pH-Dependent Conformational Transitions in Conalbumin (Ovotransferrin), a Metalloproteinase from Hen Egg White

Acid unfolding pathway of conalbumin (CA), a monomeric glycoprotein from hen egg white, has been investigated using far- and near-UV CD spectroscopy, intrinsic fluorescence emission, extrinsic fluorescence probe 1-anilino-8-napthalene sulfonate (ANS) and dynamic light scattering (DLS). We observe pH-dependent changes in secondary and tertiary structure of CA. It has native-like α-helical secondary structure at pH 4.0 but loss structure at pH 3.0. The CA existed exclusively as a pre-molten globule state and molten globule state in solution at pH 4.0 and pH 3.0, respectively. The effect of pH on the conformation and thermostability of CA points toward its heat resistance at neutral pH. DLS results show that MG state existed as compact form in aqueous solutions with hydrodynamic radii of 4.7 nm. Quenching of tryptophan fluorescence by acrylamide further confirmed the accumulation of an intermediate state, partly unfolded, in-between native and unfolded states.     

Bacterial toxins can inhibit host cell autophagy through cAMP generation

Autophagy plays a significant role in innate and adaptive immune responses to microbial infection. Some pathogenic bacteria have developed strategies to evade killing by host autophagy. These include the use of 'camouflage' proteins to block targeting to the autophagy pathway and the use of pore-forming toxins to block autophagosome maturation. However, general inhibition of host autophagy by bacterial pathogens has not been observed to date. Here we demonstrate that bacterial cAMP-elevating toxins from B. anthracis and V. cholera can inhibit host anti-microbial autophagy, including autophagic targeting of S. Typhimurium and latex bead phagosomes. Autophagy inhibition required the cAMP effector protein kinase A. Formation of autophagosomes in response to rapamycin and the endogenous turnover of peroxisomes was also inhibited by cAMP-elevating toxins. These findings demonstrate that cAMP-elevating toxins, representing a large group of bacterial virulence factors, can inhibit host autophagy to suppress immune responses and modulate host cell physiology.     

