Component analysis of the urushiol content of poison ivy and poison oak

The partial separation and quantitation of the components of the urushiol fraction of poison ivy and poison oak are discussed. The urushiol fraction of poison ivy is primarily composed of C₁₅ side-chain catechol, while the urushiol extract of poison oak is principally the C₁₇ homolog. The presence of a C₁₇ homolog in ivy and a C₁₅ homolog in poison oak urushiol is also detected. Each of these catechol derivatives contain a mixture of congeners which are partially separated by the GLC system used. In each case the tri-olefinic component occurs in greatest abundance and the mono-olefinic congener is least abundant; no saturated material was detected. The compounds were analyzed as trimethylsilyl derivatives and a qualitative analysis was accomplished by GC-MS.     

Stem hydraulic properties of vines vs. shrubs of western poison oak,Toxicodendron diversilobum

Summary This study investigated the effect of mechanical support on water transport properties and wood anatomy of stems of western poison oak, Toxicodendron diversilobum (T. & G.) Greene. This plant grows as a vine when support is present but as a shrub when support is absent. I compared vines and shrubs growing naturally in the field and those produced from cuttings of 11 source plants in a common garden. Huber value (xylem transverse area/distal leaf area) was lower but specific conductivity (water volume · time^-1 · xylem transverse area^-1 · pressure gradient^-1) was higher in supported than unsupported plants both in the field and the common garden. The opposing effects of Huber value and mon garden. The opposing effects of Huber value and specific conductivity resulted in the same values of leafspecific conductivity (LSC, water volume · time^-1 · distal leaf area^-1 · pressure gradient^-1) for supported and unsupported shoots at a given site. Therefore, for the same rates of evapotranspiration, supported and unsupported shoots will have the same pressure gradients in their stems. Vessel lumen composed a higher proportion of stem cross-section in supported than unsupported plants (due to slightly wider vessels and not to greater vessel density). These results suggest that the narrow stems of supported plants are compensated hydraulically by the production of wider vessels: at a given site, poison oak plants co-ordinate their leaf and xylem development such that their stems achieve the same overall conductive efficiencies (LSCs), regardless of support conditions.     

A murine model system for contact sensitization to poison oak or ivy urushiol components

A murine model of contact sensitization to components of poison oak or ivy urushiol oils was developed. Sensitization was effected by painting such compounds on abdominal skin, and was routinely assessed by challenging on the ears and monitoring increases in ear thickness. Sensitization to 3-heptadecylcatechol (HDC, a component of poison oak urushiol) was studied in detail. Contact sensitivity as indicated by ear swelling reactions was observed from 2 until around 25 days after primary abdominal painting with HDC. In all cases maximal ear swelling occurred 3–4 days after HDC challenge. Sensitivity could also be assessed by monitoring the uptake of radioiodinated deoxyuridine at the ear challenge site, and this correlated with the ear swelling assay in terms of kinetics. The sensitization effect induced by HDC had properties of delayed-type hypersensitivity, being antigen specific, and transferable with sensitized lymph node and spleen cells but not by serum. Also, T cells were required for activity as transfer with spleen cells was abrogated by treatment with anti-Thy-1.2 antibody and complement. In this system HDC and 3-pentadecylcatechol (PDC, a component of poison ivy urushiol oil) were completely cross-reactive both in sensitization and challenge, and both compounds also cross-reacted with native urushiol oil itself. Thus murine sensitization to HDC can be used as a model system for investigating mechanisms for the immunogenicity of such catechols.