Surfactant protein D binds to Mycobacterium tuberculosis bacilli and lipoarabinomannan via carbohydrate-lectin interactions resulting in reduced phagocytosis of the bacteria by macrophages.

Surfactant protein-D (SP-D) is a collectin produced in the distal lung airspaces that is believed to play an important role in innate pulmonary immunity. Naive immunologic responses to Mycobacterium tuberculosis (M.tb) are especially important in the lung, since entry of this inhaled pathogen into the alveolar macrophage is a pivotal event in disease pathogenesis. Here we investigated SP-D binding to M.tb and the effect of this binding on the adherence of M. tb to human macrophages. These studies demonstrate specific binding of SP-D to M.tb that is saturable, calcium dependent, and carbohydrate inhibitable. In addition to purified SP-D, SP-D in bronchoalveolar lavage fluids from healthy donors and patients with alveolar proteinosis also binds to M.tb. Incubation of M.tb with SP-D results in agglutination of the bacteria. In contrast to its binding to M.tb, SP-D binds minimally to the avirulent Mycobacterium smegmatis. SP-D binds predominantly to lipoarabinomannan from the virulent Erdman strain of M.tb, but not the lipoarabinomannan from M. smegmatis. The binding of SP-D to Erdman lipoarabinomannan is mediated by the terminal mannosyl oligosaccharides of this lipoglycan. Incubation of M.tb with subagglutinating concentrations of SP-D leads to reduced adherence of the bacteria to macrophages (62.7% of control adherence +/- 3.3% SEM, n = 8), whereas incubation of bacteria with surfactant protein A leads to significantly increased adherence to monocyte-derived macrophages. These data provide evidence for specific binding of SP-D to M. tuberculosis and indicate that SP-D and surfactant protein A serve different roles in the innate host response to this pathogen in the lung.     

Using the longest significance run to estimate region-specific p-values in genetic association mapping studies

Background  

Association testing is a powerful tool for identifying disease susceptibility genes underlying complex diseases. Technological advances have yielded a dramatic increase in the density of available genetic markers, necessitating an increase in the number of association tests required for the analysis of disease susceptibility genes. As such, multiple-tests corrections have become a critical issue. However the conventional statistical corrections on locus-specific multiple tests usually result in lower power as the number of markers increases. Alternatively, we propose here the application of the longest significant run (LSR) method to estimate a region-specific p-value to provide an index for the most likely candidate region.     

MPDA: Microarray pooled DNA analyzer

Background  

Microarray-based pooled DNA experiments that combine the merits of DNA pooling and gene chip technology constitute a pivotal advance in biotechnology. This new technique uses pooled DNA, thereby reducing costs associated with the typing of DNA from numerous individuals. Moreover, use of an oligonucleotide gene chip reduces costs related to processing various DNA segments (e.g., primers, reagents). Thus, the technique provides an overall cost-effective solution for large-scale genomic/genetic research. However, few publicly shared tools are available to systematically analyze the rapidly accumulating volume of whole-genome pooled DNA data.     

Eradication of intracellular Francisella tularensis in THP-1 human macrophages with a novel autophagy inducing agent

Background

Autophagy has been shown recently to play an important role in the intracellular survival of several pathogenic bacteria. In this study, we investigated the effect of a novel small-molecule autophagy-inducing agent, AR-12, on the survival of Francisella tularensis, the causative bacterium of tularemia in humans and a potential bioterrorism agent, in macrophages.

Methods and results

Our results show that AR-12 induces autophagy in THP-1 macrophages, as indicated by increased autophagosome formation, and potently inhibits the intracellular survival of F. tularensis (type A strain, Schu S4) and F. novicida in macrophages in association with increased bacterial co-localization with autophagosomes. The effect of AR-12 on intracellular F. novicida was fully reversed in the presence of the autophagy inhibitor, 3-methyl adenine or the lysosome inhibitor, chloroquine. Intracellular F. novicida were not susceptible to the inhibitory activity of AR-12 added at 12 h post-infection in THP-1 macrophages, and this lack of susceptibility was independent of the intracellular location of bacteria.

