They sport some of the most impressive headgear in the insect world, yet they\u2019re no bigger than a kernel of corn.<\/p>\n
They live all over the world, including in Storrs, mostly found in woods and gardens, but a select few have one of the best views of campus from their cozy mesh tents inside the rooftop research greenhouses on the Biology\/Physics Building \u2013 not typically a place where you\u2019d want to house a bug that pierces plants to feast on their juices. But these aren\u2019t typical bugs.<\/p>\n
Worldwide, there are more than 3,000 species of tiny treehoppers, known for their ornate pronotum \u2013 the dorsal topside of first of the three segments of an insect\u2019s thorax \u2013 that is commonly referred to as the treehopper\u2019s \u201chelmet.\u201d Why the treehopper developed the enlarged, three-dimensional hood ornament that distinguishes it from the rest of the insect world remains a mystery to scientists, though it\u2019s theorized that mimicry or camouflage designed to protect it from predators is a likely reason.<\/p>\n
But a study from researchers in UConn\u2019s Ecology and Evolutionary Biology Department, published today in the journal Nature Ecology & Evolution<\/em><\/a>, is shedding new light on a long-running debate over just how treehopper\u2019s helmet evolved.<\/p>\n \u201cI\u2019ve always been interested in things that look really cool,\u201d said Cera Fisher Ph.D. ’19, a post-doctoral researcher and UConn Outstanding Scholar Fellowship recipient who has been studying treehoppers since 2012 and is the lead author of the new study. \u201cAnd, in particular, the kinds of body shapes where you\u2019re like, \u2018Whoa! How did that evolve?\u2019 You know, where it\u2019s just a little bit mind blowing.\u201d<\/p>\n The treehopper\u2019s helmet is, indeed, mind blowing: Some species resemble leaves or thorns, while others look as though ants or wasps are sitting perched atop the treehopper\u2019s head. How that unique helmet came to be has been the subject of debate amongst the entomologists and evolutionary biologists that study the small insects: Does it develop using the same genes as the rest of the body wall? Or did it have to borrow developmental genes from somewhere else \u2013 maybe the legs or wings?<\/p>\n \u201cWith their closest relatives \u2013 and really almost every other bug \u2013 this same body part is just a flat piece of their back,\u201d said Fisher. \u201cWith the treehopper, that body part projects in three different dimensions, giving them this whole new space in which they can evolve. They\u2019ve been around for maybe 130 million years, but in that time they\u2019ve evolved 3000 different shapes of this body part. That kind of diversity is really stunning.\u201d<\/p>\n Fisher sought to tackle the question of how the treehopper evolved its helmet by sequencing the insect\u2019s RNA, the nucleic acid present in all living cells that works as a messenger, carrying information on how genes are expressed. She developed her samples by first domesticating her own colony of Entylia carinata<\/em>, which Fisher calls the \u201ccamelback treehopper\u201d \u2013 a species that can be found in Connecticut, has an interesting c-shaped curve in its helmet, develops relatively quickly from egg to adult, and isn\u2019t quite as picky about its diet as some other species. The UConn colony dines on fast-growing and easy-to-cultivate sunflower plants.<\/p>\n Next, Fisher dissected the tiny bugs \u2013 a painstaking process undertaken with a microscope and extremely fine tools \u2013 and extracted samples from the treehoppers. She also extracted samples from Homalodisca vitripennis<\/em>, a species of leafhopper bug that is related to treehoppers but lacks a helmet and instead displays the more-typical, smooth-surfaced pronotum.<\/p>\n \u201cThe leafhopper is our comparison case,\u201d said Fisher. \u201cIt\u2019s standing in for what we think the treehopper\u2019s ancestor might have been more like.\u201d<\/p>\n Fisher then sequenced the RNA from multiple body parts in both insects and waded through more than one billion data points in search of any similarities or signals that might point to specific genes at play in the formation of the treehopper\u2019s helmet. Ultimately, while the leafhopper\u2019s RNA sequence showed that its flat pronotum was substantially similar to its also flat mesonotum, which is the topside of its second body segment, the genes of the treehopper\u2019s helmeted pronotum were most similar to its wings.<\/p>\n \u201cWe had three different ideas for things that might have led to the evolution of the helmet,\u201d Fisher said. \u201cWe thought that maybe it was just using the same developmental pathways that normally are used in that dorsal body wall. We thought that it might be possible that it was reusing some wing-related genes, and then we thought it might be that it\u2019s reusing genes that are normally involved in leg development.\u201d<\/p>\n Fisher continued, \u201cAt a really high level, the RNA data indicates that the helmet is using a lot of the same genes that the wings use in development; it\u2019s being built with the same genes.\u201d<\/p>\n Elizabeth Jockusch, the lab director and professor overseeing Fisher\u2019s work and co-author of the study, said the biggest surprise for her was in just how large the effect on gene expression was.