The burgeoning molecular genetics of the Lyme disease spirochaete

Lyme disease is the most commonly reported vector-borne disease in North America and Europe, yet we know little about which components of the causative agent, Borrelia burgdorferi, are critical for infection or virulence. Molecular genetics has provided a powerful means by which to address these topics in other bacterial pathogens. Certain features of B. burgdorferi have hampered the development of an effective system of genetic analysis, but basic tools are now available and their application has begun to provide information about the identities and roles of key bacterial components in both the tick vector and the mammalian host. Increased genetic analysis of B. burgdorferi should advance our understanding of the infectious cycle and the pathogenesis of Lyme disease.     

Chemical xenobiotics and mitochondrial autoantigens in primary biliary cirrhosis: identification of antibodies against a common environmental, cosmetic, and food additive, 2-octynoic acid

Emerging evidence has suggested environmental factors as causative agents in the pathogenesis of primary biliary cirrhosis (PBC). We have hypothesized that in PBC the lipoyl domain of the immunodominant E2 component of pyruvate dehydrogenase (PDC-E2) is replaced by a chemical xenobiotic mimic, which is sufficient to break self-tolerance. To address this hypothesis, based upon our quantitative structure-activity relationship data, a total of 107 potential xenobiotic mimics were coupled to the lysine residue of the immunodominant 15 amino acid peptide of the PDC-E2 inner lipoyl domain and spotted on microarray slides. Sera from patients with PBC (n = 47), primary sclerosing cholangitis (n = 15), and healthy volunteers (n = 20) were assayed for Ig reactivity. PBC sera were subsequently absorbed with native lipoylated PDC-E2 peptide or a xenobiotically modified PDC-E2 peptide, and the remaining reactivity analyzed. Of the 107 xenobiotics, 33 had a significantly higher IgG reactivity against PBC sera compared with control sera. In addition, 9 of those 33 compounds were more reactive than the native lipoylated peptide. Following absorption, 8 of the 9 compounds demonstrated cross-reactivity with lipoic acid. One compound, 2-octynoic acid, was unique in both its quantitative structure-activity relationship analysis and reactivity. PBC patient sera demonstrated high Ig reactivity against 2-octynoic acid-PDC-E2 peptide. Not only does 2-octynoic acid have the potential to modify PDC-E2 in vivo but importantly it was/is widely used in the environment including perfumes, lipstick, and many common food flavorings.     

Kinetic and stability properties of Penicillium chrysogenum ATP sulfurylase missing the C-terminal regulatory domain

ATP sulfurylase from Penicillium chrysogenum is a homohexameric enzyme that is subject to allosteric inhibition by 3'-phosphoadenosine 5'-phosphosulfate. In contrast to the wild type enzyme, recombinant ATP sulfurylase lacking the C-terminal allosteric domain was monomeric and noncooperative. All kcat values were decreased (the adenosine 5'-phosphosulfate (adenylylsulfate) (APS) synthesis reaction to 17% of the wild type value). Additionally, the Michaelis constants for MgATP and sulfate (or molybdate), the dissociation constant of E.APS, and the monovalent oxyanion dissociation constants of dead end E.MgATP.oxyanion complexes were all increased. APS release (the k6 step) was rate-limiting in the wild type enzyme. Without the C-terminal domain, the composite k5 step (isomerization of the central complex and MgPPi release) became rate-limiting. The cumulative results indicate that besides (a) serving as a receptor for the allosteric inhibitor, the C-terminal domain (b) stabilizes the hexameric structure and indirectly, individual subunits. Additionally, (c) the domain interacts with and perfects the catalytic site such that one or more steps following the formation of the binary E.MgATP and E.SO4(2-) complexes and preceding the release of MgPPi are optimized. The more negative entropy of activation of the truncated enzyme for APS synthesis is consistent with a role of the C-terminal domain in promoting the effective orientation of MgATP and sulfate at the active site.     

