Characterization of temperature dependent and substrate-binding cleft movements in Bacillus circulans family 11 xylanase: A molecular dynamics investigation

Background

Xylanases (EC 3.2.1.8) hydrolyze xylan, one of the most abundant plant polysaccharides found in nature, and have many potential applications in biotechnology.

Methods

Molecular dynamics simulations were used to investigate the effects of temperature between 298 to 338 K and xylobiose binding on residues located in the substrate-binding cleft of the family 11 xylanase from Bacillus circulans (BcX).

Results

In the absence of xylobiose the BcX exhibits temperature dependent movement of the thumb region which adopts an open conformation exposing the active site at the optimum catalytic temperature (328 K). In the presence of substrate, the thumb region restricts access to the active site at all temperatures, and this conformation is maintained by substrate/protein hydrogen bonds involving active site residues, including hydrogen bonds between Tyr69 and the 2′ hydroxyl group of the substrate. Substrate access to the active site is regulated by temperature dependent motions that are restricted to the thumb region, and the BcX/substrate complex is stabilized by extensive intermolecular hydrogen bonding with residues in the active site.

General significance

These results call for a revision of both the “hinge-bending” model for the activity of group 11 xylanases, and the role of Tyr69 in the catalytic mechanism.     

Picosecond dynamics in haemoglobin from different species: A quasielastic neutron scattering study

Background

Dynamics in haemoglobin from platypus (Ornithorhynchus anatinus), chicken (Gallus gallus domesticus) and saltwater crocodile (Crocodylus porosus) were measured to investigate response of conformational motions on the picosecond time scale to naturally occurring variations in the amino acid sequence of structurally identical proteins.

Methods

Protein dynamics was measured using incoherent quasielastic neutron scattering. The quasielastic broadening was interpreted first with a simple single Lorentzian approach and then by using the Kneller–Volino Brownian dynamics model.

Results

Mean square displacements of conformational motions, diffusion coefficients of internal dynamics and residence times for jump-diffusion between sites and corresponding effective force constants (resilience) and activation energies were determined from the data.

Conclusions

Modifications of the physicochemical properties caused by mutations of the amino acids were found to have a significant impact on protein dynamics. Activation energies of local side chain dynamics were found to be similar between the different proteins being close to the energy, which is required for the rupture of single hydrogen bond in a protein.

General significance

The measured dynamic quantities showed significant and systematic variations between the investigated species, suggesting that they are the signature of an evolutionary adaptation process stimulated by the different physiological environments of the respective protein.     

In vitro cross-linking of elastin peptides and molecular characterization of the resultant biomaterials

Background

Elastin is a vital protein and the major component of elastic fibers which provides resilience to many vertebrate tissues. Elastin's structure and function are influenced by extensive cross-linking, however, the cross-linking pattern is still unknown.

Methods

Small peptides containing reactive allysine residues based on sequences of cross-linking domains of human elastin were incubated in vitro to form cross-links characteristic of mature elastin. The resultant insoluble polymeric biomaterials were studied by scanning electron microscopy. Both, the supernatants of the samples and the insoluble polymers, after digestion with pancreatic elastase or trypsin, were furthermore comprehensively characterized on the molecular level using MALDI-TOF/TOF mass spectrometry.

Results

MS² data was used to develop the software PolyLinX, which is able to sequence not only linear and bifunctionally cross-linked peptides, but for the first time also tri- and tetrafunctionally cross-linked species. Thus, it was possible to identify intra- and intermolecular cross-links including allysine aldols, dehydrolysinonorleucines and dehydromerodesmosines. The formation of the tetrafunctional cross-link desmosine or isodesmosine was unexpected, however, could be confirmed by tandem mass spectrometry and molecular dynamics simulations.

Conclusions

The study demonstrated that it is possible to produce biopolymers containing polyfunctional cross-links characteristic of mature elastin from small elastin peptides. MALDI-TOF/TOF mass spectrometry and the newly developed software PolyLinX proved suitable for sequencing of native cross-links in proteolytic digests of elastin-like biomaterials.

General significance

The study provides important insight into the formation of native elastin cross-links and represents a considerable step towards the characterization of the complex cross-linking pattern of mature elastin.     

