Abstract
The peripheral sensitivity and palatability of different carbohydrates was evaluated and their nutritional value assessed in adult females of D. suzukii by means of an electrophysiological, behavioural and metabolic approach. The electrophysiological responses were recorded from the labellar “l” type sensilla stimulated with metabolizable mono- and disaccharides (glucose and maltose) and a non-metabolizable sugar (sucralose); the response rating and the palatability to the same sugars, evaluated by recording the proboscis extension reflex (PER), was maltose>glucose>sucralose. The nutritional value of carbohydrates was assessed by means of survival trials and fatty acids profile. Flies fed on a diet containing maltose had a longer lifespan than flies on monosaccharides, while flies fed on a diet containing sucralose had a shorter one. In addition, the ability to store fat seems to be influenced by the different sugars in the diet and is in relationship with their palatability. In fact, data showed a higher synthesis of palmitic and palmitoleic acids, most likely derived from de-novo lipogenesis with glucose as precursor, in flies fed with maltose and glucose than with non-metabolizable sucralose. In conclusion, these results suggest that the ability to select different sugars on the basis of their palatability may favour the storage of energy reserves such as fat by de-novo lipogenesis, determining a longer survival capability during prolonged periods of fasting.
Highlights
In insects, the behaviour of host selection is strongly influenced from sensory input coming from their chemical senses [1,2,3,4]
Repeated- measures ANOVA revealed a significant effect of concentration on the spike frequency of the “L” neuron in response to maltose (F[1.2,40] = 413.26; P
No effect of the concentration was found for neurons “S” and “M”
Summary
The behaviour of host selection is strongly influenced from sensory input coming from their chemical senses [1,2,3,4]. Fat storage in Drosophila suzukii in relation to palatability of dietary sugars neurons (GRNs), housed within bristles called taste sensilla, located on the labellum, legs, wing margins and ovipositor [7,8]. Taste sensilla have an apical pore that enables to record the neural activity originating from single GRNs [9]. The responses of these cells have been well characterized: the spikes recorded from each of the four chemoreceptors consistently differ in amplitude and shape. They can be separated from one another and their relative amplitude ratios are conserved; they are species- and sensillum-type specific regardless of recording conditions [1,10,11]
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