N-Terminal Domain of Nuclear IL-1α Shows Structural Similarity to the C-Terminal Domain of Snf1 and Binds to the HAT/Core Module of the SAGA Complex

Interleukin-1α (IL-1α) is a proinflammatory cytokine and a key player in host immune responses in higher eukaryotes. IL-1α has pleiotropic effects on a wide range of cell types, and it has been extensively studied for its ability to contribute to various autoimmune and inflammation-linked disorders, including rheumatoid arthritis, Alzheimer's disease, systemic sclerosis and cardiovascular disorders. Interestingly, a significant proportion of IL-1α is translocated to the cell nucleus, in which it interacts with histone acetyltransferase complexes. Despite the importance of IL-1α, little is known regarding its binding targets and functions in the nucleus. We took advantage of the histone acetyltransferase (HAT) complexes being evolutionarily conserved from yeast to humans and the yeast SAGA complex serving as an epitome of the eukaryotic HAT complexes. Using gene knock-out technique and co-immunoprecipitation of the IL-1α precursor with TAP-tagged subunits of the yeast HAT complexes, we mapped the IL-1α-binding site to the HAT/Core module of the SAGA complex. We also predicted the 3-D structure of the IL-1α N-terminal domain, and by employing structure similarity searches, we found a similar structure in the C-terminal regulatory region of the catalytic subunit of the AMP-activated/Snf1 protein kinases, which interact with HAT complexes both in mammals and yeast, respectively. This finding is further supported with the ability of the IL-1α precursor to partially rescue growth defects of snf1Δ yeast strains on media containing 3-Amino-1,2,4-triazole (3-AT), a competitive inhibitor of His3. Finally, the careful evaluation of our data together with other published data in the field allows us to hypothesize a new function for the ADA complex in SAGA complex assembly.     

Structural and Functional Characterization of an Anesthetic Binding Site in the Second Cysteine-Rich Domain of Protein Kinase Cδ?

Elucidating the principles governing anesthetic-protein interactions requires structural determinations at high resolutions not yet achieved with ion channels. Protein kinase C (PKC) activity is modulated by general anesthetics. We solved the structure of the phorbol-binding domain (C1B) of PKCδ complexed with an ether (methoxymethylcycloprane) and with an alcohol (cyclopropylmethanol) at 1.36-Å resolution. The cyclopropane rings of both agents displace a single water molecule in a surface pocket adjacent to the phorbol-binding site, making van der Waals contacts with the backbone and/or side chains of residues Asn-237 to Ser-240. Surprisingly, two water molecules anchored in a hydrogen-bonded chain between Thr-242 and Lys-260 impart elasticity to one side of the binding pocket. The cyclopropane ring takes part in π-acceptor hydrogen bonds with the amide of Met-239. There is a crucial hydrogen bond between the oxygen atoms of the anesthetics and the hydroxyl of Tyr-236. A Tyr-236-Phe mutation results in loss of binding. Thus, both van der Waals interactions and hydrogen-bonding are essential for binding to occur. Ethanol failed to bind because it is too short to benefit from both interactions. Cyclopropylmethanol inhibited phorbol-ester-induced PKCδ activity, but failed to do so in PKCδ containing the Tyr-236-Phe mutation.     

Testing the Role of Climate Change in Species Decline: Is the Eastern Quoll a Victim of a Change in the Weather?

To conserve a declining species we first need to diagnose the causes of decline. This is one of the most challenging tasks faced by conservation practitioners. In this study, we used temporally explicit species distribution models (SDMs) to test whether shifting weather can explain the recent decline of a marsupial carnivore, the eastern quoll (Dasyurus viverrinus). We developed an SDM using weather variables matched to occurrence records of the eastern quoll over the last 60 years, and used the model to reconstruct variation through time in the distribution of climatically suitable range for the species. The weather model produced a meaningful prediction of the known distribution of the species. Abundance of quolls, indexed by transect counts, was positively related to the modelled area of suitable habitat between 1990 and 2004. In particular, a sharp decline in abundance from 2001 to 2003 coincided with a sustained period of unsuitable weather over much of the species’ distribution. Since 2004, abundance has not recovered despite a return to suitable weather conditions, and abundance and area of suitable habitat have been uncorrelated. We suggest that fluctuations in weather account for the species’ recent decline, but other unrelated factors have suppressed recovery.     

