Identification of the Dimerization Domain of Dehalogenase IVa of Burkholderia cepacia MBA4

Haloacid dehalogenases are enzymes that catalyze the hydrolytic removal of halogens from haloalkanoic acids. Dehalogenase IVa (DehIVa) from Burkholderia cepacia MBA4 and dehalogenase CI (DehCI) from Pseudomonas sp. strain CBS3 exhibit 68% identity. Despite their similarity DehIVa is a dimeric enzyme while DehCI is a monomer. In this work, we describe the identification of the domain that confers the dimerization function of DehIVa. Recombinant DNA molecules were constructed by fusion of the respective dehalogenase genes hdlIVa and dehCI. When amino acids 73 to 89 of DehCI were replaced by amino acids 74 to 90 of DehIVa, the recombinant molecule migrated like that of DehIVa in a nondenaturing activity-stained gel. Similarly, when residues 73 to 89 of DehIVa were replaced by the corresponding residues of DehCI, the chimera migrated as a monomer. These 17 amino acid changes were able to determine the aggregation states of the molecules. The retention of the catalytic function in these chimeras indicated that the overall folding of these proteins was not affected. Site-directed mutagenesis on hdlIVa however indicated that amino acids Phe58, Thr65, Leu78, and Phe92 of DehIVa are also important for the aggregation state of the protein. This indicates that the 17 residues are not sufficient for the dimerization of the protein.     

Tyr26 and Phe73 are essential for full biological activity of the Fd Gene 5 protein

Abstract Using site-saturation mutagenesis, we have established all possible amino acid substitutions at Tyr26 and Phe73 that are compatible with biological activity of the gene 5 protein in vivo. No substitutions were found at either site that gave rise to a fully functional gene 5 protein, indicating that these two amino acid residues are crucial. However, partial activity was found if either residue was replaced by another aromatic amino acid (Y26F, Y26W, F73Y, F73W). The results suggest that both Tyr26 and Phe73 are important for base stacking in the nucleoprotein complex. The functional consequences of the removal of the hydroxyl group from Tyr26 argue that this residue may, in addition, be involved in hydrogen bond formation to confer greater stability on the complex. In contrast, the addition of such a group to Phe73 reduces activity.     

Surface-exposed phenylalanines in the RNP1/RNP2 motif stabilize the cold-shock protein CspB from Bacillus subtilis

In the cold-shock protein CspB from Bacillus subtilis three exposed Phe residues (F15, F17, and F27) are essential for its function in binding to single-stranded nucleic acids. Usually, the hydrophobic Phe side chains are buried in folded proteins. We asked here whether the exposition of the essential Phe residues could be a cause for the very low conformational stability of CspB. Urea-induced and heat-induced equilibrium unfolding transitions were measured for three mutants of CspB, where Phe 15, Phe 17, and Phe 27 were individually replaced by alanine. Unexpectedly, all three mutations strongly destabilized CspB. The aromatic side chains of Phe 15, Phe 17, and Phe 27 in the active site are thus important for both binding to nucleic acids and conformational stability. There is no compromise between function and stability in the active site. Model calculations indicate that, although they are partially exposed to solvent, all three Phe residues nevertheless lose accessible surface upon folding, and this should favor the native state. A different result is obtained with the F38A variant. Phe 38 is hyperexposed in native CspB, and its substitution by Ala is in fact stabilizing. Proteins 30:401–406, 1998. © 1998 Wiley-Liss, Inc.     

Mariner Mos1 transposase dimerizes prior to ITR binding

The mariner Mos1 synaptic complex consists of a tetramer of transposase molecules that bring together the two ends of the element. Such an assembly requires at least two kinds of protein-protein interfaces. The first is involved in "cis" dimerization, and consists of transposase molecules bound side-by-side on a single DNA molecule. The second, which is involved in "trans" dimerization, consists of transposase molecules bound to two different DNA molecules. Here, we used biochemical and genetic methods to enhance the definition of the regions involved in cis and trans-dimerization in the mariner Mos1 transposase. The cis and trans-dimerization interfaces were both found within the first 143 amino acid residues of the protein. The cis-dimerization activity was mainly contained in amino acids 1-20. The region spanning from amino acid residues 116-143, and containing the WVPHEL motif, was involved in the cis- to trans-shift as well as in trans-dimerization stabilization. Although the transposase exists mainly as a monomer in solution, we provide evidence that the transposase cis-dimer is the active species in inverted terminal repeat (ITR) binding. We also observed that the catalytic domain of the mariner Mos1 transposase modulates efficient transposase-transposase interactions in the absence of the transposon ends.     

