Identification of the Base-Pairing Requirements for Repression of hctA Translation by the Small RNA IhtA Leads to the Discovery of a New mRNA Target in Chlamydia trachomatis

The non-coding small RNA, IhtA expressed by the obligate intracellular human pathogen Chlamydia trachomatis modulates the translation of HctA, a key protein involved in replicative to infectious cell type differentiation. Using a combination of bioinformatics and mutagenesis we sought to identify the base pairing requirement for functional repression of HctA protein expression, with an eye to applying our findings towards the identification of additional targets. IhtA is predicted to fold into a three stem:loop structure. We found that loop 1 occludes the initiation codon of hctA, while loop 2 and 3 are not required for function. This 7 nucleotide region forms G/C rich interactions surrounding the AUG of hctA. Two additional genes in the chlamydial genome, CTL0322 and CTL0097, contained some elements of the hctA:IhtA recognition sequence. The mRNA of both CTL0322and CTL0097 interacted with IhtA in vitro as measured by biolayer interferometry. However, using a CheZ reporter expression system, IhtA only inhibited the translation of CTL0322. The proposed IhtA recognition site in the CTL0322 message contains significant G/C base pairing on either side of the initiation codon while CTL0097 only contains G/C base pairing 3’ to the AUG initiation codon. These data suggest that as the functional interacting region is only 6-7nt in length that full translation repression is dependent on the degree of G/C base pairing. Additionally our results indicate that IhtA may regulate multiple mRNAs involved in the chlamydial infectious cycle.     

Assessing fern diversity: relative species richness and its environmental correlates in Uganda

Techniques for the rapid quantification of tropical biodiversity are of critical importance in deciding where to invest scarce conservation resources. Here we describe a simple survey method for assessing species-level richness of a poorly known plant group, the pteridophytes. We then illustrate the use of a powerful, rarefaction- based technique of controlling for inevitable differences in sampling effort to calculate the relative species richness of our study sites. Lastly, we explore how closely observed patterns of relative species richness of Ugandan forests are correlated with a suite of simple environmental variables. We find that fully 75% of the variance in our estimate of fern diversity can be predicted from just two measures: soil fertility (scored as C/N ratio, itself related to rainfall); and distance from the nearest putative Pleistocene refugium.     

ON THE REVERSIBILITY OF MANDIBULAR SYMPHYSEAL FUSION

Experimental and comparative studies suggest that a major determinant of increased ossification of the mandibular symphysis is elevated masticatory stress related to a mechanically challenging diet. However, the morphology of this joint tracks variation in dietary properties in only some mammalian clades. Extant anthropoid primates are a notable exception: synostosis is ubiquitous in this speciose group, despite its great age and diverse array of feeding adaptations. One possible explanation for this pattern is that, once synostosis evolves, reversion to a lesser degree of fusion is unlikely or even constrained. If correct, this has important implications for functional and phylogenetic analyses of the mammalian feeding apparatus. To test this hypothesis, we generated a molecular tree for 76 vespertilionoid and noctilionoid chiropterans using Bayesian phylogenetic analysis and examined character evolution using parsimony and likelihood ancestral-state reconstructions along with the binary state speciation and extinction (BiSSE) model. Results indicate that reversals have occurred within Vespertilionoidea. In contrast, noctilionoids exhibit an anthropoid-like pattern, which suggests that more detailed comparisons of the functional and developmental bases for fusion in these bat clades may provide insight into why fusion is maintained in some lineages but not in others. Potential functional and developmental explanations for the lack of reversal are discussed.     