Spatial structure and genetic diversity of three tropical tree species with different habitat preferences within a natural forest

Analyses of the spatial distribution pattern, spatial genetic structure and genetic diversity were carried out using a 33-ha plot in a hill dipterocarp forest for three dipterocarps with different habitat preferences, i.e. Shorea curtisii on the ridges, Shorea leprosula in the valleys and Shorea macroptera both on the ridges and in the valleys. The significant spatial aggregation in small-diameter trees of all the three species was explained by limited seed dispersal. At the large-diameter trees, only S. macroptera showed random distribution and this might further prove that S. macroptera is habitat generalist, whilst S. curtisii and S. leprosula are habitat specific. The levels of genetic diversity estimated based on five microsatellite loci were high and comparable in all the three studied species. As the three studied species reproduced mainly through outcrossing, the observed high levels of genetic diversity might support the fact that the plant mating system can be used as guideline to infer the levels of genetic diversity, regardless of whether the species is habitat specific or habitat generalist. The lack of spatial genetic structure but significant aggregation in the small-diameter trees of all the three species might indicate limited seed dispersal but extensive pollen flow. Hence, if seed dispersal is restricted but pollen flow is extensive, significant spatial aggregation but no spatial genetic structure will be observed at the small-diameter trees, regardless of whether the species is habitat specific or habitat generalist. The inferred extensive pollen flow might indicate that energetic pollinators are involved in the pollination of Shorea species in the hill dipterocarp forests.     

Profiling of glycans in serum for the discovery of potential biomarkers for ovarian cancer

A glycomic approach is developed to identify oligosaccharide markers for ovarian cancer by rapidly profiling globally released oligosaccharides. Glycoproteins shed by cancer cells are found in the supernatant (or conditioned media) of cultured cells. In this approach, shed glycoproteins are profiled for their oligosaccharide content using beta-elimination conditions. Changes in glycosylation are monitored by matrix-assisted laser desorption/ionization Fourier transform ion cyclotron resonance mass spectrometry (MALDI-FTICR-MS). Because shed glycoproteins would also be found in serum, similar glycan profiling was performed to observe potential oligosaccharide markers. Oligosaccharide profiling data on a limited set of patient and normal serum samples were studied to determine potential glycan markers in ovarian cancer. We were able to demonstrate the presence of at least 15 unique serum glycan markers in all patients but absent in normal individuals. To determine the structure of the glycan biomarkers, a number of the ions were isolated and further analyzed using infrared multiphoton dissociation (IRMPD). One major advantage of this approach is that glycans are examined directly from patient sera without the need to obtain cancer biopsy specimens or to purify glycosylated proteins from these specimens.     

Intraspecific differences in the diet of Antarctic fur seals at Nyrøysa, Bouvetøya

Intraspecific differences in the diets of many species of pinnipeds are to be expected in view of the great differences in morphology, life history and foraging behaviour between the sexes of many species. We examined the diet of the Antarctic fur seal population at Bouvetøya, Southern Ocean, to assess intersexual differences. This was made possible by the analysis of prey remains extracted from scats and regurgitations collected in areas used primarily by one or the other sex. The results indicate that both males and females feed primarily on Antarctic krill Euphausia superba with several species of fish and squid being taken, likely opportunistically given their prevalence. Significant differences were identified in the frequency of occurrence of otoliths in scats and the percentage numerical abundance of the major fish prey species in the diet. Adult males ate a smaller quantity of fish overall, but ate significantly more of the larger fish species. The greater diving capabilities of males and the fact that they are not limited in the extent of their foraging area by having to return regularly to feed dependant offspring may play a role in the differences found between the diets of males and females. Additionally, females might be more selective, favouring myctophids because they are richer in energy than krill. The absence of major differences in the diet between the sexes at this location is likely due to the high overall abundance of prey at Bouvetøya.     

