Sodium Dodecyl Sulfate Analogs as a Potential Molecular Biology Reagent.

In this study, we review the properties of three anionic detergents, sodium dodecyl sulfate (SDS), Sarkosyl, and sodium lauroylglutamate (SLG), as they play a critical role in molecular biology research. SDS is widely used in electrophoresis and cell lysis for proteomics. Sarkosyl and, more frequently, SDS are used for the characterization of neuropathological protein fibrils and the solubilization of proteins. Many amyloid fibrils are resistant to SDS or Sarkosyl to different degrees and, thus, can be readily isolated from detergent-sensitive proteins. SLG is milder than the above two detergents and has been used in the solubilization and refolding of proteins isolated from inclusion bodies. Here, we show that both Sarkosyl and SLG have been used for protein refolding, that the effects of SLG on the native protein structure are weaker for SLG, and that SLG readily dissociates from the native proteins. We propose that SLG may be effective in cell lysis for functional proteomics due to no or weaker binding of SLG to the native proteins.

Procedure-Related Complications and Survival after Gastrostomy: Results from a Japanese Cohort.

INTRODUCTION: In 2010, a large-scale multi-institutional study in Japan showed a good prognosis for percutaneous endoscopic gastrostomy (PEG). However, the function and efficacy of PEG are not fully understood by patients, families, and health-care professionals; thus, the number of PEG treatments in Japan has declined. Therefore, we aimed to investigate the safety of the PEG procedure and subsequent survival after PEG. METHODS: In total, 249 PEGs were performed at Juzenkai Hospital from 2005 to 2017. PEG was originally performed using the pull method and then by a modified introducer method from mid-2011. We examined procedure-related complications and survival rates after PEG. RESULTS: Fifty-one (20.5%) procedure-related complications occurred; emergency surgery was required in 4 cases. Infections accounted for 76.5% (39/51) of complications. More infections occurred with the pull method than with the modified introducer method. The 1-year survival rate was 66.8%; the median survival time was 678 days. Nine patients (3.6%) died within 30 days; no deaths were directly related to PEG. Sex, age, and albumin level before surgery significantly influenced the prognosis. CONCLUSION: Due to changes in the PEG insertion method and other factors, PEG has become a safer treatment method. Additionally, PEG-based nutritional supplementation is associated with adequate survival.

Capto MMC mixed-mode chromatography of murine and rabbit antibodies.

Murine antibodies have weak affinity for Protein-A. Here, we have tested binding of murine monoclonal antibody (mAb) to Protein-A or Protein-A/Protein-G mixture under salting-out conditions. The addition of ammonium sulfate to HEK conditioned medium (CM) expressing murine mAb resulted in complete binding, leading to its elution by low pH or neutral arginine solution. Alternatively, a mixed-mode chromatography using Capto MMC resin was developed as a capture step. Binding of murine mAb occurred at neutral pH. The bound mAb was eluted with a gradient from 0.3 M NaCl to 0.3 M arginine/0.3 M NaCl at pH 7.0. The Capto MMC-purified murine mAb was further purified by hydroxyl apatite chromatography. Similarly, rabbit mAb was processed with some modifications. Binding of rabbit mAb to Capto MMC required a lower pH. Elution of the bound rabbit mAb was achieved by a gradient to 0.3 M NaCl, pH 7.0.

Successful removal of an accidentally swallowed press-through package sheet using a detachable snare: A case report.

Accidental swallowing of press-through package (PTP) sheets that could cause esophageal perforation is commonly encountered in emergency departments requiring early detection and removal. We report a case in which an accidentally swallowed PTP sheet was removed from the esophagus using a detachable snare after usual endoscopic methods proved ineffective. A Japanese woman in her 60s visited the emergency department with a persistent sore throat. Cervicothoracic computed tomography revealed presence of a PTP sheet in the cervical esophagus, and emergency endoscopy was performed. Pre-endoscopy simulations using a sheet identical to the one swallowed by the patient indicated that the sheet would not have been retrievable using an overtube (its inner diameter was smaller than the sheet's diameter) and grasping forceps (they slipped off the sheet). It was successfully removed using a detachable snare, a device normally employed in colorectal polypectomy, allowing us to ligate the end of the sheet and pull it into the overtube. To the best of our knowledge, this is the first report of endoscopic removal of a PTP sheet from the esophagus using a detachable snare. We suggest that this novel method would facilitate removal of esophageal PTP sheets.

