Mature pollen grains of Betula pendula, Borago officinalis, Calluna vulgaris, Fagus sylvatica, Lilium longiflorum, Pinus sylvestris and spores of Lycopodium clavatum were exposed to 4-Methlymorpholine N-oxide monohydrate (MMNO‧H2O) at 80°C for times varying from 30 minutes to 310 minutes. After 30 minutes microchannnels had expanded from approximately 25 nm to 50 nm in diameter, the channel size during development is approximately 50 nm. After about 5 hours in MMNO‧H2O pronounced changes in exine morphology were observed except in Calluna. Changes in exine morphology of Borago and Pinus involved sporopollenin that our previous studies indicated had been added late in development. Early in development sporopollenin accumulates on Sporopollenin Acceptor Particles (SAPs) that are part of the plasma membrane surface coating (tufts, the unit-structures of exines). Subsequently, late in development, secondary sporopollenin is added between tufts or on their surfaces. At this stage SAP cross linkages permeate the exine. Our interpretation is that MMNO‧H2O, as a potent solvent for polysaccharide, penetrates the exine through the core zone (microchannels) of tufts and tuft cross linkages. When polysaccharide is removed exposure to water and solvents normally used for TEM preparation cause fracture of exine components. Exine changes during MMNO‧H2O in Betula and Fagus may be similarly interpreted since erosion parallels the orientation of the tuft core and its subunits. In Lilium the most slender columellae consisting apparently of one tuft were eroded enough to expose coils of outer (binder) zone. In Lycopodium the MMNO‧H2O resulted in exposure of closely spaced (approximately 10nm) circumferentially oriented lamellae that are grouped into linear structures. These linear structures are circular in cross section and greatly variable in size (most are 100-200 nm in diameter). Scans using atomic force- and scanning tunnelling- microscopy suggest that the mainly longitudinal subunits appear to be helical, and radial cross linkages between the structures can also be discerned. No change, other than enlargement of microchannels, could be seen in the endexines of the species studied. Our interpretation is that the greater resistance of the endexine than the ectexine is due to close packing of tufts without any secondary deposition of sporopollenin.