Modulation of the structural integrity of helix F in apomyoglobin by single amino acid replacements

The conformational features of native and mutant forms of sperm-whale apomyoglobin (apoMb) at neutral pH were probed by limited proteolysis experiments utilizing up to eight proteases of different substrate specificities. It was shown that all proteases selectively cleave apoMb at the level of chain segment 82-94 (HEAELKPLAQSHA), encompassing helix F in the X-ray structure of the holo form of the native protein; for example, thermolysin cleaves the Pro 88-Leu 89 peptide bond. These results indicate that helix F is highly flexible or largely disrupted in apoMb. Because helix F contains the helix-breaking Pro 88 residue, we propose that helix F is kept in place in the native holo protein by a variety of helix-heme stabilizing interactions. To modulate the stability of helix F, the Pro88Ala and Pro88Gly mutants were prepared by site-directed mutagenesis, and their conformational properties investigated by both far-UV circular dichroism spectroscopy and limited proteolysis. The helix content of the Pro88Ala mutant was somewhat enhanced with respect to that of both native and Pro88Gly mutant, as expected from the fact that Ala is the strongest helix inducer among the 20 amino acid residues. The rate of limited proteolysis of the three apoMb variants by thermolysin and proteinase K was in the order native > Pro88Gly > Pro88Ala, in agreement with the scale of helix propensity of Ala, Gly, and Pro. The possible role of the flexible/unfolded chain segment 82-94 for the function and fate of apoMb at the cellular level is discussed.     

Crystal structural analysis of protein-protein interactions drastically destabilized by a single mutation

The complex of barnase (bn) and barstar (bs), which has been widely studied as a model for quantitative analysis of protein-protein interactions, is significantly destabilized by a single mutation, namely, bs Asp39 --> Ala, which corresponds to a change of 7.7 kcal x mol(-1) in the free energy of binding. However, there has been no structural information available to explain such a drastic destabilization. In the present study, we determined the structure of the mutant complex at 1.58 A resolution by X-ray crystallography. The complex was similar to the wild-type complex in terms of overall and interface structures; however, the hydrogen bond network mediated by water molecules at the interface was significantly different. Several water molecules filled the cavity created by the mutation and consequently caused rearrangement of the hydrated water molecules at the interface. The water molecules were redistributed into a channel-like structure that penetrated into the complex. Furthermore, molecular dynamics simulations showed that the mutation increased the mobility of water molecules at the interface. Since such a drastic change in hydration was not observed in other mutant complexes of bn and bs, the significant destabilization of the interaction may be due to this channel-like structure of hydrated water molecules.     

Physico-chemical studies on two forms of Bengal gram lipoxygenase: implication for structural differences

Two forms of lipoxygenase have been isolated from Bengal gram (Cicer arietinum) and purified to apparent homogeneity. In sedimentation velocity experiments both forms showed a single symmetrical peak with an S_20,w value of 5.5 ± 0.5 S. From the SDS-polyacrylamide gel electrophoresis and gel filtration data they appeared to consist of a single polypeptide chain of identical size (M_r = 95000). The amino acid composition was essentially identical except for the proline and isoleucine contents. Kinetically, the two forms were quite distinct. The CD spectra of the two forms in the far-ultraviolet region were rather similar. However, in the near-ultraviolet region there were discernible differences. Although the antibody raised against each of them showed antigenic cross-reactivity, there was a perceptible difference in the cross-reaction with enzymes from other legumes. The results imply elements of dissimilarity in the structure of these two forms.     

Structural heterogeneity of the various forms of apomyoglobin: implications for protein folding.

Temperature-induced denaturation transitions of different structural forms of apomyoglobin were studied monitoring intrinsic tryptophan fluorescence. It was found that the tryptophans are effectively screened from solvent both in native and acid forms throughout most of the temperature range tested. Thus, the tryptophans' surrounding do not show a considerable change in structure where major protein conformational transitions have been found in apomyoglobin using other techniques. At high temperatures and under strong destabilizing conditions, the tryptophans' fluorescence parameters show sigmoidal thermal denaturation. These results, combined with previous studies, show that the structure of this protein is heterogeneous, including native-like (tightly packed) and molten globule-like substructures that exhibit conformation (denaturation) transitions under different conditions of pH and temperature (and denaturants). The results suggest that the folding of this protein proceeds via two "nucleation" events whereby native-like contacts are formed. One of these events, which involves AGH "core" formation, appears to occur very early in the folding process, even before significant hydrophobic collapse in the rest of the protein molecule. From the current studies and other results, a rather detailed picture of the folding of myoglobin is presented, on the level of specific structures and their thermodynamical properties as well as formation kinetics.     