Structure Analysis of Proteins and Peptides by Difference Circular Dichroism Spectroscopy.

Difference circular dichroism (CD) spectroscopy was used here to characterize changes in structure of flexible peptides upon altering their environments. Environmental changes were introduced by binding to a large target structure, temperature shift (or concentration increase) or so-called membrane-mimicking solvents. The first case involved binding of a largely disordered peptide to its target structure associated with chromatin remodeling, leading to a transition into a highly helical structure. The second example was a short 8HD (His-Asp) repeat peptide that can bind metal ions. Both Zn and Ni at µM concentrations resulted in different type of changes in secondary structure, suggesting that these metal ions provide different environments for the peptide to assume unique secondary structures. The third case is related to a few short neuroprotective peptides that were largely disordered in aqueous solution. Increased temperature resulted in induction of significant, though small, ß-sheet structures. Last example was the induction of non-helical structures for short neuroprotective peptides by membrane-mimicking solvents, including trifluoroethanol, dodecylphosphocholine and sodium dodecylsulfate. While these agents are known to induce α-helix, none of the neuropeptides underwent transition to a typical helical structure. However, trifluoroethanol did induce α-helix for the first peptide involved in chromatin remodeling described above in the first example.

Survival Rate and Shunt Infection Incidence Following Gastrostomy in Adult Patients with an Existing Ventriculoperitoneal Shunt.

Ventriculoperitoneal shunts (VPS) and gastrostomies are frequently provided in daily practice. This study investigated the incidence of VPS infection and the survival rate among adult patients who underwent gastrostomy at least 1 month after VPS placement. This single-center retrospective cohort study was conducted among patients with a VPS, who underwent a gastrostomy. This procedure was performed on a standby basis after a period of at least 1 month had elapsed since VPS placement. Subsequent VPS infection and survival rates were assessed over a period of at least 6 months. We reviewed 31 patients who had a VPS at the time of gastrostomy. Gastrostomy was performed endoscopically in 29 cases and via open surgery in 2 cases. The average interval between VPS insertion and gastrostomy was 1135.5 ± 1717.1 days. A single case of VPS infection (3.2%) was diagnosed during the study. This infection rate was not significantly different than that among 230 patients who underwent their first VPS placement (without gastrostomy) at our institution during the same time period (P = .57); there was also no significant difference in the survival rate, compared to 38 age-matched patients (with cerebrovascular disease, but without a VPS) who underwent gastrostomy (P = .73). Gastrostomy performed after an interval of at least 1 month after VPS placement was extremely safe in adult patients, and their prognosis was excellent. Additional studies are required to develop appropriate nutritional interventions for patients with a VPS.

MEP HyperCel chromatography II: binding, washing and elution.

Binding, washing and elution conditions for MEP HyperCel chromatography were examined using two conditioned media (CM) containing monoclonal antibodies (humanized IgG1) and bovine serum albumin (BSA). Monoclonal antibodies derived from mammalian expression system bound to the column without pretreatment, although a majority of contaminating proteins present in the CM also showed binding. Inorganic salts, ethanol and glycerol were ineffective in eluting proteins under the conditions examined, suggesting that electrostatic or hydrophobic interactions are not a major factor for antibody binding to the MEP resin. Ethylene glycol, 2-propanol, urea and arginine were effective, to varying degrees, in elution of the bound proteins. The bound contaminating proteins and BSA were effectively eluted with ethylene glycol and the bound antibodies were finally eluted with aqueous arginine solutions at neutral pH. MEP showed selectivity toward BSA and hence utility for removing BSA from the samples. Interestingly, Fc-fusion proteins derived from silkworm larvae showed no detectable binding. Serum proteins present in silkworm larvae strongly competed with the Fc-fusion proteins and monoclonal antibody for binding to MEP resin, while the same Fc-fusion proteins can be readily purified in one-step by Protein-A resin, again confirming weak selectivity of the MEP resin.

