N-terminal domain. The presence of the putative TPR motif strongly suggests that the N-terminal domain of BUBR1 is involved in direct protein-protein interactions and/or protein-lipid interactions.

Stability of the C-terminal peptide of CETP mediated through an (i, i + 4) array.

Based on circular dichroism (CD), we have found an essential (i, i + 4) alpha-helix stabilizing array in the C-terminus region for the cholesteryl ester transfer protein (CETP) between histidine 466 and aspartic acid 470. This region apparently corresponds to an amphipathic alpha-helix. The behavior of this peptide in solution in comparison with a mutant peptide (D470N) was also analyzed by dynamic light scattering (DLS). The results showed that alpha-helix stabilization is not due to peptide aggregation. The thermodynamic estimation of stability supports the idea that the phenomenon is carried out through an (i, i + 4) array. The representation of the C-terminal region as an amphipathic alpha-helical peptide shows that lipid-binding activity might be in part due to both the asymmetric polar/non-polar residue distribution and to the presence of an (i, i + 4) array important for helix stability.

CETP and exchangeable apoproteins: common features in lipid binding activity.

In order to define the active domain for lipid binding in CETP (cholesteryl ester transfer protein), our study discusses some fundamental physicochemical properties of this molecule such as hydrophobic moment, protein active surface and helix amphipathicity, in comparison to the properties reported for a series of apoproteins including apoAI, apoAII, apoCI, CII, CIII and apoE. Our study suggests that CETP corresponds to a protein with an active surface slightly lower than the one calculated for the exchangeable apoproteins AI, AII, CI, CII, CIII and E. Arrays type (i, i + 3) and (i, i + 4) were found in the region associated to lipid binding in these apoproteins. Seven such arrays located in the amphipathic alpha-helices of CETP are also suggested to contribute to the overall lipid binding activity as a consequence of alpha-helix stability. It is proposed that for lipid binding to occur in both types of molecules, the possibility of a conformational specificity given by a redundant stereochemical code can be actively operating.