Diagnosis of tuberculosis due to Mycobacterium bovis in New Zealand red deer (Cervus elaphus) using a composite blood test and antibody assays

A blood test for tuberculosis in deer was developed as an ancillary test to clarify the status of skin test-positive deer, with non-specific sensitisation following exposure to saprophytic mycobacteria. The blood test incorporates the measurement of the relative humoral and cellular immunological responses to Mycobacterium bovis and M. avium antigens to provia composite test with high levels of sensitivity (>95%) and specificity (>98%). The specificity of the test has allowed it to be used in parallel with the skin test to salvage thousands of tuberculosis-free deer with non-specific skin test-positive reactions, while its high sensitivity has consistently identified M. bovis-specific reactivity in tuberculous skin test-positive animals. The rules for establishing the diagnostic parameters for the cellular and antibody assays were developed by retrospective analysis of the laboratory results using blood samples from many thousand tuberculous or disease-free deer. The sensitivity of the blood test was tested in this study using 150 animals with tuberculosis diagnosed by the isolation of M. bovis. It had sensitivity values of 95.7–95.9% in herds with a low (<2.0% ) or a high (>30.0%) incidence of tuberculosis. The test had a specificity of 98.0% when tested on 218 disease-free animals, 118 of which were skin test-positive.

An antibody test was developed to diagnose M. bovis in skin test-negative “anergic” deer from tuberculosis infected herds. When this test was used with deer blood taken 10 days after reading the skin test, it had a sensitivity of 85.3% for 102 M. bovis-positive deer. When used in combination with skin test, the antibody test complemented the skin test to raise the sensitivity of the combined tests to 95.0%) when antibody-positive or skin test-positive tests were used to diagnose tuberculosis. The specificity of the antibody test was 100% when used to evaluate 218 disease-free deer from non-infected herds.     

The ACVD task force on canine atopic dermatitis (XXI): antihistamine pharmacotherapy.

Antihistamines frequently are recommended by veterinary dermatologists for symptomatic treatment of pruritus associated with canine atopic dermatitis (AD), perhaps because of their moderate success in some human patients with AD. A critical review of the literature describing antihistamine use in canine AD reveals that the majority of published, peer-reviewed studies are open, uncontrolled or partially-controlled trials. Such studies vary widely in reported efficacy, from perhaps 0 to 75% of patients, even using the same drug. The few blinded placebo-controlled trials available have failed to confirm efficacy of these drugs to relieve the pruritus of canine AD. Some studies indicate that synergistic effects could occur with concurrent use of essential fatty acid supplements. Consequently, at the time of this writing, there is insufficient evidence to conclude for or against the efficacy of antihistamines for treatment of canine AD. Additional blinded, randomized and controlled trials with larger numbers of patients are necessary to establish which of the antihistamine drugs currently available, if any, are truly efficacious for canine AD. Nevertheless, present clinician consensus suggests that several different antihistamine drugs should be evaluated in sequence, for 7-14 days each, in canine patients with AD.     

Clonal variation of Populus tremuloides responses to diurnal drought stress

We have developed an automated microprocessor controlled system for subjecting hydroponically grown plants to drought. Pumps and valves were used to move nutrient solutions into and out of a system of culture vessels in a growth chamber to provide periods of drought. Drought conditions were obtained by exposing the roots of hydroponically grown clones of aspen, Populus tremuloides Michx., to air in culture vessels temporarily emptied of nutrient medium. Over a 3-week period, the daily duration of drought was increased from 0 to 6 h. During this period, the plants became increasingly tolerant to drought, as shown by a decreasing propensity to wilt. All three clones sustained diurnal drought periods of 6 h for up to 5 weeks without detectable deterioration of health. Typical drought stress symptoms were observed including inhibition of growth, increased tissue amino acid content, and decreased water, solute, and turgor potentials in young leaves. In all clones, control plants had leaf water potentials between -1.0 and -1.6 MPa, whereas leaf water potentials of drought-treated plants were significantly lower, ranging from -1.7 to -3.0 MPa. Only one of the clones showed a significant decrease in leaf solute potential in response to drought. The decrease in leaf solute potential paralleled the decrease in water potential resulting in no significant difference in turgor potential. The other two clones had nonsignificant decreases to more negative leaf solute potentials under drought conditions resulting in significantly lowered turgor potentials. Leaf water potentials, solute potentials, and turgor potentials of the drought-treated plants returned to control values within two hours after rewatering. The growth inhibitions observed could not have been the consequence of loss of turgor. These results demonstrate genetic differences among aspen clones in water relations responses to drought.     