TnI Structural Interface with the N-Terminal Lobe of TnC as a Determinant of Cardiac Contractility

The heterotrimeric cardiac troponin complex is a key regulator of contraction and plays an essential role in conferring Ca²⁺ sensitivity to the sarcomere. During ischemic injury, rapidly accumulating protons acidify the myoplasm, resulting in markedly reduced Ca²⁺ sensitivity of the sarcomere. Unlike the adult heart, sarcomeric Ca²⁺ sensitivity in fetal cardiac tissue is comparatively pH insensitive. Replacement of the adult cardiac troponin I (cTnI) isoform with the fetal troponin I (ssTnI) isoform renders adult cardiac contractile machinery relatively insensitive to acidification. Alignment and functional studies have determined histidine 132 of ssTnI to be the predominant source of this pH insensitivity. Substitution of histidine at the cognate position 164 in cTnI confers the same pH insensitivity to adult cardiac myocytes. An alanine at position 164 of cTnI is conserved in all mammals, with the exception of the platypus, which expresses a proline. Prolines are biophysically unique because of their innate conformational rigidity and helix-disrupting function. To provide deeper structure-function insight into the role of the TnC-TnI interface in determining contractility, we employed a live-cell approach alongside molecular dynamics simulations to ascertain the chemo-mechanical implications of the disrupted helix 4 of cTnI where position 164 exists. This important motif belongs to the critical switch region of cTnI. Substitution of a proline at position 164 of cTnI in adult rat cardiac myocytes causes increased contractility independent of alterations in the Ca²⁺ transient. Free-energy perturbation calculations of cTnC-Ca²⁺ binding indicate no difference in cTnC-Ca²⁺ affinity. Rather, we propose the enhanced contractility is derived from new salt bridge interactions between cTnI helix 4 and cTnC helix A, which are critical in determining pH sensitivity and contractility. Molecular dynamics simulations demonstrate that cTnI A164P structurally phenocopies ssTnI under baseline but not acidotic conditions. These findings highlight the evolutionarily directed role of the TnI-cTnC interface in determining cardiac contractility.     

Land Use/Cover Change and the Terrestrial Carbon Cycle in the Asia-Pacific Region

Current atmospheric CO_2 concentrations are the highest on record in the last half a millionyears and are expected to reach between 540 and 970 ppm over the next one hundred years. Thisunprecedented increase is linked to human activities including fossil fuel combustion anddeforestation. The increase in CO_2 concentrations, and to a lesser extent in other greenhouse gases,is linked to changes in climate patterns and variability, and to an average global warming of 0.6℃during the 20th Century (IPCC 2001). Changes in land use and cover are critical controls of the distribution and strength of carbon     

5-Fluorotryptophan-Containing N-Terminal Domain of the α-Subunit of the Torpedo californica Acetylcholine Receptor: Preparation in Escherichia coli and 19F NMR Study

A protein corresponding to the extracellular 1–209 domain of the -subunit of the nicotine acetylcholine receptor from the electric organ of Torpedo californica was prepared using the corresponding cDNA domain by culturing Escherichia coli cells on a synthetic medium supplemented with 5-fluoro-L-tryptophan. The presence of a (His)₆ fragment preceding the 1–209 sequence allowed purification of the protein isolated from inclusion bodies by affinity chromatography on Ni-NTA Agarose. The incorporation of 5-fluorotryptophan residues was found by ¹⁹F NMR to be 50%. The spectrum of the protein reduced in the denaturing conditions and subsequently reoxidized in a dilute solution under denaturing conditions in the presence of 0.05% SDS was sufficiently resolved, which allowed partial assignment of ¹⁹F resonances using the Trp60Phe mutant protein. The ability of the prepared domains to specifically bind snake -neurotoxins was demonstrated with the use of radioiodinated -bungarotoxin and trifluoroacetylated -cobratoxin.     