Intervention of glutathione in pre-mutagenic catechol-mediated DNA damage in the presence of copper(II) ions

The catechol-mediated DNA damage in the presence of Cu(II) ions involves oxidation of guanine to 8-oxoguanine (8-oxoG) and DNA strand scission. It proceeds through the reactive oxygen species (ROS) generation. The mutagenicity of 8-oxoG lesions is due to its miscoding propensity reflected in GC→TA transversion taking place during the DNA repair process. To gain new insights into the nature of catechol-mediated DNA damage and its prevention, we have investigated the changes in DNA melting characteristics and 8-oxoG formation as the indicators of DNA damage in a model calf-thymus DNA system. A novel fluorescence method for DNA melting temperature determination, based on DAPI fluorescent-probe staining, has been proposed. The DNA melting-onset temperature has been found to be more sensitive to DNA damage than the standard melting temperature due to the increased width of the melting transition observed in oxidatively damaged DNA. We have found that the efficiency of Fenton cascade in generating DNA-damaging ROS is higher for catechol than for GSH, two strong antioxidants, mainly due to the much longer distance between ROS-generating radical group in GS to nucleobases than that of semiquinone radical group to nucleobases (2.1nm vs. 0.27nm), making the ROS transport from GSH an order of magnitude less likely to damage DNA because of short lifetime of HO radicals. The antioxidant and DNA-protecting behaviors of GSH have been elucidated. We have found that the redox potential of GSH/GSSG couple is lower than that of catechol/semiquinone couple. Hence, GSH keeps catechol in the reduced state, thereby shutting down the initial step of the catechol-mediated Fenton cascade. The catechol-induced DNA damage in the presence of Cu(II) ions has also been confirmed in studies of ON-OFF hairpin-oligonucleotide beacons.     

Diet of chimpanzees (Pan troglodytes schweinfurthii) at Ngogo, Kibale National Park, Uganda, 1. Diet composition and diversity

Chimpanzees (Pan troglodytes) are ecologically flexible omnivores with broad diets comprising many plant and animal foods, although they mostly eat fruit (including figs). Like other ecologically flexible nonhuman primates (e.g., baboons, Papio spp.) with broad diets, their diets vary across habitats. Much data on diets come from short studies that may not capture the range of variation, however, and data are scant on variation within habitats and populations. We present data on diet composition and diversity for chimpanzees at Ngogo, in Kibale National Park, Uganda, collected over a 15-year period, with a focus on the plant components of the diet. We compare Ngogo data to those on chimpanzees at the nearby Kibale site of Kanyawara, on other chimpanzee populations, and on some other frugivorous-omnivorous primates. Results support the argument that chimpanzees are ripe fruit specialists: Ngogo chimpanzees ate a broad, mostly fruit-based diet, feeding time devoted to fruit varied positively with fruit availability, and diet diversity varied inversely with fruit availability. Comparison of Ngogo and Kanyawara shows much similarity, but also pronounced within-population dietary variation. Chimpanzees fed much more on leaves, and much less on pith and stems, at Ngogo. Figs accounted for somewhat less feeding time at Ngogo, but those of Ficus mucuso were quantitatively the most important food. This species is essentially absent at Kanayawara; its abundance and high productivity at Ngogo, along with much higher abundance of several other important food species, help explain why chimpanzee community size and population density are over three times higher at Ngogo. High inter-annual variation at Ngogo highlights the value of long-term data for documenting the extent of ecological variation among chimpanzee populations and understanding how such variation might affect population biology and social dynamics.     

On the unyielding hydrophobic core of villin headpiece

Villin headpiece (HP67) is a small, autonomously-folding domain that has become a model system for understanding the fundamental tenets governing protein folding. In this communication, we explore the role that Leu61 plays in the structure and stability of the construct. Deletion of Leu61 results in a completely unfolded protein that cannot be expressed in Escherichia coli. Omission of only the aliphatic leucine side chain (HP67 L61G) perturbed neither the backbone conformation nor the orientation of local hydrophobic side chains. As a result, a large, solvent-exposed hydrophobic pocket, a negative replica of the leucine side-chain, was created on the surface. The loss of the hydrophobic interface between leucine 61 and the hydrophobic pocket destabilized the construct by ~3.3 kcal/mol. Insertion of a single glycine residue immediately before Leu61 (HP67 L61[GL]) was also highly destabilizing and had the effect of altering the backbone conformation (α-helix to π-helix) in order to precisely preserve the wild-type position and conformation of all hydrophobic residues, including Leu61. In addition to demonstrating that the hydrophobic side-chain of Leu61 is critically important for the stability of villin headpiece, our results are consistent with the notion that the precise interactions present within the hydrophobic core, rather than the hydrogen bonds that define the secondary structure, specify a protein's fold.     

