Differences in activity between alpha and beta type I interferons explored by mutational analysis

Type I interferon (IFN) subtypes alpha and beta share a common multicomponent, cell surface receptor and elicit a similar range of biological responses, including antiviral, antiproliferative, and immunomodulatory activities. However, alpha and beta IFNs exhibit key differences in several biological properties. For example, IFN-beta, but not IFN-alpha, induces the association of tyrosine-phosphorylated receptor components ifnar1 and ifnar2, and has activity in cells lacking the IFN receptor-associated, Janus kinase tyk2. To define the structural basis for these functional differences we produced human IFN-beta with point mutations and compared them to wild-type IFN-beta in assays that distinguish alpha and beta IFN subtypes. IFN-beta mutants with charged residues (N86K, N86E, or Y92D) introduced at two positions in the C helix lost the ability to induce the association of tyrosine-phosphorylated receptor chains and had reduced activity on tyk2-deficient cells. The combination of negatively charged residues N86E and Y92D (homologous with IFN-alpha8) increased the cross-species activity of the mutant IFN-betas on bovine cells to a level comparable to that of human IFN-alphas. In contrast, point mutations in the AB loop and D helix had no significant effect on these subtype-specific activities. A subset of these latter mutations did, however, reduce activity in a manner analogous to IFN-alpha mutations. The effects of these mutations on IFN-beta activity are discussed in the context of a family of related ligands acting through a common receptor and signaling pathway.     

Structural characterisation of N-linked and O-linked oligosaccharides derived from interferon-alpha2b and interferon-alpha14c produced by Sendai-virus-induced human peripheral blood leukocytes

We have previously isolated and partially characterised the components of a highly purified interferon-alpha (IFN-alpha) preparation produced by Sendai-virus-induced human peripheral blood leukocytes. Nine IFN-alpha species were identified, and two of these were found to be glycosylated [Nyman, T. A., T?l?, H., Parkkinen, J. & Kalkkinen, N. (1998) Identification of nine interferon-alpha subtypes produced by Sendai-virus-induced human peripheral blood leukocytes, Biochem. J. 329, 295-302]. Here, we isolated the N-linked oligosaccharides of IFN-alpha14c and the O-linked chains of IFN-alpha2b, and the glycans were characterised by electrospray tandem mass spectrometry and by specific glycosidase digestions monitored by matrix-assisted laser desorption ionisation time of flight mass spectrometry. The IFN-alpha14c N-glycans were shown to exhibit core-fucosylated biantennary glycans, with about 10% carrying an additional alpha1,3-linked fucose unit at the antennae. The IFN-alpha2b was shown to carry about 50% core type-1 disialyltetrasaccharides, 30% core type-1 monosialyltrisaccharides and 20% core type-2 monosialylpentasaccharides.     

Solution structure of a GAAA tetraloop receptor RNA

The GAAA tetraloop receptor is an 11-nucleotide RNA sequence that participates in the tertiary folding of a variety of large catalytic RNAs by providing a specific binding site for GAAA tetraloops. Here we report the solution structure of the isolated tetraloop receptor as solved by multidimensional, heteronuclear magnetic resonance spectroscopy. The internal loop of the tetraloop receptor has three adenosines stacked in a cross-strand or zipper-like fashion. This arrangement produces a high degree of base stacking within the asymmetric internal loop without extrahelical bases or kinking the helix. Additional interactions within the internal loop include a U. U mismatch pair and a G.U wobble pair. A comparison with the crystal structure of the receptor RNA bound to its tetraloop shows that a conformational change has to occur upon tetraloop binding, which is in good agreement with previous biochemical data. A model for an alternative binding site within the receptor is proposed based on the NMR structure, phylogenetic data and previous crystallographic structures of tetraloop interactions.     

