Talk:Host–parasite coevolution

Latest comment: 3 years ago by Jens Lallensack in topic GA Review

Oak - Powdery Mildew Example

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Oak trees and powdery mildew are a common host-parasite interaction in nature. I think adding this example would be beneficial to the page. Some research of this interaction has used methods testing a third variable such as altitude which can be described as a method for studying the third variable effect of coevolution. Due to the varying environment, the response to selection differs, and therefore the phenological changes in the population of both the plants and fungi will differ.c[1] Stephenoff.2 (talk) 20:36, 1 October 2014 (UTC)Reply

References

  1. ^ Desprez-Loustau, M.; Vitasse, Y.; Delzon, S.; Capdevielle, X.; Marcais, B.; Kremer, A. (January 2010). "Are plant pathogen populations adapted for encounter with their host? A case study of phenological synchrony between oak and an obligate fungal parasite along an altitudinal gradient". Journal of Evolutionary Biology. 23 (1): 87-97. doi:10.1111/j.1420-9101.2009.01881.x.

GA Review

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This review is transcluded from Talk:Host–parasite coevolution/GA1. The edit link for this section can be used to add comments to the review.

Reviewer: Jens Lallensack (talk · contribs) 20:50, 4 August 2021 (UTC)Reply


Comments follow soon! --Jens Lallensack (talk) 20:50, 4 August 2021 (UTC)Reply

Many thanks for taking this on. Chiswick Chap (talk) 08:59, 5 August 2021 (UTC)Reply
  • Host–parasite coevolution is a special case of coevolution, the reciprocal adaptive genetic change of a host and a parasite through reciprocal selective pressures. – maybe we can get rid of the first "reciprocal"? Seems repetitive to have this word twice.
  • Done.
  • It is characterized by reciprocal genetic change and thus changes in allele frequencies within populations. – Why is this specific for host-parasite coevolution, doesn't it apply to coevolution in general? --Jens Lallensack (talk) 22:06, 4 August 2021 (UTC)Reply
  • Yes it is, said so.
  • overdominance caused by heterozygote advantage; – aren't both terms describing the same thing, some being more specific than the other? To reduce the count of technical terms in the lead, what do we loose when removing "overdominance caused by"?
  • Removed, happy to simplify here.
  • and directional selective sweeps near an advantageous mutation – in the main text, there is only the sub-heading "directional selection". Why do you use the term "selective sweeps" in the lead, then, instead of simply "directional selection"?
  • Reworded, and linked.
  • Selective sweeps are one form of directional selection, where the increase in frequency will eventually lead to the fixation of the advantageous allele. – Isn't that definition different from what was said in the lead ("selective sweeps near an advantageous mutation")?
  • Harmonised the two.
  • The lead summarizes the article, but is, I think, too technical and difficult to comprehend. The lead should be as accessible as possible. One problem is that it jumps right into the selection dynamics right after the first sentence. To improve the lead, I would, for example, suggest to add general info provided in the "Overview" section to the lead, after its first sentence. Maybe even repeat most of the "Overview" section in the lead. Also, plain-language explanations of central terms in parentheses could help.
  • I've rewritten the first paragraph and added more explanation.
  • interspecific interactions – link, or even better use "interactions between species" instead to be more accessible to readers.
  • Good idea, done both.
  • In other words, the specific environmental conditions determine how any genotype of one species influences the fitness of another species.[10] – Would be helpful to have, in addition, also an example, as examples greatly help with comprehension.
  • The Plantago/Podosphaera example is given immediately after the list. I've reworded the start of that paragraph to make its purpose clear.
  • Extended the example.
  • These hotspots are intermixed with so-called coldspots in which only one or neither species adapts to the antagonist. – Again, an example could help. What environmental conditions could possibly cause a coldspot?
  • Same example. If a specific value of environmental variable favours the parasite - say the mildew likes it damp - then places with values other than that (dry) will be coldspots.
  • Between the communities/regions there is a continuous "mixing" of traits by gene flow, random genetic drift, population extinction, or mutation. – How can extinction possibly lead to mixing of traits? I thought it can only lead to loss.
  • This is the extinction of populations not species. If population B is lost, populations A and C may meet for the first time and mix.
  • Aland islands – need to be spelled with the proper A character: Åland Islands
  • Woops, fixed.
  • Added explanation.
  • Therefore, investment in one trait (e.g. virulence or immunity) – Is "investment" the proper term? It sounds as if evolution would be an active process controlled by the organism, like a human who invests time to get something done. --Jens Lallensack (talk) 21:42, 5 August 2021 (UTC)Reply
  • Ah, teleology in biology. The language of purpose is hard to avoid; the meaning is natural selection. But we don't need the word "investment".
  • binding of the bacteriophage to E. coli surface receptor – "a" or "the" missing?
  • Added.
  • It means both partners (host and parasite).
Done. Many thanks for the review. Chiswick Chap (talk) 09:55, 6 August 2021 (UTC)Reply