Serotyping of Campylobacter jejuni, Campylobacter coli, and Campylobacter laridis from domestic and wild animals.

By using 50 unabsorbed antisera, we were able to serotype 272 (65.7%) of 414 thermotolerant campylobacters from wild and domestic animals, on the basis of heat-stable antigens identified by means of passive hemagglutination. Forty-two serotypes were recognized. The pattern of serotypes detected in the various animal species was compared to human clinical isolates by using the Czekanowski index (proportional similarity index). The highest degree of similarity to the clinical isolates was observed for the poultry isolates, followed by strains from wild birds, flies, and pigs (in order of decreasing similarity). The serotypes recovered most frequently from poultry (LAU 1 and LAU 2) were also most prevalent in Norwegian patients. In contrast, serotype LAU 35/44, the predominant porcine serotype, was never recovered from human clinical specimens. Flies captured in chicken farms and in piggeries harbored serotypes which were also commonly seen in chickens and pigs, respectively. Nine of the strains included in this study could not be ascribed to any defined species. All of these were resistant to nalidixic acid and did not produce H2S.     

Thermal properties of enzymes from Bacillus flavothermus,grown between 34 and 70°C

The activity and stability of several enzymes from the facultative thermophile Bacillus flavothermus, grown within the mesophilic and thermophilic region at 34 degrees C, 43 degrees C, 52 degrees C and 70 degrees C, have been examined. While the temperature optima and maxima of all enzymes tested were found to remain unchanged at all growth temperatures, it was demonstrated that the heat stability of the proteins increased with ten perature, however, not uniformly for all enzymes. One exception was acetate kinase and the intrinsic stability of pyruvate kinase was found to increase only slightly. With all other proteins tested (alanine dehydrogenase, isocitric dehydrogenase and glucose-6-phosphate dehydrogenase, glutamate-oxalacetate and glutamate-pyruvate transaminase and myokinase) the intrinsic stability was found to increase to about 55 degrees C, but stayed unaltered at higher growth temperatures. Except for acetate kinase and myokinase, the enzymes could be stabilized by their respective substrates and the heat stability of the ES-complexes was found also to depend on the growth temperature of the cells. These data lead to the conclusion that the enzymes undergo a transition from heat-labile to thermostable within the growth temperature range between 44 degrees C and 51 degrees C while the thermal characteristics are not changed below and beyond this crucial region.     

Properties of enzymes from bacteria grown in the 70–100°C range

In chemostat cultures of Bacillus caldolyticus, adaptation in a single step from 70–100°C was followed under aerobic and oxygen-limited conditions and was found to proceed more smoothly under the latter circumstances. Variations of the medium (e.g. yeast extract or silicate concentrations) showed that growth at 100°C is in all respects similar to that of cultures at moderate temperatures.Enzyme preparations derived from cultures at 5°C intervals between 70 and 100°C were used to determine the temperature range. For all nine enzymes tested, the optimum temperature was found to be 67°C; the latter was independent of the growth temperature. Differences were found, however, with respect to the maximum temperature of individual enzymes, and three groups, with maxima between 70 and 80°C, 80 and 90°C and 90 and 100°C can be distinguished. Again, there was no correlation with the growth temperature.Stability experiments also revealed that enzymes from the same organism can have different thermal properties: Some were found to be quite thermolabile (e.g. the pyruvate kinase), while others (e.g. hexokinase and glutamate-pyruvate transaminase) exhibited a high thermostability. These properties were not related to the growth temperature within the 70–100°C range, too.Six of the enzymes tested could be stabilized by their respective substrates, but the degree of protection varied for individual enzymes. Three enzymes (acetate kinase, glutamate dehydrogenase and myokinase) could not be stabilized by their substrates.Comparative experiments with the hexokinase suggested, that the thermal integrity of the enzymes is better protected within the cell as compared to the stability of the enzyme preparations.Abbreviations used AK acetate kinase - Ala-DH alanine dehydrogenase - Ald aldolase - GIDH glutamate dehydrogenase - G6P-DH glucose-6-phosphate dehydrogenase - GTP glutamate-pyruvate transaminase - HK hexokinase - ICDH isocitrate dehydrogenase - MK myokinase - PK pyruvate kinase     

