EVOLUTIONARY REDUCTION OF COMPLEX LIFE CYCLES: LOSS OF HOST‐ALTERNATION IN
            <i>PEMPHIGUS</i>
            (HOMOPTERA: APHIDIDAE)

Moran, Nancy A.; Whitham, Thomas G.

doi:10.1111/j.1558-5646.1988.tb02490.x

Cited by 39 publications

(3 citation statements)

References 33 publications

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“…An alternative hypothesis for the increase in resistance as one proceeds higher in elevation contends that aphids are directly affected by elevational differences in environment (e.g., temperature). Environmental differences, such as temperature, are known to effect patterns of aphid host-alternation (Moran and Whitham, 1988). Such environmental differences may also result in increased mortality as well (aphids were collected from a single source tree and transferred, therefore results are not confounded by potential genotypic effects of site).…”

Section: Host-plant Resistance: Environmental Effectsmentioning

confidence: 99%

The Effects of Host‐plant Genotype, Hybridization, and Environment on Gall‐aphid Attack and Survival in Cottonwood: The Importance of Genetic Studies and the Utility of RFLPS

Paige

Capman

1993

Evolution

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Abstract. -Using restriction fragment length polymorphisms (RFLPs) we show how host-plant genotype and hybridization in cottonwood, Populus sp., affects the attack and survival of the gallforming aphid, Pemphigus betae. Fremont cottonwoods, hybrid FI 's and backcross I's were found to be highly resistant, while backcross 2's, 3's, 4's and pure narrowleafs ranged from highly resistant to highly susceptible with only a few trees being highly resistant. Results from our genetic analysis also suggest that resistance is likely polygenic, not the result of single gene resistance. In addition, genetic analysis showed that studies based upon leaf morphology alone give an inaccurate assessment of host-plant genotype an" the extent of hybridization, altering previous views of the relationship between plant hybridization and pest attack. Previous studies assumed that narrowleafs were more resistant than backcross genotypes based upon comparisons ofoverall levels ofresistance between the hybrid zone and the "pure" narrowleafzone. Results from RFLP analyses, however, show that there are no significant differences in the levels of resistance between backcross genotypes (BC2's-4's) and pure narrowleafs. Furthermore, results show that the "pure" narrow leaf zone is in fact a mixture of pure and backcross genotypes, extending the zone of introgression previously reported. Experiments in combination with RFLP analyses suggest that resistance traits are differentially expressed along an environmental gradient partially explaining the previously reported differences in resistance between these two regions. In light of our results it is clear that genetic studies will be necessary to discern the true relationship between hybridization and pest resistance. Until such studies are widely conducted generalizations regarding the effects of hybridization on the structure and dynamics of pest populations will be premature at best. With the recent advent of recombinant DNA technology, and its use in the identification of restriction fragment length polymorphisms (RFLPs), we now have the capability of addressing a number of problems of ecological and evolutionary interest that have proven intractable using conventional methods ofinvestigation. Restriction fragment length polymorphisms have been successfully used to assign parentage to individuals within populations (Wetton et aI., 1987;Burke and Bruford, 1987;Quinn and White, 1987; Rabenold et aI., 1990), to establish matriarchal ancestry (Avise and Nelson, 1989) to assess genotypic differences within and between populations (Harrison et aI., 1987; Baker et aI., 1989; Paige et aI., 1991) and to measure genetic distance and levels of heterozygosity (Plante et aI., 1989). In particular, these techniques circumvent many of the problems associated with electrophoretic (isozyme) studies of natural populations of plants and animals.For example, such genetic studies are often limited by the number of marker loci available. With the development ofRFLPs, however, we now have an almost unlimited n...

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Section: Host-plant Resistance: Environmental Effectsmentioning

confidence: 99%

The Effects of Host‐plant Genotype, Hybridization, and Environment on Gall‐aphid Attack and Survival in Cottonwood: The Importance of Genetic Studies and the Utility of RFLPS

Paige

Capman

1993

Evolution

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“…Along with various indirect losses, both species can result in direct crop losses through the release of several allelochemicals, and their allelopathic effects have been reported on sunflower, tomato, mustard, and a few other crop species [ 7 , 10 , 11 ]. Furthermore, C. album also serves as an alternate host for plentiful plant pathogens ( Stagonospora atriplicis, Polymyxa betae, Yellow Vein Virus, Beet Yellows Virus, Peanut Stunt Cucumovirus, Prunus Necrotic Ring Spot Virus), insects ( Pemphigus betae ), and nematodes ( Ditylenchus destructor, Meloidogyne incognita ) [ 12 , 13 , 14 , 15 , 16 , 17 , 18 , 19 ]. Besides crop fields, both species propagate luxuriantly on wastelands, pastures, and uncultivated lands.…”