Extensive mutagenesis of the hepatitis B virus core gene and mapping of mutations that allow capsid formation

We generated a large number of mutations in the hepatitis B virus (HBV) core gene inserted into a bacterial expression vector. The new mutagenesis procedure generated deletions and insertions (as sequence repeats) of various lengths at random positions between M1 and E145 but not substitutions. The R-rich 30-amino-acid C-terminal domain was not analyzed. A total of 50,000 colonies were tested with a polyclonal human serum for the expression of hepatitis B core or e antigen. A total of 110 mutants randomly chosen from 1,500 positive colonies were genotyped. Deletions and insertions were clustered in four regions: D2 to E14, corresponding to the N-terminal loop in a model for the core protein fold (B. Bottcher, S. A. Wynne, and R. A. Crowther, Nature 386:88-91, 1997); V27 to P50 (second loop); L60 to V86 (upper half of the alpha helix forming the N-terminal part of the spike and the tip of the spike); and V124 to L140 (C-terminal part of the C-terminal helix and downstream loop). Deletions or insertions in the remaining parts of the molecule forming the compact center of the fold seemed to destabilize the protein. Of the 110 mutations, 38 allowed capsid formation in Escherichia coli. They mapped exclusively to nonhelical regions of the proposed fold. The mutations form a basis for subsequent analysis of further functions of the HBV core protein in the viral life cycle.     

The antigenic structure of the HIV gp120 envelope glycoprotein

The human immunodeficiency virus HIV-1 establishes persistent infections in humans which lead to acquired immunodeficiency syndrome (AIDS). The HIV-1 envelope glycoproteins, gp120 and gp41, are assembled into a trimeric complex that mediates virus entry into target cells. HIV-1 entry depends on the sequential interaction of the gp120 exterior envelope glycoprotein with the receptors on the cell, CD4 and members of the chemokine receptor family. The gp120 glycoprotein, which can be shed from the envelope complex, elicits both virus-neutralizing and non-neutralizing antibodies during natural infection. Antibodies that lack neutralizing activity are often directed against the gp120 regions that are occluded on the assembled trimer and which are exposed only upon shedding. Neutralizing antibodies, by contrast, must access the functional envelope glycoprotein complex and typically recognize conserved or variable epitopes near the receptor-binding regions. Here we describe the spatial organization of conserved neutralization epitopes on gp120, using epitope maps in conjunction with the X-ray crystal structure of a ternary complex that includes a gp120 core, CD4 and a neutralizing antibody. A large fraction of the predicted accessible surface of gp120 in the trimer is composed of variable, heavily glycosylated core and loop structures that surround the receptor-binding regions. Understanding the structural basis for the ability of HIV-1 to evade the humoral immune response should assist in the design of a vaccine.     

The adenylation domain of tyrocidine synthetase 1--structural and functional role of the interdomain linker region and the (S/T)GT(T/S)GXPKG core sequence

Sequence analysis of peptide synthetases revealed extensive structure similarity with firefly luciferase, whose crystal structure has recently become available, providing evidence for the localization of the active site at the interface between two subdomains separated by a distorted linker region [Conti, E., Franks, N. P. & Brick, P. (1996) Structure 4, 287-298]. The functional importance of two flexible loops, corresponding to the linker region of firefly luciferase and the highly conserved (S/T)GT(T/S)GXPKG core sequence, has been studied in view of the proposed conformational changes by the use of mutant analysis, limited proteolysis and chemical modification of tyrocidine synthetase 1. Substitution of the highly conserved Arg416, residing in the loop separating the subdomains of the adenylation domain, resulted in profound loss of activity. Limited proteolysis of the mutant suggested significant structural changes as manifested by lack of protection to degradation in the presence of substrates, revealing a probable disturbance of the induced-fit mechanism regulating the transformation from an open to a closed conformation. Mutants, obtained by replacement of the conserved Lys186 from the (S/T)GT(T/S)GXPKG core sequence, displayed only minor differences in substrate-binding affinity despite significant reduction of catalytic efficiency. Residue Lys186 appears to play an important role in either stabilization of the bound substrate through charge-charge-interactions, and/or fixing of the loop for maintainance of the active-site conformation.     