Role of voltage‐gated potassium channels in the fate determination of embryonic stem cells

Embryonic stem cells (ESCs) possess two unique characteristics: self‐renewal and pluripotency. In this study, roles of voltage‐gated potassium channels (K_v) in maintaining mouse (m) ESC characteristics were investigated. Tetraethylammonium (TEA⁺), a K_v blocker, attenuated cell proliferation in a concentration‐dependent manner. Possible reasons for this attenuation, including cytotoxicity, cell cycle arrest and differentiation, were examined. Blocking K_v did not change the viability of mESCs. Interestingly, K_v inhibition increased the proportion of cells in G₀/G₁ phase and decreased that in S phase. This change in cell cycle distribution can be attributed to cell cycle arrest or differentiation. Loss of pluripotency as determined at both molecular and functional levels was detected in mESCs with K_v blockade, indicating that K_v inhibition in undifferentiated mESCs directs cells to differentiate instead of to self‐renew and progress through the cell cycle. Membrane potential measurement revealed that K_v blockade led to depolarization, consistent with the role of K_v as the key determinant of membrane potential. The present results suggest that membrane potential changes may act as a “switch” for ESCs to decide whether to proliferate or to differentiate: hyperpolarization at G₁ phase would favor ESCs to enter S phase while depolarization would favor ESCs to differentiate. Consistent with this notion, S‐phase‐synchronized mESCs were found to be more hyperpolarized than G₀/G₁‐phase‐synchronized mESCs. Moreover, when mESCs differentiated, the differentiation derivatives depolarized at the initial stage of differentiation. This investigation is the first study to provide evidence that K_v and membrane potential affect the fate determination of ESCs. J. Cell. Physiol. 224:165–177, 2010 © 2010 Wiley‐Liss, Inc.     

SpoIID-Mediated Peptidoglycan Degradation Is Required throughout Engulfment during Bacillus subtilis Sporulation

