Amphotropic murine leukemia virus entry is determined by specific combinations of residues from receptor loops 2 and 4

Pit2 is the human receptor for amphotropic murine leukemia virus (A-MuLV); the related human protein Pit1 does not support A-MuLV entry. Interestingly, chimeric proteins in which either the N-terminal or the C-terminal part of Pit2 was replaced by the Pit1 sequence all retained A-MuLV receptor function. A possible interpretation of these observations is that Pit1 harbors sequences which can specify A-MuLV receptor function when presented in a protein context other than Pit1, e.g., in Pit1-Pit2 hybrids. We reasoned that such Pit1 sequences might be identified if presented in the Neurospora crassa protein Pho-4. This protein is distantly related to Pit1 and Pit2, predicted to have a similar membrane topology with five extracellular loops, and does not support A-MuLV entry. We show here that introduction of the Pit1-specific loop 2 sequence conferred A-MuLV receptor function upon Pho-4. Therefore, we conclude that (i) a functional A-MuLV receptor can be constructed by combining sequences from two proteins each lacking A-MuLV receptor function and that (ii) a Pit1 sequence can specify A-MuLV receptor function when presented in another protein context than that provided by Pit1 itself. Previous results indicated a role of loop 4 residues in A-MuLV entry, and the presence of a Pit2-specific loop 4 sequence was found here to confer A-MuLV receptor function upon Pho-4. Moreover, the introduction of a Pit1-specific loop 4 sequence, but not of a Pit2-specific loop 4 sequence, abolished the A-MuLV receptor function of a Pho-4 chimera harboring the Pit1-specific loop 2 sequence. Together, these data suggest that residues in both loop 2 and loop 4 play a role in A-MuLV receptor function. A-MuLV is, however, not dependent on the specific Pit2 loop 2 and Pit2 loop 4 sequences for entry; rather, the role played by loops 2 and 4 in A-MuLV entry can be fulfilled by several different combinations of loop 2 and loop 4 sequences. We predict that the residues in loops 2 and 4, identified in this study as specifying A-MuLV receptor function, are to be found among those not conserved among Pho-4, Pit1, and Pit2.     

Substrate recognition by a eukaryotic RNase III: the double-stranded RNA-binding domain of Rnt1p selectively binds RNA containing a 5'-AGNN-3' tetraloop

Rnt1p is an RNase III homolog from budding yeast, required for processing snRNAs, snoRNAs, and rRNA. Numerous Rnt1p RNA substrates share potential to form a duplex structure with a terminal four-base loop with the sequence AGNN. Using a synthetic RNA modeled after the 25S rRNA 3' ETS cleavage site we find that the AGNN loop is an important determinant of substrate selectivity. When this loop sequence is altered, the rate of Rnt1p cleavage is reduced. The reduction in cleavage rate can be attributed to reduced binding of the mutant substrate as measured by a gel-shift assay. Deletion of the nonconserved N-terminal domain of Rnt1p does not affect cleavage site choice or the ability of the enzyme to distinguish substrates that contain the AGNN loop, indicating that this region is not required for selective cleavage. Strikingly, a recombinant fragment of Rnt1p containing little more than the dsRBD is able to discriminate between wild-type and mutant loop sequences in a binding assay. We propose that a major determinant of AGNN loop recognition by Rnt1p is present in its dsRBD.     

Effect of translocation on topology and conformation of anticodon and D loops of tRNAPhe

Steady-state fluorescence and fluorescence anisotropy measurements have been carried out on isolated complexes of fluorescent derivatives of N-AcPhe-tRNA^Phe with 70 S ribosomes from Escherichia coli. As a fluorescent probe, proflavine was inserted into either the anticodon loop or the D loop.Upon binding to the A site of poly(U)-programmed ribosomes, the probe in the anticodon loop is highly immobilized and effectively shielded against solvent access in a hydrophobic binding site. Elongation factor G-dependent translocation to the P site does not change any of the fluorescence parameters. These observations indicate that in both sites the environment of the probe with respect to hydrophobicity and shielding against solvent access is rather similar. Moreover, substantial conformational changes of the anticodon loop upon translocation are made unlikely.In contrast to the anticodon loop, the D loop is fully exposed to the solvent in both A and P sites, indicating that the variable region in the middle of the D loop is oriented away from the ribosomal surface.On the other hand, depolarization measurements show that the D loop is strongly immobilized in the A site, possibly by binding interactions of invariant bases of the loop. Upon translocation, the D loop gains considerable flexibility, indicating that in the P site it is neither fixed by contacts with the ribosome nor by intramolecular base-pairing with the T loop.In the absence of poly(U) or in the presence of poly(C), the fluorescence parameters of the probes in the anticodon loop and, more significantly, in the D loop, differ from those observed in the presence of poly(U). These differences are best explained by assuming a codon-induced conformational change of the anticodon loop, which in turn is transmitted to the D loop.When the non-aminoacylated tRNA^Phe derivatives are studied, spectroscopic differences as compared to the respective N-AcPhe-tRNA^Phe derivatives are observed only for the A site complexes. It appears that the aminoacylation influences the binding of transfer RNA in the A site, but not in the P site.     