15N NMR relaxation studies of calcium-loaded parvalbumin show tight dynamics compared to those of other EF-hand proteins

Dynamics of the rat alpha-parvalbumin calcium-loaded form have been determined by measurement of 15N nuclear relaxation using proton-detected heteronuclear NMR spectroscopy. The relaxation data were analyzed using spectral density functions and the Lipari-Szabo formalism. The major dynamic features for the rat alpha-parvalbumin calcium-loaded form are (1) the extreme rigidity of the helix-loop-helix EF-hand motifs and the linker segment connecting them, (2) the N and C termini of the protein being restricted in their mobility, (3) a conformational exchange occurring at the kink of helix D, and (4) the residue at relative position 2 in the Ca2+-binding sites having an enhanced mobility. Comparison of the Ca2+-binding EF-hand domains of alpha-parvalbumin-Ca2+, calbindin-Ca2+, and calmodulin-Ca2+ shows that parvalbumin is probably the most rigid of the EF-hand proteins. It also illustrates the dynamical properties which are conserved in the EF-hand domains from different members of this superfamily: (1) a tendency toward higher mobility of NH vectors at relative position 2 in the Ca2+-binding loop, (2) a restricted mobility for the other residues in the binding loop, and (3) an overall rigidity for the helices of EF-hand motifs. The differences in mobility between parvalbumin and the two EF-hand proteins occur mainly at the linker connecting the pair of EF hands and also at the C terminus of the last helix. In parvalbumin-Ca2+, these two regions are characterized by a pronounced rigidity compared to the corresponding more mobile regions in calbindin-Ca2+ and calmodulin-Ca2+.     

Viability and survival of hNT neurons determine degree of functional recovery in grafted ischemic rats

Histone macroH2A is an unusual core histone that contains a large non-histone region, and a region that resembles a full length H2A. We examined theconservation of this novel structural arrangement by cloning chicken macroH2A cDNAs and comparing them to their rat counterparts. The amino acid sequences of the two known macroH2A subtypes are >95% identical between these species despite evolutionary separation of approximately 300 million years. The H2A region of macroH2A is completely conserved, and thus is even more conserved than conventional H2A in these species. The origin of the non-histone domain was examined by comparing its sequence to proteins found in bacteria and RNA viruses. These comparisons indicate that this domain is derived from a gene that originated prior to the appearance of eukaryotes, and suggest that the non-histone region has retained the basic function of its ancestral gene.     

Non-canonical interactions in a kissing loop complex: the dimerization initiation site of HIV-1 genomic RNA

Retroviruses encapsidate two molecules of genomic RNA that are noncovalently linked close to their 5' ends in a region called the dimer linkage structure (DLS). The dimerization initiation site (DIS) of human immunodeficiency virus type 1 (HIV-1) constitutes the essential part of the DLS in vitro and is crucial for efficient HIV-1 replication in cell culture. We previously identified the DIS as a hairpin structure, located upstream of the major splice donor site, that contains in the loop a six-nucleotide self-complementary sequence preceded and followed by two and one purines, respectively. Two RNA monomers form a kissing loop complex via intermolecular interactions of the six nucleotide self-complementary sequence. Here, we introduced compensatory mutations in the self-complementary sequence and/or a mutation in the flanking purines. We determined the kinetics of dimerization, the thermal stabilities and the apparent equilibrium dissociation constants of wild-type and mutant dimers and used chemical probing to obtain structural information. Our results demonstrate the importance of the 5'-flanking purine and of the two central bases of the self-complementary sequence in the dimerization process. The experimental data are rationalized by triple interactions between these residues in the deep groove of the kissing helix and are incorporated into a three-dimensional model of the kissing loop dimer. In addition, chemical probing and molecular modeling favor the existence of a non-canonical interaction between the conserved adenine residues at the first and last positions in the DIS loop. Furthermore, we show that destabilization of the kissing loop complex at the DIS can be compensated by interactions involving sequences located downstream of the splice donor site of the HIV-1 genomic RNA.     