Distinct modulation of voltage-gated and ligand-gated Ca2+ currents by PPAR-γ agonists in cultured hippocampal neurons

Type 2 diabetes mellitus is a metabolic disorder characterized by hyperglycemia and is especially prevalent in the elderly. Because aging is a risk factor for type 2 diabetes mellitus, and insulin resistance may contribute to the pathogenesis of Alzheimer's disease (AD), anti-diabetic agents (thiazolidinediones-TZDs) are being studied for the treatment of cognitive decline associated with AD. These agents normalize insulin sensitivity in the periphery and can improve cognition and verbal memory in AD patients. Based on evidence that Ca²⁺ dysregulation is a pathogenic factor of brain aging/AD, we tested the hypothesis that TZDs could impact Ca²⁺ signaling/homeostasis in neurons. We assessed the effects of pioglitazone and rosiglitazone (TZDs) on two major sources of Ca²⁺ influx in primary hippocampal cultured neurons, voltage-gated Ca²⁺ channel (VGCC) and the NMDA receptor (NMDAR). VGCC- and NMDAR-mediated Ca²⁺ currents were recorded using patch-clamp techniques, and Ca²⁺ intracellular levels were monitored with Ca²⁺ imaging techniques. Rosiglitazone, but not pioglitazone reduced VGCC currents. In contrast, NMDAR-mediated currents were significantly reduced by pioglitazone but not rosiglitazone. These results show that TZDs modulate Ca²⁺-dependent pathways in the brain and have different inhibitory profiles on two major Ca²⁺ sources, potentially conferring neuroprotection to an area of the brain that is particularly vulnerable to the effects of aging and/or AD.     

Nuclear Magnetic Resonance Structure Shows that the Severe Acute Respiratory Syndrome Coronavirus-Unique Domain Contains a Macrodomain Fold

The nuclear magnetic resonance (NMR) structure of a central segment of the previously annotated severe acute respiratory syndrome (SARS)-unique domain (SUD-M, for “middle of the SARS-unique domain”) in SARS coronavirus (SARS-CoV) nonstructural protein 3 (nsp3) has been determined. SUD-M(513-651) exhibits a macrodomain fold containing the nsp3 residues 528 to 648, and there is a flexibly extended N-terminal tail with the residues 513 to 527 and a C-terminal flexible tail of residues 649 to 651. As a follow-up to this initial result, we also solved the structure of a construct representing only the globular domain of residues 527 to 651 [SUD-M(527-651)]. NMR chemical shift perturbation experiments showed that SUD-M(527-651) binds single-stranded poly(A) and identified the contact area with this RNA on the protein surface, and electrophoretic mobility shift assays then confirmed that SUD-M has higher affinity for purine bases than for pyrimidine bases. In a further search for clues to the function, we found that SUD-M(527-651) has the closest three-dimensional structure homology with another domain of nsp3, the ADP-ribose-1"-phosphatase nsp3b, although the two proteins share only 5% sequence identity in the homologous sequence regions. SUD-M(527-651) also shows three-dimensional structure homology with several helicases and nucleoside triphosphate-binding proteins, but it does not contain the motifs of catalytic residues found in these structural homologues. The combined results from NMR screening of potential substrates and the structure-based homology studies now form a basis for more focused investigations on the role of the SARS-unique domain in viral infection.     