Chaperoning the synapse—NMNAT protects Bruchpilot from crashing

Maintaining active zone structure is crucial for synaptic function. In this issue of EMBO reports, NMNAT is shown to act as a chaperone that protects the active zone structural protein Bruchpilot from degradation.EMBO reports (2013) 14 1, 87–94 doi:10.1038/embor.2012.181Synapses perform several tasks independently from the cell body of the neuron, including synaptic vesicle recycling through endocytosis or local protein maturation and degradation. Failure to regulate protein function locally is detrimental to the nervous system as evidenced by neuronal dysfunctions that arise as a consequence of synaptic ageing. This relative synaptic autonomy comes with a need for mechanisms that ensure correct protein (re)folding, and there is accumulating evidence that key chap-erones have a central role in the regulation and maintenance of synaptic structural integrity and function [1]. Work by Grace Zhai''s group, published in this issue of EMBO reports, demonstrates a key role of the Drosophila nicotinamide mononucleotide adenylyltransferase (NMNAT) chaperone in the protection of active zone components against activity-induced degeneration (Fig 1; [2]).Open in a separate windowFigure 1Results reported by Zang and colleagues [2] reveal a specific role of nicotinamide mononucleotide adenylyltransferase (NMNAT) in preserving active zone structure against use-dependent decline. This protection is exerted by direct interaction with BRP and protection of this key structural protein against ubiquitination and subsequent degradation. BRP, Bruchpilot; Ub, ubiquitin.Active zones, the specialized sites for neurotransmitter release at presynaptic terminals, are characterized by a dense protein network called the cytomatrix at the active zone (CAZ). The protein machinery of the CAZ is responsible for efficient synaptic vesicle tethering, docking and fusion with the presynaptic membrane and, thus, for reliable signal transmission from the neuron to the postsynaptic cell. Clearly, proteins in the CAZ are tightly regulated, especially in response to external cues such as synaptic activity [3,4]. Yet, this particularly crowded protein environment might be favourable for the formation of non-functional—and sometimes toxic—protein aggregates. Chaperones that act at the synapse reduce the probability of crucial protein aggregation by preventing and reverting these inappropriate interactions, which happen as a result of environmental stress.One of these chaperones, the Drosophila neuroprotective NMNAT, was identified in a genetic screen for factors involved in synapse function [5]. Its chaperone activity was later confirmed by using in vitro and in vivo protein folding assays [6]. NMNAT null mutants show severe and early onset neurodegeneration, whereas neurodevelopment does not seem to be strongly affected. Interestingly, degeneration of photoreceptors lacking NMNAT can be significantly attenuated by limiting synaptic activity, either by rearing flies in the dark or by introducing the no receptor potential A (norpA) mutation that blocks phototransduction [5]. These results indicate that NMNAT protects adult neurons from activity-induced degeneration.In this issue of EMBO reports, Zang and colleagues report a role for NMNAT at the synapse. They observed that loss or reduced levels of NMNAT leads to a concomitant loss of several synaptic markers including cysteine-string protein (CSP), synaptotagmin and the active zone structural protein Bruchpilot (BRP). Remarkably, BRP was the only one of these proteins found to co-immunoprecipitate with NMNAT from brain lysates. Both proteins show approximately 50% co-localization at the neuromuscular junction when imaged by 3D-SIM^™ super-resolution microscopy, suggesting that NMNAT might act directly as a chaperone for maintaining a functional BRP conformation.Consistent with a protective role of NMNAT against BRP degradation, RNA interference-mediated NMNAT knockdown leads to BRP ubiquitination, whereas this modification was not detected in control brain lysates. Given the involvement of the ubiquitin proteasome pathway in regulating synaptic development and function [1], the authors tested the effect of the proteasome inhibitor MG-132 on BRP ubiquitination. They observed an increased level of BRP ubiquitination in wild-type flies fed with this drug, suggesting a role for the proteasome in the clearance