Sites of Intra- and Intermolecular Cross-linking of the N-terminal Extension of Troponin I in Human Cardiac Whole Troponin Complex

Our previous studies (Howarth, J. W., Meller, J., Solaro, R. J., Trewhella, J., and Rosevear, P. R. (2007) J. Mol. Biol. 373, 706–722) of the unique N-terminal region of human cardiac troponin I (hcTnI), predicted a possible intramolecular interaction near the basic inhibitory peptide. To explore this possibility, we generated single cysteine mutants (hcTnI-S5C and hcTnI-I19C), which were labeled with the hetero-bifunctional cross-linker benzophenone-4-maleimide. The labeled hcTnI was reconstituted to whole troponin and exposed to UV light to form cross-linked proteins. Reversed-phase high-performance liquid chromatography and SDS-PAGE indicated intra- and intermolecular cross-linking with hcTnC and hcTnT. Moreover, using tandem mass spectrometry and Edman sequencing, specific intramolecular sites of interaction were determined at position Met-154 (I19C mutant) and Met-155 (S5C mutant) of hcTnI and intermolecular interactions at positions Met-47 and Met-80 of hcTnC in all conditions. Even though specific intermolecular cross-linked sites did not differ, the relative abundance of cross-linking was altered. We also measured the Ca²⁺-dependent ATPase rate of reconstituted thin filament-myosin-S1 preparation regulated by either cross-linked or non-labeled troponin. Ca²⁺ regulation of the ATPase rate was lost when the Cys-5 hcTnI mutant was cross-linked in the absence of Ca²⁺, but only partially inhibited with Cys-19 cross-linking in either the presence or absence of Ca²⁺. This result indicates different functional effects of cross-linking to Met-154 and Met-155, which are located on different sides of the hcTnI switch peptide. Our data provide novel evidence identifying interactions of the hcTnI-N terminus with specific intra- and intermolecular sites.The human cardiac variant of troponin I (hcTnI)² has structural and functional specializations that are related to its critical role in control of cardiac dynamics. These specializations include variations in amino acids that are significant factors in the response of the heart to: adrenergic stimulation (1), sarcomere length (2, 3), and pH (4, 5). An especially significant region of specialization is a unique N-terminal extension of 30–32 amino acids, which contains serial serines at positions 23/24 that are substrates for kinases that control cardiac dynamics (6–8). Despite its significance in control of cardiac function, molecular mechanisms of how the N-terminal human cardiac troponin I (N-hcTnI) region controls sarcomeric and cardiac function remain poorly understood. There is evidence that upon phosphorylation the interaction between the N-hcTnI and the N-lobe of N-hcTnC is weakened (9, 10). The structure of the N-hcTnI was missing in the crystal structure of cardiac troponin (11). However, we recently reported (12) the structure of the N-terminal peptide using NMR. Docking of this structure into the core troponin structure indicated the potential for a previously unappreciated intramolecular interactions of the N terminus with the regions at or near the highly basic inhibitory peptide region of cardiac troponin (12, 13). This interaction appeared plausible not only on the basis of the structure of hcTnI, but also on the basis of the preponderance of basic amino acids in the inhibitory peptide and the presence of acidic residues in the N terminus.In experiments reported here, we tested the hypothesis that the unique N-terminal region of hcTnI engages in both intra- and intermolecular interactions. We introduced Cys residues into the N-hcTnI at positions 5 and 19 and labeled the Cys residue with the hetero-bifunctional cross-linker, BP-MAL, which upon UV irradiation cross-links to residues within ∼10 Å of the modified Cys (14). We analyzed the cross-linked peptides by Edman sequencing and mass spectrometry to determine specific sites of interaction. The intramolecular sites of interaction were Met-154 and Met-155 in the hcTnI switch peptide for labeled positions 19 and 5, respectively. The intermolecular cross-linking sites on N-hcTnC were 47 and 80 for hcTnI labeled at either position 5 or 19. Measurement of Ca²⁺-dependent ATPase rate in reconstituted preparations indicated that allosteric effects of the different specific intramolecular cross-links (position Met-154 versus Met-155) to different hydrophobic positions on the switch peptide may affect hcTnC interaction with the switch peptide.     

Solution equilibria of cytosine- and guanine-rich sequences near the promoter region of the n-myc gene that contain stable hairpins within lateral loops

Background

Cytosine- and guanine-rich regions of DNA are capable of forming complex structures named i-motifs and G-quadruplexes, respectively. In the present study the solution equilibria at nearly physiological conditions of a 34-base long cytosine-rich sequence and its complementary guanine-rich strand corresponding to the first intron of the n-myc gene were studied. Both sequences, not yet studied, contain a 12-base tract capable of forming stable hairpins inside the i-motif and G-quadruplex structures, respectively.