A role for diacylglycerol in antibacterial autophagy

Antibacterial autophagy is understood to be a key cellular immune response to invading microbes. However, the mechanism(s) by which bacteria are selected as targets of autophagy remain unclear. We recently identified diacylglycerol as a novel signaling molecule that targets bacteria to the autophagy pathway, and show that it acts via protein kinase C activation. We also found that Pkc1 is required for autophagy in yeast, indicating that this kinase plays a conserved role in autophagy regulation.Key words: bacteria, Salmonella, innate immunity, adaptor, lipid second messenger, diacylglycerol, ubiquitin, NDP52, p62, SQSTM1The mechanism by which bacteria and other subcellular targets are identified and degraded by the autophagy pathway is an area of intense research. Ubiquitin has been recently found to act as an essential signal required for the autophagy of bacteria and proteins. We have previously observed ubiquitin on autophagy-targeted Salmonella enterica serovar Typhimurium (S. Typhimurium) but were surprised to see that only 50% of these bacteria were positive for ubiquitin. This indicated the possibility that an alternate signal was required for efficient autophagic targeting of the nonubiquitinated population of these bacteria.We initially performed a screen quantifying the colocalization of different lipid second messengers (diacylglycerol (DAG), PtdIns(3)P, PtdIns(4,5)P₂, PtdIns(3,4) P₂, and PtdIns(3,4,5)P₃) with autophagytargeted (i.e., LC3⁺) S. Typhimurium. We observed that DAG preferentially localizes with LC3⁺ bacteria. A kinetic analysis revealed that maximal DAG colocalization with bacteria (45 min post-infection) precedes maximal autophagy of the bacteria (60 min post-infection). Using pharmacological agents, siRNA and dominant negative constructs we were able to determine that DAG localization to the bacteria requires the action of phospholipase D (PLD; phosphatidylcholine to phosphatidic acid conversion) and phosphatidic acid phosphatase (PAP; phosphatidic acid to DAG conversion). We observed that inhibition of these pathways significantly reduces DAG localization to bacteria as well as concomitant autophagy of the bacteria, indicating a role for this lipid second messenger in the regulation of this process.Having determined that DAG is necessary for autophagy of bacteria we subsequently wanted to identify the effector through which it was signaling. Conventional and novel isoforms of the protein kinase C (PKC) family contain DAG-binding C1 domains. Accordingly, we targeted PKC isoforms using pharmacological agents, siRNA and knockout cell lines and were able to determine that DAG is signaling through the δ isoform of PKC. Inhibition of this serine/threonine kinase results in significant inhibition of antibacterial autophagy. Furthermore, bacterial replication in PKCδ knockout mouse embryonic fibroblasts is significantly higher compared to control fibroblasts, consistent with previous observations demonstrating that autophagy impairs intracellular replication of S. Typhimurium (Birmingham et al. 2006).We addressed the possibility that DAG and ubiquitin are functioning in a cooperative manner to target Salmonella for degradation by autophagy. We simultaneously inhibited both pathways using siRNA or pharmacological agents and observed additive inhibitory effects on autophagy of the bacteria. While this is indicative of two independent pathways, we cannot discount the possibility that there is still cooperation between the two pathways, especially as we did observe a small population of bacteria that were positive for both DAG and ubiquitin (Fig. 1). There are also a number of technical limitations in the methods we used, such as detection levels of the probes and antibodies that warrant caution in concluding that the two pathways are completely independent. Nonetheless, our studies clearly demonstrate a role for both DAG (Shahnazari et al. 2010) and ubiquitin (Zheng et al. 2009) in autophagy of S. Typhimurium. Future studies are required to further examine how these signals contribute to regulation of antibacterial autophagy.Open in a separate windowFigure 1Autophagic targeting of Salmonella Typhimurium. Invading S. Typhimurium can be targeted to the autophagy pathway by two independent signaling mechanisms. The first requires ubiquitin and the autophagy adaptors p62 and NDP52. The second requires DAG generation and PKCδ function. DAG generation on the SCV may occur through interaction of the SCV with DAG-positive endocytic vesicles (pathway 1) or through direct DAG production on the SCV (pathway 2). SCV, Salmonella-containing vacuole; PA, phosphatidic acid; DAG, diacylglycerol; PAP, phosphatidic acid phosphatase; PKCδ, protein kinase C delta; Ub, ubiquitin.Having characterized this pathway in antibacterial autophagy we were interested in determining whether these components were required for general autophagy. We therefore tested whether DAG localizes with rapamycin-induced autophagosomes. We observed DAG on these compartments and also found a requirement for PAP and PKCδ in this process. Other PKC isoforms are involved in alternate types of autophagy including ER stress-induced autophagy (Sakaki et al. 2008) as well as hypoxia-induced autophagy (Chen et al. 2009). As a result, we were interested in determining whether PKC function in autophagy was evolutionarily conserved. We therefore tested a role for the yeast ortholog, Pkc1, in this process and observed that it is required for starvation-induced autophagy in Saccharomyces cerevisiae.Having identified and characterized a novel signal and effector for antibacterial autophagy, further work still remains to be done in order to obtain a complete picture of this process. This includes additional study of the mechanism by which DAG is generated and the subcellular localization of PLD and PAP during this process. It is possible that DAG⁺ endocytic vesicles fuse with the Salmonella-containing vacuole (SCV) coating this compartment with DAG (pathway 1, see Fig. 1). It is also possible that both PLD and PAP function directly on the SCV, converting phosphatidylcholine to DAG via the phosphatidic acid intermediate (pathway 2, Fig. 1).More work also needs to be done to dissect DAG and ubiquitin signaling contributions to this pathway. Questions to be answered include the identification of the ubiquitinated protein(s) on the SCV, which may be host or bacterial proteins. Additionally, while we know that DAG is present on the SCV we do not yet know the signal that induces its generation. One intriguing possibility is that DAG generation occurs in response to bacterial-induced damage to the SCV during invasion. To date, PKC has been implicated in at least three different types of autophagy, and the possibility exists that other PKC isoforms (DAG responsive or not) are also involved in this process.     