of ubiquitinated BRP. By contrast, overexpression of NMNAT reduces the level of BRP ubiquitination both in the absence and the presence of MG-132, providing further evidence for the protective role of this chaperone against ubiquitination of BRP (Fig 1).a key role of the […] nicotinamide mononucleotide adenylyltransferase (NMNAT) chaperone in the protection of active zone components against activity-induced degenerationBRP is a cytoskeletal-like protein that is an integral component of T-bars—electron-dense structures that project from the presynaptic membrane and around which synaptic vesicles cluster. In agreement with a protective role of NMNAT against BRP ubiquitination, reduced levels of this chaperone give rise to a marked decrease in T-bar size in an age-dependent manner (Fig 1). Active zones are known to show dynamic changes in response to synaptic activity, and NMNAT was previously reported to protect photoreceptors against activity-induced degeneration [5]. The authors thus tested the effect of minimizing photoreceptor activity on active zone structure by keeping flies in the dark or inhibiting phototransduction by means of the norpA mutation. Both manipulations largely reversed the effect of NMNAT knockdown on T-bar size. Absence of light exposure also significantly reduced the amount of BRP that co-immunoprecipitates with NMNAT, indicating that neuronal activity regulates NMNAT–BRP interaction. Further experiments are needed to examine whether there is a positive correlation between synaptic activity and BRP ubiquitination levels, and whether NMNAT can indeed keep T-bar structure intact by protecting BRP against this modification under conditions of high synaptic activity.Finally, the study shows that reduced NMNAT levels not only caused a loss of BRP from the synapse but also a specific mislocalization of this protein to the cell body, where it accumulates in clusters together with the remaining NMNAT protein. Under these conditions BRP co-immunoprecipitated with the stress-induced Hsp70, a chaperone classically used as a marker for protein aggregation. It is still unclear whether these BRP clusters form as a result of defective anterograde trafficking and/or of enhanced retrograde transport of BRP. In the absence of light stimulation T-bars are properly assembled in nmnat null photoreceptors, but at this stage a role of NMNAT in regulating the axonal transport of BRP under conditions of normal synaptic activity cannot be excluded. Noticeably, two independent recent reports show involvement of NMNAT in mitochondrial mobility [7,8].As BRP and NMNAT co-localize and interact with one another, the simplest model that accounts for all the observations by Zang et al is that NMNAT directly prevents activity-induced ubiquitination of BRP and subsequent degradation. Yet, as its name indicates, this chaperone is an essential enzyme in NAD synthesis. It was previously shown by the Bellen lab that mutant versions of NMNAT, impaired for NAD production, rescue photoreceptor degeneration caused by loss of NMNAT [5]. This strongly suggests that NAD production is not required for stabilization of BRP but this might need further scrutiny [9].…reduced levels of this chaperone [NMNAT] give rise to a marked decrease in T-bar sizeWhile providing further insights into the role of NMNAT at the active zone in Drosophila, the paper by Zang et al might also have important implications for neurodegeneration in mammals. When ectopically expressed in mice, Nmnat has a protective role against Wallerian degeneration, that is, synapse and axon degeneration that rapidly occurs distal from an axonal wound in wild-type animals. This process is significantly delayed in mice overexpressing a chimaeric protein consisting of the amino-terminal 70 residues of the ubiquitination factor E4B (Ube4b) fused through a linker to Nmnat1, known as the Wallerian degeneration slow (Wld^s) protein. Conversely, mutations in the human NMNAT1 gene were characterized in several families with Leber congenital amaurosis—a severe, early-onset neurodegenerative disease of the retina [10,11,12,13]. As Wld^s or Nmnat1 overexpression protects axons from degeneration in various disease models [9], Nmnat1 emerges as a promising candidate for developing protective strategies against axonal degeneration in peripheral neuropathies such as amyotrophic lateral sclerosis but also in glaucoma, AIDS and other diseases [9].     