Methods

Spectroscopic, mass spectrometry and separation techniques, as well as multivariate data analysis methods, were used to unravel the species and conformations present.

Results

The cytosine-rich sequence forms two i-motifs that differ in the protonation of bases located in the loops. A stable Watson–Crick hairpin is formed by the bases in the first loop, stabilizing the i-motif structure. The guanine-rich sequence adopts a parallel G-quadruplex structure that is stable throughout the pH range 3–7, despite the protonation of cytosine and adenine bases at lower pH values. The presence of G-quadruplex aggregates was confirmed using separation techniques. When mixed, G-quadruplex and i-motif coexist with the Watson–Crick duplex across a pH range from approximately 3.0 to 6.5.

Conclusions

Two cytosine- and guanine-rich sequences in n-myc gene may form stable i-motif and G-quadruplex structures even in the presence of long loops. pH modulates the equilibria involving the intramolecular structures and the intermolecular Watson–Crick duplex.

General significance

Watson–Crick hairpins located in the intramolecular G-quadruplexes and i-motifs in the promoter regions of oncogenes could play a role in stabilizing these structures.     

Anisotropic intersubunit and inter-ring interactions revealed in the native bullet-shaped chaperonin complex from Thermus thermophilus

Background

The recent morphological studies on chaperonins have revealed that nearly equivalent amount of symmetric GroEL–(GroES)₂ (football-shaped) and asymmetric GroEL–GroES (bullet-shaped) complexes coexist during the chaperonin reaction cycle, which prompted us to reexamine the equatorial split observed for chaperonin from Thermus thermophilus by implementing semi-empirical molecular orbital (MO) calculations, since it is now believed that the symmetric formation is a precursor to the equatorial split.

Methods

Semi-empirical MO calculations were employed to investigate the intersubunit interactions within the bullet-shaped T. thermophilus chaperonin capturing the substrate of folding intermediates. Interaction energies between each cis-GroEL subunit and closely related remaining subunits in cis-GroEL ring, or in trans-GroEL ring across the equatorial plane, and further, interaction energies between each GroES subunit and adjacent subunits in the same GroES ring and in cis-GroEL ring were simulated.

Results

Anisotropic intensities and energy distribution of the subunits were revealed by the calculations, which are consistent with two conformations of the subunits forming cis-GroEL ring as revealed by X-ray crystal structure, and with an anisotropic critical binding site on cis-GroEL ring for chaperonin functioning.

Conclusions

This is the first application of semi-empirical MO calculations to the macromolecular complex of the native bullet-shaped chaperonin (GroEL–GroES–ADP homolog) from T. thermophilus.

General significance

The results also appear to support the occurrence of the equatorial split for T. thermophilus chaperonin observed via electron microscopy, but has not yet been fully observed for Escherichia coli GroEL–GroES system.     

Identification of the amino acid residues involved in the hemolytic activity of the Cucumaria echinata lectin CEL-III

Background

CEL-III is a hemolytic lectin isolated from the sea cucumber Cucumaria echinata that shows Ca^2 +-dependent Gal/GalNAc-binding specificity. This lectin is composed of two carbohydrate-recognition domains (domains 1 and 2) and an oligomerization domain (domain 3) that facilitates CEL-III assembly in the target cell membrane to form ion-permeable pores.

Methods

Several amino acid residues in domain 3 were replaced by alanine, and hemolytic activity of the mutants was examined.

Results

K344A, K351A, K405A, K420A and K425A showed marked increases in activity. In particular, K405A had activity that was 360-fold higher than the wild-type recombinant CEL-III and 3.6-fold higher than the native protein purified from sea cucumber. Since these residues appear to play roles in the stabilization of domain 3 through ionic and hydrogen bonding interactions with other residues, the mutations of these residues presumably lead to destabilization of domain 3, which consequently induces the oligomerization of the protein through association of domain 3 in the membrane. In contrast, K338A, R378A and R408A mutants exhibited a marked decrease in hemolytic activity. Since these residues are located on the surface of domain 3 without significant interactions with other residue, they may be involved in the interaction with components of the target cell membrane.

Conclusions

Several amino acid residues, especially basic residues, are found to be involved in the hemolytic activity as well as the oligomerization ability of CEL-III.