MEP chromatography of antibody and Fc-fusion protein using aqueous arginine solution.

MEP HyperCel resin, one of the Protein-A mimetic columns, is designed to bind antibodies at physiological pH and elutes the bound antibodies at mildly acidic pH. We have tested aqueous arginine solution for washing and elution of the resin. To our surprise, bound antibody and Fc-fusion protein eluted at pH 7.0 using 1M arginine solution. Various solvent additives were then examined at pH 7.0. Among the tested additives, urea and arginine were the only additives that were effective in elution. Thus, urea and arginine at low concentrations were effectively used for washing the resin. NaCl and MgCl(2) at 0.1-1M and ethanol at 5-20% were not effective. Based on these observations, it appears that protein binds to MEP resin through both polar and hydrophobic interactions with some contribution of electrostatic interaction, which can be simultaneously reduced by arginine or urea. On the other hand, Mabsorbent, another Protein-A mimetic column, appears to be more non-specific and non-selective.

Active form of neuroprotective Humanin, HN, and inactive analog, S7A-HN, are monomeric and disordered in aqueous phosphate solution at pH 6.0; No correlation of solution structure with activity.

A novel neuroprotective peptide, Humanin (HN), has a strong tendency to aggregate in phosphate-buffered saline. Here we attempted to reduce aggregation employing an aqueous phosphate solution, without NaCl, at pH 6.0 and low peptide concentrations wherever possible. Such a condition, though not fully physiological, allowed us to determine the secondary structure and molecular weight of the peptides. Comparison of a parent HN peptide, an inactive analog (S7A-HN) and a 1000-fold more active analog (S14G-HN) showed no apparent differences in the secondary structure. These peptides were all disordered over the wide range of peptide concentration. Sedimentation analysis was done only for HN and S7A-HN and showed aggregation into soluble oligomers in 20 mM phosphate at pH 6.0. Aggregation was greatly suppressed in 5 mM phosphate at the same pH in terms of aggregate size, with the formation of smaller oligomers. Sedimentation velocity experiments at 60,000 rpm in 5 mM phosphate at pH 6.0 showed that both HN and S7A-HN distributed into soluble aggregates that sedimented to the bottom of the cell and low molecular weight species that approached sedimentation equilibrium. The mass of this low molecular weight species was determined by sedimentation equilibrium to be close to monomers for both peptides. Thus, these results clearly demonstrate that the active HN and inactive S7A-HN are identical in structure and hence there is no apparent correlation between solution structure and biological activity.

Protein Solvent Interaction: Transition of Protein-solvent Interaction Concept from Basic Research into Solvent Manipulation of Chromatography.

Previously, we have reviewed in this journal (Arakawa, T., Kita, Y., Curr. Protein Pept. Sci., 15, 608-620, 2014) the interaction of arginine with proteins and various applications of this solvent additive in the area of protein formulations and downstream processes. In this special issue, we expand the concept of protein-solvent interaction into the analysis of the effects of solvent additives on various column chromatography, including mixed-mode chromatography. Earlier in our research, we have studied the interactions of such a variety of solvent additives as sugars, salts, amino acids, polymers and organic solvents with a variety of proteins, which resulted in mechanistic understanding on their protein stabilization and precipitation effects, the latter known as Hofmeister series. While such a study was then a pure academic research, rapid development of genetic engineering technologies and resultant biotechnologies made it a valuable knowledge in fully utilizing solvent additives in manipulation of protein solution, including column chromatography.

Mammalian Gup1, a homolog of Saccharomyces cerevisiae glycerol uptake/transporter 1, acts as a negative regulator for N-terminal palmitoylation of Sonic hedgehog.

