Asymmetry in the Multiprotein Systems of Molecular Biology

Signaling in living systems needs to achieve high specificity, to be reversible, and to achieve high signal to noise. Signaling mediated by multiprotein systems has evolved that avoids the requirement for high-affinity binary complexes that would be difficult to reverse and which, in the overcrowded cell, would lead to excessive noise in the system. Symmetrical structures are only occasionally formed. When they are, it is principally to colocate components, for example, the tyrosyl kinases of growth factors, where dimers form. Symmetry is, however, often broken, presumably to create more sensitivity and specificity in the signaling system by assembling other components, into higher-order multiprotein systems. The binding of a single heparin to two 1:1 FGF:FGFR complexes is an example, as is the binding of a single ligase to the Xrcc4 dimer, perhaps so creating a further DNA-binding site.     

Characterization of the tetratricopeptide-containing domain of BUB1, BUBR1, and PP5 proves that domain amphiphilicity over amino acid sequence specificity governs protein adsorption and interfacial activity

The tetratricopeptide motif repeat (TPR) is an alpha-helix-turn-alpha-helix motif that typically mediates protein-protein and, in some cases, protein-lipid interactions. Because of its success, this motif has been preserved through evolution and can be identified in proteins of a wide range of functions in lower and higher organisms. The N-terminal region of BUB1, BUBR1, and protein phosphatase 5 (PP5) contains tandem arrangements of the TPR motif. BUB1 and BUBR1 are conserved multidomain protein kinases that play a key role in the mitotic checkpoint, the mechanism that ensures the synchrony of chromosome segregation. PP5 is an enzyme that targets a wide range of protein substrates including single transmembrane receptors and mammalian cryptochromes. The N-terminal TPR domain of PP5 regulates the activity of the C-terminal catalytic domain through direct interaction with protein and lipid molecules. We portray the biophysical and biochemical properties of the tandem arrangements of the TPR motif of BUB1, BUBR1, and PP5 using far-UV spectroscopy, solution X-ray scattering, null ellipsometry, surface rheology measurements, and Brewster angle microscopy (BAM) observations. We show that, despite the low amino acid sequence conservation and different function, the TPR motif repeats of the three proteins exhibit similar interfacial properties including adsorption kinetics, high surface activity, and the formation of stable, rigid films at the air/water interface. Our studies demonstrate that domain amphiphilicity is of higher importance than amino acid sequence specificity in the determination of protein adsorption and interfacial activity.     

Evidence for the role of the monB genes in polyether ring formation during monensin biosynthesis

Ionophoric polyethers are produced by the exquisitely stereoselective oxidative cyclization of a linear polyketide, probably via a triepoxide intermediate. We report here that deletion of either or both of the monBI and monBII genes from the monensin biosynthetic gene cluster gave strains that produced, in place of monensins A and B, a mixture of C-3-demethylmonensins and a number of minor components, including C-9-epi-monensin A. All the minor components were efficiently converted into monensins by subsequent acid treatment. These data strongly suggest that epoxide ring opening and concomitant polyether ring formation are catalyzed by the MonB enzymes, rather than by the enzyme MonCII as previously thought. Consistent with this, homology modeling shows that the structure of MonB-type enzymes closely resembles the recently determined structure of limonene-1,2-epoxide hydrolase from Rhodococcus erythropolis.