Nuclear Magnetic Resonance Structure of the Nucleic Acid-Binding Domain of Severe Acute Respiratory Syndrome Coronavirus Nonstructural Protein 3

The nuclear magnetic resonance (NMR) structure of a globular domain of residues 1071 to 1178 within the previously annotated nucleic acid-binding region (NAB) of severe acute respiratory syndrome coronavirus nonstructural protein 3 (nsp3) has been determined, and N- and C-terminally adjoining polypeptide segments of 37 and 25 residues, respectively, have been shown to form flexibly extended linkers to the preceding globular domain and to the following, as yet uncharacterized domain. This extension of the structural coverage of nsp3 was obtained from NMR studies with an nsp3 construct comprising residues 1066 to 1181 [nsp3(1066-1181)] and the constructs nsp3(1066-1203) and nsp3(1035-1181). A search of the protein structure database indicates that the globular domain of the NAB represents a new fold, with a parallel four-strand β-sheet holding two α-helices of three and four turns that are oriented antiparallel to the β-strands. Two antiparallel two-strand β-sheets and two 3₁₀-helices are anchored against the surface of this barrel-like molecular core. Chemical shift changes upon the addition of single-stranded RNAs (ssRNAs) identified a group of residues that form a positively charged patch on the protein surface as the binding site responsible for the previously reported affinity for nucleic acids. This binding site is similar to the ssRNA-binding site of the sterile alpha motif domain of the Saccharomyces cerevisiae Vts1p protein, although the two proteins do not share a common globular fold.The coronavirus replication cycle begins with the translation of the 29-kb positive-strand genomic RNA to produce two large polyprotein species (pp1a and pp1ab), which are subsequently cleaved to produce 15 or possibly 16 nonstructural proteins (nsp''s) (11). Among these, nsp3 is the largest nsp and also the largest coronavirus protein. nsp3 is a glycosylated (16, 22), multidomain (36, 51), integral membrane protein (38). All known coronaviruses encode a homologue of severe acute respiratory syndrome coronavirus (SARS-CoV) nsp3, and sequence analysis suggests that at least some functions of nsp3 may be found in all members of the order Nidovirales (11). Hallmarks of the coronavirus nsp3 proteins include one or two papain-like proteinase domains (3, 12, 16, 31, 56, 62), one to three histone H2A-like macrodomains which may bind RNA or RNA-like substrates (5, 9, 48, 54, 55), and a carboxyl-terminal Y domain of unknown function (13). An extensive bioinformatics analysis of the coronavirus replicase proteins by Snijder et al. (51) provided detailed annotations of the then-recently sequenced SARS-CoV genome (35, 47), including the identification of a domain unique to SARS-CoV and the prediction of the ADP-ribose-1″-phosphatase (ADRP) activity of the X domain (since shown to be one of the macrodomains).Only limited information is so far available regarding the ways in which the functions of nsp3 are involved in the coronavirus replication cycle. Some functions of nsp3 appear to be directed toward protein; e.g., the nsp3 proteinase domain cleaves the amino-terminal two or three nsp''s from the polyprotein and has deubiquitinating activity (4, 6, 14, 30, 53, 60). Most homologues of the most conserved macrodomain of nsp3 appear to possess ADRP activity (9, 34, 41-43, 48, 59) and may act on protein-conjugated poly(ADP-ribose); however, this function appears to be dispensable for replication (10, 42) and may not be conserved in all coronaviruses (41). The potential involvement of nsp3 in RNA replication is suggested by the presence of several RNA-binding domains (5, 36, 49, 54, 55). nsp3 has been identified in convoluted membrane structures that are also associated with other replicase proteins and that have been shown to be involved in viral RNA synthesis (16, 24, 52), and nsp3 papain-like proteinase activity is essential for replication (14, 62). Other conserved structural features of nsp3 include two ubiquitin-like domains (UB1 and UB2) (45, 49). We have also recently reported that nsp3 is a structural protein, since it was identified as a minor component of purified SARS-CoV preparations, although it is not known whether nsp3 is directly involved in virogenesis or is incidentally incorporated due to protein-protein or protein-RNA interactions (36).A nucleic acid-binding region (NAB) is located within the polypeptide segment of residues 1035 to 1203 of nsp3. The NAB is expected to be located in the cytoplasm, along with the papain-like protease, ADRP, a region unique to SARS-CoV (the SARS-CoV unique domain [SUD]), and nsp3a, since both the N and C termini of nsp3 were shown previously to be cytoplasmic (38). Two hydrophobic segments are membrane spanning (38), and the NAB is located roughly 200 residues in the N-terminal direction from the first membrane-spanning segment. This paper presents the next step in the structural coverage of nsp3, with the determination of the NAB structure. The structural studies included nuclear magnetic resonance (NMR) characterization of two constructs, an nsp3 construct comprising residues 1035 to 1181 [nsp3(1035-1181)] and nsp3(1066-1203), and complete NMR structure determination for the construct nsp3(1066-1181) (see Fig. ​Fig.8).8). The structural data were then used as a platform from which to investigate the nature of the previously reported single-stranded RNA (ssRNA)-binding activity of the NAB (36). Since no three-dimensional (3D) structures for the corresponding domains in other group II coronaviruses are known and since the SARS-CoV NAB has only very-low-level sequence identity to other proteins, such data could not readily be derived from comparisons with structurally and functionally characterized homologues.Open in a separate windowFIG. 8.Sequence alignment of the polypeptide segment nsp3(1066-1181) that forms the globular domain of the SARS-CoV NAB with homologues from other group II coronaviruses. Protein multiple-sequence alignment was performed using ClustalW2 and included sequences from SARS-CoV Tor2 (accession no. {"type":"entrez-protein","attrs":{"text":"AAP41036","term_id":"30795144","term_text":"AAP41036"}}AAP41036) and representatives of three protein clusters corresponding to three group II coronavirus lineages identified by a BLAST search: bat coronavirus HKU5-5 (BtCoV-HKU5-5; accession no. {"type":"entrez-protein","attrs":{"text":"ABN10901","term_id":"124389468","term_text":"ABN10901"}}ABN10901), BtCoV-HKU9-1 (accession no. {"type":"entrez-protein","attrs":{"text":"P0C6T6","term_id":"190360129","term_text":"P0C6T6"}}P0C6T6), and human coronavirus HKU1-N16 (HCoV-HKU1-N16; accession no. {"type":"entrez-protein","attrs":{"text":"ABD75496","term_id":"89515407","term_text":"ABD75496"}}ABD75496). Above the sequences, the positions in full-length SARS-CoV nsp3, the locations of the regular secondary structures in the presently solved NMR structure of the SARS-CoV NAB globular domain, and the residue numbering in this domain are indicated. Amino acids are colored according to conservation and biochemical properties, following ClustalW conventions. Residues implicated in interactions with ssRNA are marked with inverted black triangles. In the present context, the key features are that there is only one position with conservation of K or R (red) and that there are extended sequences with conservation of hydrophobic residues (blue) (see the text).     

