It’s known that plant-pollinator relationships are central to the proper functioning of agricultural and ecological systems. Of the many navigation pathways pollinators use, floral scent signaling for insects is the most complex yet also the most at-risk from atmospheric human activity. Oenothera pallida, a primrose, interacts with the pollinators Hyles lineata, a hawk moth, and Megachile rotundata, a leaf-cutter bee, via this scent pathway. Because of their reactivity with floral scent, human-released ozone and NO2 are the main perpetrators of scent degradation. To understand this relationship being damaged, I exposed the moth and bee species to a normal Oenothera scent versus a degraded one, recording the antennal response as well as the behavioral, expecting a poorer response to the degraded scent. Moth antennae act as the site of odor reception, bearing sensory hairs that detect odors, allowing the moths to navigate to scent sources. I conducted electroantennographic experiments (EAG) to record the electric signal from the insect antennae in response to each scent blend, with the degraded scent representing the impact of NOx interactions. Following the EAG, I conducted Proboscis Extension Reflex (PER) experiments with Megachile to show the relationship between insect behavior and antennal physiology when in the presence of the scent blends. I expect that the EAG experiments show that the antennae respond worse to NOx degraded scents in comparison to the normal, unaltered scent blend. Likewise, Megachile has a worse PER when exposed to the degraded scent, linking the chemical biology of the scent interaction to the feeding and pollination behavior. This work has broader implications regarding the importance of plant-pollinator relationships, especially when considering environmental and agricultural health as well as the issue of food security in our changing climate.