Growth CO2 concentration modifies the transpiration response of Populus deltoides to drought and vapor pressure deficit

Cottonwood (Populus deltoides Bartr. ex Marsh.) trees grown for 9 months in elevated carbon dioxide concentration ([CO2]) showed significant increases in height, leaf area and basal diameter relative to trees in a near-ambient [CO2] control treatment. Sample trees in the CO2 treatments were subjected to high and low atmospheric vapor pressure deficits (VPD) over a 5-week period at both high and low soil water contents (SWC). During these periods, transpiration rates at both the leaf and canopy levels were calculated based on sap flow measurements and leaf-to-sapwood area ratios. Leaf-level transpiration rates were approximately equivalent across [CO2] treatments when soil water was not limiting. In contrast, during drought stress, canopy-level transpiration rates were approximately equivalent across [CO2] treatments, indicating that leaf-level fluxes during drought stress were reduced in elevated [CO2] by a factor equal to the leaf area ratio of the two canopies. The shift from equivalent leaf-level transpiration to equivalent canopy-level transpiration with increasing drought stress suggests maximum water use rates were controlled primarily by atmospheric demand at high SWC and by soil water availability at low SWC. Changes in VPD had less effect on transpiration than changes in SWC for trees in both CO2 treatments. Transpiration rates of trees in both CO2 treatments reached maximum values at a VPD of about 2.0 kPa at high SWC, but leveled off and decreased slightly in both canopies as VPD increased above this value. At low SWC, increasing VPD from approximately 1.4 to 2.5 kPa caused transpiration rates to decline slightly in the canopies of trees in both treatments, with significant (P = 0.004) decreases occurring in trees in the near-ambient [CO2] treatment. The transpiration responses at high VPD in the presence of high SWC and throughout the low SWC treatment suggest some hydraulic limitations to water use occurred. Comparisons of midday leaf water potentials of trees in both CO2 treatments support this conclusion.     

Canopy position and needle age affect photosynthetic response in field-grown Pinus radiata after five years of exposure to elevated carbon dioxide partial pressure

Photosynthesis of tree seedlings is generally enhanced during short-term exposure to elevated atmospheric CO2 partial pressure, but longer-term studies often indicate some degree of photosynthetic adjustment. We present physiological and biochemical evidence to explain observed long-term photosynthetic responses to elevated CO2 partial pressure as influenced by needle age and canopy position. We grew Pinus radiata D. Don. trees in open-top chambers for 5 years in sandy soil at ambient (36 Pa) and elevated (65 Pa) CO2 partial pressures. The trees were well watered and exposed to natural light and ambient temperature. In the fourth year of CO2 exposure (fall 1997), when foliage growth had ceased for the year, photosynthetic down-regulation was observed in 1-year-old needles, but not in current-year needles, suggesting a reduction in carbohydrate sink strength as a result of increasing needle age (Turnbull et al. 1998). In 5-year-old trees (spring 1997), when foliage expansion was occurring, photosynthetic down-regulation was not observed, reflecting significantly large sinks for carbohydrates throughout the tree. Net photosynthesis was stimulated by 79% in trees growing in elevated CO2 partial pressure, but there was no significant effect on photosynthetic capacity or Rubisco activity and concentration. Current-year needles were more responsive to elevated CO2 partial pressure than 1-year-old needles, exhibiting larger relative increases in net photosynthesis to elevated CO2 partial pressure (98 versus 64%). Lower canopy and upper canopy leaves exhibited similar relative responses to growth in elevated CO2 partial pressure. However, needles in the upper canopy exhibited higher net photosynthesis, photosynthetic capacity, and Rubisco activity and concentration than needles in the lower canopy. Given that the ratio of mature to juvenile foliage mass in the canopy will increase as trees mature, we suggest that trees may become less responsive to elevated CO2 partial pressure with increasing age. We conclude that tree response to elevated CO2 partial pressure is based primarily on sink strength and not on the duration of exposure.