Urinary C-peptide tracks seasonal and individual variation in energy balance in wild chimpanzees

C-peptide of insulin presents a promising new tool for behavioral ecologists that allows for regular, non-invasive assessment of energetic condition in wild animals. C-peptide is produced on an equimolar basis with insulin, thus is indicative of the body's response to available glucose and, with repeated measurement, provides a biomarker of energy balance. As yet, few studies have validated the efficacy of C-peptide for monitoring energy balance in wild animals. Here, we assess seasonal and interindividual variation in urinary C-peptide concentrations of East African chimpanzees (Pan troglodytes schweinfurthii). We assayed 519 urine samples from 13 adult male chimpanzees in the Kanyawara community of Kibale National Park, Uganda. C-peptide levels were significantly predicted by the total amount of fruit and the amount of preferred fruit in the diet. However, chimpanzees had very low C-peptide titers during an epidemic of severe respiratory illness, despite highly favorable feeding conditions. Kanyawara males had significantly lower C-peptide levels than males at Ngogo, a nearby chimpanzee community occupying a more productive habitat. Among Kanyawara males, low-ranking males had consistently higher C-peptide levels than dominant males. While counterintuitive, this result supports previous findings of costs associated with dominance in male chimpanzees. Our preliminary investigations demonstrate that C-peptide has wide applications in field research, providing an accessible tool for evaluating seasonal and individual variation in energetic condition, as well as the costs of processes such as immune function and reproduction.