Removal of N-terminal blocking groups from proteins.

Two enzymatic methods commonly used in N-terminal sequence analysis of blocked proteins are presented: one uses pyroglutamate aminopeptidase for N(α)-pyrrolidone carboxyl-proteins in solution or blotted onto a membrane, and the other uses acylaminoacyl-peptide hydrolase for N(α)-acyl-proteins blocked with other acyl groups. A Support Protocol describes a colorimetric assay for pyroglutamate aminopeptidase activity. Sequencing with acylaminoacyl-peptide hydrolase must include fragmentation of the protein before unblocking, so procedures are provided for chemically blocking newly generated peptides with either succinic anhydride or phenylisothiocyanate/performic acid. The hydrolase is then applied to the total mixture of peptides, only one of which, the acylated N-terminal peptide, should be a substrate for hydrolase. After incubation, the mixture of peptides is subjected to sequence analysis.

Role of intramolecular disulfides in stability and structure of a noncovalent homodimer.

The importance of intramolecular disulfides in a noncovalent dimeric protein interleukin-8 (IL-8) has been studied by replacing cysteines in each of the two disulfide pairs with alpha-aminobutyric acid (CH(2)-SH --> CH(2)-CH(3)). Both disulfide mutants are less stable and exist as molten globules in the monomeric state. Interestingly, both mutants dimerize, though with slightly lower affinities compared to the native protein. NMR studies suggest a molten globule-like structure also in the dimeric state. Structures, sequence analysis, and mutagenesis studies have shown that the conserved hydrophobic residues are packed against each other in the protein core and that H bonding and van der Waals interactions stabilize the dimer interface. Deleting either disulfide in IL-8 results in substantial loss in receptor activity, indicating that both disulfides are critical for function in the folded protein. These data together suggest that the packing interactions of the hydrophobic core determine IL-8 monomer fold, that disulfides play only a marginal role in dimer formation, and that the stability imparted by the disulfides is intimately coupled to fold and function.

Role of subunit interactions in P450 oligomers in the loss of homotropic cooperativity in the cytochrome P450 3A4 mutant L211F/D214E/F304W.

The contribution of conformational heterogeneity to cooperativity in cytochrome P450 3A4 was investigated using the mutant L211F/D214E/F304W. Initial spectral studies revealed a loss of cooperativity of the 1-pyrenebutanol (1-PB) induced spin shift (S(50)=5.4 microM, n=1.0) but retained cooperativity of alpha-naphthoflavone binding. Continuous variation (Job's titration) experiments showed the existence of two pools of enzyme with different 1-PB binding characteristics. Monitoring of 1-PB binding by fluorescence resonance energy transfer from the substrate to the heme confirmed that the high-affinity site (K(D)=0.3 microM) is retained in at least some fraction of the enzyme, although cooperativity is masked. Removal of apoprotein on a second column increased the high-spin content and restored cooperativity of 1-PB binding and of progesterone and testosterone 6beta-hydroxylation. The loss of cooperativity in the mutant is, therefore, mediated by the interaction of holo- and apo-P450 in mixed oligomers.

Conformational flexibility of mammalian cytochrome P450 2B4 in binding imidazole inhibitors with different ring chemistry and side chains. Solution thermodynamics and molecular modeling.

