127 research outputs found
Mikrobielle Proteinsynthese im Pansen bei der VerfĂŒtterung von artenreichen GrĂŒnlandaufwĂŒchsen des Ăkologischen Landbaus
Artenreiche und artenarme GrĂŒnlandaufwĂŒchse der Jahre 2007 und 2008 wurden hinsichtlich Siliereignung und Futterwert fĂŒr WiederkĂ€uer vergleichend untersucht. Die SommeraufwĂŒchse 2008 wurden siliert und in Stoffwechselversuchen an 4 pansenfistulierte Schafen allein und in Kombination mit Gerste gefĂŒttert. Im Kot wurden die Weender RohnĂ€hrstoffe, neutrale (NDF) und saure Detergentienfaser (ADF) sowie N-Fraktionen, im Harn Gesamt-N, Harnstoff, Allantoin und HarnsĂ€ure bestimmt. Die mikrobielle Proteinsynthese wurde mittels Dauerinfusionstechnik und Verwendung von 15N als Marker gemessen.
Die artenreichen AufwĂŒchse wiesen hohe Anteile an Leguminosen und KrĂ€utern auf, die artenarmen AufwĂŒchse bestanden nahezu vollstĂ€ndig aus GrĂ€sern. Der artenarme FrĂŒhjahrsaufwuchs 2007 enthielt mehr NDF und ADF als die entsprechende artenreiche Variante. Die Silagen waren reicher an Rohprotein (XP) und Nicht-Faser-Kohlenhydraten zugunsten der artenreichen und enthielten mehr NDF und ADF zugunsten der artenarmen Variante. Die artenreiche Silage wies im Vergleich zur artenarmen Silage höhere Anteile leicht löslicher Inhaltsstoffe und in situ höhere potentielle Trockensubstanz- und NDF-Abbaubarkeiten auf. Bei FĂŒtterung der artenreichen Silage wurden die organische Substanz, XP und ADF höher verdaut, und die Tiere schieden mehr bakteriell gebundenen Kotstickstoff sowie mehr Harnstoff ĂŒber den Harn als bei FĂŒtterung artenarmer Silage aus. Die Allantoin- und HarnsĂ€ureausscheidungen blieben unbeeinflusst von der Silageart. Die artenreiche Silage fĂŒhrte unabhĂ€ngig von der FĂŒtterung in Kombination mit Gerste zur Steigerung der ruminalen mikrobiellen Proteinsynthese
Linkages between mineralogy, fluid chemistry, and microbial communities within hydrothermal chimneys from the Endeavor Segment, Juan de Fuca Ridge
Rock and fluid samples were collected from three hydrothermal chimneys at the Endeavour Segment, Juan de Fuca Ridge to evaluate linkages among mineralogy, fluid chemistry, and microbial community composition within the chimneys. Mössbauer, midinfrared thermal emission, and visible-near infrared spectroscopies were utilized for the first time to characterize vent mineralogy, in addition to thin-section petrography, X-ray diffraction, and elemental analyses. A 282°C venting chimney from the Bastille edifice was composed primarily of sulfide minerals such as chalcopyrite, marcasite, and sphalerite. In contrast, samples from a 300°C venting chimney from the Dante edifice and a 321°C venting chimney from the Hot Harold edifice contained a high abundance of the sulfate mineral anhydrite. Geochemical modeling of mixed vent fluids suggested the oxic-anoxic transition zone was above 100°C at all three vents, and that the thermodynamic energy available for autotrophic microbial redox reactions favored aerobic sulfide and methane oxidation. As predicted, microbes within the Dante and Hot Harold chimneys were most closely related to mesophilic and thermophilic aerobes of the Betaproteobacteria and Gammaproteobacteria and sulfide-oxidizing autotrophic Epsilonproteobacteria. However, most of the microbes within the Bastille chimney were most closely related to mesophilic and thermophilic anaerobes of the Deltaproteobacteria, especially sulfate reducers, and anaerobic hyperthermophilic archaea. The predominance of anaerobes in the Bastille chimney indicated that other environmental factors promote anoxic conditions. Possibilities include the maturity or fluid flow characteristics of the chimney, abiotic Fe2+ and S2â oxidation in the vent fluids, or O2 depletion by aerobic respiration on the chimney outer wall
a review
It is well documented that global warming is unequivocal. Dairy production
systems are considered as important sources of greenhouse gas emissions;
however, little is known about the sensitivity and vulnerability of these
production systems themselves to climate warming. This review brings different
aspects of dairy cow production in Central Europe into focus, with a holistic
approach to emphasize potential future consequences and challenges arising
from climate change. With the current understanding of the effects of climate
change, it is expected that yield of forage per hectare will be influenced
positively, whereas quality will mainly depend on water availability and soil
characteristics. Thus, the botanical composition of future grassland should
include species that are able to withstand the changing conditions (e.g.