Interaction of nick-directed DNA mismatch repair and loop repair in human cells

In human cells, large DNA loop heterologies are repaired through a nick-directed pathway independent of mismatch repair. However, a 3'-nick generated by bacteriophage fd gene II protein heterology is not capable of stimulating loop repair. To evaluate the possibility that a mismatch near a loop could induce both repair types in human cell extracts, we constructed and tested a set of DNA heteroduplexes, each of which contains a combination of mismatches and loops. We have demonstrated that a strand break generated by restriction endonucleases 3' to a large loop is capable of provoking and directing loop repair. The repair of 3'-heteroduplexes in human cell extracts is very similar to that of 5'-heteroduplex repair, being strand-specific and highly biased to the nicked strand. This observation suggests that the loop repair pathway possesses bidirectional repair capability similar to that of the bacterial loop repair system. We also found that a nick 5' to a coincident mismatch and loop can apparently stimulate the repair of both. In contrast, 3'-nick-directed repair of a G-G mismatch was reduced when in the vicinity of a loop (33 or 46 bp between two sites). Increasing the distance separating the G-G mismatch and loop by 325 bp restored the efficiency of repair to the level of a single base-base mismatch. This observation suggests interference between 3'-nick-directed large loop repair and conventional mismatch repair systems when a mispair is near a loop. We propose a model in which DNA repair systems avoid simultaneous repair at adjacent sites to avoid the creation of double-stranded DNA breaks.     

SecA-dependence of the translocation of a large periplasmic loop in the Escherichia coli MalF inner membrane protein is a function of sequence context

We have analysed the translocation of a large periplasmic loop in the Escherichia coli MalF Inner membrane protein when placed in different sequence contexts and under conditions when the function of the SecA protein is Inhibited. The results show that the degree of SecA-dependence varies with sequence context: while translocation of the large loop In its normal context Is only minimally affected by SecA Inhibition, translocation is much more sensitive to SecA inhibition when the loop is placed in the context of other inner membrane proteins. Conversely, when the large MalF loop is replaced by segments from other proteins, translocation of those segments is again very sensitive to SecA inhibition. Thus, SecA-dependence is not an all-or-none phenomenon and Is not only a simple function of, e.g. the length of a translocated segment or the hydrophobicity of the flanking transmembrane segments.     

Dissection of the structural determinants involved in formation of the dimeric form of D-amino acid oxidase from Rhodotorula gracilis: role of the size of the betaF5-betaF6 loop

The role of the long loop connecting beta-strands F5 and F6 (21 amino acids, Pro302-Leu-Asp-Arg-Thr-Lys-Ser-Pro-Leu-Ser-Leu-Gly-Arg-Gly-Ser-Ala-Arg-Ala-Ala-Lys-Glu322) present in Rhodotorula gracilis d-amino acid oxidase (RgDAAO) was investigated by site-directed mutagenesis. This loop was proposed to play an important role in the 'head-to-tail' monomer-monomer interaction of this dimeric flavoenzyme: in particular, by means of electrostatic interactions between positively charged residues of the betaF5-betaF6 loop of one monomer and negatively charged residues belonging to the alpha-helices I3' and I3" of the other monomer. We produced a mutant of RgDAAO (namely, DAAO-DeltaLOOP2), in which only minor structural perturbations were introduced (only five amino acids were deleted; new sequence of the betaF5-betaF6 loop is Pro302-Leu-Asp-Arg-Thr-Leu-Gly-Arg-Gly-Ser-Ala-Arg-Ala-Ala-Lys-Glu317), and the charge of the betaF5-betaF6 loop not modified. The DeltaLOOP2 mutant is monomeric, has a weaker binding with the FAD cofactor, a decrease of the kinetic efficiency, and slight modifications in its spectral properties. The short version of the loop does not allow a correct monomer-monomer interaction, and its presence in the monomeric DAAO is a destabilizing structural element since the DeltaLOOP2 mutant is highly susceptible to proteolysis. These results, confirming the role of this loop in the subunits interaction and thus in stabilization of the sole dimeric form of RgDAAO, put forward the evidence that even a short deletion of the loop generates a consistent variation of the enzyme structure-function properties.     

