Analysis of quantitative methods for rib seriation using the Spitalfields documented skeletal collection

Accurate rib seriation is essential in forensic anthropology and bioarchaeology for determination of minimum numbers of individuals, sequencing trauma patterns to the chest, and identification of central ribs for use in age estimation. We investigate quantitative methods for rib seriation based on three metric variables: superior (anterior) costo-transverse crest height (SCTCH), articular facet of the tubercle-to-angle length (AFTAL), and head-to-articular facet length (HAFL). The sample consists of complete but unseriated sets of ribs from 133 individuals from the documented (known age and sex) and undocumented skeletal collections of Christ Church Spitalfields, London. This research confirms the results of an earlier study (Hoppa and Saunders [1998] J. Forensic. Sci. 43:174-177) and extends it with the application of two new metric traits and further analyses of sex differences. Analyses of variance showed that SCTCH and AFTAL are significantly associated (P < 0.001) with rib number. Tukey tests of pairwise rib comparisons revealed that for two dimensions (SCTCH and AFTAL), the central ribs (3rd-6th) are significantly distinct from each other (P < 0.05). Using simple ranking of either the SCTCH or AFTAL traits, the proportion of correctly identified ribs within +/-1 position was 80%, compared to initial seriation using morphological methods (Dudar [1993] J. Forensic. Sci. 28:788-797; Mann [1993] J. Forensic. Sci. 28:151-155). Significant sex dimorphism was also identified for these two traits. Analysis of the HAFL trait produced somewhat equivocal results, suggesting that this variable is not reliable for rib seriation. The variable SCTCH proves to be the most useful dimension for seriation, and shows that all but the 7th-9th ribs can be distinguished from others in the sequence, with important results for the 4th rib, where ranking allowed identification in 86% of cases, consistent with morphological methods for intact ribs.     

Changes in Conformation and Stability upon SCF/sKit Complex Formation

Stem cell factor (SCF) is thought to be a member of the four-helical bundle cytokine superfamily, and exists in solution as a noncovalent homodimer. It is the ligand for Kit, a tyrosine kinase type III receptor. The interaction of SCF and Kit affects early hematopoietic progenitors, as well as gametocytes, melanocytes, and mast cells. Upon binding of SCF the Kit undergoes dimerization and transphosphorylation. Circular dichroism (CD), intrinsic fluorescence, and Fourier transform infrared (FTIR) spectroscopy were used for conformational analyses of free SCF, soluble Kit (sKit), and the complex. The sKit consisted of the extracellular domain of Kit, contained five Ig-like domains, and was prepared from the conditioned media of transfected Chinese hamster ovary cells. With these techniques, a reproducible conformational change was seen upon ligand/receptor binding. The far-UV CD and FTIR spectroscopy indicated a slight increase in the -helical content. The near-UV CD and fluorescence spectra showed changes in the environments of the aromatic amino acids. The thermal denaturation of SCF was not affected by complex formation, while the melting temperature of sKit increased only a few degrees when binding SCF. This indicates that binding is temperature dependent, consistent with titration calorimetry results published previously which demonstrated that there is a large enthalpy of binding. The conformational changes which accompany SCF/sKit binding could play a role in the receptor dimerization and signal transduction which follow.     

The effect of carbohydrate on the structure and stability of erythropoietin.

Erythropoietin is a glycoprotein hormone that stimulates the maturation of late erythroid progenitor cells. It has three N-linked and one O-linked carbohydrates which play an important role in the biosynthesis and biological activities of the protein. To determine the role the carbohydrate might have in maintaining the conformational stability of the protein, the protein expressed in mammalian cells (fully glycosylated), the asialo mammalian-expressed protein, and the protein expressed in Escherichia coli (no carbohydrate) were compared for their stability to guanidine HCl, pH, and temperature. Circular dichroism was used to follow protein unfolding. Both the intact and asialo mammalian-expressed proteins unfolded with a cooperative transition in guanidine HCl, with a midpoint at 1.75 M guanidine HCl. The E. coli-expressed material unfolded with a midpoint of 1.2 M guanidine HCl, and a delta G of unfolding which was 1.4 kcal/mol less than that of the two glycosylated molecules. The E. coli-derived protein was also significantly less stable to pH-induced conformational changes, showing a cooperative transition in 35% glycerol with a midpoint at pH 4.4, while both the intact and asialo mammalian-expressed molecules had a transition midpoint of pH 3.75 in the absence of glycerol, and approximately pH 3 in the presence of 35% glycerol. The E. coli-expressed molecule unfolded and precipitated upon heating to 44 degrees C, while the asialo and intact mammalian-expressed proteins remained soluble, with a Tm of 56 degrees C. From these experiments, the carbohydrate appears to play a critical role in stabilizing the erythropoietin molecule to denaturing conditions, and this increased stability does not depend on the presence of sialic acid.     