SpoIID is a membrane-anchored enzyme that degrades peptidoglycan and is essential for engulfment and sporulation in Bacillus subtilis. SpoIID is targeted to the sporulation septum, where it interacts with two other proteins required for engulfment: SpoIIP and SpoIIM. We changed conserved amino acids in SpoIID to alanine to determine whether there was a correlation between the effect of each substitution on the in vivo and in vitro activities of SpoIID. We identified one amino acid substitution, E88A, that eliminated peptidoglycan degradation activity and one, D210A, that reduced it, as well as two substitutions that destabilized the protein in B. subtilis (R106A and K203A). Using these mutants, we show that the peptidoglycan degradation activity of SpoIID is required for the first step of engulfment (septal thinning), as well as throughout membrane migration, and we show that SpoIID levels are substantially above the minimum required for engulfment. The inactive mutant E88A shows increased septal localization compared to the wild type, suggesting that the degradation cycle of the SpoIID/SpoIIP complex is accompanied by the activity-dependent release of SpoIID from the complex and subsequent rebinding. This mutant is also capable of moving SpoIIP across the sporulation septum, suggesting that SpoIID binding, but not peptidoglycan degradation activity, is needed for relocalization of SpoIIP. Finally, the mutant with reduced activity (D210A) causes uneven engulfment and time-lapse microscopy indicates that the fastest-moving membrane arm has greater concentrations of SpoIIP than the slower-moving arm, demonstrating a correlation between SpoIIP protein levels and the rate of membrane migration.Endospore formation is an evolutionarily conserved process that allows Bacillus subtilis and related Gram-positive bacteria to adapt to changes in the environment, such as nutrient depletion. Many dramatic morphological changes occur during sporulation, each requiring a multitude of specialized proteins (reviewed in references 13 and 17). First, a sporulation septum is formed near one of the cell poles, forming two separate compartments of unequal sizes and with differing fates (Fig. ​(Fig.1A).1A). The smaller of the two, the forespore, will eventually become the spore, while the larger, the mother cell, will ultimately lyse. Next, the mother cell membranes move up and around the forespore in the poorly understood process of engulfment. Although this process is superficially similar to eukaryotic engulfment, it is complicated by the thick cell wall that surrounds and separates the two compartments. After engulfment, the migrating membranes pinch off from the mother cell membrane, thereby releasing the forespore into the cytoplasm of the mother cell, where it can be enveloped with protective coat proteins and eventually released into the environment as a mature spore. Sporulation provides an ideal, nonessential system for understanding how bacterial cells are capable of undergoing dramatic morphological changes.Open in a separate windowFIG. 1.Engulfment in B. subtilis. (A) (i) Engulfment begins with formation of an asymmetric septum that divides the cell into the forespore (FS) and mother cell (MC). SpoIID (orange pacman) and SpoIIP (green pacman) peptidoglycan degradation enzymes localize to the center of the septum. (ii) SpoIID and SpoIIP thin the septal peptidoglycan, starting from the center and moving toward the cell edges. SpoIIQ (purple ball) and SpoIIIAH (red ball) form a zipper across the septum, assembling foci behind the leading edges. (iii) The peptidoglycan degradation enzymes localize to the leading edges during membrane migration, while additional SpoIIQ-SpoIIIAH complexes assemble around the forespore. (iv) Engulfment membrane fission occurs at the top of the forespore, releasing the forespore into the mother cell cytoplasm. (B) Burnt-bridge Brownian ratchet model for membrane migration, adapted from earlier studies (1, 7). (C) Schematic representation of the SpoIID domain structure. The transmembrane domain (TM) and putative enzymatic domain, as defined by Pfam (14), are indicated. Amino acid numbers are below the schematic, and mutations causing in vivo phenotypes are indicated by an “X”.Engulfment involves dynamic protein localization and large-scale rearrangements of cellular membranes and peptidoglycan to accommodate internalization of the forespore. The physical basis for engulfment remains unclear, but two separate protein machineries that contribute to engulfment have been discovered. The first module involves the only three proteins known to be required for engulfment under all physiological conditions: SpoIID, SpoIIM, and SpoIIP (16, 24, 35). Zymography assays have demonstrated that both SpoIID and SpoIIP degrade peptidoglycan in vitro (1, 8), and this function is thought to be essential for engulfment in wild-type cells (1, 2, 8). SpoIID and SpoIIP are membrane-spanning proteins that directly interact both in vivo and in vitro, as demonstrated by coimmunoprecipitation and affinity chromatography techniques (2, 8). These studies failed to demonstrate an interaction between SpoIIM and either SpoIID or SpoIIP, perhaps because SpoIIM is an integral membrane protein. However, SpoIIM is required for localization of SpoIID and SpoIIP (2, 8), suggesting that all three proteins interact to form a peptidoglycan degradation module that is essential for engulfment.The second system influencing membrane migration is the SpoIIQ/SpoIIIAH zipper, which is required for engulfment only under certain conditions (2, 7, 38). SpoIIQ is produced in the forespore (23) and SpoIIIAH is produced in the mother cell (19). SpoIIQ and SpoIIIAH interact both in vitro and in vivo via their extracellular domains (6, 7, 10). Because these two proteins are produced in separate compartments, the only possible place for an interaction is the intermembrane space between the mother cell and forespore, forming a protein-protein zipper between the two cells. This zipperlike interaction is necessary for septal localization of SpoIIIAH and other mother cell proteins (6, 10, 18) and is capable of holding the two cells together when peptidoglycan is removed with lysozyme (7). Surprisingly, digestion of the peptidoglycan with lysozyme also allows membrane migration in about half of treated cells, in a process requiring the SpoIIQ/SpoIIIAH zipper but not the SpoIIDMP peptidoglycan degradation module. The SpoIIQ-SpoIIIAH zipper also contributes to engulfment in living cells, since strains lacking SpoIIQ or SpoIIIAH complete engulfment more slowly than the wild type and have synergistic engulfment defects when certain secondary mutations are introduced (2, 7, 38). Together, these results strongly support a role for the SpoIIQ/SpoIIIAH module in engulfment, demonstrating that the zipper contributes to the efficiency of membrane migration even when the SpoIIDMP module is present and functional. They also suggest that the engulfment machinery displays functional redundancy and that the zipper module provides a backup machinery for membrane migration.The precise role of the SpoIIDMP module during engulfment remains unclear. One model proposes that SpoIID and SpoIIP act as a burnt-bridge Brownian ratchet (Fig. ​(Fig.1B)1B) (1, 7). This model asserts that as SpoIID and SpoIIP degrade peptidoglycan, they eliminate their own enzymatic targets, resulting in the absence of substrate in one direction and therefore, overall movement in the opposite direction. As the enzymes move forward toward new targets, the mother cell membranes are dragged along with them because they are anchored in the membrane. This hypothesis predicts that SpoIID and SpoIIP are processive enzymes and that the SpoIIDMP complex could function as a motor, moving along peptidoglycan as a track and pulling the membranes with it (1, 7). A second model predicts that peptidoglycan degradation could simply remove a steric hindrance to membrane migration (such as links between the forespore membrane and the cell wall) and that some other mechanism provides the force required for membrane migration. Although the SpoIIQ-SpoIIIAH module can contribute to membrane migration, these proteins are not always essential for engulfment in intact cells (7, 38), suggesting that another unidentified system must generate the force required for membrane movement if the DMP module does not act as a burnt-bridge Brownian ratchet. Recent evidence suggests that peptidoglycan biosynthesis, which is localized to the leading edge of the engulfing membrane and necessary for membrane migration in the absence of the SpoIIQ-SpoIIIAH proteins, might be this missing force generating mechanism (26).Both models predict that the activities of SpoIID and SpoIIP are essential for membrane migration. This requirement has been demonstrated for SpoIIP (8) and, while this work was under review, for SpoIID. SpoIID shows no sequence similarity to any characterized enzyme that degrades peptidoglycan and thus constitutes the founding member of a new class of enzymes that remodel peptidoglycan (1, 27). However, SpoIID does show some similarity to B. subtilis LytB (24), a protein that enhances the activity of the amidase LytC (5, 20, 34), while SpoIIP is related to LytC (14). A recent study demonstrated that SpoIIP is both an amidase and endopeptidase and that SpoIID both activates SpoIIP and functions as a lytic transglycosylase, cleaving peptidoglycan between NAG and NAM (27). Together, these two enzymes degrade peptidoglycan into its smallest repeating subunits. However, it remains unclear which of the demonstrated or suggested biochemical functions of SpoIID are required for its various in vivo activities (interaction with SpoIIP, localization, septal thinning, and membrane migration), and it is unclear whether peptidoglycan degradation activity is required throughout engulfment or only for the initial stage of septal thinning.We use site-directed mutagenesis to test the role of 56 conserved amino acids in SpoIID, focusing on hydrophilic amino acids that might be involved in protein-protein interactions and peptidoglycan degradation. We identified one mutation (E88A) that eliminates and three others (R106A, K203A, and D210A) that reduce peptidoglycan degradation activity and show that SpoIID activity is required for the earliest stage of engulfment (septal thinning), as well as throughout membrane migration. Our results confirm and extend those of Morlot et al. (27) and also demonstrate that SpoIID activity is required throughout engulfment. Furthermore, our data indicate that the enzymatically inactive mutant protein (E88A) shows increased septal localization compared to the wild-type protein, suggesting that peptidoglycan degradation contributes to the release of SpoIID from the septum. We propose a modified model for the enzymatic cycle of the SpoIID and SpoIIP complex.     