The suitability of a faecal suspension of sheep as inocula for the estimation of utilizable crude protein of feeds by in vitro incubation

The objective of this review is to outline those parts of modelling approaches in pig production which are not highly developed; these are the partitioning of protein and lipid accretion in different anatomical body parts. The authors introduce present models with a critical evaluation and draw some conlusions for further developments. Based on present knowledge this paper demonstrates the process of protein and fat accretion in different body compartments in pigs and influencing factors. A further aim is to assist in the conceptual development of a new pig model, which is more detailed, precise and accurate than currently available models. Exsisting models are generally deficient with regard to the translation of lipid and protein gain into lean and fatty tissue. Only assumed values for this translation have been used so far and the concepts underlying these values are not well understood. Therefore, it may be appropriate to develop a compartimental model to predict protein and fat deposition in growing and fattening pigs. With this new approach the model can supply sufficiently the changing consumer demands regarding to the possibility of meat quality prediction.     

Functional expression of murine LRP1 requires correction of Lrp1 cDNA sequences

Here, we describe the reconstruction of a functional 14 kbp full-length murine Lrp1 cDNA from overlapping partial cDNAs, which were described before [Biochim. Biophys. Acta 1173 (1993) 71]. The reconstructed full-length cDNA needed sequence correction (by mutagenesis) due to nucleotide errors present in the underlying partial cDNAs. These mistakes compromised the proteolytical maturation of the LRP precursor (4545 aa) into its alpha- and beta-subunits. To identify these mistakes initially, detailed sequence analyses and comparison of genomic and cDNA sequences of different murine strains proved to be necessary to obtain correct wild-type sequences. Comparison of Lrp1 cDNA sequences of CBA mice with Lrp1 genomic exon sequences of 129P3/J mice (like in man 89 exons) revealed only 24 nucleotide differences within about 14.8 kbp. Only 1 out of 23 nucleotide differences in the protein coding region affected an amino acid residue: Thr versus Ala at amino acid residue position 2642 in 129P3/J and CBA, respectively. After correction by mutagenesis, both a 129P3/J and a CBA-based version of a full-length wild-type Lrp1 cDNA were functionally expressed in an LRP-deficient mutant CHO cell line. Transient expression showed the expected maturation of the LRP precursor into its two subunits. Furthermore, stable transfection restored the sensitivity to exposure to Pseudomonas aeruginosa toxin A (PEA). Since LRP is the unique receptor for this toxin, this indicates that the toxin could enter the cells after binding to and endocytosis by its genuine receptor. This murine LRP expression system will be instrumental in future experimental dissection of this multifunctional receptor.     

Soil inorganic carbon storage pattern in China

Soils with pedogenic carbonate cover about 30% (3.44 × 10⁶ km²) of China, mainly across its arid and semiarid regions in the Northwest. Based on the second national soil survey (1979–1992), total soil inorganic carbon (SIC) storage in China was estimated to be 53.3±6.3 PgC (1 Pg=10¹⁵ g) to the depth investigated to 2 m. Soil inorganic carbon storages were 4.6, 10.6, 11.1, and 20.8 Pg for the depth ranges of 0–0.1, 0.1–0.3, 0.3–0.5, and 0.5–1 m, respectively. Stocks for 0.1, 0.3, 0.5, and 1 m of depth accounted for 8.7%, 28.7%, 49.6%, and 88.9% of total SIC, respectively. In contrast with soil organic carbon (SOC) storage, which is highest under 500–800 mm yr⁻¹ of mean precipitation, SIC storage peaks where mean precipitation is <400 mm yr⁻¹. The amount and vertical distribution of SIC was related to climate and land cover type. Content of SIC in each incremental horizon was positively related with mean annual temperature and negatively related with mean annual precipitation, with the magnitude of SIC content across land cover types showing the following order: desert, grassland >shrubland, cropland >marsh, forest, meadow. Densities of SIC increased generally with depth in all ecosystem types with the exception of deserts and marshes where it peaked in intermediate layers (0.1–0.3 m for first and 0.3–0.5 m for latter). Being an abundant component of soil carbon stocks in China, SIC dynamics and the process involved in its accumulation or loss from soils require a better understanding.     

Evidence for coupled biogenesis of yeast Gap1 permease and sphingolipids: essential role in transport activity and normal control by ubiquitination

Current models for plasma membrane organization integrate the emerging concepts that membrane proteins tightly associate with surrounding lipids and that biogenesis of surface proteins and lipids may be coupled. We show here that the yeast general amino acid permease Gap1 synthesized in the absence of sphingolipid (SL) biosynthesis is delivered to the cell surface but undergoes rapid and unregulated down-regulation. Furthermore, the permease produced under these conditions but blocked at the cell surface is inactive, soluble in detergent, and more sensitive to proteases. We also show that SL biogenesis is crucial during Gap1 production and secretion but that it is dispensable once Gap1 has reached the plasma membrane. Moreover, the defects displayed by cell surface Gap1 neosynthesized in the absence of SL biosynthesis are not compensated by subsequent restoration of SL production. Finally, we show that down-regulation of Gap1 caused by lack of SL biogenesis involves the ubiquitination of the protein on lysines normally not accessible to ubiquitination and close to the membrane. We propose that coupled biogenesis of Gap1 and SLs would create an SL microenvironment essential to the normal conformation, function, and control of ubiquitination of the permease.     