Recent x-ray structures of cytochrome P450 2B4 (CYP2B4) reveal an open form that undergoes a large-scale structural transition to a closed form upon binding to 4-(4-chlorophenyl)imidazole (4-CPI). Here, we report for the first time a complete solution thermodynamic study using isothermal titration calorimetry supported by spectroscopic studies to elucidate the conformational flexibility of CYP2B4 in binding imidazole inhibitors with different ring chemistry and side chains: 4-CPI, 1-benzylimidazole (1-BI), 1-CPI, 4-phenylimidazole (4-PI), 1-(2-(benzyloxy)ethyl)imidazole (BEI), and 1-PI. Each of the inhibitors induced type II spectral changes, and IC50 values for enzyme inhibition ranged from 0.1 to 2.4 microM, following the order 1-BI < 4-CPI < 1-CPI < 4-PI < BEI < 1-PI. Calorimetric titrations using monomeric enzyme yielded a 1:1 binding stoichiometry, with the associated KD values ranging from 0.3 to 4.8 microM and following the same rank order as the IC50 values. Changes in enthalpy at 25 degrees C ranged from -6.5 to -8.8 kcal mol(-1). The largest difference in binding entropy (+5.9 versus -4.1 cal mol(-1) K(-1)) was observed between 4-CPI and BEI, respectively, with a 2-fold difference in heat capacity changes (-604 versus -331 cal mol(-1) K(-1)), which is inferred to result from the reduction of apolar surface area of the enzyme ensuing from a conformational change upon 4-CPI binding. Accessibility to acrylamide of the only tryptophan (Trp121), which is located in helix C, was greatly decreased only in protein bound to 4-CPI. Steric restrictions hindered the perfect docking of only BEI to the closed conformation of the enzyme. The thermodynamic signature obtained for structurally similar inhibitors suggests remarkable plasticity of CYP2B4.

An open conformation of mammalian cytochrome P450 2B4 at 1.6-A resolution.

The xenobiotic metabolizing cytochromes P450 (P450s) are among the most versatile biological catalysts known, but knowledge of the structural basis for their broad substrate specificity has been limited. P450 2B4 has been frequently used as an experimental model for biochemical and biophysical studies of these membrane proteins. A 1.6-A crystal structure of P450 2B4 reveals a large open cleft that extends from the protein surface directly to the heme iron between the alpha-helical and beta-sheet domains without perturbing the overall P450 fold. This cleft is primarily formed by helices B' to C and F to G. The conformation of these regions is dramatically different from that of the other structurally defined mammalian P450, 2C5/3LVdH, in which the F to G and B' to C regions encapsulate one side of the active site to produce a closed form of the enzyme. The open conformation of 2B4 is trapped by reversible formation of a homodimer in which the residues between helices F and G of one molecule partially fill the open cleft of a symmetry-related molecule, and an intermolecular coordinate bond occurs between H226 and the heme iron. This dimer is observed both in solution and in the crystal. Differences between the structures of 2C5 and 2B4 suggest that defined regions of xenobiotic metabolizing P450s may adopt a substantial range of energetically accessible conformations without perturbing the overall fold. This conformational flexibility is likely to facilitate substrate access, metabolic versatility, and product egress.

Ability of E. coli cyclic AMP receptor protein to differentiate cyclic nucelotides: effects of single site mutations.

Escherichia coli cyclic AMP receptor protein (CRP) is a global transcriptional regulator which controls the expression of many different genes. Although different cyclic nucleotides can bind to CRP with almost equal affinity, only in the presence of cAMP could wild-type CRP bind to specific DNA sequences. Molecular genetic studies have identified a class of mutants, CRP*, which either do not require exogenous cAMP for activation or can be activated by cGMP. Thus, these mutants might aid in identifying the structural elements that are involved in the modulation of CRP to correctly differentiate the messages embedded in cyclic nucleotides. In this in vitro study, five CRP* mutants, namely, D53H, S62F, G141Q, G141K, and L148R, were tested for their abilities to bind the lac promoter sequence and the effects of cyclic nucleotides in modulating DNA sequence recognition. For comparison, non-CRP* mutants K52N, T127L, H159L, and K52N/H159L were studied. cCMP and cGMP can replace cAMP as an allosteric effector in all of these CRP mutants except S62F and non-CRP* mutants. The D53H, G141Q, G141K, and L148R mutants exhibit significantly higher affinity for the lac promoter sequence than wild-type CRP while S62F and the non-CRP* mutants exhibit reduced affinity. To probe the pathway of communication, the energetics of subunit assembly in these mutants were monitored by sedimentation equilibrium, and the conformational states of these mutants were probed by proteolysis and accessibility of Cys178 to chemical modifications. Results from these studies imply that signals due to mutations are mostly transmitted through the subunit interface. Thus, residues in CRP outside of the cyclic nucleotide binding site modulate the ability of CRP to differentiate these three cyclic nucleotides through long-range communication. Furthermore, this study shows that CRP* mutations do not impart any unique properties to CRP except that the DNA binding constants are shifted to a regime of higher affinity.