Stability of the unique anticodon loop conformation of E.coli tRNAfMet.

Initiator tRNAs have an anticodon loop conformation distinct from that of elongation tRNAs as detected by susceptibility to S1 nuclease. We now find the anticodon loop conformation of E. coli tRNAfMet to be stable under different salt conditions as detected by using S1 nuclease as a structural probe. In contrast, a conformational change is observed in the T- and D- loop of this tRNA in the absence of added Mg2+. This change can be suppressed by spermine. Even under those conditions effecting a change in T- and D- loop conformation, the anticodon loop does not change. This suggests that the conformational shift is controlled by Mg2+ and restricted to the D- and T- loop region only without affecting the anticodon domain. The use of S1 nuclease as a conformational probe requires the use of kinetic studies to determine the initial cleavage sites. Thus, the use of a strong inhibitor which immediately stops the action of this nuclease is necessary. ATP is shown to be such an inhibitor.     

Role of SLV in SLI substrate recognition by the Neurospora VS ribozyme

Substrate recognition by the VS ribozyme involves a magnesium-dependent loop/loop interaction between the SLI substrate and the SLV hairpin from the catalytic domain. Recent NMR studies of SLV demonstrated that magnesium ions stabilize a U-turn loop structure and trigger a conformational change for the extruded loop residue U700, suggesting a role for U700 in SLI recognition. Here, we kinetically characterized VS ribozyme mutants to evaluate the contribution of U700 and other SLV loop residues to SLI recognition. To help interpret the kinetic data, we structurally characterized the SLV mutants by NMR spectroscopy and generated a three-dimensional model of the SLI/SLV complex by homology modeling with MC-Sym. We demonstrated that the mutation of U700 by A, C, or G does not significantly affect ribozyme activity, whereas deletion of U700 dramatically impairs this activity. The U700 backbone is likely important for SLI recognition, but does not appear to be required for either the structural integrity of the SLV loop or for direct interactions with SLI. Thus, deletion of U700 may affect other aspects of SLI recognition, such as magnesium ion binding and SLV loop dynamics. As part of our NMR studies, we developed a convenient assay based on detection of unusual (31)P and (15)N N7 chemical shifts to probe the formation of U-turn structures in RNAs. Our model of the SLI/SLV complex, which is compatible with biochemical data, leads us to propose novel interactions at the loop I/loop V interface.     

A flexible loop as a functional element in the catalytic mechanism of nucleoside hydrolase from Trypanosoma vivax

The nucleoside hydrolase of Trypanosoma vivax hydrolyzes the N-glycosidic bond of purine nucleosides. Structural and kinetic studies on this enzyme have suggested a catalytic role for a flexible loop in the vicinity of the active sites. Here we present the analysis of the role of this flexible loop via the combination of a proline scan of the loop, loop deletion mutagenesis, steady state and pre-steady state analysis, and x-ray crystallography. Our analysis reveals that this loop has an important role in leaving group activation and product release. The catalytic role involves the entire loop and could only be perturbed by deletion of the entire loop and not by single site mutagenesis. We present evidence that the loop closes over the active site during catalysis, thereby ordering a water channel that is involved in leaving group activation. Once chemistry has taken place, the loop dynamics determine the rate of product release.     

Analysis of the structure and stability of omega loop A replacements in yeast iso-1-cytochrome c.