Conclusion

Together, AR-12 represents a proof-of-principle that intracellular F. tularensis can be eradicated by small-molecule agents that target innate immunity.     

Detergent-activated BAX Protein Is a Monomer

BAX is a pro-apoptotic member of the BCL-2 protein family. At the onset of apoptosis, monomeric, cytoplasmic BAX is activated and translocates to the outer mitochondrial membrane, where it forms an oligomeric pore. The chemical mechanism of BAX activation is controversial, and several in vitro and in vivo methods of its activation are known. One of the most commonly used in vitro methods is activation with detergents, such as n-octyl glucoside. During BAX activation with n-octyl glucoside, it has been shown that BAX forms high molecular weight complexes that are larger than the combined molecular weight of BAX monomer and one detergent micelle. These large complexes have been ascribed to the oligomerization of BAX prior to its membrane insertion and pore formation. This is in contrast to the in vivo studies that suggest that active BAX inserts into the outer mitochondrial membrane as a monomer and then undergoes oligomerization. Here, to simultaneously determine the molecular weight and the number of BAX proteins per BAX-detergent micelle during detergent activation, we have used an approach that combines two single-molecule sensitivity technique, fluorescence correlation spectroscopy, and fluorescence-intensity distribution analysis. We have tested a range of detergents as follows: n-octyl glucoside, dodecyl maltoside, Triton X-100, Tween 20, 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonic acid, and cholic acid. With these detergents we observe that BAX is a monomer before, during, and after interaction with micelles. We conclude that detergent activation of BAX is not congruent with oligomerization and that in physiologic buffer conditions BAX can assume two stable monomeric conformations, one inactive and one active.BAX² is a pro-apoptotic member of the BCL-2 protein family. In a simplified apoptosis model, monomeric inactive BAX is localized in the cytoplasm of healthy nondying cells (1). During apoptosis BAX is activated and translocates to the outer mitochondrial membrane (2) where it inserts as a monomer (3), undergoes oligomerization (4), and forms a pore through which cytochrome c and other apoptotic factors are released into the cytoplasm. Once in the cytoplasm, these apoptotic factors induce the activation of the effector caspases that execute the cell death process. This mechanism, which is generally correct, requires that soluble BAX becomes integrated into the mitochondrial membrane where it forms a functional oligomeric pore capable of cytochrome c release. However, the molecular mechanism of BAX activation remains controversial (5, 6).It has been understood for some time, but frequently ignored, that activity of the BCL-2 family proteins is exhibited in cells when these proteins are associated with the hydrophobic environment of membranes. Therefore, it has always seemed that attention to the effect of hydrophobic environments on the BCL-2 family proteins would be rewarding. It has been shown that BAX can be directly activated by treatment with nonionic detergents such as n-octyl glucoside, dodecyl maltoside, and Triton X-100 (1, 7). During activation by nonionic detergents, to gain the ability to form pores in a bilayer membrane, BAX needs to undergo a major conformational transition from a globular protein with two pore-forming α-helices 5 and 6 hidden in the protein core (8) to a conformation in which these two helices are exposed and inserted into a lipid membrane (3, 5, 9). The nature of this active conformation of BAX is important for the understanding of the death decision in cells. Most proposals suggest that in a cell this activated form of BAX protein is initiated and maintained by the interactions with other proteins, such as tBID, or by BAX itself as a homo-oligomer (7, 10).Nonionic detergents have been commonly used to activate BAX for in vitro studies because they are reliably effective and simple to employ. However, little is known about the detailed molecular mechanism of BAX activation by these detergents and its comparability with in vivo activation of BAX. What is known is that concentrations of detergent above their critical micelle concentration (CMC) are necessary for BAX activation. This suggests that, to be activated, BAX needs to interact with detergent micelles instead of monomeric detergent molecules. For example, in the case of BAX activation by n-octyl glucoside, it has been shown that n-octyl glucoside