Molecular dynamics simulations reveal structural differences among wild-type NPC1 protein and its mutant forms

Abstract

NPC1 is a 25-exon gene located on the long arm of chromosome 18q11.2 and encodes NPC1, a transmembrane protein comprising 1278 amino acid residues. Mutations in the NPC1 gene can cause Niemann-Pick disease type C (NP-C), a rare autosomal-recessive neurovisceral disease. We assessed mutant protein folding using computer-based molecular dynamics (MD) simulations and molecular docking of the three most common NPC1 mutations, all of which result in changes in a cysteine-rich luminal loop region of the protein: a) I1061T is the most commonly detected variant in patients with NP-C worldwide; b) P1007A is the second most common variant, frequently detected in Portuguese, British and German patients; c) G992W occurs most often in patients of Acadian descent. Analyses of molecular structural information and related cellular physiological processes revealed that mutant NPC1 proteins exhibited altered function despite being far from the N-terminal domain cholesterol binding. MD simulations revealed that mutant I1061T protein shows remarkable instability in comparison the WT and also de other mutants, and interestingly this mutant has been identified as the most common variant. In the case of the mutant P1007A, it is presumed that this substitution promotes larger structural changes than proline due to their greater hydrophobic properties.

Structural changes related to the G992W mutation may affect the physicochemical space of G992W variant protein because tryptophan induces hydrophobic interactions. Cholesterol docking studies focused on binding recognition showed differences in the binding positions of variants versus the wild-type protein that go some way to explaining the molecular pathogenesis.

Communicated by Ramaswamy H. Sarma     

Ultraviolet resonance Raman examination of horse apomyoglobin acid unfolding intermediates.

We have used UV resonance Raman spectroscopy to study the acid-induced denaturation of horse apomyoglobin (apoMb) between pH 7. 0 and 1.8. The 206.5 nm excited Raman spectra are dominated by amide vibrations, which are used to quantitatively determine the apoMb secondary structure. The 229 nm excited Raman spectra are dominated by the Tyr and Trp Raman bands, which are analyzed to examine changes of Tyr and Trp environments and solvent exposures. We observe two partially unfolded apoMb intermediates at pH 4 and pH 2, while we observe only one partially unfolded holoMb intermediate at 2, in which the G and H helices are mainly intact, while the rest of protein is unfolded. This partially unfolded holoMb intermediate at pH 2 is essentially identical to the pH 2 apoMb intermediate. The partially unfolded pH 4 apoMb intermediate is composed of the three folded A, G, and H helices and contains 38% helical structure. The changes in the Trp Raman cross sections during the acid-induced denaturation indicates that Trp 7 is likely to be fully exposed in the apoMb pH 4 intermediate and that the A helix melts with a pKa approximately 3.5.     

Human and yeast Hsp110 chaperones exhibit functional differences

Hsp110 proteins constitute a heterogeneous family of abundant molecular chaperones, related to the Hsp70 proteins and exclusively found in the cytosol of eukaryotic organisms. Hsp110 family members are described as efficient holdases, preventing the aggregation and assisting the refolding of heat-denatured model substrates in the presence of Hsp70 chaperones and their co-chaperones. To gain more insights into the mode of action of this protein family we compared two homologues representing two subtypes of Hsp110 proteins, S. cerevisiae Sse1 and H. sapiens Apg-2, in their structural and functional properties in vitro. In contrast to previous publications both proteins exhibited intrinsic ATPase activities, which only in the case of Sse1 could be stimulated by the Hsp40 co-chaperone Sis1. Similar to Hsp70 proteins ATP binding and hydrolysis induced conformational rearrangements in both Hsp110 proteins as detected by tryptophane fluorescence. However, nucleotide induced changes in the proteolytic digestion pattern were detected only for Sse1. Sse1 and Apg-2 thus show significant differences in their biochemical properties, which may relate to differences in their functional roles in vivo.     