Identification of amino acids essential for estrone-3-sulfate transport within transmembrane domain 2 of organic anion transporting polypeptide 1B1

As an important structure in membrane proteins, transmembrane domains have been found to be crucial for properly targeting the protein to cell membrane as well as carrying out transport functions in transporters. Computer analysis of OATP sequences revealed transmembrane domain 2 (TM2) is among those transmembrane domains that have high amino acid identities within different family members. In the present study, we identify four amino acids (Asp70, Phe73, Glu74, and Gly76) that are essential for the transport function of OATP1B1, an OATP member that is specifically expressed in the human liver. A substitution of these four amino acids with alanine resulted in significantly reduced transport activity. Further mutagenesis showed the charged property of Asp70 and Glu74 is critical for proper function of the transporter protein. Comparison of the kinetic parameters indicated that Asp70 is likely to interact with the substrate while Glu74 may be involved in stabilizing the binding site through formation of a salt-bridge. The aromatic ring structure of Phe73 seems to play an important role because substitution of Phe73 with tyrosine, another amino acid with a similar structure, led to partially restored transport function. On the other hand, replacement of Gly76 with either alanine or valine could not recover the function of the transporter. Considering the nature of a transmembrane helix, we proposed that Gly76 may be important for maintaining the proper structure of the protein. Interestingly, when subjected to transport function analysis of higher concentration of esteone-3-sulfate (50 μM) that corresponds to the low affinity binding site of OATP1B1, mutants of Phe73, Glu74, and Gly76 all showed a transport function that is comparable to that of the wild-type, suggesting these amino acids may have less impact on the low affinity component of esteone-3-sulfate within OATP1B1, while Asp 70 seems to be involved in the interaction of both sites.     

Putative interhelical interactions within the PheP protein revealed by second-site suppressor analysis

Highly conserved glycine residues within span I and span II of the phenylalanine and tyrosine transporter PheP were shown to be important for the function of the wild-type protein. Replacement by amino acids with increasing side chain volume led to progressive loss of transport activity. Second-site suppression studies performed with a number of the primary mutants revealed a tight packing arrangement between spans I and II that is important for function and an additional interaction between spans I and III. We also postulate that a third motif, GXXIG, present in span I and highly conserved within different members of the amino acid-polyamine-organocation family, may function as a dimerization motif. Surprisingly, other highly conserved residues, such as Y60 and L41, could be replaced by various residues with no apparent loss of activity.     

Structural requirements for catalysis and dimerization of human methionine adenosyltransferase I/III

We have used site-directed mutagenesis to probe the structural requirements for catalysis and dimerization of human hepatic methionine adenosyltransferase (hMAT). We built a homology model of the dimeric hMAT III inferred by the crystal structure of the highly homologous Escherichia coli MAT dimer. The active sites of both enzymes comprise the same amino acids and are located in the inter-subunit interface. All of the amino acids predicted to be in the hMAT III active site were mutated, as well as residues in a conserved ATP binding region. All of the mutations except one severely affected catalytic activity. On the other hand, dimerization was affected only by single mutations of three different residues, all on one monomer. The homology model suggested that the side chains of these residues stabilized the monomer and participated in a bridge between subunits consisting of a network of metal and phosphate ions. In agreement with this observation, we demonstrated that dimerization cannot occur in the absence of phosphate.     

Role of interactions involving C-terminal nonpolar residues of hirudin in the formation of the thrombin-hirudin complex

The role of interactions involving C-terminal nonpolar residues of hirudin in the formation of the thrombin-hirudin complex has been investigated by site-directed mutagenesis. The residues Phe56, Pro60, and Tyr63 of hirudin were replaced by a number of different amino acids, and the kinetics of the inhibition of thrombin by the mutant proteins were determined. Phe56 could be replaced by aromatic amino acids without significant loss in binding energy. While substitution of Phe56 by alanine decreased the binding energy (delta G degrees b by only 1.9 kJ mol-1, replacement of this residue by amino acids with branched side chains caused larger decreases in delta G degrees b. For example, the mutant Phe56----Val displayed a decrease in delta G degrees b of 10.5 kJ mol-1. Substitution of Pro60 by alanine or glycine resulted in a decrease in delta G degrees b of about 6 kJ mol-1. Tyr63 could be replaced by phenylalanine without any loss in binding energy, and replacement of this residue by alanine caused a decrease of 2.2 kJ mol-1 in delta G degrees b. Substitution of Tyr63 by residues with branched side chains resulted in smaller decreases in delta G degrees b than those seen with the corresponding substitutions of Phe56; for example, the mutant Tyr63----Val showed a decrease in binding energy of 5.1 kJ mol-1. The effects of the mutations are discussed in terms of the crystal structure of the thrombin-hirudin complex.     

