Coyotes as Sentinels for Monitoring Bovine Tuberculosis Prevalence in White-Tailed Deer

Abstract: Mycobacterium bovis, the causative agent of bovine tuberculosis (bTB), is endemic in free-ranging white-tailed deer (Odocoileus virginianus) in 5 counties (Alcona, Alpena, Montmorency, Oscoda, and Presque Isle) in the northeastern Lower Peninsula of Michigan, USA. The presence of a wildlife reservoir of tuberculosis in Michigan and the incidence of bTB in cattle (Bos taurus) resulted in Michigan losing its bTB accredited-free status. Subsequent wildlife surveillance programs identified relatively high disease prevalence in coyotes (Canis latrans), generating interest in their potential to serve as a sentinel species to detect bTB prevalence in white-tailed deer. Our goal was to develop an empirical basis for generating hypotheses about the spatial epidemiology of bTB infection in coyotes for future surveillance, management, and modeling efforts. Though variation in coyote home-range size may confound attempts to spatially correlate the incidence of disease in the sentinel and host species at a fine scale, overlap zones (OZs) between adjacent coyote home ranges may be the appropriate sample unit for spatially correlating disease prevalence in coyotes and white-tailed deer. Because overlapping home ranges are generally configured around resource rich (e.g., small mammals and white-tailed deer) timber management patches, the OZ concentrates spatial interaction between adjacent groups in a relatively small area. Furthermore, there is a direct relationship between interaction probabilities and the spatial dispersion of those patches. The latter finding provides a useful metric to incorporate into future efforts to develop spatially explicit models of bTB dynamics. Modeling efforts can then be used as a foundation to predict the epidemiological ramifications of alterations in intensively managed forested landscapes. (JOURNAL OF WILDLIFE MANAGEMENT 71(5):1545-1554; 2007)     

Hydrologic regulation of gross methyl chloride and methyl bromide uptake from Alaskan Arctic tundra

The Arctic tundra has been shown to be a potentially significant regional sink for methyl chloride (CH₃Cl) and methyl bromide (CH₃Br), although prior field studies were spatially and temporally limited, and did not include gross flux measurements. Here we compare net and gross CH₃Cl and CH₃Br fluxes in the northern coastal plain and continental interior. As expected, both regions were net sinks for CH₃Cl and CH₃Br. Gross uptake rates (−793 nmol CH₃Cl m⁻² day⁻¹ and −20.3 nmol CH₃Br m⁻² day⁻¹) were 20–240% greater than net fluxes, suggesting that the Arctic is an even greater sink than previously believed. Hydrology was the principal regulator of methyl halide flux, with an overall trend towards increasing methyl halide uptake with decreasing soil moisture. Water table depth was one of the best predictors of net and gross uptake, with uptake increasing proportionately with water table depth. In drier areas, gross uptake was very high, averaging −1201 nmol CH₃Cl m⁻² day⁻¹ and −34.9 nmol CH₃Br m⁻² day⁻¹; in flooded areas, gross uptake was significantly lower, averaging −61 nmol CH₃Cl m⁻² day⁻¹ and −2.3 nmol CH₃Br m⁻² day⁻¹. Net and gross uptake was greater in the continental interior than in the northern coastal plain, presumably due to drier inland conditions. Within certain microtopographic features (low‐ and high‐centered polygons), uptake rates were positively correlated with soil temperature, indicating that temperature played a secondary role in methyl halide uptake. Incubations suggested that the inverse relationship between water content and methyl halide uptake was the result of mass transfer limitation in saturated soils, rather than because of reduced microbial activity under anaerobic conditions. These findings have potential regional significance, as the Arctic is expected to become warmer and drier due to anthropogenic climate forcing, potentially enhancing the Arctic sink for CH₃Cl and CH₃Br.     

Factors limiting the number of radiation-induced chromosome exchanges. I. Distance: evidence from non-interaction of x-ray- and neutron-induced breaks

Soaked seeds of Vicia faba were exposed to fractionated doses of x-rays or x-rays and fast neutrons. When the two-hit (exchange) chromosome aberrations were scored at the first mitosis of the root tip, it was observed that with short fractionation times the radiation-induced breaks from the two x-ray doses could rejoin with one another to form exchanges in proportion to the square of the total dose. If, however, one dose was x-rays and the second neutrons, then no quantitatively determinable interaction occurred between the breaks induced by each of the doses, and the aberration yield was simply the sum of that induced by each fraction. The phenomenon of non-interaction as observed by these dose fractionation studies and also by the linear dose response curve for two-break aberrations induced by neutrons has led to calculations of the distance over which two breaks can rejoin. The distance is evidently much smaller than the previously accepted value of 1 micro.     