General significance

The results provide important clues to the membrane pore-forming mechanism of CEL-III, which is also related to that of bacterial pore-forming toxins.     

Disulfide-bonded multimers of proteoglycan 4 (PRG4) are present in normal synovial fluids

Background

The proteoglycan 4 (PRG4) gene encodes for a mucin-like O-linked glycosylated protein with several names, including lubricin and superficial zone protein. The objective of this study was to analyze PRG4 in normal bovine calf and steer synovial fluids for evidence of native multimers formed by intermolecular disulfide bonds.

Methods

A combination of mucin biochemical techniques, with antibodies to both terminal domains and the mucin-like domain of PRG4, were used for analyses.

Results

Multimers were present in both calf and steer fluids, and reduction and alkylation converts the multimeric complex (likely dimeric) into monomeric subunits. Tandem mass spectrometry analyses supported the Western blot data and identified PRG4 in the reduced ∼ 345 kDa monomeric form. Interestingly, ∼ 70 kDa fragments released upon reduction contained peptides from both the N and C terminal regions, which most likely represent fragments of a sparsely glycosylated PRG4 population that are disulfide-linked to extensively glycosylated, intact monomers.

Conclusions

The analyses described here have demonstrated the presence of native disulfide-bonded multimers of PRG4 in normal bovine synovial fluids.

General significance

These structures are similar to those described for multimerization of mucins in general. Such multimerization and proteolytic cleavage of PRG4 may have functional significance in joint health and disease.     

Cysteine endoprotease activity of human ribosomal protein S4 is entirely due to the C-terminal domain,and is consistent with Michaelis–Menten mechanism

Background

It is known that tandem domains of enzymes can carry out catalysis independently or by collaboration. In the case of cysteine proteases, domain sequestration abolishes catalysis because the active site residues are distributed in both domains. The validity of this argument is tested here by using isolated human ribosomal protein S4, which has been recently identified as an unorthodox cysteine protease.

Methods

Cleavage of the peptide substrate Z-FR↓-AMC catalyzed by recombinant C-terminal domain of human S4 (CHS4) is studied by fluorescence-monitored steady-state and stopped-flow kinetic methods. Proteolysis and autoproteolysis were analyzed by electrophoresis.

Results

The CHS4 domain comprised of sequence residues 116–263 has been cloned and ovreexpressed in Escherichia coli. The purified domain is enzymatically active. Barring minor differences, steady-state kinetic parameters for catalysis by CHS4 are very similar to those for full-length human S4. Further, stopped-flow transient kinetics of pre-steady-state substrate binding shows that the catalytic mechanism for both full-length S4 and CHS4 obeys the Michaelis–Menten model adequately. Consideration of the evolutionary domain organization of the S4e family of ribosomal proteins indicates that the central domain (residues 94–170) within CHS4 is indispensable.

Conclusion

The C-terminal domain can carry out catalysis independently and as efficiently as the full-length human S4 does.

Significance

Localization of the enzyme function in the C-terminal domain of human S4 provides the only example of a cysteine endoprotease where substrate-mediated intramolecular domain interaction is irrelevant for catalytic activity.     

A novel synthetic luteinizing hormone-releasing hormone (LHRH) analogue coupled with modified β-cyclodextrin: Insight into its intramolecular interactions

Background

Cyclodextrins (CDs) in combination with therapeutic proteins and other bioactive compounds have been proposed as candidates that show enhanced chemical and enzymatic stability, better absorption, slower plasma clearance and improved dose–response curves or immunogenicity. As a result, an important number of therapeutic complexes between cyclodextrins and bioactive compounds capable to control several diseases have been developed.

Results

In this article, the synthesis and the structural study of a conjugate between a luteinizing hormone-releasing hormone (LHRH) analogue, related to the treatment of hormone dependent cancer and fertility, and modified β-cyclodextrin residue are presented. The results show that both the phenyl group of tyrosine (Tyr) as well as the indole group of tryptophan (Trp) can be encapsulated inside the cyclodextrin cavity. Solution NMR experiments provide evidence that these interactions take place intramolecularly and not intermolecularly.

Conclusions

The study of a LHRH analogue conjugated with modified β-cyclodextrin via high field NMR and MD experiments revealed the existence of intramolecular interactions that could lead to an improved drug delivery.

General significance

NMR in combination with MD simulation is of great value for a successful rational design of peptide–cyclodextrin conjugates showing stability against enzymatic proteolysis and a better pharmacological profile.     