Mammalian glycerol uptake/transporter 1 (Gup1), a homolog of Saccharomyces cerevisiae Gup1, is predicted to be a member of the membrane-bound O-acyltransferase family and is highly homologous to mammalian hedgehog acyltransferase, known as Skn, the homolog of the Drosophila skinny hedgehog gene product. Although mammalian Gup1 has a sequence conserved among the membrane-bound O-acyltransferase family, the histidine residue in the motif that is indispensable to the acyltransferase activity of the family has been replaced with leucine. In this study, we cloned Gup1 cDNA from adult mouse lung and examined whether Gup1 is involved in the regulation of N-terminal palmitoylation of Sonic hedgehog (Shh). Subcellular localization of mouse Gup1 was indistinguishable from that of mouse Skn detected using the fluorescence of enhanced green fluorescent protein that was fused to each C terminus of these proteins. Gup1 and Skn were co-localized with an endoplasmic reticulum marker, 78 kDa glucose-regulated protein, suggesting that these two molecules interact with overlapped targets, including Shh. In fact, full-length Shh coprecipitated with FLAG-tagged Gup1 by immunoprecipitation using anti-FLAG IgG. Ectopic expression of Gup1 with full-length Shh in cells lacking endogenous Skn showed no hedgehog acyltransferase activity as determined using the monoclonal antibody 5E1, which was found to recognize the palmitoylated N-terminal signaling domain of Shh under denaturing conditions. On the other hand, Gup1 interfered with the palmitoylation of Shh catalyzed by endogenous Skn in COS7 and NSC34. These results suggest that Gup1 is a negative regulator of N-terminal palmitoylation of Shh and may contribute to the variety of biological actions of Shh.

The complex structure transition of Humanin peptides by sodium dodecylsulfate and trifluoroethanol.

We have examined the structure of two Humanin (HN) analog peptides, HNG and AGA-(C8R)HNG17, in the presence of sodium dodecylsulfate (SDS) and trifluoroethanol (TFE) using CD and sedimentation velocity. Both HNG and AGA-(C8R)HNG17 underwent complex conformational changes with increasing concentrations of SDS and TFE, in contrast to general trend of increasing alpha-helix with their concentration. To our surprise, both peptides appear to converge into a similar structure in SDS and TFE at higher concentrations; e.g., above 0.05 % SDS or 30-40 % TFE. Sedimentation velocity analysis showed extensive aggregation of HNG at 0.1 mg/ml in PBS in the absence of SDS, but a highly homogeneous solution in 0.1 % SDS, indicating formation of a uniform structure by SDS. These two peptides also formed an intermediate structure both in SDS and TFE at lower concentrations, which appeared to be associated with extensive aggregation. It is interesting that the structure changes of these peptides occur well below the critical micelle concentration of SDS, suggesting that conformational changes are mediated through molecular, not micellar, interactions with SDS.

Solvent modulation of column chromatography.

A majority of column chromatographies use only selected salts, e.g., ammonium sulfate, NaCl, Citrate and phosphate in hydrophobic interaction chromatography (HIC) and NaCl in ion exchange and dye affinity chromatographies. Alternatively, a pH range below or above the neutral value is often used to reduce affinity interactions, e.g., in Protein-A or dye affinity column chromatography. Although these parameters are easily manipulated, they are not necessarily the optimal conditions for high recovery and resolution of the proteins. So-called co-solvents have been used, although to a limited extent, to manipulate performance of column chromatography. Here the term co-solvent is used to indicate its relatively high concentrations required for these applications, meaning that it also serves as solvent along with water. Ethylene glycol and MgCl(2) have been used to elute specific antibodies from antigen-affinity column. Arginine has also been used for the same purpose. Arginine has much wider applications for various column chromatographies, including size exclusion chromatography (SEC), HIC and affinity chromatography. Polyethylene glycol and glycine have also been used to improve the performance of HIC and hydroxyapatite chromatography. This review summarizes these applications of co-solvents for column chromatographies.

Solubility enhancement of gluten and organic compounds by arginine.