Proton magnetic resonance and binding studies of proteolytically modified neurophysins

The proton NMR spectra and role in peptide binding of carboxyl-terminal and NH2-terminal neurophysin residues were studied by preparation of bovine neurophysin-I derivatives from which residues 90-92 had been cleaved by carboxypeptidase or residues 1-8 excised by trypsin. The carboxypeptidase-treated protein showed normal peptide-binding behavior. NMR comparisons of this derivative and the native protein allowed identification of proton resonances associated with residues 89-92, confirmed a lack of functional role for this region of the protein, and permitted new observations on the behavior of neurophysin's aromatic residues. The trypsin-treated protein bound peptide with an affinity only 1/50 that of the native protein at pH 6 but evinced the same binding specificity and pH dependence of binding as the native protein. These results argued against direct interaction of residues in the 1-8 sequence with bound peptide and for a role for these residues, particularly Arg-8, in conformational stabilization of the active site; this role is held to be additional to the reported influence of 1-8 on dimerization. NMR comparisons of the trypsin product and native protein allowed preliminary assignment of a set of alkyl proton resonances to residues within the 1-8 sequence and were compatible with a restricted environment for Arg-8. Conformational differences between native and trypsin-treated proteins were manifest particularly by differences in the NMR spectra of Phe and Tyr-49 ring protons. The behavior of Phe ring protons was consistent with the reported decreased dimerization constant of the trypsin product and suggested participation of Phe-22 or -35 in dimerization. The behavior of Tyr-49 provided the first direct evidence of a change in secondary or tertiary structure associated with excision of residues 1-8. Suggested mechanisms by which this conformational change reduces binding include a direct effect on Tyr-49 and/or a conformational rearrangement of active site residues near Tyr-49.     

A disulfide bridge mediated by cysteine 574 is formed in the dimer of the 70-kDa heat shock protein

The 70-kDa heat shock protein (Hsp70) is predominantly present intracellularly as a monomer, but a small population is converted to dimers and oligomers under certain conditions. In the present study, we investigated the dimeric structure of human inducible Hsp70. As reported earlier, the C-terminal client-binding domain (amino acids 382-641) was required for the dimerization. A 40-amino acid deletion in the client-binding domain from either the N-terminus or C-terminus greatly enhanced the dimerization potential of Hsp70. Limited proteolysis indicated that the dimer formed through truncation from the C-terminus had a conformation similar to that of the non-truncated form. Truncation experiments demonstrated that the client-binding sub-domain (amino acids 382-520) with its adjacent region up to amino acid 541 was not sufficient for the dimerization but that the region up to amino acid 561 was sufficient. Interestingly, the dimer formed through truncation from the C-terminus acquired a homomeric disulfide bridge at Cys574.     

Solution structure of the mature HIV-1 protease monomer: insight into the tertiary fold and stability of a precursor

We present the first solution structure of the HIV-1 protease monomer spanning the region Phe1-Ala95 (PR1-95). Except for the terminal regions (residues 1-10 and 91-95) that are disordered, the tertiary fold of the remainder of the protease is essentially identical to that of the individual subunit of the dimer. In the monomer, the side chains of buried residues stabilizing the active site interface in the dimer, such as Asp25, Asp29, and Arg87, are now exposed to solvent. The flap dynamics in the monomer are similar to that of the free protease dimer. We also show that the protease domain of an optimized precursor flanked by 56 amino acids of the N-terminal transframe region is predominantly monomeric, exhibiting a tertiary fold that is quite similar to that of PR1-95 structure. This explains the very low catalytic activity observed for the protease prior to its maturation at its N terminus as compared with the mature protease, which is an active stable dimer under identical conditions. Adding as few as 2 amino acids to the N terminus of the mature protease significantly increases its dissociation into monomers. Knowledge of the protease monomer structure and critical features of its dimerization may aid in the screening and design of compounds that target the protease prior to its maturation from the Gag-Pol precursor.     

Protein Evolution via Amino Acid and Codon Elimination

Background

Global residue-specific amino acid mutagenesis can provide important biological insight and generate proteins with altered properties, but at the risk of protein misfolding. Further, targeted libraries are usually restricted to a handful of amino acids because there is an exponential correlation between the number of residues randomized and the size of the resulting ensemble. Using GFP as the model protein, we present a strategy, termed protein evolution via amino acid and codon elimination, through which simplified, native-like polypeptides encoded by a reduced genetic code were obtained via screening of reduced-size ensembles.