Compactness of protein molten globules: temperature-induced structural changes of the apomyoglobin folding intermediate

Apomyoglobin undergoes a two-step unfolding transition when the pH is lowered from 6 to 2. The partly folded intermediate (1) state at pH 4 and low ionic strength has properties of a molten globule. We have studied structural features of this state, its compactness, content of secondary structure, and specific packing of aromatic side chains, using dynamic light scattering, and small-angle X-ray scattering and far- and near-ultraviolet circular dichroism spectroscopy. Particular attention was paid to temperature-dependent structural changes. The results are discussed with reference to the native-like (N) state and the highly unfolded (U) state. It turned out that the I-state is most compact near 30°C, having a Stokes radius 20% larger and a radius of gyration 30% larger than those of the N-state. Both cooling and heating relative to 30°C led to an expansion of the molecule, but the structural changes at low and high temperatures were of a different kind. At temperatures above 40°C non co-operative melting of structural elements was observed, while the secondary structure was essentially retained on cooling. The results are discussed in context with theoretical predictions of the compactness and the stability of apomyoglobin by Alonso et al. [Alonso, D. O. V., Dill, K, A., and Stigler, D. (1991) Biopolymers 31:1631–1649]. Comparing the I-state of apomyoglobin with the molten globules of -lactalbumin and cytochrome c, we found that the compactness of the molten globule states of the three proteins decreases in the order -lactalbumin > apocytochrome c > apomyoglobin. While -lactalbumin and cytochrome c are rather homogeneously expanded, apomyoglobin exhibits a non uniform expansion, since two structural domains could clearly be detected by small-angle X-ray scattering.Abbreviations CD circular dichroism - DLS dynamic light scattering - SAXS small-angle X-ray scattering - N, 1, and U the native, intermediate, and unfolded forms of apomyoglobin Correspondence to: G. Damaschun     

Acetylcholinesterases--the structural similarities and differences

Acetylcholinesterase (AChE) is a widely spread enzyme playing a very important role in nerve signal transmission. As AChE controls key processes, its inhibition leads to the very fast death of an organism, including humans. However, when this feature is to be used for killing of unwanted organisms (i.e. mosquitoes), one is faced with the question - how much do AChEs differ between species and what are the differences? Here, a theoretical point of view was utilized to identify the structural basis for such differences. The various primary and tertiary alignments show that AChEs are very evolutionary conserved enzymes and this fact could lead to difficulties, for example, in the search for inhibitors specific for a particular species.     

Chain length dependence of apomyoglobin folding: structural evolution from misfolded sheets to native helices

Very little is known about how protein structure evolves during the polypeptide chain elongation that accompanies cotranslational protein folding. This in vitro model study is aimed at probing how conformational space evolves for purified N-terminal polypeptides of increasing length. These peptides are derived from the sequence of an all-alpha-helical single domain protein, Sperm whale apomyoglobin (apoMb). Even at short chain lengths, ordered structure is found. The nature of this structure is strongly chain length dependent. At relatively short lengths, a predominantly non-native beta-sheet conformation is present, and self-associated amyloid-like species are generated. As chain length increases, alpha-helix progressively takes over, and it replaces the beta-strand. The observed trends correlate with the specific fraction of solvent-accessible nonpolar surface area present at different chain lengths. The C-terminal portion of the chain plays an important role by promoting a large and cooperative overall increase in helical content and by consolidating the monomeric association state of the full-length protein. Thus, a native-like energy landscape develops late during apoMb chain elongation. This effect may provide an important driving force for chain expulsion from the ribosome and promote nearly-posttranslational folding of single domain proteins in the cell. Nature has been able to overcome the above intrinsic misfolding trends by modulating the composition of the intracellular environment. An imbalance or improper functioning by the above modulating factors during translation may play a role in misfolding-driven intracellular disorders.     

Two structural forms of histone octamer

It has been found that histone octamer of calf thymus (H2A--H2B--H3--H4)2 can exist in two structural states--"loose" (2M NaCl) and "compact" one (4M NaCl). The compact state of the octamer is characterized by screening of part of tyrosyls for quenching effect of ions I-, longer relaxation time of tyrosyls, greater stability of histone H3 towards trypsinolysis, complete absence of interactions between histone H3 SH-groups and parachlormercuribenzoate.     