Arginine suppresses protein-protein and protein-surface interactions and thus is expected to increase the solubility of the proteins. We have examined here the effects of arginine on the solubility of a highly insoluble protein, gluten, and two organic compounds, octyl-gallate and coumarin, which have low to moderate aqueous solubilities. Arginine significantly increased the solubility of these molecules concentration dependently, while a weak salting-out salt, NaCl, decreased it. The observed ability of arginine to salt-in these compounds can be explained from its binding to aromatic groups and protein surface. Such solubilizing action of arginine may be used to enhance the solubility of poorly soluble organic drug substances.

The structure analysis of Humanin analog, AGA-(C8R)HNG17, by circular dichroism and sedimentation equilibrium: comparison with the parent molecule.

A 24-amino acid peptide, Humanin (HN), is a novel peptide that protects neuronal cells in vitro and in vivo from Alzheimer's disease-related toxicities. We have shown before that the structures of HN and a 1000-fold more active analog, HNG, with a Ser14Gly mutation are largely disordered. During additional mutational analysis, a shorter 17-amino acid form, AGA-(C8R)HNG17, was accidentally discovered to have a 100-fold higher activity than HNG. Here we have characterized the structural properties of the AGA-(C8R)HNG17 analog by circular dichroism (CD) and sedimentation equilibrium analysis. First, the structure in water was characterized, since these peptides have been dissolved in water prior to biological analysis. The AGA-(C8R)HNG17 peptide exhibited extensive beta-sheet structure in water, completely different from the aqueous HN and HNG structures. The beta-sheet structure was converted to a disordered structure upon dilution into phosphate-buffered saline (PBS) at low peptide concentration (e.g., below 0.2mg/ml), which was similar to the structure of HN and HNG, observed under similar conditions. Sedimentation equilibrium analysis showed that the AGA-(C8R)HNG17 analog was essentially monomeric in PBS, while HNG showed extensive aggregation. Such aggregation of HNG was observed when the peptide was added to the serum-containing cell culture media. Thus, the mutations introduced into the AGA-(C8R)HNG17 analog generated a peptide different from the parent HNG and HN peptides in the self-association properties and hence the solubility, which most likely contributed to the increased biological activity of the AGA-(C8R)HNG17 analog.

Small molecule pharmacological chaperones: From thermodynamic stabilization to pharmaceutical drugs.

A great deal of attention has been paid to so-called amyloid diseases, in which the proteins responsible for the cell death and resultant diseases undergo conformational changes and aggregate in vivo, although whether aggregate formation is the cause or the result of the cell death is controversial. Recently, an increasing attention is given to protein folding diseases tightly associated with mutations. These mutations result in temperature-dependent misfolding and hence inactivation of the proteins, leading to loss of function, at physiological temperature; at low so-called permissive temperatures, the mutant proteins correctly fold and acquire functional structure. Alternatively, activation can be induced by use of osmolytes, which restores the folding of the mutant proteins and hence are called chemical chaperones. The osmolytes are compatible with macromolecular function and do stabilize the native protein structure. However, chemical chaperones require high concentrations for effective folding of mutant proteins and hence are too toxic in in-vivo applications. This limitation can be overcome by pharmacological chaperones, whose functions are similar to the chemical chaperones, but occur at much lower concentrations, i.e., physiologically acceptable concentrations. Although the research and clinical importance of pharmacological chaperones has been emphasized, the initial and central concept of osmolytes is largely ignored. Here we attempt to bridge the concept of osmolytes to applications of pharmacological chaperones.

Structure analysis of activity-dependent neurotrophic factor 9 by circular dichroism and sedimentation equilibrium.