Role of Activity in Determining Properties of the Neuromuscular System in Crustaceans

SYNOPSIS. Crustacean muscle fibers, like those of higher vertebrates,are diversified in physiology, morphology, and biochemical attributes.However, unlike motor units of mammals, those of crustaceansusually do not contain fibers of uniform type. Motor neuronactivity acts as a unifying force for the motor units of mammalianmuscles, but its role in determining properties of crustaceanmotor units is less well defined. In certain crustacean muscles,differential activity of sensory-motor systems is importantfor establishing muscle fiber properties during early development.In freshwater crayfish, neuromuscular junctions of a phasicmotor neuron are altered physiologically and morphologicallyby chronic stimulation; the adapted junctions release less transmitterper impulse and are more fatigue-resistant than naive junctions.The muscle fibers may also adapt to chronic stimulation, butless dramatically and at a slower rate. The adaptive responsesof the neuromuscular junction can be achieved through manipulationof sensory input and with little increase in motor impulse activity.This suggests that altered protein synthesis is triggered centrallyby synaptic input to the motor neuron. In general, present evidencesuggests that long-term adaptation of neuromuscular junctionsand muscle fibers of crustaceans can occur in response to alteredactivity in the nervous system, in spite of the fact that certainmuscle fiber properties appear to be genetically predetermined.Some aspects of matching between neuromuscular junction andmuscle fiber appear to be determined in response to growth ofthe muscle fiber; other features are activity-dependent; andsome may result from expression of inherent neuronal properties.     

Crustacean Neuromuscular Mechanisms: Functional Morphology of Nerve Terminals and the Mechanism of Facilitation

Two aspects of crustacean neuromuscular physiology are discussed:(1) the ultrastructural identification of the excitatory andinhibitory nerve terminals, and (2) the characteristics of,and the possible mechanisms for, facilitation. The first problem was studied in crayfish opener muscle whichhas one excitatory and one inhibitory axon. One of the nerveswas stimulated in the presence of DNP until synaptic transmissionfailed; the preparations were then fixed for electron microscopy.Whenever the excitatory nerve was stimulated, the terminalswith round synaptic vesicles were depleted while nearby terminalswith smaller elongate vesicles were normal. When the inhibitorynerve was stimulated, the converse was true. The possible reasons for the diversity in crustacean neuromuscularproperties are discussed. Large EPSP's with a high quantal content(m), appear to be produced by terminals which are invaded bya propagated spike. Small EPSP's (small m) appear to be producedby terminals which don't spike and which are depolarized bya decrementally conducted potential. There is an inverse relationshipbetween m and the amount of facilitation. The physiologicalbasis for facilitation is discussed; previous hypotheses arefound wanting and a new one is proposed, that of slow depolarization.     

Functional and Structural Parallels in Crustacean and Drosophila Neuromuscular Systems

Comparison of morphological and physiological phenotypes ofrepresentative crustacean motor neurons, and selected motorneurons of Drosophila larval abdominal muscles, shows severalfeatures in common. Crustacean motor nerve terminals, and thoseof Drosophila, possess numerous small synapses with well-definedactive zones. In crustaceans, neurons that are more tonicallyactive have markedly varicose terminals; synapses and mitochondriaare selectively localized in the varicosities. Phasic motoraxons have filiform terminals, sometimes with small varicosities;mitochondrial content is less than for tonic axons, and synapsesare distributed along the terminals. Tonic axons generate smallexcitatory potentials which facilitate strongly at higher frequencies,and which are resistant to depression. Thephasic neurons generatelarge excitatory potentials which exhibit relatively littlefrequency facilitation, and depress rapidly. In Drosophila,counterparts of crustacean phasic and tonic motor neurons havebeen found, but the differentiation is less pronounced. It isinferredthat cellular factors regulating the number of participatingsynapses and the probability of quantal release are similarin crustaceans and Drosophila, and that advantage can be takenof this in future to develop experiments addressing the regulationof synaptic plasticity.     

The expansion of woody riparian vegetation,and subsequent stream restoration,influences the metabolism of prairie streams

1. Tallgrass prairies and their streams are highly endangered ecosystems, and many remaining streams are threatened by the encroachment of woody riparian vegetation. An increase in riparian vegetation converts the naturally open‐canopy prairie streams to closed‐canopy systems. The effects of a change in canopy cover on stream metabolism are unknown. 2. Our goal was to determine the effects of canopy cover on prairie stream metabolism during a 4‐year period in Kings Creek, KS, U.S.A. Metabolic rates from forested reaches were compared to rates in naturally open‐canopy reaches and restoration reaches, the latter having closed canopies in 2006 and 2007 and open canopies in 2008 and 2009. Whole‐stream metabolism was estimated using the two‐station diurnal method. Chlorophyll a concentrations and mass of filamentous algae were measured after riparian removal to assess potential differences in algal biomass between reaches with open or closed canopies. 3. Metabolic rates were spatially and temporally variable even though the sites were on very similar streams or adjacent to each other within streams. Before riparian vegetation removal, whole‐stream community respiration (CR) and net ecosystem production were greater with greater canopy cover. In the vegetation removal reaches, gross primary production was slightly greater after removal. 4. Chlorophyll a concentrations were marginally significantly greater in open (naturally open and removal reaches) than in closed canopy and differed significantly between seasons. Filamentous algal biomass was greater in open than in closed‐canopy reaches. 5. Overall, the restoration allowed recovery of some features of open‐canopy prairie streams. Woody expansion apparently increases CR and moves prairie stream metabolism towards a more net heterotrophic state. An increase in canopy cover decreases benthic chlorophyll, decreases dominance of filamentous algae and potentially alters resources available to the stream food web. The results of this study provide insights for land managers and conservationists interested in preserving prairie streams in their native open‐canopy state.     