Omega (omega)-loop A, residues 18-32 in wild-type yeast iso-1-cytochrome c, has been deleted and replaced with loop sequences from three other cytochromes c and one from esterase. Yeast expressing a partial loop deletion do not contain perceptible amounts of holoprotein as measured by low-temperature spectroscopy and cannot grow on nonfermentable media. Strains expressing loop replacement mutations accumulate holoprotein in vivo, but the protein function varies depending on the sequence and length of the replacement loop; in vivo expression levels do not correlate with their thermal denaturation temperatures. In vitro spectroscopic studies of the loop replacement proteins indicate that all fold into a native-like cytochrome c conformation, but are less stable than the wild-type protein. Decreases in thermal stability are caused by perturbation of loop C backbone in one case and a slight reorganization of the protein hydrophobic core in another case, rather than rearrangement of the loop A backbone. A single-site mutation in one of the replacement mutants designed to relieve inefficient hydrophobic core packing caused by the new loop recovers some, but not all, of the lost stability.     

AraC-DNA looping: orientation and distance-dependent loop breaking by the cyclic AMP receptor protein.

The arabinose operon promoter, pBAD, is negatively regulated in the absence of arabinose by AraC protein, which forms a DNA loop by binding to two sites separated by 210 base-pairs, araO2 and araI1. pBAD is also positively regulated by AraC-arabinose and the cyclic AMP receptor protein, CRP. We provide evidence that CRP breaks the araO2-araI1 repression loop in vitro. The ability of CRP to break the loop in vitro and to activate pBAD in vivo is dependent upon the orientation and distance of the CRP binding site relative to araI1. An insertion of one DNA helical turn, 11 base-pairs, between CRP and araI only partially inhibits CRP loop breaking and activation of pBAD, while an insertion of less than one DNA helical turn, 4 base-pairs, not only abolishes CRP activation and loop breaking, but actually causes CRP to stabilize the loop and increases the araO2-mediated repression of pBAD. Both integral and non-integral insertions of greater than one helical turn completely abolish CRP activation and loop breaking in vitro.     

The long and short flavodoxins: II. The role of the differentiating loop in apoflavodoxin stability and folding mechanism

Flavodoxins are classified in two groups according to the presence or absence of a approximately 20-residue loop of unknown function. In the accompanying paper (36), we have shown that the differentiating loop from the long-chain Anabaena PCC 7119 flavodoxin is a peripheral structural element that can be removed without preventing the proper folding of the apoprotein. Here we investigate the role played by the loop in the stability and folding mechanism of flavodoxin by comparing the equilibrium and kinetic behavior of the full-length protein with that of loop-lacking, shortened variants. We show that, when the loop is removed, the three-state equilibrium thermal unfolding of apoflavodoxin becomes two-state. Thus, the loop is responsible for the complexity shown by long-chain apoflavodoxins toward thermal denaturation. As for the folding reaction, both shortened and wild type apoflavodoxins display three-state behavior but their folding mechanisms clearly differ. Whereas the full-length protein populates an essentially off-pathway transient intermediate, the additional state observed in the folding of the shortened variant analyzed seems to be simply an alternative native conformation. This finding suggests that the long loop may also be responsible for the accumulation of the kinetic intermediate observed in the full-length protein. Most revealing, however, is that the influence of the loop on the overall conformational stability of apoflavodoxin is quite low and the natively folded shortened variant Delta(120-139) is almost as stable as the wild type protein. The fact that the loop, which is not required for a proper folding of the polypeptide, does not even play a significant role in increasing the conformational stability of the protein supports our proposal (36) that the differentiating loop of long-chain flavodoxins may be related to a recognition function, rather than serving a structural purpose.     

Inhibitors of different structure induce distinguishing conformations in the omega loop,Cys69-Cys96, of mouse acetylcholinesterase

We have shown previously that association of reversible active site ligands induces a conformational change in an omega loop (Omega loop), Cys(69)-Cys(96), of acetylcholinesterase. The fluorophore acrylodan, site-specifically incorporated at positions 76, 81, and 84, on the external portion of the loop not lining the active site gorge, shows changes in its fluorescence spectrum that reflect the fluorescent side chain moving from a hydrophobic environment to become more solvent-exposed. This appears to result from a movement of the Omega loop accompanying ligand binding. We show here that the loop is indeed flexible and responds to conformational changes induced by both active center and peripheral site inhibitors (gallamine and fasciculin). Moreover, phosphorylation and carbamoylation of the active center serine shows distinctive changes in acrylodan fluorescence spectra at the Omega loop sites, depending on the chirality and steric dimensions of the covalently conjugated ligand. Capping of the gorge with fasciculin, although it does not displace the bound ligand, dominates in inducing a conformational change in the loop. Hence, the ligand-induced conformational changes are distinctive and suggest multiple loop conformations accompany conjugation at the active center serine. The fluorescence changes induced by the modified enzyme may prove useful in the detection of organophosphates or exposure to cholinesterase inhibitors.     