Subunit interactions in pig-kidney fructose-1,6-bisphosphatase: Binding of substrate induces a second class of site with lowered affinity and catalytic activity

Background

Fructose-1,6-bisphosphatase, a major enzyme of gluconeogenesis, is inhibited by AMP, Fru-2,6-P₂ and by high concentrations of its substrate Fru-1,6-P₂. The mechanism that produces substrate inhibition continues to be obscure.

Methods

Four types of experiments were used to shed light on this: (1) kinetic measurements over a very wide range of substrate concentrations, subjected to detailed statistical analysis; (2) fluorescence studies of mutants in which phenylalanine residues were replaced by tryptophan; (3) effect of Fru-2,6-P₂ and Fru-1,6-P₂ on the exchange of subunits between wild-type and Glu-tagged oligomers; and (4) kinetic studies of hybrid forms of the enzyme containing subunits mutated at the active site residue tyrosine-244.

Results

The kinetic experiments with the wild-type enzyme indicate that the binding of Fru-1,6-P₂ induces the appearance of catalytic sites with lower affinity for substrate and lower catalytic activity. Binding of substrate to the high-affinity sites, but not to the low-affinity sites, enhances the fluorescence emission of the Phe219Trp mutant; the inhibitor, Fru-2,6-P₂, competes with the substrate for the high-affinity sites. Binding of substrate to the low-affinity sites acts as a “stapler” that prevents dissociation of the tetramer and hence exchange of subunits, and results in substrate inhibition.

Conclusions

Binding of the first substrate molecule, in one dimer of the enzyme, produces a conformational change at the other dimer, reducing the substrate affinity and catalytic activity of its subunits.

General significance

Mimics of the substrate inhibition of fructose-1,6-bisphosphatase may provide a future option for combatting both postprandial and fasting hyperglycemia.     

Complementation of intramolecular interactions for structural–functional stability of plant serine proteinase inhibitors

Background

Plant protease inhibitors (PIs) constitute a diverse group of proteins capable of inhibiting proteases. Among PIs, serine PIs (SPIs) display stability and conformational restrictions of the reactive site loop by virtue of their compact size, and by the presence of disulfide bonds, hydrogen bonds, and other weak interactions.

Scope of review

The significance of various intramolecular interactions contributing to protein folding mechanism and their role in overall stability and activity of SPIs is discussed here. Furthermore, we have reviewed the effect of variation or manipulation of these interactions on the activity/stability of SPIs.

Major conclusions

The selective gain or loss of disulfide bond(s) in SPIs can be associated with their functional differentiation, which is likely to be compensated by non-covalent interactions (hydrogen bonding or electrostatic interactions). Thus, these intramolecular interactions are collectively responsible for the functional activity of SPIs, through the maintenance of scaffold framework, conformational rigidity and shape complementarities of reactive site loop.

General significance

Structural insight of these interactions will provide an in-depth understanding of kinetic and thermodynamic parameters involved in the folding and stability mechanisms of SPIs. These features can be explored for engineering canonical SPIs for optimizing their overall stability and functionality for various applications.     

Molecular basis of thermal stability in truncated (2/2) hemoglobins

Background

Understanding the molecular mechanism through which proteins are functional at extreme high and low temperatures is one of the key issues in structural biology. To investigate this phenomenon, we have focused on two instructive truncated hemoglobins from Thermobifida fusca (Tf-trHbO) and Mycobacterium tuberculosis (Mt-trHbO); although the two proteins are structurally nearly identical, only the former is stable at high temperatures.

Methods

We used molecular dynamics simulations at different temperatures as well as thermal melting profile measurements of both wild type proteins and two mutants designed to interchange the amino acid residue, either Pro or Gly, at E3 position.

Results

The results show that the presence of a Pro at the E3 position is able to increase (by 8°) or decrease (by 4°) the melting temperature of Mt-trHbO and Tf-trHbO, respectively. We observed that the ProE3 alters the structure of the CD loop, making it more flexible.

Conclusions

This gain in flexibility allows the protein to concentrate its fluctuations in this single loop and avoid unfolding. The alternate conformations of the CD loop also favor the formation of more salt-bridge interactions, together augmenting the protein's thermostability.

General significance

These results indicate a clear structural and dynamical role of a key residue for thermal stability in truncated hemoglobins.     