Structural basis for binding of the plasmid ColIb-P9 antisense Inc RNA to its target RNA with the 5'-rUUGGCG-3' motif in the loop sequence

The sequence 5'-rUUGGCG-3' is conserved within the loop regions of antisense RNAs or their targets involved in replication of various prokaryotic plasmids. In IncIalpha plasmid ColIb-P9, the partially base paired 21-nucleotide loop of a stem-loop called structure I within RepZ mRNA contains this hexanucleotide sequence, and comprises the target site for the antisense Inc RNA. In this report, we find that the base pairing interaction at the 5'-rGGC-3' sequence in the hexanucleotide motif is important for interaction between Inc RNA and structure I. In addition, the 21-base loop domain of structure I is folded tighter than predicted, with the hexanucleotide sequence at the top. The second U residue in the sequence is favored for Inc RNA binding in a base-specific manner. On the other hand, the upper domain of the Inc RNA stem-loop is loosely structured, and maintaining the loop sequence single-stranded is important for the intermolecular interaction. Based on these results, we propose that a structural feature in the loop I domain, conferred probably by the conserved 5'-rUUGGCG-3' sequence, favors binding to a complementary, single-stranded RNA. This model also explains how the RepZ mRNA pseudoknot, described in the accompanying paper (Asano, K., and Mizobuchi, K. (1998) J. Biol. Chem. 273, 11815-11825) is formed specifically with structure I. A possible conformation adopted by the 5'-rUUGGCG-3' loop sequence is discussed.     

The organization of human leucocyte antigen class I epitopes in HIV genome products: implications for HIV evolution and vaccine design

Knowledge of human leucocyte antigen (HLA) peptide binding motifs permits rapid selection of candidate viral protein fragments for induction of T cell-mediated immunity. A search for HLA class I peptide binding motifs in structural proteins of human immunodeficiency virus (HIV) of different genetic lineages provides a map of the genetic organization of potential T cell antigenic sites, and at the same time identifies all motifs in highly conserved regions of HIV-1 env, gag and pol. The density of motifs is anomalous at both the high and low end of the spectrum: local organization is characterized by clustering in relatively short regions, while large scale organization is characterized by anomalously long runs between motifs. The former is expected simply due to the fact that motifs often have overlapping anchor residue sets. A detailed statistical analysis of the latter, however, shows that the length of the runs cannot be accounted for by chance alone. Although motif clusters show no preference to be in either conserved or variable regions, low motif density stretches occur preferentially in variable portions of the protein sequence, which suggests that the virus may be mutating to evade the cellular arm of the immune system.     

Structure and function of Cerebratulus lacteus neurotoxin B-IV: tryptophan-30 is critical for function while lysines-18, -19, -29, and -33 are not required

The Cerebratulus lacteus B-toxins are a family of polypeptide neurotoxins known to bind to crustacean voltage-sensitive sodium channels. We have previously shown that in the most abundant homolog, toxin B-IV, Arg-17 in the N-terminal helix and a positive charge at position 25 in the loop region are essential for function. In this report, we target a tryptophan residue at position 30, as well as lysine residues found in both the N-terminal helix and loop regions by polymerase chain reaction mutagenesis, to determine their contributions to toxin activity. Substitution of Trp-30 with a serine causes a more than 40-fold reduction in specific toxicity, whereas replacement by tyrosine and phenylalanine is well tolerated. The secondary structures of both these muteins are identical to that of the wild-type toxin as determined by circular dichroism spectroscopy. Thermal denaturation experiments also show that their conformational stabilities are intact. These results demonstrate that an aromatic residue at this position is required for toxin function. Charge neutralizing substitutions of Lys-18 and Lys-19 located in the N-terminal helix have very little effect on toxicity, suggesting the nonessentiality of these residues. Similar results are also obtained for the charge neutralizing muteins for Lys-29 and Lys-33 in the loop region. Interestingly, reduction experiments demonstrate that both K29N and W30S are more sensitive to reducing agent than wild-type B-IV, raising the possibility that the loop sequence may modulate toxin stability.     