Ion‐specific modulation of protein interactions: Anion‐induced,reversible oligomerization of a fusion protein

Ions can significantly modulate the solution interactions of proteins. We aim to demonstrate that the salt-dependent reversible heptamerization of a fusion protein called peptibody A or PbA is governed by anion-specific interactions with key arginyl and lysyl residues on its peptide arms. Peptibody A, an E. coli expressed, basic (pI = 8.8), homodimer (65.2 kDa), consisted of an IgG1-Fc with two, C-terminal peptide arms linked via penta-glycine linkers. Each peptide arm was composed of two, tandem, active sequences (SEYQGLPPQGWK) separated by a spacer (GSGSATGGSGGGASSGSGSATG). PbA was monomeric in 10 mM acetate, pH 5.0 but exhibited reversible self-association upon salt addition. The sedimentation coefficient (s_w) and hydrodynamic diameter (D_H) versus PbA concentration isotherms in the presence of 140 mM NaCl (A5N) displayed sharp increases in s_w and D_H, reaching plateau values of 9 s and 16 nm by 10 mg/mL PbA. The D_H and sedimentation equilibrium data in the plateau region (>12 mg/mL) indicated the oligomeric ensemble to be monodisperse (PdI = 0.05) with a z-average molecular weight (M_z) of 433 kDa (stoichiometry = 7). There was no evidence of reversible self-association for an IgG1-Fc molecule in A5N by itself or in a mixture containing fluorescently labeled IgG1-Fc and PbA, indicative of PbA self-assembly being mediated through its peptide arms. Self-association increased with pH, NaCl concentration, and anion size (I⁻ > Br⁻ > Cl⁻ > F⁻) but could be inhibited using soluble Trp-, Phe-, and Leu-amide salts (Trp > Phe > Leu). We propose that in the presence of salt (i) anion binding renders PbA self-association competent by neutralizing the peptidyl arginyl and lysyl amines, (ii) self-association occurs via aromatic and hydrophobic interactions between the..xx..xxx..xx.. motifs, and (iii) at >10 mg/mL, PbA predominantly exists as heptameric clusters.     

Asn to Lys mutations at three sites which are N-glycosylated in the mammalian protein decrease the aggregation of Escherichia coli-derived erythropoietin

Erythropoietin (EPO) derived from Escherichia coli is unstable to elevated temperature and tends to aggregate with time, making it unsuitable for high-resolution structure analysis. The mammalian EPO contains about 40% carbohydrate, which makes this protein more stable and less prone to aggregate than non-glycosylated E.coli-derived EPO, but makes it unsuitable for high-resolution analysis owing to its size and flexibility. In an attempt to decrease the aggregation of E.coli-derived EPO, the three asparagine residues at positions 24, 38 and 83 were mutated to lysine residues. In the native protein, these residues are the sites of N-linked glycosylation, which suggests that they should be located on the surface of the protein and should not be involved in interactions in the hydrophobic protein core. Therefore, the substitution of basic amino acids for these neutral asparagine residues is not expected to affect the protein structure, but should increase the isoelectric point of the protein and its net positive charge, decreasing its tendency to aggregate at or below neutral pH due to electrostatic interactions. No apparent alterations in receptor binding, as determined by both cell-surface receptor competition assay and in vitro receptor dimerization experiments, were observed when these mutations were introduced into the EPO sequence. However, this mutant protein displayed a significant increase in stability to heat treatment and to storage, relative to the wild-type molecule. This resulted in a greater number of observable cross peaks in the mutant EPO in 2D NOESY experiments. However, the mutant was similar to the wild-type in stability when urea was used as a denaturant. This indicates that the introduced mutations resulted in a decrease in aggregation with heating or with prolonged incubation at ambient temperature, without changing the conformational stability or the receptor binding affinity of the mutant protein. This approach of placing charged residues at sites where N-glycosylation occurs in vivo could be applied to other systems as well.     

Spatial and Temporal Clustering of Chikungunya Virus Transmission in Dominica

Using geo-referenced case data, we present spatial and spatio-temporal cluster analyses of the early spread of the 2013–2015 chikungunya virus (CHIKV) in Dominica, an island in the Caribbean. Spatial coordinates of the locations of the first 417 reported cases observed between December 15^th, 2013 and March 11^th, 2014, were captured using the Global Positioning System (GPS). We observed a preponderance of female cases, which has been reported for CHIKV outbreaks in other regions. We also noted statistically significant spatial and spatio-temporal clusters in highly populated areas and observed major clusters prior to implementation of intensive vector control programs suggesting early vector control measures, and education had an impact on the spread of the CHIKV epidemic in Dominica. A dynamical identification of clusters can lead to local assessment of risk and provide opportunities for targeted control efforts for nations experiencing CHIKV outbreaks.     