The Membrane Proximal Region of the Integrin β Cytoplasmic Domain Can Mediate Oligomerization

Integrin-ligand binding generates many intracellular signals, including signals to initiate focal contact formation and to regulate cellular decisions concerning growth and differentiation. Oligomerization of the β subunit cytoplasmic domain appears to be required for many of these events. In order to study these processes, we have generated a novel chimeric protein, consisting of the chicken integrin β₁, cytoplasmic domain connected to the central rod domain of a neuronal intermediate filament, a-internexin. This chimeric protein, when expressed transiently in 293T cells, oligomerizes in a β cytoplasmic domain-dependent manner. This oligomerization requires the membrane proximal amino acids LLMII of the β₁ cytoplasmic domain, as demonstrated by deletion analysis. Therefore, the integrin β cytoplasmic domain in this system contains an oligomerization function, which may provide some insight as to the function of intact integrins in vivo.     

Structural and Mechanical Hierarchies in the α-Crystallin Domain Dimer of the Hyperthermophilic Small Heat Shock Protein Hsp16.5

In biological systems, proteins rarely act as isolated monomers. Association to dimers or higher oligomers is a commonly observed phenomenon. As an example, small heat shock proteins form spherical homo-oligomers of mostly 24 subunits, with the dimeric α-crystallin domain as the basic structural unit. The structural hierarchy of this complex is key to its function as a molecular chaperone. In this article, we analyze the folding and association of the basic building block, the α-crystallin domain dimer, from the hyperthermophilic archaeon Methanocaldococcus jannaschii Hsp16.5 in detail. Equilibrium denaturation experiments reveal that the α-crystallin domain dimer is highly stable against chemical denaturation. In these experiments, protein dissociation and unfolding appear to follow an “all-or-none” mechanism with no intermediate monomeric species populated. When the mechanical stability was determined by single-molecule force spectroscopy, we found that the α-crystallin domain dimer resists high forces when pulled at its termini. In contrast to bulk denaturation, stable monomeric unfolding intermediates could be directly observed in the mechanical unfolding traces after the α-crystallin domain dimer had been dissociated by force. Our results imply that for this hyperthermophilic member of the small heat shock protein family, assembly of the spherical 24mer starts from folded monomers, which readily associate to the dimeric structure required for assembly of the higher oligomer.     

The N-Terminal Actin-Binding Tandem Calponin-Homology (CH) Domain of?Dystrophin Is in a Closed Conformation in Solution and When Bound to?F-actin

Deficiency of the vital muscle protein dystrophin triggers Duchenne/Becker muscular dystrophy, but the structure-function relationship of dystrophin is poorly understood. To date, molecular structures of three dystrophin domains have been determined, of which the N-terminal actin-binding domain (N-ABD or ABD1) is of particular interest. This domain is composed of two calponin-homology (CH) domains, which form an important class of ABDs in muscle proteins. A previously determined x-ray structure indicates that the dystrophin N-ABD is a domain-swapped dimer, with each monomer adopting an extended, open conformation in which the two CH domains do not interact. This structure is controversial because it contradicts functional studies and known structures of similar ABDs from other muscle proteins. Here, we investigated the solution conformation of the dystrophin N-ABD using a very simple and elegant technique of pyrene excimer fluorescence. Using the wild-type protein, which contains two cysteines, and the corresponding single-cysteine mutants, we show that the protein is a monomer in solution and is in a closed conformation in which the two CH domains seem to interact, as observed from the excimer fluorescence of pyrene-labeled wild-type protein. Excimer fluorescence was also observed in its actin-bound form, indicating that the dystrophin N-ABD binds to F-actin in a closed conformation. Comparison of the dystrophin N-ABD conformation with other ABDs indicates that the tandem CH domains in general may be monomeric in solution and predominantly occur in closed conformation, whereas their actin-bound conformations may differ.     