Derivation of the three-dimensional architecture of bacterial ribonuclease P RNAs from comparative sequence analysis

The secondary structure of bacterial RNase P RNA, a ribozyme responsible for the maturation of the 5' end of tRNAs, is well established on the basis of sequence comparison analysis. RNase P RNA secondary structures fall into two types, A and B, which share a common core formed by the assembly of two main folding domains, but differ in their peripheral elements.A revised alignment of 137 available sequences reveals new covariations allowing for the refinement of both types of secondary structures. Phylogenetic evidence is thus provided for the extension of stems P11, P14, P19, P10.1 and P15.1 through further canonical base-pairs or GAellipsisGA mismatches. These refinements led in turn to a new organization of the catalytic core, with coaxial stackings of helices P2 and P19 as well as P1 and P4. New inter-domain tertiary interactions involve loop L9 and helix P1 and loop L8 with helix P4. These features were incorporated into atomic-scale 3D models of RNase P RNA for representatives of each structural type, namely Escherichia coli and Bacillus subtilis. In each model, the juxtaposition of the core helices creates a cradle onto which the pre-tRNA substrate binds with most evolutionarily conserved residues converging towards the cleavage site. The inner cores of both types are stabilized similarly, albeit by different peripheral elements, emphasizing the modular and hierarchical organisation of the architecture of RNase P RNAs. Similarities are thus apparent between the type A modules, P16/P17/P6 and P13/P14, and their type B analogs, P5.1/P15.1 and P10. 1/P10.1a, respectively. Other noteworthy features of these models include compactness and good agreement with published crosslinking data.     

Geometrical and sequence characteristics of alpha-helices in globular proteins

Understanding the sequence-structure relationships in globular proteins is important for reliable protein structure prediction and de novo design. Using a database of 1131 alpha-helices with nonidentical sequences from 205 nonhomologous globular protein chains, we have analyzed structural and sequence characteristics of alpha-helices. We find that geometries of more than 99% of all the alpha-helices can be simply characterised as being linear, curved, or kinked. Only a small number of alpha-helices ( approximately 4%) show sharp localized bends in their middle regions, and thus are classified as kinked. Approximately three-fourths (approximately 73%) of the alpha-helices in globular proteins show varying degrees of smooth curvature, with a mean radius of curvature of 65 +/- 33 A; longer helices are less curved. Computation of helix accessibility to the solvent indicates that nearly two-thirds of the helices ( approximately 66%) are largely buried in the protein core, and the length and geometry of the helices are not correlated with their location in the protein globule. However, the amino acid compositions and propensities of individual amino acids to occur in alpha-helices vary with their location in the protein globule, their geometries, and their lengths. In particular, Gln, Glu, Lys, and Arg are found more often in helices near the surface of globular proteins. Interestingly, kinks often seem to occur in regions where amino acids with low helix propensities (e.g., beta-branched and aromatic residues) cluster together, in addition to those associated with the occurrence of proline residues. Hence the propensities of individual amino acids to occur in a given secondary structure depend not only on conformation but also on its length, geometry, and location in the protein globule.     