Chemical modifications in therapeutic protein aggregates generated under different stress conditions

In this study, we characterized the chemical modifications in the monoclonal antibody (IgG(2)) aggregates generated under various conditions, including mechanical, chemical, and thermal stress treatment, to provide insight into the mechanism of protein aggregation and the types of aggregate produced by the different stresses. In a separate study, additional biophysical characterization was performed to arrange these aggregates into a classification system (Joubert, M. K., Luo, Q., Nashed-Samuel, Y., Wypych, J., and Narhi, L. O. (2011) J. Biol. Chem. 286, 25118-25133). Here, we report that different aggregates possessed different types and levels of chemical modification. For chemically treated samples, metal-catalyzed oxidation using copper showed site-specific oxidation of Met(246), His(304), and His(427) in the Fc portion of the antibody, which might be attributed to a putative copper-binding site. For the hydrogen peroxide-treated sample, in contrast, four solvent-exposed Met residues in the Fc portion were completely oxidized. Met and/or Trp oxidation was observed in the mechanically stressed samples, which is in agreement with the proposed model of protein interaction at the air-liquid interface. Heat treatment resulted in significant deamidation but almost no oxidation, which is consistent with thermally induced aggregates being generated by a different pathway, primarily by perturbing conformational stability. These results demonstrate that chemical modifications are present in protein aggregates; furthermore, the type, locations, and severity of the modifications depend on the specific conditions that generated the aggregates.     

Effect of the intermolecular disulfide bond on the conformation and stability of glial cell line-derived neurotrophic factor

Glial cell line-derived neurotrophic factor (GDNF) is a member of the TGF-beta superfamily of proteins. It exists as a covalent dimer in solution, with the 15 kDa monomers linked by an interchain disulfide bond through the Cys101 residues. Sedimentation equilibrium and velocity experiments demonstrated that, after removal of the interchain disulfide bond, GDNF remains as a non-covalent dimer and is stable at pH 7.0. To investigate the effect of the intermolecular disulfide on the structure and stability of GDNF, we compared the solution structures of the wild-type protein and a cysteine-101 to alanine (C101A) mutant using Fourier transform infrared (FTIR), FT-Raman and circular dichroism (CD) spectroscopy and sedimentation analysis. The elimination of the intermolecular disulfide bond causes only minor changes (approximately 4%) in the secondary structures of GDNF. The far- and near-UV CD spectra demonstrated that the secondary and tertiary structures were similar for both wild-type and C101A GDNF. Heparin binding and sedimentation velocity experiments also indicated that the folded structure of the wild-type and C101A GDNF are indistinguishable. The thermal stability of GDNF does not appear to be affected by the absence of the interchain disulfide bond and the biological activity of the C101A mutant is identical with that of the wild-type protein. However, small but significant changes in side chain conformations of tyrosine and aliphatic residues were observed by FT-Raman spectroscopy upon removal of the intermolecular disulfide bond, which may reflect structural changes in the area of dimeric contact. By comparing the Raman spectrum of wild-type GDNF with that of the C101A analog, we identified the conformation of the intermolecular disulfide as trans-gauche-trans geometry. These results indicate that GDNF is an active, properly folded molecule in the absence of the interchain disulfide bond.     

Hydrophobic interaction chromatography in alkaline pH

Hydrophobic interaction chromatography is a very powerful protein purification technique which is dependent on strong salting-out salts to increase the hydrophobic interactions between the protein and the ligand. Ammonium sulfate is the salt most commonly used for this purpose, but it cannot be used at very alkaline pH. Monosodium glutamate was therefore tested as a salt for hydrophobic interaction chromatography at pH 9.5. When ribonuclease A, ovalbumin, and beta-lactoglobulin were individually applied to a phenyl superose column in 2 M monosodium glutamate, all three proteins bound to the column and could be subsequently eluted by decreasing the salt concentration. Using this salt, it was possible to separate commercially obtained beta-lactoglobulin into authentic protein and contaminants and to purify the individual proteins from a mixture of ovalbumin and beta-lactoglobulin. These results demonstrate that monosodium glutamate is a useful salt for hydrophobic interaction chromatography. Guanidine and sodium sulfate and sodium aspartate were also examined at the same pH, demonstrating that they also resulted in the binding and elution of the proteins examined.