Incubation with 10mM MnCl 2 for 1h decreased the effective quantum yield of photochemical energy conversion in photosystem 2 in the bipartite chlorolichen Hypogymnia physodes as well as in the bipartite cyanolichens Leptogium saturninum and Nephroma helveticum, but not in the tripartite lichen Lobaria pulmonaria. Among the bipartite species, Mn sensitivity increased in the order H. physodes < N. helveticum < L. saturninum. This equals the sequence heteromerous chlorolichen < heteromerous cyanolichen < homoiomerous (gelatinous) cyanolichen. MnCl 2 reduced non-photochemical quenching of chlorophyll fluorescence in the bipartite cyanolichens and in H. physodes; in the latter, however, this decrease was limited to light intensities above the adapted growth light intensity. Photochemical quenching was increased in H. physodes, but reduced in the bipartite cyanolichens. The results indicate that the bipartite cyanolichens L. saturninum and N. helveticum are even more sensitive to high Mn concentrations than the chlorolichen H. physodes, the low Mn tolerance of which has been already demonstrated. This agrees with results of field studies from western North America, where conifer bark under cyanolichens (including L. saturninum and N. helveticum) was found to contain less Mn than bark which only supported chlorolichens. The high sensitivity of the bipartite cyanolichens probably results from high sensitivity of the Nostoc photobiont. The high Mn tolerance of L. pulmonaria is probably not due to its being a tripartite lichen, but might be caused by high tolerance of the green-algal primary photobiont Dictyochloropsis, which is, however, not experimentally proven. The high Mn tolerance of the highly SO 2 -sensitive L. pulmonaria shows that different mechanisms are responsible for Mn and SO 2 toxicity in lichens.