Stereo-selectivity of human serum albumin to enantiomeric and isoelectronic pollutants dissected by spectroscopy, calorimetry and bioinformatics

1-naphthol (1N), 2-naphthol (2N) and 8-quinolinol (8H) are general water pollutants. 1N and 2N are the configurational enantiomers and 8H is isoelectronic to 1N and 2N. These pollutants when ingested are transported in the blood by proteins like human serum albumin (HSA). Binding of these pollutants to HSA has been explored to elucidate the specific selectivity of molecular recognition by this multiligand binding protein. The association constants (K(b)) of these pollutants to HSA were moderate (10(4)-10(5) M(-1)). The proximity of the ligands to HSA is also revealed by their average binding distance, r, which is estimated to be in the range of 4.39-5.37 nm. The binding free energy (ΔG) in each case remains effectively the same for each site because of enthalpy-entropy compensation (EEC). The difference observed between ΔC(p) (exp) and ΔC(p) (calc) are suggested to be caused by binding-induced flexibility changes in the HSA. Efforts are also made to elaborate the differences observed in binding isotherms obtained through multiple approaches of calorimetry, spectroscopy and bioinformatics. We suggest that difference in dissociation constants of pollutants by calorimetry, spectroscopic and computational approaches could correspond to occurrence of different set of populations of pollutants having different molecular characteristics in ground state and excited state. Furthermore, our observation of enhanced binding of pollutants (2N and 8H) in the presence of hemin signifies that ligands like hemin may enhance the storage period of these pollutants in blood that may even facilitate the ill effects of these pollutants.     

Dectin-1 Activation Controls Maturation of β-1,3-Glucan-containing Phagosomes

Elimination of fungal pathogens by phagocytes requires phagosome maturation, a process that involves the recruitment and fusion of intracellular proteins. The role of Dectin-1, a β-1,3-glucan receptor, critical for fungal recognition and triggering of Th17 responses, to phagosomal maturation has not been defined. We show that GFP-Dectin-1 translocates to the fungal phagosome, but its signal decays after 2 h. Inhibition of acidification results in retention of GFP-Dectin-1 to phagosome membranes highlighting the requirement for an acidic pH. Following β-1,3-glucan recognition, GFP-Dectin-1 undergoes tyrosine phosphorylation by Src kinases with subsequent Syk activation. Our results demonstrate that Syk is activated independently of intraphagosomal pH. Inhibition of Src or Syk results in prolonged retention of GFP-Dectin-1 to the phagosome signifying a link between Syk and intraphagosomal pH. β-1,3-glucan phagosomes expressing a signaling incompetent Dectin-1 failed to mature as demonstrated by prolonged Dectin-1 retention, presence of Rab5B, failure to acquire LAMP-1 and inability to acidify. Phagosomes containing Candida albicans also require Dectin-1-dependent Syk activation for phagosomal maturation. Taken together, these results support a model where Dectin-1 not only controls internalization of β-1,3-glucan containing cargo and triggers proinflammatory cytokines, but also acts as a master regulator for subsequent phagolysosomal maturation through Syk activation.     