Activity-dependent neurotrophic factor (ADNF) is a glia-derived neurotrophic peptide, which protects neurons from tetrodoxin treatment and Alzheimer's disease-related and amyotrophic-lateral-sclerosis-related insults at femto-molar concentrations. However, the mechanism of the femto-molar neuroprotection by the peptide has not been elucidated. The characterization of the peptide structure in solution at molecular level should shed light in the mechanism of such extremely high biological activity. From that point of view, the secondary and quaternary structure analysis of ADNF9, an active core fragment peptide of ADNF, was performed by circular dichroism (CD) and sedimentation equilibrium. ADNF9 has also been shown to exhibit a neurotrophic activity in femto-molar concentrations; in this study it showed sub-pM neuroprotective activity against V642I-APP-induced cytotoxity in the mouse primary cortical neuron. CD analysis showed that the secondary structure of ADNF9 is identical in water and phosphate-buffered saline (PBS) and is independent of the peptide concentration. The CD spectra appear to be characterized most likely as disordered. The sedimentation equilibrium experiments demonstrated monomeric structure of the protein over the wide range of peptide concentration. There is a slight enhancement of CD intensity at 37 degrees C relative to 20 degrees C, suggesting a possible hydrophobic association of the peptide. There is no change in the secondary structure in PBS upon freeze-thaw treatment, which has previously been suggested to cause activity loss.

Protein precipitation and denaturation by dimethyl sulfoxide.

Solvent conditions play a major role in a wide range of physical properties of proteins in solution. Organic solvents, including dimethyl sulfoxide (DMSO), have been used to precipitate, crystallize and denature proteins. We have studied here the interactions of DMSO with proteins by differential refractometry and amino acid solubility measurements. The proteins used, i.e., ribonuclease, lysozyme, beta-lactoglobulin and chymotrypsinogen, all showed negative preferential DMSO binding, or preferential hydration, at low DMSO concentrations, where they are in the native state. As the DMSO concentration was increased, the preferential interaction changed from preferential hydration to preferential DMSO binding, except for ribonuclease. The preferential DMSO binding correlated with structural changes and unfolding of these proteins observed at higher DMSO concentrations. Amino acid solubility measurements showed that the interactions between glycine and DMSO are highly unfavorable, while the interactions of DMSO with aromatic and hydrophobic side chains are favorable. The observed preferential hydration of the native protein may be explained from a combination of the excluded volume effects of DMSO and the unfavorable interaction of DMSO with a polar surface, as manifested by the unfavorable interactions of DMSO with the polar uncharged glycine molecule. Such an unfavorable interaction of DMSO with the native protein correlates with the enhanced self-association and precipitation of proteins by DMSO. Conversely, the observed conformational changes at higher DMSO concentration are due to increased binding of DMSO to hydrophobic and aromatic side chains, which had been newly exposed on protein unfolding.

Suppression of protein interactions by arginine: a proposed mechanism of the arginine effects.

Arginine has been used to suppress protein aggregation and protein-protein or protein-surface interactions during protein refolding and purification. While its biotechnology applications are gradually expanding, the mechanism of these effects of arginine has not been fully elucidated. Arginine is more effective at higher concentrations, an indication of weak interactions with the proteins. The effects of weakly interacting additives, such as arginine, on protein solubility, stability and aggregation have been explained from three different approaches: i.e., (1) the effects of additives on the structure of water, (2) the interactions of additives with the amino acid side chains and peptide bonds and (3) the preferential interactions of additives with the proteins. Here we have examined these properties of arginine and compared with those of other additives, e.g., guanidine hydrochloride (GdnHCl) and certain amino acids and amines. GdnHCl is a strong salting-in agent and denatures proteins, while betaine is a protein stabilizer. Several amino acids and amine compounds, including betaine, which stabilize the proteins, are strongly excluded; i.e., the proteins are preferentially hydrated in these solutions. On the other hand, GdnHCl preferentially binds to the proteins. Arginine is intermediate between these two extreme cases and shows a more complicated pattern of interactions with the proteins. The effects of additives on water structure, e.g., the surface tension of aqueous solution of the additives and the solubility of amino acids in the presence of additives also shed light on the mechanism of the effects of the additives on protein aggregation. While arginine increases the surface tension of water, it favorably interacts with most amino acid side chains and the peptide bonds, a property shared with GdnHCl. Thus, we propose that while arginine is similar to GdnHCl in the amino acid level, arginine interacts with the proteins differently from GdnHCl.