The structure of the L3 loop from the hepatitis delta virus ribozyme: a syn cytidine.

The structure of the L3 central hairpin loop isolated from the antigenomic sequence of the hepatitis delta virus ribozyme with the P2 and P3 stems from the ribozyme stacked on top of the loop has been determined by NMR spectroscopy. The 26 nt stem-loop structure contains nine base pairs and a 7 nt loop (5'-UCCUCGC-3'). This hairpin loop is critical for efficient catalysis in the intact ribozyme. The structure was determined using homonuclear and heteronuclear NMR techniques on non-labeled and15N-labeled RNA oligonucleotides. The overall root mean square deviation for the structure was 1.15 A (+/- 0.28 A) for the loop and the closing C.G base pair and 0.90 A (+/- 0.18 A) for the loop and the closing C.G base pair but without the lone purine in the loop, which is not well defined in the structure. The structure indicates a U.C base pair between the nucleotides on the 5'- and 3'-ends of the loop. This base pair is formed with a single hydrogen bond involving the cytosine exocyclic amino proton and the carbonyl O4 of the uracil. The most unexpected finding in the loop is a syn cytidine. While not unprecedented, syn pyrimidines are highly unusual. This one can be confidently established by intranucleotide distances between the ribose and the base determined by NMR spectroscopy. A similar study of the structure of this loop showed a somewhat different three-dimensional structure. A discussion of differences in the two structures, as well as possible sites of interaction with the cleavage site, will be presented.     

A small loop in the capsid protein of Moloney murine leukemia virus controls assembly of spherical cores

We report the identification of a novel domain in the Gag protein of Moloney murine leukemia virus (MoLV) that is important for the formation of spherical cores. Analysis of 18 insertional mutations in the N-terminal domain of the capsid protein (CA) identified 3 that were severely defective for viral assembly and release. Transmission electron microscopy of cells producing these mutants showed assembly of Gag proteins in large, flat or dome-shaped patches at the plasma membrane. Spherical cores were not formed, and viral particles were not released. This late assembly/release block was partially rescued by wild-type virus. All three mutations localized to the small loop between alpha-helices 4 and 5 of CA, analogous to the cyclophilin A-binding loop of human immunodeficiency virus type 1 CA. In the X-ray structure of the hexameric form of MLV CA, this loop is located at the periphery of the hexamer. The phenotypes of mutations in this loop suggest that formation of a planar lattice of Gag is unhindered by mutations in the loop. However, the lack of progression of these planar structures to spherical ones suggests that mutations in this loop may prevent formation of pentamers or of stable pentamer-hexamer interactions, which are essential for the formation of a closed, spherical core. This region in CA, focused to a few residues of a small loop, may offer a novel therapeutic target for retroviral diseases.     

Involvement of the C-terminal disulfide-bonded loop of murine leukemia virus SU protein in a postbinding step critical for viral entry

A role for the C-terminal domain (CTD) of murine leukemia virus (MuLV) Env protein in viral fusion was indicated by the potent inhibition of MuLV-induced fusion, but not receptor binding, by two rat monoclonal antibodies (MAbs) specific for epitopes in the CTD. Although these two MAbs, 35/56 and 83A25, have very different patterns of reactivity with viral isolates, determinants of both epitopes were mapped to the last C-terminal disulfide-bonded loop of SU (loop 10), and residues in this loop responsible for the different specificities of these MAbs were identified. Both MAbs reacted with a minor fraction of a truncated SU fragment terminating four residues after loop 10, indicating that while the deleted C-terminal residues were not part of these epitopes, they promoted their formation. Neither MAb recognized the loop 10 region expressed in isolated form, suggesting that these epitopes were not completely localized within loop 10 but required additional sequences located N terminal to the loop. Direct support for a role for loop 10 in fusion was provided by the demonstration that Env mutants containing an extra serine or threonine residue between the second and third positions of the loop were highly attenuated for infectivity and defective in fusion assays, despite wild-type levels of expression, processing, and receptor binding. Other mutations at positions 1 to 3 of loop 10 inhibited processing of the gPr80 precursor protein or led to increased shedding of SU, suggesting that loop 10 also affects Env folding and the stability of the interaction between SU and TM.     