Characterization of Inhibitor-Bound α-Synuclein Dimer: Role of α-Synuclein N-Terminal Region in Dimerization and Inhibitor Binding

α-Synuclein is a major component of filamentous inclusions that are histological hallmarks of Parkinson's disease and other α-synucleinopathies. Previous analyses have revealed that several polyphenols inhibit α-synuclein assembly with low micromolar IC₅₀ values, and that SDS-stable, noncytotoxic soluble α-synuclein oligomers are formed in their presence. Structural elucidation of inhibitor-bound α-synuclein oligomers is obviously required for the better understanding of the inhibitory mechanism. In order to characterize inhibitor-bound α-synucleins in detail, we have prepared α-synuclein dimers in the presence of polyphenol inhibitors, exifone, gossypetin, and dopamine, and purified the products. Peptide mapping and mass spectrometric analysis revealed that exifone-treated α-synuclein monomer and dimer were oxidized at all four methionine residues of α-synuclein. Immunoblot analysis and redox-cycling staining of endoproteinase Asp-N-digested products showed that the N-terminal region (1-60) is involved in the dimerization and exifone binding of α-synuclein. Ultra-high-field NMR analysis of inhibitor-bound α-synuclein dimers showed that the signals derived from the N-terminal region of α-synuclein exhibited line broadening, confirming that the N-terminal region is involved in inhibitor-induced dimerization. The C-terminal portion still predominantly exhibited the random-coil character observed in monomeric α-synuclein. We propose that the N-terminal region of α-synuclein plays a key role in the formation of α-synuclein assemblies.     

Measurement of the Change in Twist at a Helical Junction in RNA Using the?Orientation Dependence of FRET

Indocarbocyanine fluorophores attached via the 5′ terminus of double-stranded nucleic acids have a strong propensity to stack onto the terminal basepair. We previously demonstrated that the efficiency of fluorescence resonance energy transfer between cyanine 3 and 5 terminally attached to duplex species exhibits a pronounced modulation with helix length. This results from a systematic variation in the orientation parameter κ² as the relative rotation of the fluorophore transition moments changes due to the helical geometry. Analysis of such profiles provides a rich source of orientational information. In this work, we applied this methodology to the structure of a three-way helical junction that plays an important role in the hepatitis C virus internal ribosome entry site. By comparing matched pairs of duplex and junction species, we were able to measure the change in rotation at the junction. The data reveal a 29.5° overwinding and a small axial extension. This shows the power of this approach for measuring orientational information in biologically important RNA junctions.     

Structural variability in the genome of phage ?H of Halobacterium halobium

Summary The partially circularly permuted, terminally redundant structure of the DNA of phage H has been confirmed by a cleavage map for the restriction enzymes PstI, ClaI, BglII, HindIII, and, partially, BamHI.Six variants of phage H have been isolated from 71 single plaques. Their genomes differ by several insertions, a deletion, and an inversion of a DNA segment with a minimal length of 11 kb. The inversion occurs with high frequency in variants carrying at the flanks of the invertible DNA in verted repeats of a 1.8 kb DNA element which shares sequence homology with the DNA of H. halobium and may be involved in the extreme variability of its genome.     

The N-Terminal Domain of the Repressor of Staphylococcus aureus Phage Φ11 Possesses an Unusual Dimerization Ability and DNA Binding Affinity

Bacteriophage Φ11 uses Staphylococcus aureus as its host and, like lambdoid phages, harbors three homologous operators in between its two divergently oriented repressor genes. None of the repressors of Φ11, however, showed binding to all three operators, even at high concentrations. To understand why the DNA binding mechanism of Φ11 repressors does not match that of lambdoid phage repressors, we studied the N-terminal domain of the Φ11 lysogenic repressor, as it harbors a putative helix-turn-helix motif. Our data revealed that the secondary and tertiary structures of the N-terminal domain were different from those of the full-length repressor. Nonetheless, the N-terminal domain was able to dimerize and bind to the operators similar to the intact repressor. In addition, the operator base specificity, binding stoichiometry, and binding mechanism of this domain were nearly identical to those of the whole repressor. The binding affinities of the repressor and its N-terminal domain were reduced to a similar extent when the temperature was increased to 42°C. Both proteins also adequately dislodged a RNA polymerase from a Φ11 DNA fragment carrying two operators and a promoter. Unlike the intact repressor, the binding of the N-terminal domain to two adjacent operator sites was not cooperative in nature. Taken together, we suggest that the dimerization and DNA binding abilities of the N-terminal domain of the Φ11 repressor are distinct from those of the DNA binding domains of other phage repressors.     

