Landscape heterogeneity and the reconfiguration of host plant distributions as a consequence of Quaternary climate oscillations are suggested to play a determinant role in shaping the evolutionary history of herbivorous insects. The cactus moth, Cactoblastis cactorum, is a southern South American phytophagous insect specialized in the use of cacti as feeding and breeding resources. It can be found across broad latitudinal and longitudinal gradients feeding on diverse native Opuntia species as well as the exotic and cultivated species Opuntia ficus-indica. Using high-throughput sequence data for the nuclear genome and mitochondrial DNA sequencing, we investigated patterns of genomic variation of C. cactorum across its native distribution. We integrated a demographic modeling approach for inferring gene flow and divergence times between C. cactorum populations, within a landscape genomic framework, to test alternative spatially-explicit hypotheses of past and current population connectivity based on climatically suitable areas for the focal species and distributions of host plants. Regions currently exhibiting high genomic diversity were evaluated for congruence with areas where suitable climatic conditions remained stable from the last glacial maximum to the present. Results revealed significant population structure across the range of C. cactorum, that can be explained by the spatial configuration of persistently suitable environmental conditions and host plant ranges during interglacial and glacial periods. Moreover, genomic data supported a hypothesis of long-term habitat stability in the northern regions of the distribution that served as a refuge for C. cactorum, enabling the accumulation and maintenance of high levels of genetic diversity over time.

Surveys of patterns of genetic variation in natural sympatric and allopatric populations of recently diverged species are necessary to understand the processes driving intra and interspecific diversification. The South American moths Cactoblastis cactorum, Cactoblastis doddi and Cactoblastis bucyrus are specialized in the use of cacti as host plants. These species have different distribution ranges and differ in patterns of host plant use. However, there are areas in which their ranges overlap, as in northwestern Argentina, where they are largely sympatric. Using a combination of genome-wide SNPs and mitochondrial data we investigated the phylogeographic patterns of these cactophilic moths and searched for footprints of hybridization. Additionally, we evaluated a moth population feeding on Cleistocactus baumannii, a plant never reported as a host for the genus. We identified three well delimited species and detected signs of historical gene flow. Our survey also revealed intraspecific geographic structure in both C. doddi and C. cactorum and showed that the moth population feeding on C. baumannii may be considered as conspecific to C. bucyrus. Overall, our results indicated historical events of genetic interchange occurred in Cactoblastis cactophagous moths, but host plants likely played an important role during divergence limiting gene flow across species.

Cryptic taxa have often been observed in the form of host‐associated species that diverged as the result of adaptation to alternate host plants. Untangling cryptic diversity in species complexes that encompass invasive species is a mandatory task for pest management. Moreover, investigating the evolutionary history of a species complex may help to understand the drivers of their diversification. The mealybug Hypogeococcus pungens was believed to be a polyphagous species from South America and has been reported as a pest devastating native cacti in Puerto Rico, also threatening cactus diversity in the Caribbean and North America. There is neither certainty about the identity of the pest, nor the source population from South America. Recent studies pointed to substantial genetic differentiation among local populations, suggesting that H. pungens is a species complex. In this study, we used a combination of genome-wide SNPs and mtDNA variation to investigate species diversity within H. pungens sensu lato to establish host plant ranges of each one of the putative members of the complex, to evaluate whether the pattern of host plant association drove diversification in the species complex, and to determine the source population of the Puerto Rican cactus pest. Our results suggested that H. pungens comprises at least five different species, each one strongly associated with specific host plants. We also established that the Puerto Rican cactus pest derives from southeastern Brazilian mealybugs. This is an important achievement because it will help to design reliable strategies for biological control using natural enemies of the pest from its native range.