Fitness consequences of intraguild predation between Spodoptera frugiperda (Lepidoptera: Noctuidae) and Ostrinia furnacalis (Lepidoptera: Crambidae).

The introduction of the fall armyworm, Spodoptera frugiperda (J.E. Smith) (Lepidoptera: Noctuidae), into Thailand has significantly altered the dynamics of maize pests. It has overshadowed Ostrinia furnacalis (Guenée) (Asian corn borer) (Lepidoptera: Crambidae), previously the most severe maize insect in Thailand. This transition is postulated to stem from the superior intraguild predation (IGP) capabilities of S. frugiperda. To validate this supposition, we assessed the co-distribution patterns and damage locales of both pests within maize fields and analyzed the IGP's repercussions on their larval growth, survival, and fecundity. Our findings demonstrate that: (i) incidence of O. furnacalis in maize fields is markedly reduced following the introduction of S. frugiperda; (ii) abundance of S. frugiperda and O. furnacalis is negatively correlated in field; (iii) interspecific interactions affect the spatial distributions of S. frugiperda and O. furnacalis on shared plants; (iv) S. frugiperda has lower generation time and higher fecundity; and (v) IGP amplifies the growth rate of S. frugiperda and elevates mortality in O. furnacalis. Moreover, in response to the competitive pressure exerted by S. frugiperda, O. furnacalis exhibited expedited molting and growth without a commensurate increase in size. Our data suggest IGP proficiency underpins S. frugiperda's dominance in Thai maize fields. We propose a niche differentiation on spatiotemporal distribution facilitating the coexistence of S. frugiperda and O. furnacalis. The impact of S. frugiperda on pest management strategies is discussed.

Desiccation tolerance of Termitidae termites in relation to their nest type.

The family Termitidae is renowned for its diverse nesting behaviors, with the evolution of epigeal and arboreal nests hypothesized to increase desiccation stress due to greater exposure to air. However, these nests may also alleviate desiccation stress through humidity regulation. To explore the implications of acquiring epigeal and arboreal nests, we investigated desiccation tolerance traits in 16 Termitidae termite species with varying nest types and analyzed trait correlations. Principal component analysis revealed that termites constructing epigeal and arboreal nests exhibited reduced water loss rates and enhanced survival under desiccated conditions. Furthermore, termites building arboreal nests displayed a notably higher water content. Redundancy analysis demonstrated that nest types accounted for a substantial portion (57.2%) of the observed variation in desiccation tolerance. These findings support the hypothesis that epigeal and arboreal nests in termites are associated with increased desiccation stress and increased desiccation tolerance. These findings highlight the role of nest type in influencing desiccation tolerance mechanisms and water regulation strategies in termites.