C-terminal Amidation of an Osteocalcin-derived Peptide Promotes Hydroxyapatite Crystallization

Genesis of natural biocomposite-based materials, such as bone, cartilage, and teeth, involves interactions between organic and inorganic systems. Natural biopolymers, such as peptide motif sequences, can be used as a template to direct the nucleation and crystallization of hydroxyapatite (HA). In this study, a natural motif sequence consisting of 13 amino acids present in the first helix of osteocalcin was selected based on its calcium binding ability and used as substrate for nucleation of HA crystals. The acidic (acidic osteocalcin-derived peptide (OSC)) and amidic (amidic osteocalcin-derived peptide (OSN)) forms of this sequence were synthesized to investigate the effects of different C termini on the process of biomineralization. Electron microscopy analyses show the formation of plate-like HA crystals with random size and shape in the presence of OSN. In contrast, spherical amorphous calcium phosphate is formed in the presence of OSC. Circular dichroism experiments indicate conformational changes of amidic peptide to an open and regular structure as a consequence of interaction with calcium and phosphate. There is no conformational change detectable in OSC. It is concluded that HA crystal formation, which only occurred in OSN, is attributable to C-terminal amidation of a natural peptide derived from osteocalcin. It is also proposed that natural peptides with the ability to promote biomineralization have the potential to be utilized in hard tissue regeneration.     

Core flooding tests to investigate the effects of IFT reduction and wettability alteration on oil recovery during MEOR process in an Iranian oil reservoir

Microbial enhanced oil recovery (MEOR) refers to the process of using bacterial activities for more oil recovery from oil reservoirs mainly by interfacial tension reduction and wettability alteration mechanisms. Investigating the impact of these two mechanisms on enhanced oil recovery during MEOR process is the main objective of this work. Different analytical methods such as oil spreading and surface activity measurements were utilized to screen the biosurfactant-producing bacteria isolated from the brine of a specific oil reservoir located in the southwest of Iran. The isolates identified by 16S rDNA and biochemical analysis as Enterobacter cloacae (Persian Type Culture Collection (PTCC) 1798) and Enterobacter hormaechei (PTCC 1799) produce 1.53 g/l of biosurfactant. The produced biosurfactant caused substantial surface tension reduction of the growth medium and interfacial tension reduction between oil and brine to 31 and 3.2 mN/m from the original value of 72 and 29 mN/m, respectively. A novel set of core flooding tests, including in situ and ex situ scenarios, was designed to explore the potential of the isolated consortium as an agent for MEOR process. Besides, the individual effects of wettability alteration and IFT reduction on oil recovery efficiency by this process were investigated. The results show that the wettability alteration of the reservoir rock toward neutrally wet condition in the course of the adsorption of bacteria cells and biofilm formation are the dominant mechanisms on the improvement of oil recovery efficiency.     

Mesenchymal stem cells alter the frequency and cytokine profile of natural killer cells in abortion-prone mice

Natural killer cells, which play a pivotal role in the establishment and maintenance of normal pregnancy, are the most abundant leukocytes at the fetomaternal interface that their subsets frequencies and cytokine profile are influential factors in the preservation of the decidual tolerogenic microenvironment. Any imbalance in NK cells' frequency and functions could be associated with pregnancy failure. Mesenchymal stem cells (MSCs) are shown to have immunomodulatory effects on NK cells and their cytokine profile. The purpose of this study is to evaluate the impact of MSCs therapy on the cytokine profiles and subpopulations of NK cells in a murine model of recurrent pregnancy loss. Adipose-derived MSCs were injected intraperitoneally to the abortion-prone mice on Day 4.5 of gestation. The abortion rate was determined after MSCs administration and the frequency and cytokine profiles of the different subsets of NK cells were determined using the flow cytometry. Our results showed that, in abortion-prone mice, the frequency of CD49b⁺ NK cells was significantly higher than normal pregnant mice that decreased after therapy. We also demonstrated that MSCs downregulated the production of IFN-γ and upregulated IL-4 and IL-10 production by uNK cells. These findings indicate that MSCs can decrease the infiltration of CD49b⁺ NK cells to the fetomaternal interface and modulate the cytokine profile of NK cells from inflammatory to tolerogenic profile and thereby improve the tolerogenic microenvironment at the fetomaternal interface in benefit of pregnancy maintenance.