Does exogenous carbon extend the realized niche of canopy lichens? Evidence from sub‐boreal forests in British Columbia

Foliose lichens with cyanobacterial bionts (bipartite and tripartite) form a distinct assemblage of epiphytes strongly associated with humid microclimatic conditions in inland British Columbia. Previous research showed that these cyano‐ and cephalolichen communities are disproportionately abundant and species‐rich on conifer saplings beneath Populus compared to beneath other tree species. More revealing, lichens with cyanobacterial bionts were observed beneath Populus even in stands that did not otherwise support them. We experimentally test the hypothesis that this association is due to the interception of glucose‐rich nectar that is exuded from Populus extra‐floral nectaries (EFN). Using CO 2 flux measurements and phospholipid fatty acid (PLFA) analysis with experimental applications of 13 C 6 ‐labeled glucose, we demonstrate that cyano‐ and cephalolichens have a strong respiratory response to glucose. Lichens treated with glucose had lower net photosynthesis and higher establishment rates than control thalli. Furthermore, lichens with cyanobacterial bionts rapidly incorporate exogenous 13 C into lichen fatty acid tissues. A large proportion of the 13 C taken up by the lichens was incorporated into fungal biomarkers, suggesting that the mycobiont absorbed and assimilated the majority of applied 13 C 6 glucose. Our observations suggest that both cyanolichens and cephalolichens may utilize an exogenous source of glucose, made available by poplar EFNs. The exogenous C may enable these lichens to become established by providing a source of C for fungal respiration despite drought‐induced inactivity of the cyanobacterial partner. As such, the mycobiont may adopt an alternative nutritional strategy, using available exogenous carbon to extend its realized niche.