Concordant phylogeography and cryptic speciation in two Western Palaearctic oak gall parasitoid species complexes

Little is known about the evolutionary history of most complex multi‐trophic insect communities. Widespread species from different trophic levels might evolve in parallel, showing similar spatial patterns and either congruent temporal patterns (Contemporary Host‐tracking) or later divergence in higher trophic levels (Delayed Host‐tracking). Alternatively, host shifts by natural enemies among communities centred on different host resources could disrupt any common community phylogeographic pattern. We examined these alternative models using two Megastigmus parasitoid morphospecies associated with oak cynipid galls sampled throughout their Western Palaearctic distributions. Based on existing host cynipid data, a parallel evolution model predicts that eastern regions of the Western Palaearctic should contain ancestral populations with range expansions across Europe about 1.6 million years ago and deeper species‐level divergence at both 8–9 and 4–5 million years ago. Sequence data from mitochondrial cytochrome b and multiple nuclear genes showed similar phylogenetic patterns and revealed cryptic genetic species within both morphospecies, indicating greater diversity in these communities than previously thought. Phylogeographic divergence was apparent in most cryptic species between relatively stable, diverse, putatively ancestral populations in Asia Minor and the Middle East, and genetically depauperate, rapidly expanding populations in Europe, paralleling patterns in host gallwasp species. Mitochondrial and nuclear data also suggested that Europe may have been colonized multiple times from eastern source populations since the late Miocene. Temporal patterns of lineage divergence were congruent within and across trophic levels, supporting the Contemporary Host‐tracking Hypothesis for community evolution.     

Nonuse of bicycle helmets and risk of fatal head injury: a proportional mortality, case�Ccontrol study

Background:

The effectiveness of helmets at preventing cycling fatalities, a leading cause of death among young adults worldwide, is controversial, and safety regulations for cycling vary by jurisdiction. We sought to determine whether nonuse of helmets is associated with an increased risk of fatal head injury.

Methods:

We used a case–control design involving 129 fatalities using data from a coroner’s review of cycling deaths in Ontario, Canada, between 2006 and 2010. We defined cases as cyclists who died as a result of head injuries; we defined controls as cyclists who died as a result of other injuries. The exposure variable was nonuse of a bicycle helmet.

Results:

Not wearing a helmet while cycling was associated with an increased risk of dying as a result of sustaining a head injury (adjusted odds ratio [OR] 3.1, 95% confidence interval [CI] 1.3–7.3). We saw the same relationship when we excluded people younger than 18 years from the analysis (adjusted OR 3.5, 95% CI 1.4–8.5) and when we used a more stringent case definition (i.e., only a head injury with no other substantial injuries; adjusted OR 3.6, 95% CI 1.2–10.2).

Interpretation:

Not wearing a helmet while cycling is associated with an increased risk of sustaining a fatal head injury. Policy changes and educational programs that increase the use of helmets while cycling may prevent deaths.One cyclist dies in Canada each week, and cycling fatalities account for more than 2% of traffic fatalities, a leading cause of death in young adults.¹ Cycling safety regulations vary by jurisdiction, and controversy remains about the effectiveness of safety measures such as helmets. There is strong evidence that helmets prevent nonfatal head injuries,² but very limited evidence exists related to fatal head injuries. A meta-analysis of case–control studies showed a protective effect of helmets against head injuries, but it was based on just 4 case fatalities in which helmets were not worn.³ Another large study involving 1710 cycling collisions found a trend toward a protective effect of helmets, but included only 14 fatalities.⁴ The existing literature leaves open the possibility that helmets prevent nonfatal head injuries, but not fatal ones.We sought to determine whether cycling without a helmet was associated with an increased risk of sustaining a fatal head injury.