Spatial Partitioning of Predation Risk in a Multiple Predator-Multiple Prey System

ABSTRACT Minimizing risk of predation from multiple predators can be difficult, particularly when the risk effects of one predator species may influence vulnerability to a second predator species. We decomposed spatial risk of predation in a 2-predator, 2-prey system into relative risk of encounter and, given an encounter, conditional relative risk of being killed. Then, we generated spatially explicit functions of total risk of predation for each prey species (elk [Cervus elaphus] and mule deer [Odocoileus hemionus]) by combining risks of encounter and kill. For both mule deer and elk, topographic and vegetation type effects, along with resource selection by their primary predator (cougars [Puma concolor] and wolves [Canis lupus], respectively), strongly influenced risk of encounter. Following an encounter, topographic and vegetation type effects altered the risk of predation for both ungulates. For mule deer, risk of direct predation was largely a function of cougar resource selection. However, for elk, risk of direct predation was not only a function of wolf occurrence, but also of habitat attributes that increased elk vulnerability to predation following an encounter. Our analysis of stage-based (i.e., encounter and kill) predation indicates that the risk effect of elk shifting to structurally complex habitat may ameliorate risk of direct predation by wolves but exacerbate risk of direct predation by cougars. Information on spatiotemporal patterns of predation will be become increasingly important as state agencies in the western United States face pressure to integrate predator and prey management.     

Comparative Patterns of Predation by Cougars and Recolonizing Wolves in Montana's Madison Range

Abstract: Numerous studies have documented how prey may use antipredator strategies to reduce the risk of predation from a single predator. However, when a recolonizing predator enters an already complex predator—prey system, specific antipredator behaviors may conflict and avoidance of one predator may enhance vulnerability to another. We studied the patterns of prey selection by recolonizing wolves (Canis lupus) and cougars (Puma concolor) in response to prey resource selection in the northern Madison Range, Montana, USA. Elk (Cervus elaphus) were the primary prey for wolves, and mule deer (Odocoileus hemionus) were the primary prey for cougars, but elk made up an increasingly greater proportion of cougar kills annually. Although both predators preyed disproportionately on male elk, wolves were most likely to prey on males in poor physical condition. Although we found that the predators partitioned hunting habitats, structural complexity at wolf kill sites increased over time, whereas complexity of cougar kill sites decreased. We concluded that shifts by prey to structurally complex refugia were attempts by formerly naïve prey to lessen predation risk from wolves; nevertheless, shifting to more structurally complex refugia might have made prey more vulnerable to cougars. After a change in predator exposure, use of refugia may represent a compromise to minimize overall risk. As agencies formulate management strategies relative to wolf recolonization, the potential for interactive predation effects (i.e., facilitation or antagonism) should be considered.     

Crustacean Neuromuscular Mechanisms

Properties of crustacean muscle fibers and neuromuscular synapsesare discussed, with particular reference to the problems offast and slow contraction, synaptic diversity, and peripheralinhibition. Electrical and mechanical responses of crustacean muscle fibersare variable, and govern to a large extent the muscle's performance.Fast and slow contractions are often mediated by distinct "phasic"and "tonic" muscle fibers, as in abdominal muscles, in whichsuch fibers are segregated into two parallel sets of muscles.In leg muscles the fibers are often heterogeneous in propertiesand innervation. In doubly-motor-innervated muscles of crabsthe axons producing fast and slow contractions preferentiallyinnervate rapidly and slowly contracting fibers, respectively. Crustacean neuromuscular synapses vary greatly in electricalbehavior and in ultrastructural characteristics. Some motoraxons possess both facilitating and nonfacilitating synapses.The proportion of the different types of synapse associatedwith a motor axon probably determines in large measure the propertiesof the postsynaptic potentials evoked by that axon. Pre-synaptic and post-synaptic inhibition both occur, sometimesin the same muscle. The latter type is more common. Pre-synapticinhibition is thought to be mediated by the action of an inhibitorytransmitter-substance on receptors of the motor nerve terminals.