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Scientific classification
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S. lineatus
Binomial name
Sitona lineatus

Sitona lineatus

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Sitona lineatus, commonly known as the pea leaf weevil is a species of weevil with a Palearctic distribution. It is a common pest of beans, peas, and other plants in the family Fabaceae [1]. Adult beetles of S. lineatus measure 3.4-5.3 mm in length. They are characterized by a series of colored scales arranged in alternating lines (striae) on the elytra; it is from this characteristic where the species gets its name lineatus meaning 'lined' or 'striped'. The head and pronotum also have fine pointed setae amongst the scales. The antennae are clubbed, pointed and preceded by 7 segments. The femora is dark, but tibiae and tarsi are red. As a member of Order Coleoptera (beetles) their forewings are modified to form hardened covers over the thorax and abdomen, with the hindwings for flight underneath [2].

Distribution

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S. lineatus is native to Europe and North Africa, and is considered an invasive species in North America. They are typically found in the western prairie provinces of Canada (Alberta, Saskatchewan, Manitoba) and are expanding east from Saskatchewan, south near the Canada/USA border into North Dakota, and north into higher latitudes of Alberta[1]. Expansion is limited by both temperature and precipitation, but they are more sensitive to precipitation[1]. Climate models have predicted the potential for expansion north in those distribution territories[1].

Behavior and life cycle

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S. lineatus are are univoltine species that are oligophagous within the Fabaceae plants. Adults will overwinter in the field margins of pea, bean crops, or migrate to fields of alfalfa before the onset of winter[3]. Their emergence from winter dormancy is related to temperature, as adults have been seen to prefer temperatures of 12.5 °C as an indicator to leave their winter site habitat, [1] with wind currents being the main mechanism by which they find and colonize new crop habitats[3]. Both males and females have been shown to have increased longevity when feeding on pea plants as opposed to the alfalfa they eat over winter and in spring prior to migration[4]. Increased longevity for females translates to higher fecundity, and females will disperse from areas of high population density to areas with low density to maximize their egg to plant ratio[4]. Females that feed on pea crops generally have a higher reproductive capability than ones that feed more on alfalfa, it is advantageous to migrate from the field margins and winter shelters to the new pea plants emerging in spring[4]. After the respective reproductive periods in spring for males and females, adults will feed on the leaves of Fabaceae plants, and larvae will burrow into the soil after hatching where they feed primarily on Rhizobium at the nodules of the root system [1]. During their feeding underground, larvae go through 5 stages of growth (instars), and emerge as adults to feed on the crop above ground just as their parents in mid summer[1]. In late summer (August) the surviving adults leave the crop plants and migrate to the field margins, alfalfa fields, or other areas of habitat that make suitable shelter for the overwintering period of dormancy[5].

Agricultural Impact

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The impact of this invasive species can be difficult to estimate accurately as its distribution is widespread, and there are often abiotic factors (temperature, precipitation, growing season) that determine the success of S. lineatus which are inconsistent within its indigenous and invasive habitat ranges (Europe, Africa, and North America)[1].There is a way to focus on these types of pests and how to look at them in terms of potential cropland for their habitation. In 2018 in Canada, for example, approximately 3.6 million acres of pulse crops were grown, valuable domestically and as an export, the yields can be diminished as much as 28% from feeding activities of S. lineatus[6]. Damage to pea and bean crops can be severely impacted by S. lineatus feeding, due to the fact that both the root Rhizobium and foliage are fed upon by larvae and adults respectively. These crops are important as food resources and as nitrogen fixing plants, an ability which is reduced when larval feeding on rhizobium is significant enough. The damage to root nodules from hosting larvae can lead to decrease pod production, lower protein content of peas or beans, and the necessity of artificially fertilizing pulse crops and the increased cost associated with this[5],[7]

Pest Management

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Strategies for pest management has led to research relating to farming practices, biological agents, pesticides, and soil manipulation in order to mitigate harmful effects towards pulse crops by insects like S. lineatus. Farming practices like tilling can also make an impact on populations of S. lineatus, with the implementation of no till farming. Using this strategy, researchers have shown that S. lineatus prefers to colonize farmland that undergoes conventional tilling practices vs no tilling ones[8]. Some strategies involve supplementing crops with nitrogen-containing fertilizers to increase yields, where fertilized plants showed increases in yields despite root nodule damage[7]. S. lineatus can also be targeted by introducing to its habitat species of beetles that are natural predators of both egg deposits and grown adults[7]. In a laboratory study on insect pathogens it was shown that introducing biopesticides, in the form of toxic materials produced by bacterium, to a population of S. lineatus can have beneficial effects on mortality rates of exposed individuals [9]. Also, the potential to add insect pathogens directly to soil as a preventative measure could possibly create a pre-delivered natural buffer defense against the larvae that are responsible for damage to rhizobium bearing root nodules[10].

