Foliar nitrogen isotope (δsup.15N) composition patterns have been linked to soil N, mycorrhizal fractionation, and within-plant fractionations. However, few studies have examined the potential importance of the direct foliar uptake of gaseous reactive N on foliar δsup.15N. Using an experimental set-up in which the rate of mycorrhizal infection was reduced using a fungicide, we examined the influence of mycorrhizae on foliar δsup.15N in potted red maple (Acer rubrum) seedlings along a regional N deposition gradient in New York State. Mycorrhizal associations altered foliar δsup.15N values in red maple seedlings from 0.06 to 0.74 % across sites. At the same sites, we explored the predictive roles of direct foliar N uptake, soil δsup.15N, and mycorrhizae on foliar δsup.15N in adult stands of A. rubrum, American beech (Fagus grandifolia), black birch (Betula lenta), and red oak (Quercus rubra). Multiple regression analysis indicated that ambient atmospheric nitrogen dioxide (NO.sub.2) concentration explained 0, 69, 23, and 45 % of the variation in foliar δsup.15N in American beech, red maple, red oak, and black birch, respectively, after accounting for the influence of soil δsup.15N. There was no correlation between foliar δsup.13C and foliar %N with increasing atmospheric NO.sub.2 concentration in most species. Our findings suggest that total canopy uptake, and likely direct foliar N uptake, of pollution-derived atmospheric N deposition may significantly impact foliar δsup.15N in several dominant species occurring in temperate forest ecosystems.