Methodology/Principal Findings

The strategy involves combining a sequential mutagenesis scheme to reduce library size with structurally stabilizing mutations, chaperone complementation, and reduced temperature of gene expression. In six steps, we eliminated a common buried residue, Phe, from the green fluorescent protein (GFP), while retaining activity. A GFP variant containing 11 Phe residues was used as starting scaffold to generate 10 separate variants in which each Phe was replaced individually (in one construct two adjacent Phe residues were changed simultaneously), while retaining varying levels of activity. Combination of these substitutions to generate a Phe-free variant of GFP abolished fluorescence. Combinatorial re-introduction of five Phe residues, based on the activities of the respective single amino acid replacements, was sufficient to restore GFP activity. Successive rounds of mutagenesis generated active GFP variants containing, three, two, and zero Phe residues. These GFPs all displayed progenitor-like fluorescence spectra, temperature-sensitive folding, a reduced structural stability and, for the least stable variants, a reduced steady state abundance.

Conclusions/Significance

The results provide strategies for the design of novel GFP reporters. The described approach offers a means to enable engineering of active proteins that lack certain amino acids, a key step towards expanding the functional repertoire of uniquely labeled proteins in synthetic biology.     

Expression and site-specific mutagenesis of phospholamban. Studies of residues involved in phosphorylation and pentamer formation

Full-length cDNAs encoding either dog cardiac or rabbit skeletal muscle phospholamban were expressed transiently in COS-1 cells. The expressed protein displayed the mobility of a pentamer when dissolved in sodium dodecyl sulfate and separated in polyacrylamide gels, and of a monomer when boiled prior to polyacrylamide gel separation. Site-specific mutagenesis was used to analyze the roles of several amino acids in the structure and function of the protein. Ser16 and Thr17 were shown to be phosphorylated uniquely by cAMP- and calmodulin-dependent protein kinases, respectively, confirming earlier observations on the native protein (Simmerman, H. K. B., Collins, J. H., Theibert, J.L., Wegener, A.D., and Jones, L.R. (1986) J. Biol. Chem. 261, 13333-13341). Arg13 and Arg14 were shown to be essential for both types of phosphorylation, and Arg9 was shown to be essential for calmodulin-dependent phosphorylation. In studies of pentamer stability, mutation of Gln22-Gln23 to Ala-Ala or Glu-Glu, of Gln26-Asn27 to Glu-Asp, or of Gln29-Asn30 to Glu-Asp had no effect on thermal stability of the pentamer, suggesting that hydrogen bonding involving these residues in domain IB is not important for pentamer stability. By contrast, mutation of Cys36, Cys41, and Cys46 in transmembrane domain II to Ser, Ala, or Phe diminished the stability of the pentamer when microsomal proteins were dissociated in sodium dodecyl sulfate and separated by polyacrylamide gel electrophoresis. In particular, the Cys41 to Phe mutant existed as a monomer at ambient temperature. These results suggest that the intramembranous cysteine residues are important for pentamer formation even though they are not disulfide-bonded.     

Structural changes of human RNase L upon homodimerization investigated by Raman spectroscopy

RNase L, a key enzyme in the host defense system, is activated by the binding of 2'-5'-linked oligoadenylates (2-5A) to the N-terminal ankyrin repeat domain, which causes the inactive monomer to form a catalytically active homodimer. We focused on the structural changes of human RNase L as a result of interactions with four different activators: natural 2-5 pA(4) and three tetramers with 3'-end AMP units replaced with ribo-, arabino- and xylo-configured phosphonate analogs of AMP (pA(3)X). The extent of the RNase L dimerization and its cleavage activity upon binding of all these activators were similar. A drop-coating deposition Raman (DCDR) spectroscopy possessed uniform spectral changes upon binding of all of the tetramers, which verified the same binding mechanism. The estimated secondary structural composition of monomeric RNase L is 44% α-helix, 28% β-sheet, 17% β-turns and 11% of unordered structures, whereas dimerization causes a slight decrease in α-helix and increase in β-sheet (ca. 2%) content. The dimerization affects at least three Tyr, five Phe and two Trp residues. The α-β structural switch may fix domain positions in the hinge region (residues ca. 336-363) during homodimer formation.     