lucerne and bird's foot trefoil). Changes in nutrient concentration of forage
plants, elevated heat loads and altered feeding patterns of animals may
influence rumen physiology. Several promising nutritional strategies are
available to lower potential negative impacts of climate change on dairy cow
nutrition and performance. Adjustment of feeding and drinking regimes, diet
composition and additive supplementation can contribute to the maintenance of
adequate dairy cow nutrition and performance. Provision of adequate shade and
cooling will reduce the direct effects of heat stress. As estimated genetic
parameters are promising, heat stress tolerance as a functional trait may be
included into breeding programmes. Indirect effects of global warming on the
health and welfare of animals seem to be more complicated and thus are less
predictable. As the epidemiology of certain gastrointestinal nematodes and
liver fluke is favourably influenced by increased temperature and humidity,
relations between climate change and disease dynamics should be followed
closely. Under current conditions, climate change associated economic impacts
are estimated to be neutral if some form of adaptation is integrated.
Therefore, it is essential to establish and adopt mitigation strategies
covering available tools from management, nutrition, health and plant and
animal breeding to cope with the future consequences of climate change on
dairy farming
MIRO-1 Determines Mitochondrial Shape Transition upon GPCR Activation and Ca^(2+) Stress
Mitochondria shape cytosolic calcium ([Ca^(2+)]_c) transients and utilize the mitochondrial Ca_2^+ ([Ca^(2+)]_m) in exchange for bioenergetics output. Conversely, dysregulated [Ca^(2+)]_c causes [Ca^(2+)]_m overload and induces permeability transition pore and cell death. Ablation of MCU-mediated Ca^(2+) uptake exhibited elevated [Ca^(2+)]_c and failed to prevent stress-induced cell death. The mechanisms for these effects remain elusive. Here, we report that mitochondria undergo a cytosolic Ca^(2+)-induced shape change that is distinct from mitochondrial fission and swelling. [Ca^(2+)]_c elevation, but not MCU-mediated Ca^(2+) uptake, appears to be essential for the process we term mitochondrial shape transition (MiST). MiST is mediated by the mitochondrial protein Miro1 through its EF-hand domain 1 in multiple cell types. Moreover, Ca^(2+)-dependent disruption of Miro1/KIF5B/tubulin complex is determined by Miro1 EF1 domain. Functionally, Miro1-dependent MiST is essential for autophagy/mitophagy that is attenuated in Miro1 EF1 mutants. Thus, Miro1 is a cytosolic Ca^(2+) sensor that decodes metazoan Ca^(2+) signals as MiST
Impaired Ca2+-handling in HIF-1α+/â mice as a consequence of pressure overload
The hypoxia-inducible factor (HIF)-1 is critically involved in the cellular adaptation to a decrease in oxygen availability. The influence of HIF-1α for the development of cardiac hypertrophy and cardiac function that occurs in response to sustained pressure overload has been mainly attributed to a challenged cardiac angiogenesis and cardiac hypertrophy up to now. Hif-1α+/+ and Hif-1α+/â mice were studied regarding left ventricular hypertrophy and cardiac function after being subjected to transverse aortic constriction (TAC). After TAC, both Hif-1α+/+ and Hif-1α+/â mice developed left ventricular hypertrophy with increased posterior wall thickness, septum thickness and increased left ventricular weight to a similar extent. No significant difference in cardiac vessel density was observed between Hif-1α+/+ and Hif-1α+/â mice. However, only the Hif-1α+/â mice developed severe heart failure as revealed by a significantly reduced fractional shortening mostly due to increased end-systolic left ventricular diameter. On the single cell level this correlated with reduced myocyte shortenings, decreased intracellular Ca2+-transients and SR-Ca2+ content in myocytes of Hif-1a+/â mice. Thus, HIF-1α can be critically involved in the preservation of cardiac function after chronic pressure overload without affecting cardiac hypertrophy. This effect is mediated via HIF-dependent modulation of cardiac calcium handling and contractility