Dopamine receptor subtypes expressed in vertebrate (carp and eel) retinae: cloning, sequencing and comparison of five D1-like and three D2-like receptors

Eight dopamine receptor-like cDNA clones were isolated from the carp (Cyprinus carpio) retina and four dopamine receptor-like cDNA clones were isolated from the European eel (Anguilla anguilla) retina. These cDNA clones show high sequence and structural homology to the known dopamine receptor subtypes. The sequence similarity and phylogenetic analysis revealed that five subtypes (D1A3, D1A4, D1B, D1C and D1X) in the carp retina and four subtypes (D1A1, D1A2, D1B and D1C) in the eel retina are D1-like receptor subtypes, and three (D2, D4A and D4B) in the carp retina are D2-like receptor subtypes; no D2-like receptor was found in the eel. Carp D1A3 and D1A4, carp D4A and D4B, and eel D1A1 and D1A2 are highly homologous pairs of receptors which show significant, domain-specific differences to each other and to their species homologues. The structure of the third cytoplasmic loop in the carp D1X receptor was particularly different from the other D1-like receptors. The implications of these structural differences in terms of dopamine receptor activation and signalling are discussed. It is suggested that the known diverse physiological and pharmacological effects of dopamine on the retinal neurones are likely to be mediated through these multiple receptor subtypes which may be coupled to different signal transduction pathways.     

Invariant U2 RNA sequences bordering the branchpoint recognition region are essential for interaction with yeast SF3a and SF3b subunits

U2 small nuclear RNA (snRNA) contains a sequence (GUAGUA) that pairs with the intron branchpoint during splicing. This sequence is contained within a longer invariant sequence of unknown secondary structure and function that extends between U2 and I and stem IIa. A part of this region has been proposed to pair with U6 in a structure called helix III. We made mutations to test the function of these nucleotides in yeast U2 snRNA. Most single base changes cause no obvious growth defects; however, several single and double mutations are lethal or conditional lethal and cause a block before the first step of splicing. We used U6 compensatory mutations to assess the contribution of helix III and found that if it forms, helix III is dispensable for splicing in Saccharomyces cerevisiae. On the other hand, mutations in known protein components of the splicing apparatus suppress or enhance the phenotypes of mutations within the invariant sequence that connect the branchpoint recognition sequence to stem IIa. Lethal mutations in the region are suppressed by Cus1-54p, a mutant yeast splicing factor homologous to a mammalian SF3b subunit. Synthetic lethal interactions show that this region collaborates with the DEAD-box protein Prp5p and the yeast SF3a subunits Prp9p, Prp11p, and Prp21p. Together, the data show that the highly conserved RNA element downstream of the branchpoint recognition sequence of U2 snRNA in yeast cells functions primarily with the proteins that make up SF3 rather than with U6 snRNA.     

A model of the quaternary structure of enolases, based on structural and evolutionary analysis of the octameric enolase from Bacillus subtilis

Purified enolase from Bacillus subtilis has a native mass of approximately 370 kDa. Since B. subtilis enolase was found to have a subunit mass of 46.58 kDa, the quaternary structure of B. subtilis is octameric. The pl for B. subtilis enolase is 6.1, the pH optimum (pHo) for activity is 8.1-8.2, and the Km for 2-PGA is approximately 0.67 mM. Using the dimeric Calpha structure of yeast dimeric enolase as a guide, these dimers were arranged as a tetramer of dimers to simulate the electron microscopy image processing obtained for the octameric enolase purified from Thermotoga maritima. This arrangement allowed identification of helix J of one dimer (residues 86-96) and the loop between helix L and strand 1 (HL-S1 loop) of another dimer as possible subunit interaction regions. Alignment of available enolase amino acid sequences revealed that in 16 there are two tandem glycines at the C-terminal end of helix L and the HL-S1 loop is truncated by 4-6 residues relative to the yeast polypeptide, two structural features absent in enolases known to be dimers. From these arrangements and alignments it is proposed that the GG tandem at the C-terminal end of helix L and truncation of the HL-S1 loop may play a critical role in octamer formation of enolases. Interestingly, the sequence features associated with dimeric quaternary structure are found in three phylogenetically disparate groups, suggesting that the ancestral enolase was an octamer and that the dimeric structure has arisen independently multiple times through evolutionary history.