Conformational changes in the activation loop of the insulin receptor's kinase domain.

Low catalytic efficiency of basal-state protein kinases often depends on activation loop residues blocking substrate access to the catalytic cleft. Using the recombinant soluble form of the insulin receptor's kinase domain (IRKD) in its unphosphorylated state, activation loop conformation was analyzed by limited proteolysis. The rate of activation loop cleavage by trypsin is slow in the apo-IRKD. Bound Mg-adenine nucleoside di- and triphosphates increased the cleavage rate with half-maximal effects observed at 0.4-0.9 mM nucleotide. Adenosine monophosphate at concentrations up to 10 mM was not bound appreciably by the IRKD and had virtually no impact on activation loop cleavage. Amino-terminal and carboxy-terminal core-flanking regions of the IRKD had no statistically significant impact on the ligand-dependent or -independent activation loop cleavages. Furthermore, the core-flanking regions did not change the inherent conformational stability of the active site or the global stability of the IRKD, as determined by guanidinium chloride-induced denaturation. These measurements indicate that the intrasterically inhibitory conformation encompasses > or =90% of the ligand-free basal state kinase. However, normal intracellular concentrations of Mg-adenine nucleotides, which are in the millimolar range, would favor a basal-state conformation of the activation loop that is more accessible.     

Selective reconstitution of human D4 dopamine receptor variants with Gi alpha subtypes

G protein-coupled receptors (GPCRs) are seven-transmembrane (TM) helical proteins that bind extracellular molecules and transduce signals by coupling to heterotrimeric G proteins in the cytoplasm. The human D4 dopamine receptor is a particularly interesting GPCR because the polypeptide loop linking TM helices 5 and 6 (loop i3) may contain from 2 to 10 similar direct hexadecapeptide repeats. The precise role of loop i3 in D4 receptor function is not known. To clarify the role of loop i3 in G protein coupling, we constructed synthetic genes for the three main D4 receptor variants. D4-2, D4-4, and D4-7 receptors contain 2, 4, and 7 imperfect hexadecapeptide repeats in loop i3, respectively. We expressed and characterized the synthetic genes and found no significant effect of the D4 receptor polymorphisms on antagonist or agonist binding. We developed a cell-based assay where activated D4 receptors coupled to a Pertussis toxin-sensitive pathway to increase intracellular calcium concentration. Studies using receptor mutants showed that the regions of loop i3 near TM helices 5 and 6 were required for G protein coupling. The hexadecapeptide repeats were not required for G protein-mediated calcium flux. Cell membranes containing expressed D4 receptors and receptor mutants were reconstituted with purified recombinant G protein alpha subunits. The results show that each D4 receptor variant is capable of coupling to several G(i)alpha subtypes. Furthermore, there is no evidence of any quantitative difference in G protein coupling related to the number of hexadecapeptide repeats in loop i3. Thus, loop i3 is required for D4 receptors to activate G proteins. However, the polymorphic region of the loop does not appear to affect the specificity or efficiency of G(i)alpha coupling.     

The loops facing the active site of prolyl oligopeptidase are crucial components in substrate gating and specificity

Prolyl oligopeptidase (POP) has emerged as a drug target for neurological diseases. A flexible loop structure comprising loop A (res. 189–209) and loop B (res. 577–608) at the domain interface is implicated in substrate entry to the active site. Here we determined kinetic and structural properties of POP with mutations in loop A, loop B, and in two additional flexible loops (the catalytic His loop, propeller Asp/Glu loop). POP lacking loop A proved to be an inefficient enzyme, as did POP with a mutation in loop B (T590C). Both variants displayed an altered substrate preference profile, with reduced ligand binding capacity. Conversely, the T202C mutation increased the flexibility of loop A, enhancing the catalytic efficiency beyond that of the native enzyme. The T590C mutation in loop B increased the preference for shorter peptides, indicating a role in substrate gating. Loop A and the His loop are disordered in the H680A mutant crystal structure, as seen in previous bacterial POP structures, implying coordinated structural dynamics of these loops. Unlike native POP, variants with a malfunctioning loop A were not inhibited by a 17-mer peptide that may bind non-productively to an exosite involving loop A. Biophysical studies suggest a predominantly closed resting state for POP with higher flexibility at the physiological temperature. The flexible loop A, loop B and His loop system at the active site is the main regulator of substrate gating and specificity and represents a new inhibitor target.