Section: Introductionmentioning

confidence: 99%

Seed Germination Ecology of Chenopodium album and Chenopodium murale

Bana

Kumar

Sangwan

et al. 2022

Biology

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Chenopodium album L. and Chenopodium murale L. are two principal weed species, causing substantial damage to numerous winter crops across the globe. For sustainable and resource-efficient management strategies, it is important to understand weeds’ germination behaviour under diverse conditions. For the germination investigations, seeds of both species were incubated for 15 days under different temperatures (10–30 °C), salinity (0–260 mM NaCl), osmotic stress (0–1 MPa), pH (4–10), and heating magnitudes (50–200 °C). The results indicate that the germination rates of C. album and C. murale were 54–95% and 63–97%, respectively, under a temperature range of 10 to 30 °C. The salinity levels for a 50% reduction in the maximum germination (GR50) for C. album and C. murale were 139.9 and 146.3 mM NaCl, respectively. Regarding osmotic stress levels, the GR50 values for C. album and C. murale were 0.44 and 0.43 MPa, respectively. The two species showed >95% germination with exposure to an initial temperature of 75 °C for 5 min; however, seeds exposed to 100 °C and higher temperatures did not show any germination. Furthermore, a drastic reduction in germination was observed when the pH was less than 6.0 and greater than 8.0. The study generated information on the germination biology of two major weed species under diverse ecological scenarios, which may be useful in developing efficient weed management tactics for similar species in future agri-food systems.

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“…Eriosomatinae is an extraordinary aphid group exhibiting very diverse life history traits and is widely distributed in the Holarctic and Oriental regions [63]. Most eriosomatine species show a heteroecious holocyclic life history, i.e., seasonal switching between primary and secondary host plants [64][65][66]. Eriosomatinae aphids have strong primary host specificity, with different patterns of host association among tribes.…”

Section: Introductionmentioning

confidence: 99%

Host Plants Influence the Symbiont Diversity of Eriosomatinae (Hemiptera: Aphididae)

Jiang

Chen

et al. 2020

Insects

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Eriosomatinae is a particular aphid group with typically heteroecious holocyclic life cycle, exhibiting strong primary host plant specialization and inducing galls on primary host plants. Aphids are frequently associated with bacterial symbionts, which can play fundamental roles in the ecology and evolution of their host aphids. However, the bacterial communities in Eriosomatinae are poorly known. In the present study, using high-throughput sequencing of the bacterial 16S ribosomal RNA gene, we surveyed the bacterial flora of eriosomatines and explored the associations between symbiont diversity and aphid relatedness, aphid host plant and geographical distribution. The microbiota of Eriosomatinae is dominated by the heritable primary endosymbiont Buchnera and several facultative symbionts. The primary endosymbiont Buchnera is expectedly the most abundant symbiont across all species. Six facultative symbionts were identified. Regiella was the most commonly identified facultative symbiont, and multiple infections of facultative symbionts were detected in the majority of the samples. Ordination analyses and statistical tests show that the symbiont community of aphids feeding on plants from the family Ulmaceae were distinguishable from aphids feeding on other host plants. Species in Eriosomatinae feeding on different plants are likely to carry different symbiont compositions. The symbiont distributions seem to be not related to taxonomic distance and geographical distance. Our findings suggest that host plants can affect symbiont maintenance, and will improve our understanding of the interactions between aphids, their symbionts and ecological conditions.

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EVOLUTIONARY REDUCTION OF COMPLEX LIFE CYCLES: LOSS OF HOST‐ALTERNATION IN PEMPHIGUS (HOMOPTERA: APHIDIDAE)

Cited by 39 publications

References 33 publications

The Effects of Host‐plant Genotype, Hybridization, and Environment on Gall‐aphid Attack and Survival in Cottonwood: The Importance of Genetic Studies and the Utility of RFLPS

The Effects of Host‐plant Genotype, Hybridization, and Environment on Gall‐aphid Attack and Survival in Cottonwood: The Importance of Genetic Studies and the Utility of RFLPS

Seed Germination Ecology of Chenopodium album and Chenopodium murale

Host Plants Influence the Symbiont Diversity of Eriosomatinae (Hemiptera: Aphididae)

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