Structural differences in solution and crystalline forms of met-myoglobin

For several decades X-ray diffraction studies have been the paragon of biological structure studies at atomic resolution. Diffraction provides three-dimensional structure information, which is essential to our fundamental understanding of protein function. However, since X-ray diffraction cannot be done to atomic resolution on proteins in their native solution or membrane-bound state, the possibility exists that the conformations of the protein in crystals are slightly different from the conformations in solution, and attempts to interpret details of the structure may be misleading and without physiological relevance. In this paper, we show that this concern is justified for a familiar protein, myoglobin. Performing X-ray absorption fine structure experiments on both solution and crystalline met-myoglobin (met-Mb), we find significant differences in the local environment of the iron between the two states. Specifically, the average iron-nearest neighbor atom distance in the crystalline form is 0.05 A shorter than that in the solution form, and the iron-nearest neighbor bond is more rigid in the crystalline met-Mb. Possible artifactual explanations for the differences have been ruled out.     

Archaeal and bacterial SecD and SecF homologs exhibit striking structural and functional conservation

The majority of secretory proteins are translocated into and across hydrophobic membranes via the universally conserved Sec pore. Accessory proteins, including the SecDF-YajC Escherichia coli membrane complex, are required for efficient protein secretion. E. coli SecDF-YajC has been proposed to be involved in the membrane cycling of SecA, the cytoplasmic bacterial translocation ATPase, and in the stabilizing of SecG, a subunit of the Sec pore. While there are no identified archaeal homologs of either SecA or SecG, many archaea possess homologs of SecD and SecF. Here, we present the first study that addresses the function of archaeal SecD and SecF homologs. We show that the SecD and SecF components in the model archaeon Haloferax volcanii form a cytoplasmic membrane complex in the native host. Furthermore, as in E. coli, an H. volcanii deltasecFD mutant strain exhibits both severe cold sensitivity and a Sec-specific protein translocation defect. Taken together, these results demonstrate significant functional conservation among the prokaryotic SecD and SecF homologs despite the distinct composition of their translocation machineries.     

Molecular dynamics of a thermostable multicopper oxidase from Thermus thermophilus HB27: structural differences between the apo and holo forms

Molecular dynamic (MD) simulations have been performed on Tth-MCO, a hyperthermophilic multicopper oxidase from thermus thermophilus HB27, in the apo as well as the holo form, with the aim of exploring the structural dynamic properties common to the two conformational states. According to structural comparison between this enzyme and other MCOs, the substrate in process to electron transfer in an outer-sphere event seems to transiently occupy a shallow and overall hydrophobic cavity near the Cu type 1 (T1Cu). The linker connecting the β-strands 21 and 24 of the second domain (loop (β21-β24)(D2)) has the same conformation in both states, forming a flexible lid at the entrance of the electron-transfer cavity. Loop (β21-β24)(D2) has been tentatively assigned a role occluding the access to the electron-transfer site. The dynamic of the loop (β21-β24)(D2) has been investigated by MD simulation, and results show that the structures of both species have the same secondary and tertiary structure during almost all the MD simulations. In the simulation, loop (β21-β24)(D2) of the holo form undergoes a higher mobility than in the apo form. In fact, loop (β21-β24)(D2) of the holo form experiences a conformational change which enables exposure to the electron-transfer site (open conformation), while in the apo form the opposite effect takes place (closed conformation). To confirm the hypothesis that the open conformation might facilitate the transient electron-donor molecule occupation of the site, the simulation was extended another 40 ns with the electron-donor molecule docked into the protein cavity. Upon electron-donor molecule stabilization, loops near the cavity reduce their mobility. These findings show that coordination between the copper and the protein might play an important role in the general mobility of the enzyme, and that the open conformation seems to be required for the electron transfer process to T1Cu.     

Eugenol and its structural analogs inhibit monoamine oxidase A and exhibit antidepressant-like activity

Eugenol (1) is an active principle of Rhizoma acori graminei, a medicinal herb used in Asia for the treatment of symptoms reminiscent of Alzheimer's disease (AD). It has been shown to protect neuronal cells from the cytotoxic effect of amyloid beta peptides (Abetas) in cell cultures and exhibit antidepressant-like activity in mice. Results from this study show that eugenol inhibits monoamine oxidase A (MAOA) preferentially with a K(i)=26 microM. It also inhibits MAOB but at much higher concentrations (K(i)=211 microM). In both cases, inhibition is competitive with respect to the monoamine substrate. Survey of compounds structurally related to eugenol has identified a few that inhibit MAOs more potently. Structure activity relationship reveals structural features important for MAOA and MAOB inhibition. Molecular docking experiments were performed to help explain the SAR outcomes. Four of these compounds, two (1, 24) inhibiting MAOA selectively and the other two (19, 21) inhibiting neither MAOA nor MAOB, were tested for antidepressant-like activity using the forced swim test in mice. Results suggest a potential link between the antidepressant activity of eugenol and its MAOA inhibitory activity.     