Molecular mechanism of the inhibition of cytochrome c aggregation by Phe-Gly

Experimental and computational studies suggest that few general principles govern protein/protein interactions and aggregation. The knowledge of these rules may be exploited to design peptides that are able to interfere with the self-assembly and aggregation of proteins. This work is aimed to verify the validity of this hypothesis by investigating the interaction of cytochrome c with Phe and Gly amino acids, Ala-His (carnosine), and two water-soluble dipeptides Phe-Gly and Gly-Phe. The combined use of (1)H NMR, MD, and DSC has shown that: (i) at neutral pH, only Phe-Gly is able to prevent the thermally induced aggregation of cytochrome c; (ii) Phe-Gly interacts with Gly45 and Phe46 residues of the protein, either when the protein is in the folded or in the unfolded state; and (iii) the interaction of Phe-Gly with cytochrome c is sequence-dependent. These results support the hypothesis that the basic principles that describe protein aggregation can be used for the design of peptides with antiaggregating properties.     

Identification of the key residues responsible for the assembly of selenodeiodinases

Type I deiodinase is the best characterized member of a small family of selenoenzymes catalyzing the bioactivation and disposal of thyroid hormone. This enzyme is an integral membrane protein composed of two 27-kDa subunits that assemble into a functional enzyme after translation using a highly conserved sequence of 16 amino acids in the C-terminal half of the polypeptide, (148)DFLXXYIXEAHXXDGW(163). In this study, we used alanine scanning mutagenesis to identify the key residues in this domain required for holoenzyme assembly. Overexpression of sequential alanine-substituted mutants of a dimerization domain-green fluorescent protein fusion showed that sequence (152)IYI(154) was required for type I enzyme assembly and that a catalytically active monomer was generated by a single I152A substitution. Overexpression of the sequential alanine-substituted dimerization domain mutants in type II selenodeiodinase-expressing cells showed that five residues ((153)FLIVY(157)) at the beginning and three residues ((164)SDG(166)) at the end of this region were required for the assembly of the type II enzyme. In vitro binding analysis revealed a free energy of association of -60 +/- 5 kJ/mol for the noncovalent interaction between dimerization domain monomers. These data identify and characterize the essential residues in the dimerization domain that are responsible for the post-translational assembly of selenodeiodinases.     

Gene encoding a hybrid OmpF-PhoE pore protein in the outer membrane of Escherichia coli K12

Summary To study the structure-function relationship of outer membrane pore proteins of E. coli K12, a hybrid gene was constructed in which the DNA encoding amino acid residues 2–73 of the mature PhoE protein is replaced by the homologous part of the related ompF gene. The product of this gene is incorporated normally into the outer membrane. It was characterized with respect to its pore activity and its phage receptor and colicin receptor properties. It is concluded (i) that the preference of the PhoE protein pore for negatively charged solutes is partly determined by the amino terminal 73 amino acids, (ii) that part of the receptor site of PhoE protein for phage TC45 is located in this part of the protein, (iii) that colicin N uses OmpF protein as (part of) its receptor, (iv) that the specificity of OmpF protein as a colicin N receptor is completely located within the 80 amino terminal amino acid residues, whereas the specificity of this protein as a colicin A receptor is completely located within the 260 carboxy terminal amino acid residues, and (v) that the amino terminal 73 amino acid residues of PhoE protein span the membrane at least once.     

Helical integrity and microsolvation of transmembrane domains from Flaviviridae envelope glycoproteins

Charged and polar amino acids in the transmembrane domains of integral membrane proteins can be crucial for protein function and also promote helix-helix association or protein oligomerization. Yet, our current understanding is still limited on how these hydrophilic amino acids are efficiently translocated from the Sec61/SecY translocon into the cell membrane during the biogenesis of membrane proteins. In hepatitis C virus, the putative transmembrane segments of envelope glycoproteins E1 and E2 were suggested to heterodimerize via a Lys-Asp ion-pair in the host endoplasmic reticulum. Therefore in this work, we carried out molecular dynamic simulations in explicit lipid bilayer and solvent environment to explore the stability of all possible bridging ion-pairs using the model of H-segment helix dimers. We observed that, frequently, several water molecules penetrated from the interface into the membrane core to stabilize the charged and polar pairs. The hydration time and amount of water molecules in the membrane core depended on the position of the charged residues as well as on the type of ion-pairs. Similar microsolvation events were observed in simulations of the putative E1-E2 transmembrane helix dimers. Simulations of helix monomers from other members of the Flaviviridae family suggest that these systems show similar behaviors. Thus this study illustrates the important contribution of water microsolvation to overcome the unfavorable energetic cost of burying charged and polar amino acids in membrane lipid bilayers. Also, it emphasizes the novel role of bridging charged or polar interactions stabilized by water molecules in the hydrophobic lipid bilayer core that has an important biological function for helix dimerization in several envelope glycoproteins from the family of Flaviviridae viruses.