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A mechanistic model of small intestinal starch digestion and glucose uptake in the cow
The high contribution of postruminal starch digestion (up to 50%) to total-tract starch digestion on energy-dense, starch-rich diets demands that limitations to small intestinal starch digestion be identified. A mechanistic model of the small intestine was described and evaluated with regard to its ability to simulate observations from abomasal carbohydrate infusions in the dairy cow. The 7 state variables represent starch, oligosaccharide, glucose, and pancreatic amylase in the intestinal lumen, oligosaccharide and glucose in the unstirred water layer at the intestinal wall, and intracellular glucose of the enterocyte. Enzymatic hydrolysis of starch was modeled as a 2-stage process involving the activity of pancreatic amylase in the lumen and of oligosaccharidase at the brush border of the enterocyte confined within the unstirred water layer. The Na+-dependent glucose transport into the enterocyte was represented along with a facilitative glucose transporter 2 transport system on the basolateral membrane. The small intestine is subdivided into 3 main sections, representing the duodenum, jejunum, and ileum for parameterization. Further subsections are defined between which continual digesta flow is represented. The model predicted nonstructural carbohydrate disappearance in the small intestine for cattle unadapted to duodenal infusion with a coefficient of determination of 0.92 and a root mean square prediction error of 25.4%. Simulation of glucose disappearance for mature Holstein heifers adapted to various levels of duodenal glucose infusion yielded a coefficient of determination of 0.81 and a root mean square prediction error of 38.6%. Analysis of model behavior identified limitations to the efficiency of small intestinal starch digestion with high levels of duodenal starch flow. Limitations to individual processes, particularly starch digestion in the proximal section of the intestine, can create asynchrony between starch hydrolysis and glucose uptake capacity
Comparative physical maps derived from BAC end sequences of tilapia (Oreochromis niloticus)
Background: The Nile tilapia is the second most important fish in aquaculture. It is an excellent laboratory model, and is closely related to the African lake cichlids famous for their rapid rates of speciation. A suite of genomic resources has been developed for this species, including genetic maps and ESTs. Here we analyze BAC endsequences to develop comparative physical maps, and estimate the number of genome rearrangements, between tilapia and other model fish species. Results: We obtained sequence from one or both ends of 106,259 tilapia BACs. BLAST analysis against the genome assemblies of stickleback, medaka and pufferfish allowed identification of homologies for approximately 25,000 BACs for each species. We calculate that rearrangement breakpoints between tilapia and these species occur about every 3 Mb across the genome. Analysis of 35,000 clones previously assembled into contigs by restriction fingerprints allowed identification of longer-range syntenies. Conclusions: Our data suggest that chromosomal evolution in recent teleosts is dominated by alternate loss of gene duplicates, and by intra-chromosomal rearrangements (~one per million years). These physical maps are a useful resource for comparative positional cloning of traits in cichlid fishes. The paired BAC end sequences from these clones will be an important resource for scaffolding forthcoming shotgun sequence assemblies of the tilapia genome. (Résumé d'auteur
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