Predictions of Abundance for the Future

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A long term prediction for the future of food crop pests like S. lineatus indicates that increasing temperatures can facilitate the increase in population abundance with negative consequences for plants that struggle with change, and benefits to pests like increased life spans and the survivorship of more and overlapping generations [11]. Air temperature has been shown to have increased over a 30 year period retroactively from 2020[11], which could enable these insects to leave their winter habitat earlier in spring to colonize crop land with greater ease[11]. If the trends seen over the last 30 years of study continue, pest management solutions may increase in importance to ensure the viability of pulse crops, and mitigate the worst of the effects of pest infestations.

External Web Resources

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Invasive Species Compendium- https://www.cabi.org/isc/datasheet/50230

Plantwise Knowledge Bank- https://www.plantwise.org/knowledgebank/datasheet/50230

Mindat.org - https://www.mindat.org/taxon-1181282.html

Prairie West Monitoring Network - https://prairiepest.ca/tag/sitona/

References

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  1. ^ a b c d e f g h Carcamo, Hector A. (2018). "Progress Toward Integrated Pest Management of Pea Leaf Weevil: A Review. Annals of the Entomological Society of America, Volume 111, Issue 4, July 2018, Pages 144–153,". library.macewan.ca. doi:10.1093/aesa/say007. Retrieved 2021-12-07.{{cite web}}: CS1 maint: url-status (link)
  2. ^ "S. lineatus description". www.thewcg.org.uk. Retrieved 2021-12-07.{{cite web}}: CS1 maint: url-status (link)
  3. ^ a b Landon, F.; Levieux, J.; Rougon, D.; Taupin, P. (1997-09-01). "Influence of the immediate environment on the dispersal of Sitona lineatus L. (Col., Curc.) during crop colonisation". Agriculture, Ecosystems & Environment. 64 (3): 261–266. doi:10.1016/S0167-8809(97)00025-X. ISSN 0167-8809.
  4. ^ a b c Schotzko, D. J.; O’Keeffe, L. E. (1988-12-01). "Effects of Food Type, Duration of Hibernal Quiescence, and Weevil Density on Longevity of Sitona lineatus (Coleoptera: Curculionidae)". Journal of Economic Entomology. 81 (6): 1631–1636. doi:10.1093/jee/81.6.1631. ISSN 0022-0493.
  5. ^ a b Vankosky, M. A.; Cárcamo, H. A.; Dosdall, L. M. (2011). "Identification of potential natural enemies of the pea leaf weevil, Sitona lineatus L. in western Canada". Journal of Applied Entomology. 135 (4): 293–301. doi:10.1111/j.1439-0418.2010.01542.x. ISSN 1439-0418.
  6. ^ Morley-Senkler, Vivian; Williams, Jonathon; Vankosky, Meghan (2020-04). "Effect of temperature, population density, and sex on feeding damage caused by adult pea leaf weevil (Coleoptera: Curculionidae)". The Canadian Entomologist. 152 (2): 159–168. doi:10.4039/tce.2019.76. ISSN 0008-347X. {{cite journal}}: Check date values in: |date= (help)
  7. ^ a b c Vankosky, M. A.; Cárcamo, H. A.; Dosdall, L. M. (2011-10-01). "Response of Pisum sativum (Fabales: Fabaceae) to Sitona lineatus (Coleoptera: Curculionidae) Infestation: Effect of Adult Weevil Density on Damage, Larval Population, and Yield Loss". Journal of Economic Entomology. 104 (5): 1550–1560. doi:10.1603/EC10392. ISSN 0022-0493.
  8. ^ Hatten, Timothy D.; Dahlquist, Ruth M.; Eigenbrode, Sanford D.; Bosque-Pérez, Nilsa A. (2010). "Tillage affects the activity-density, absolute density, and feeding damage of the pea leaf weevil in spring pea". Entomologia Experimentalis et Applicata. 136 (3): 235–242. doi:10.1111/j.1570-7458.2010.01023.x. ISSN 1570-7458.
  9. ^ Shrestha, Govinda; Mettupalli, Sindhura; Gadi, Ramadevi; Miller, Debra A; Reddy, Gadi V P (2020-04-06). "Spinosad and Mixtures of an Entomopathogenic Fungus and Pyrethrins for Control of Sitona lineatus (Coleoptera: Curculionidae) in Field Peas". Journal of Economic Entomology. 113 (2): 669–678. doi:10.1093/jee/toz348. ISSN 0022-0493.
  10. ^ Hokkanen, Heikki M T; Menzler-Hokkanen, Ingeborg (2018-07-24). "Insect Pest Suppressive Soils: Buffering Pulse Cropping Systems Against Outbreaks of Sitona Weevils". Annals of the Entomological Society of America. 111 (4): 139–143. doi:10.1093/aesa/say019. ISSN 0013-8746.
  11. ^ a b c Almogdad, Mohammad; Tamošiūnas, Kęstutis; Semaškienė, Roma (2020-04-10). "Changes in Sitona lineatus abundance in faba beans as influenced by the air temperature and rainfall in the three decades". Zemdirbyste-Agriculture. 107 (2): 139–146. doi:10.13080/z-a.2020.107.018. ISSN 1392-3196.