Positional specifity of acetylxylan esterases on natural polysaccharide: An NMR study

Background

Microbial degradation of acetylated plant hemicelluloses involves besides enzymes cleaving the glycosidic linkages also deacetylating enzymes. A detailed knowledge of the mode of action of these enzymes is important in view of the development of efficient bioconversion of plant materials that did not undergo alkaline pretreatment leading to hydrolysis of ester linkages.

Methods

In this work deacetylation of hardwood acetylglucuronoxylan by acetylxylan esterases from Streptomyces lividans (carbohydrate esterase family 4) and Orpinomyces sp. (carbohydrate esterase family 6) was monitored by ¹H-NMR spectroscopy.

Results

The ¹H-NMR resonances of all acetyl groups in the polysaccharide were fully assigned. The targets of both enzymes are 2- and 3-monoacetylated xylopyranosyl residues and, in the case of the Orpinomyces sp. enzyme, also the 2,3-di-O-acetylated xylopyranosyl residues. Both enzymes do not recognize as a substrate the 3-O-acetyl group on xylopyranosyl residues α-1,2-substituted with 4-O-methyl-d-glucuronic acid.

Conclusions

The ¹H-NMR spectroscopy approach to study positional and substrate specificity of AcXEs outlined in this work appears to be a simple way to characterize catalytic properties of enzymes belonging to various CE families.

Significance

The results contribute to development of efficient and environmentally friendly procedures for enzymatic degradation of plant biomass.     

Mutational analysis of NHAoc/NHA2 in Saccharomyces cerevisiae

Background

NHAoc/NHA2 is highly and selectively expressed in osteoclasts and plays a role(s) in normal osteoclast differentiation, apoptosis and bone resorptive function in vitro. Extensive mutational analysis of a bacterial homologue, NhaA, has revealed a number of amino acid residues essential for its activity. Some of these residues are evolutionarily conserved and have been shown to be essential not only for activity of NhaA in bacteria, but also of NHAoc/NHA2 in eukaryotes.

Methods

The salt-sensitive Saccharomyces cerevisiae strain BW31a was used for heterologous expression of mutants of NHAoc/NHA2. Membrane expression of NHAoc/NHA2 was confirmed by confocal microscopy. Intracellular concentration of Na+ (a measure of Na+ antiporter activity) was estimated by atomic absorption spectroscopy. The growth phenotypes of cells expressing NHAoc/NHA2 mutants were studied on YNB agar supplemented with NaCl and by growth curves in YNB broth.

Results

Mutations in amino acid residues V161 and F357 reduced the ability of transfected BW31a cells to remove intracellular sodium and to grow in NaCl-containing medium. Yeast expressing the double mutant F357 F437 cannot grow in 0.4 M NaCl, suggesting that these residues are also essential for antiporter activity.

Conclusions

Evolutionarily conserved amino acids are required for full antiporter function.

General Significance

Mutations in these amino acid residues may impact NHAoc activity and therefore osteoclast function in vitro and in vivo.     

Analyses of non-leucine-rich repeat (non-LRR) regions intervening between LRRs in proteins

Background

Many proteins have LRR (leucine-rich repeat) units interrupted by non-LRRs which we call IR (non-LRR island region).

Methods

We identified proteins containing LRR@IRs (LRRs having IR) by using a new method and then analyzed their natures and distributions.

Results

LRR@IR proteins were found in over two hundred proteins from prokaryotes and from eukaryotes. These are divided into twenty-one different protein families. The IRs occur one to four times in LRR regions and range in length from 5 to 11,265 residues. The IR lengths in Fungi adenylate cyclases (acys) range from 5 to 116 residues; there are 22 LRR repeats. The IRs in Leishmania proteophosphoglycans (ppgs) vary from 105 to 11,265 residues. These results indicate that the IRs evolved rapidly. A group of LRR@IR proteins—LRRC17, chondroadherin-like protein, ppgs, and four Pseudomonas proteins—have a super motif consisting of an LRR block and its adjacent LRR@IR region. This indicates that the entire super motif experienced duplication. The sequence analysis of IRs offers functional similarity in some LRR@IR protein families.

General significance

This study suggests that various IRs and super motifs provide a great variety of structures and functions for LRRs.     