Involvement of the 3’ Untranslated Region in Encapsidation of the Hepatitis C Virus

Although information regarding morphogenesis of the hepatitis C virus (HCV) is accumulating, the mechanism(s) by which the HCV genome encapsidated remains unknown. In the present study, in cell cultures producing HCV, the molecular ratios of 3’ end- to 5’ end-regions of the viral RNA population in the culture medium were markedly higher than those in the cells, and the ratio was highest in the virion-rich fraction. The interaction of the 3’ untranslated region (UTR) with Core in vitro was stronger than that of the interaction of other stable RNA structure elements across the HCV genome. A foreign gene flanked by the 3’ UTR was encapsidated by supplying both viral NS3-NS5B proteins and Core-NS2 in trans. Mutations within the conserved stem-loops of the 3’ UTR were observed to dramatically diminish packaging efficiency, suggesting that the conserved apical motifs of the 3´ X region are important for HCV genome packaging. This study provides evidence of selective packaging of the HCV genome into viral particles and identified that the 3’ UTR acts as a cis-acting element for encapsidation.     

Structural and Functional Elements of the Promoter Encoded by the 5′ Untranslated Region of the Venezuelan Equine Encephalitis Virus Genome

Venezuelan equine encephalitis virus (VEEV) is one of the most pathogenic members of the Alphavirus genus in the Togaviridae family. The pathogenesis of this virus depends strongly on the sequences of the structural proteins and on the mutations in the RNA promoter encoded by the 5′ untranslated region (5′UTR) of the viral genome. In this study, we performed a detailed investigation of the structural and functional elements of the 5′-terminal promoter and analyzed the effect of multiple mutations introduced into the VEEV 5′UTR on virus and RNA replication. The results of this study demonstrate that RNA replication is determined by two synergistically functioning RNA elements. One of them is a very 5′-terminal AU dinucleotide, which is not involved in the stable RNA secondary structure, and the second is a short, G-C-rich RNA stem. An increase or decrease in the stem''s stability has deleterious effects on virus and RNA replication. In response to mutations in these RNA elements, VEEV replicative machinery was capable of developing new, compensatory sequences in the 5′UTR either containing 5′-terminal AUG or AU repeats or leading to the formation of new, heterologous stem-loops. Analysis of the numerous compensatory mutations suggested that at least two different mechanisms are involved in their generation. Some of the modifications introduced into the 5′ terminus of the viral genome led to an accumulation of the mutations in the VEEV nsPs, which suggested to us that there is a direct involvement of these proteins in promoter recognition. Furthermore, our data provide new evidence that the 3′ terminus of the negative-strand viral genome in the double-stranded RNA replicative intermediate is represented by a single-stranded RNA. Both the overall folding and the sequence determine its efficient function as a promoter for VEEV positive-strand RNA genome synthesis.Alphaviruses are a group of important human and animal pathogens. They are widely distributed both in the New and the Old Worlds and circulate between mosquito vectors and vertebrate hosts (45). In mosquitoes, they cause a persistent, life-long infection characterized by virus accumulation in salivary glands, which is required for infecting vertebrate hosts during a blood meal (50). In vertebrates, alphaviruses develop high-titer viremia, and their replication induces a variety of diseases with symptoms depending on both the host and the causative virus (11). Venezuelan equine encephalitis virus (VEEV), the New World alphavirus, is one of the most pathogenic members of the genus (16, 45). Representatives of the VEEV serocomplex circulate in Central, South, and North America and cause severe, and sometimes fatal, encephalitis in humans and horses (3, 11, 16, 24). Accordingly, VEEV represents a serious public health threat in the United States (39, 48, 51, 53), and during VEEV epizootics, equine mortality can reach 83%, and in humans, neurological diseases can be detected in up to 14% of all infected individuals, especially children (15). The overall mortality rate for humans is below 1%, but it is usually higher among children, the elderly, and, most likely, immunocompromised individuals (49). In spite of the continuous threat of VEEV epidemics, the biology of this virus, its pathogenesis, and the mechanism of replication are insufficiently understood. To date, no safe and efficient vaccine and therapeutic means have been developed for this pathogen.The