Kinetics of interactions between apomyoglobin and phospholipid membrane

The interaction of apomyoglobin and its mutant forms with phospholipid membranes was studied using tryptophan fluorescence and circular dichroism in the far UV region. It is shown that a negatively charged phospholipid membrane can have a dual effect on the structure of protein molecule upon their interaction. On the one hand, the membrane induces denaturation of the protein native structure to its intermediate state, acting as a moderate denaturing agent. On the other hand, it can stabilize the structure of unfolded protein to the same intermediate state, acting as a moderate structuring agent. The kinetics of interaction between apomyoglobin and its mutant forms and the phospholipid membrane depends on the membrane surface charge. Here the interaction rate depends on the concentration of phospholipids vesicles and stability of protein molecule, which increase with a decrease in the latter. The roles of these factors in the folding of membrane proteins and the choice of the targeted delivery pathways for protein drugs are discussed.     

Molecular analysis of a novel family of complex glycoinositolphosphoryl ceramides from Cryptococcus neoformans: structural differences between encapsulated and acapsular yeast forms

Complex glycoinositolphosphoryl ceramides (GIPCs) have been purified from a pathogenic encapsulated wild-type (WT) strain of Cryptococcus neoformans var. neoformans and from an acapsular mutant (Cap67). The structures of the GIPCs were determined by a combination of tandem mass spectrometry, nuclear magnetic resonance spectroscopy, methylation analysis, gas chromatography-mass spectrometry, and chemical degradation. The main GIPC from the WT strain had the structure Manp(alpha1-3)[Xylp(beta1-2)] Manp(alpha1-4)Galp(beta1-6)Manp(alpha1-2)Ins-1-phosphoryl ceramide (GIPC A), whereas the compounds from the acapsular mutant were more heterogeneous in their glycan chains, and variants with Manp(alpha1-6) (GIPC B), Manp(alpha1-6) Manp(alpha1-6) (GIPC C), and Manp(alpha1-2)Manp(alpha1-6)Manp(alpha1-6) (GIPC D) substituents linked to the nonreducing terminal mannose residue found in the WT GIPC A were abundant. The ceramide moieties of C. neoformans GIPCs were composed of a C(18) phytosphingosine long-chain base mainly N-acylated with 2-hydroxy-tetracosanoic acid in the WT GIPC while in the acapsular Cap67 mutant GIPCs, as well as 2-hydroxy-tetracosanoic acid, the unusual 2,3-dihydroxy-tetracosanoic acid was characterized. In addition, structural analysis revealed that the amount of GIPC in the WT cells was fourfold less of that in the acapsular mutant.     

The multiple forms and kinetic differences of rat colonic beta-N-acetylhexosaminidases

Rat colonic beta-N-acetylhexosaminidase (2-acetamido-2-deoxy-beta-D-glucoside acetamidodeoxyglucohydrolase, EC 3.2.1.30) has been separated into three forms by DEAE-cellulose chromatography with an increasing salt gradient. It was not possible to separate the glucosaminidase activity from the galactosaminidase activity by a variety of chromatographic procedues, but the ratio of the two specific activities varied during purification. The pH optima were however identical, for both activities and all three forms. Kinetic measurements including inhibition by substrate analogues showed differences between the two activities as well as among the three forms. A common active site model was inconsistent with the results. Data from mixed substrate experiments were consistent with a model wherein the two activities reside in seperate active sites, each able to be inhibited by the substrate for the other site. The effect of acetate and SH reagents confirmed the two-site model. Treatment with neuraminidase, thimerosal, p-hydroxymercuribenzoate, HgCl2 and AgNO3 or heating at 50 degrees C did not produce any effect on the A form that could be identified as a conversion to the B form. Measurement of the effects on both activities supported the two-site model. It is concluded that the relationship between the A and B forms in the rat colonic mucosa hexosaminidases must be different from that reported for such enzymes from other sources.