Different activities of the conserved lysine residues in the double-stranded RNA binding domains of RNA helicase A in vitro and in the cell

Background

RNA helicase A regulates a variety of RNA metabolism processes including HIV-1 replication and contains two double-stranded RNA binding domains (dsRBD1 and dsRBD2) at the N-terminus. Each dsRBD contains two invariant lysine residues critical for the binding of isolated dsRBDs to RNA. However, the role of these conserved lysine residues was not tested in the context of enzymatically active full-length RNA helicase A either in vitro or in the cells.

Methods

The conserved lysine residues in each or both of dsRBDs were substituted by alanine in the context of full-length RNA helicase A. The mutant RNA helicase A was purified from mammalian cells. The effects of these mutations were assessed either in vitro upon RNA binding and unwinding or in the cell during HIV-1 production upon RNA helicase A–RNA interaction and RNA helicase A-stimulated viral RNA processes.

Results

Unexpectedly, the substitution of the lysine residues by alanine in either or both of dsRBDs does not prevent purified full-length RNA helicase A from binding and unwinding duplex RNA in vitro. However, these mutations efficiently inhibit RNA helicase A-stimulated HIV-1 RNA metabolism including the accumulation of viral mRNA and tRNA^Lys3 annealing to viral RNA. Furthermore, these mutations do not prevent RNA helicase A from binding to HIV-1 RNA in vitro as well, but dramatically reduce RNA helicase A–HIV-1 RNA interaction in the cells.

Conclusions

The conserved lysine residues of dsRBDs play critical roles in the promotion of HIV-1 production by RNA helicase A.

General significance

The conserved lysine residues of dsRBDs are key to the interaction of RNA helicase A with substrate RNA in the cell, but not in vitro.     

Identification of potential protein dithiol-disulfide substrates of mammalian Grx2

Background

Glutaredoxins (Grxs) catalyze the reduction of protein disulfides via the dithiol mechanism and the de-/glutathionylation of substrates via the monothiol mechanism. These rapid, specific, and generally also reversible modifications are part of various signaling cascades regulating for instance cell proliferation, differentiation and apoptosis. Even though crucial functions of the conserved, mitochondrial Grx2a and the cytosolic/nuclear Grx2c isoforms have been proposed, only a few substrates have been identified in vitro or in vivo. The significance of redox signaling is emerging, yet a general lack of methods for the time-resolved analysis of these distinct and rapid modifications in vivo constitutes the biggest challenge in the redox signaling field.

Methods and results

Here, we have identified potential interaction partners for Grx2 isoforms in human HeLa cells and mouse tissues by an intermediate trapping approach. Some of the 50 potential substrates are part of the cytoskeleton or act in protein folding, cellular signaling and metabolism. Part of these interactions were further verified by immunoprecipitation or a newly established 2-D redox blot.

Conclusions

Our study demonstrates that Grx2 catalyzes both the specific oxidation and the reduction of cysteinyl residues in the same compartment at the same time and without affecting the global cellular thiol-redox state.

General significance

The knowledge of specific targets will be helpful in understanding the functions of Grx2. The 2-D redox blot may be useful for the analysis of the overall thiol-redox state of proteins with high molecular weight and numerous cysteinyl residues, that evaded analysis by previously described methods.     

The allosteric modulation of thyroxine-binding globulin affinity is entropy driven

Background

Thyroxine-binding globulin (TBG) is a non-inhibitory member of the serpin family of proteins whose main structural element is the reactive center loop (RCL), that, upon cleavage by proteases, is inserted into the protein core adopting a β-strand conformation (stressed to relaxed transition, S-to-R). After S-to-R transition thyroxine (T4) affinity decreases. However, crystallographic studies in the presence or absence of the hormone in different states are unable to show significant differences in the structure and interactions of the binding site. Experimental results also suggest the existence of several S states (differing in the number of inserted RCL residues), associated with a differential affinity.

Methods

To shed light into the molecular basis that regulates T4 affinity according to the degree of RCL insertion in TBG, we performed extended molecular dynamics simulations combined with several thermodynamic analysis of the T4 binding to TBG in three different S states, and in the R state.

Results

Our results show that, despite T4 binding in the protein by similar interactions in all states, a good correlation between the degree of RCL insertion and the binding affinity, driven by a change in TBG conformational entropy, was observed.

Conclusion

TBG allosteric regulation is entropy driven. The presence of multiple S states may allow more efficient T4 release due to protease activity.

General significance

The presented results are clear examples of how computer simulation methods can reveal the thermodynamic basis of allosteric effects, and provide a general framework for understanding serpin allosteric affinity regulation.