Evidence that the SpoIIIE DNA translocase participates in membrane fusion during cytokinesis and engulfment

During Bacillus subtilis sporulation, SpoIIIE is required for translocation of the trapped forespore chromosome across the sporulation septum, for compartmentalization of cell-specific gene expression, and for membrane fusion after engulfment. We isolated mutations within the SpoIIIE membrane domain that block localization and function. One mutant protein initially localizes normally and completes DNA translocation, but shows reduced membrane fusion after engulfment. Fluorescence recovery after photobleaching experiments demonstrate that in this mutant the sporulation septum remains open, allowing cytoplasmic contents to diffuse between daughter cells, suggesting that it blocks membrane fusion after cytokinesis as well as after engulfment. We propose that SpoIIIE catalyses these topologically opposite fusion events by assembling or disassembling a proteinaceous fusion pore. Mutants defective in SpoIIIE assembly also demonstrate that the ability of SpoIIIE to provide a diffusion barrier is directly proportional to its ability to assemble a focus at the septal midpoint during DNA translocation. Thus, SpoIIIE mediates compartmentalization by two distinct mechanisms: the SpoIIIE focus first provides a temporary diffusion barrier during DNA translocation, and then mediates the completion of membrane fusion after division to provide a permanent diffusion barrier. SpoIIIE-like proteins might therefore serve to couple the final step in cytokinesis, septal membrane fusion, to the completion of chromosome segregation.