VEEV genome is represented by a single-stranded, almost 11.5-kb-long RNA molecule of positive polarity. This RNA mimics the structure of cellular mRNAs by containing a cap at the 5′ ends and a poly(A) tail at the 3′ ends of the genome (18). The genomic RNA encodes two polyproteins: the 5′-terminal open reading frame (ORF) is translated into viral nonstructural proteins (nsP1 to nsP4), forming the replication enzyme complex (RC). The second ORF corresponds to the 3′-terminal one-third of the genome and encodes all of the viral structural proteins, C, E2, and E1. The latter proteins are translated from the subgenomic RNA synthesized during virus replication (45).The replication of the alphavirus genome is a highly regulated, multistep process, which includes the synthesis of three different RNA species (45). The regulation of their synthesis is achieved by differential processing of viral nsPs (22, 23, 43). First, the initially synthesized nonstructural polyprotein is partially processed by the nsP2-associated protease into P123 and nsP4, and this complex is active in negative-strand RNA synthesis (22). The latter RNA is present in the double-stranded RNA (dsRNA) replicative intermediate and is associated with plasma membrane and endosome-like vesicular organelles (8). Further processing of the polyproteins into individual nsP1 to nsP4 makes the RC capable of the synthesis of the positive-strand genome and subgenomic RNA but not of negative-strand RNA (23, 41, 42). Thus, the completely processed nsPs utilize only the promoters located on the negative strand of the viral genome.The defined promoters in the alphavirus genomes include (i) a 3′-terminal 19-nucleotide (nt)-long, conserved sequence element (CSE) adjacent to the poly(A) tail (12, 13, 19); (ii) the subgenomic promoter in the negative-strand copy of the viral genome (25); and (iii) the promoter for the synthesis of the positive-strand viral genome (45). The latter promoter is located at the 3′ end of the negative strand of the viral genome and has a complex structure. The two identified elements include the sequence, encoded by the 5′ untranslated region (5′UTR) (a core promoter) (5, 9, 32), and a 51-nt CSE, found ∼150 nt downstream of the genome''s 5′ terminus in the nsP1-encoding sequence. Our previous results and those of other research groups demonstrated that the 51-nt CSE functions as a replication enhancer in a virus- and cell-dependent mode (4, 33). Clustered mutations in the VEEV 51-nt CSE or its complete deletion either had deleterious effects on RNA replication or completely abolished RNA synthesis (30). However, RNA replication was ultimately recovered due to an accumulation of compensatory, adaptive mutations in either VEEV nsP2 or nsP3 (30). Thus, the 51-nt CSE in the VEEV genome is not absolutely essential for virus replication, but its presence is highly beneficial for achieving the most efficient growth rates in cells of both vertebrate and invertebrate origins. Alphavirus core promoters demonstrate a very low level of sequence conservation and also function in cell- and virus-specific modes (9). Previous studies suggested that the sequence and/or secondary structure of the VEEV core promoter plays a critical role in virus pathogenesis, and the G3→A (A3) mutation, found in an attenuated strain of VEEV TC-83, is one of the determinants of its less pathogenic phenotype (17, 55). However, information about functional elements of the VEEV core promoter remains incomplete, and its structural and functional elements have not yet been dissected.In this study, we applied a combination of molecular approaches to further define the functional components of the VEEV 5′UTR-specific core promoter, which mediates positive-strand genome synthesis. Our results demonstrate the presence of three structural RNA elements, two of which synergistically determine promoter activity. The first element of the promoter is a very short, 5′-terminal sequence, which is not involved in a stable secondary structure. Point mutations in the very 5′-terminal nucleotides have a deleterious effect on genome RNA replication. The second element is the short RNA stem, located in close proximity to the 5′ end of the genome. Mutations changing either the stability or sequence of the stem strongly affect virus replication and cause its rapid evolution, leading to the appearance of heterologous repeating elements in the unpaired 5′ terminus or the generation of other sequences that might potentially fold into stem structures. Surprisingly, the third structural RNA element, the loop, appears to play no important role in RNA replication and can be replaced either by a shorter loop or by the loop having a heterologous sequence without a detectable effect on virus and RNA replication.