concentration should be 1% (w/v) (7), which is well above the CMC for this detergent (0.6% w/v) (11). In addition, it has also been shown that above their individual CMC concentrations most BAX-activating detergents produce a change in BAX conformation that can be detected by a conformation-sensitive 6A7 antibody against BAX (1, 12, 13). In cellular experiments this feature of BAX reactivity to 6A7 antibody is commonly associated with the onset of apoptosis (14, 15). However, CHAPS does not generate the antibody-detected conformational change or the activation of BAX. The small micelle size of this detergent (10 kDa) suggests that perhaps BAX cannot adopt an activated state with this detergent. However, cholic acid with even smaller micelle size (4 kDa) can partially activate BAX (1).Many important detergent properties are associated with micelles. The formation of detergent micelles in solution is concentration-dependent beginning at the CMC. The CMC value for a detergent has practical importance because in most cases only monomers of detergent can be removed by dialysis, and therefore, it is easier to remove detergent monomers for a detergent with high CMC value than for a detergent with low CMC (11). For BAX this same consideration applies to its activation with n-octyl glucoside (CMC ∼23 mm) as compared with its activation with Triton X-100 (CMC ∼0.25 mm). The ease of dialysis is why, in most cases, OG is used to activate BAX in vitro.It has been shown by analytical gel filtration that, when incubated with n-octyl glucoside, BAX creates complexes with molecular weight larger than the combined size of a BAX monomer (21 kDa) and an n-octyl glucoside micelle (∼26 kDa) (7, 11). It has also been shown that in defined liposomes BAX pore formation requires oligomerization (16). These data combined with the knowledge that oligomerization is important for the biological function of BAX led to a hypothesis that BAX oligomerizes during its detergent activation prior to membrane insertion (7). However, it has been shown that in vivo activated BAX inserts into the outer mitochondrial membrane as a monomer (3), and to create a pore, BAX undergoes oligomerization in this membrane (4). This discrepancy between the oligomeric state of active BAX prior to its insertion into a lipid membrane in vivo (monomer) and in vitro (possibly hexamer or octamer) led us to study the oligomerization state of BAX in detergent micelles. The important issue is whether BAX activation requires protein oligomerization or whether active BAX conformation can be generated from a single protein monomer. To solve this issue we used two single-molecule sensitivity techniques: fluorescence correlation spectroscopy (FCS) (17) and fluorescence-intensity distribution analysis (FIDA) (18). Combined use of FCS and FIDA allows simultaneous determination of the apparent molecular weight and the number of fluorescently labeled BAX monomers per protein-detergent micelle. Our results are consistent with previously established results in which BAX forms high molecular weight protein-detergent micelles with n-octyl glucoside (4) and show that BAX is present as a monomer in these complexes. In addition, we determined the apparent molecular weight and the number of BAX proteins bound per protein-detergent micelles formed by BAX and micelles of five additional detergents (dodecyl maltoside, Triton X-100, Tween 20, cholic acid, and CHAPS). Our data show that BAX is a monomer before, during, and after interaction with the micelles of all tested detergents.     

Global transcriptional response of pig brain and lung to natural infection by Pseudorabies virus

Background  

Pseudorabies virus (PRV) is an alphaherpesviruses whose native host is pig. PRV infection mainly causes signs of central nervous system disorder in young pigs, and respiratory system diseases in the adult.     

Force measurements of the disruption of the nascent polypeptide chain from the ribosome by optical tweezers

We show that optical tweezers are a valuable tool to study the co-translational folding of a nascent polypeptide chain at the ribosome in real-time. The aim of this study was to demonstrate that a stable and intact population of ribosomes can be tethered to polystyrene beads and that specific hook-ups to the nascent polypeptide chain by dsDNA handles, immobilized on a second bead, can be detected. A rupture force of the nascent chain in the range of 10-50 pN was measured, which demonstrates that the system is anchored to the surface in a stable and specific way. This will allow in numerous future applications to follow protein folding using much lower forces.