<\/p>\n \u201cI would have thought that even if the helmet had incorporated a developmental network from some other body part,\u201d she said, \u201cthat we would still predominately see that it looked like its serial homologue,\u201d meaning the body part nearest to it, the second thoracic segment. That, however, was not the case: the genetic landscape linking the wings to the helmet was overwhelmingly clear.<\/p>\n Jockusch said the other surprise from the study was that, between the two species \u2013 the treehopper and the leafhopper \u2013 everything in the gene expression lines up exactly the way you think it would, except for the treehopper\u2019s helmet.<\/p>\n \u201cEspecially in insects, with how their body plans change, the way you get all this diversity is by these serially repeated body parts diverging from each other,\u201d Fisher said. \u201cWhat is interesting about the treehopper is that it\u2019s a case of divergence of these serial homologues where it\u2019s not just acquiring a few changes gradually over the course of hundreds of millions of years. It\u2019s taking this entire suite of genes and redeploying it in this spot and, by doing so, you get a really different body part.\u201d<\/p>\n Fisher\u2019s study only involved one species of treehopper and one species of leafhopper, and only sampled the insects at one point in their development from immature nymphs to complete, helmeted adults. Her work on the fascinating little bugs will continue, though, with additional study that involves sampling the same species at different points in their nymphal development as well as sampling two additional species of treehoppers to see if the same RNA signaling occurs in across different members of the diverse treehopper family. The continuing study will also add another comparison species, the milkweed bug.<\/p>\n Fisher said that there are still questions to be answered about how the treehopper helmet came to be.<\/p>\n \u201cYou can try to get at the early changes, like what exactly changed to kick off all of this wing-like gene expression?\u201d she said. \u201cAnother question is that, given that we have this wing-like gene expression, how do we get all these shapes? How do we get all this diversity? Because there\u2019s a lot of diversity in insect wings, too, and a lot of the ways that insect wings can change shape and form have been studied a lot, especially in butterflies. But we don\u2019t know how this three-dimensional thing might get tinkered with through natural selection.\u201d<\/p>\n You can learn more about treehoppers and the Jockusch lab\u2019s<\/a> work with these fascinating insects at a new exhibit curated by the Connecticut State Museum of Natural History<\/a>. The exhibit officially opens in January 2020, but is available for viewing now at UConn\u2019s Homer Babbidge Library.<\/p>\n The study is also co-authored by Jill Wegrzyn, an assistant professor in UConn\u2019s Ecology and Evolutionary Biology Department whose Computational Genomics Lab played a critical role in analyzing the RNA data from the treehoppers and leafhoppers.<\/p>\n <\/p>\n The study was supported by funding from the National Science Foundation (no. IOS 1656572) and was supported in part by pilot funding from the Sigma Xi Grants in Aid of Research program and the Society for the Study of Evolution Rosemary Grant Award program.<\/em><\/p>\n","protected":false},"excerpt":{"rendered":" A study by UConn researchers sheds new light on how the distinctive “helmets” of treehopper insects evolved. <\/p>\n","protected":false},"author":134,"featured_media":157048,"comment_status":"closed","ping_status":"open","sticky":false,"template":"","format":"standard","meta":{"_acf_changed":false,"_crdt_document":"","wds_primary_category":0,"wds_primary_series":0,"wds_primary_attribution":0,"footnotes":""},"categories":[2226,2076,2225],"tags":[],"magazine-issues":[],"coauthors":[2168],"class_list":["post-157016","post","type-post","status-publish","format-standard","has-post-thumbnail","hentry","category-clas","category-research","category-uconn-storrs"],"pp_statuses_selecting_workflow":false,"pp_workflow_action":"current","pp_status_selection":"publish","acf":[],"publishpress_future_action":{"enabled":false,"date":"2026-05-08 19:23:47","action":"change-status","newStatus":"draft","terms":[],"taxonomy":"category","extraData":[]},"publishpress_future_workflow_manual_trigger":{"enabledWorkflows":[]},"_links":{"self":[{"href":"https:\/\/today.uconn.edu\/wp-rest\/wp\/v2\/posts\/157016","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/today.uconn.edu\/wp-rest\/wp\/v2\/posts"}],"about":[{"href":"https:\/\/today.uconn.edu\/wp-rest\/wp\/v2\/types\/post"}],"author":[{"embeddable":true,"href":"https:\/\/today.uconn.edu\/wp-rest\/wp\/v2\/users\/134"}],"replies":[{"embeddable":true,"href":"https:\/\/today.uconn.edu\/wp-rest\/wp\/v2\/comments?post=157016"}],"version-history":[{"count":6,"href":"https:\/\/today.uconn.edu\/wp-rest\/wp\/v2\/posts\/157016\/revisions"}],"predecessor-version":[{"id":157077,"href":"https:\/\/today.uconn.edu\/wp-rest\/wp\/v2\/posts\/157016\/revisions\/157077"}],"wp:featuredmedia":[{"embeddable":true,"href":"https:\/\/today.uconn.edu\/wp-rest\/wp\/v2\/media\/157048"}],"wp:attachment":[{"href":"https:\/\/today.uconn.edu\/wp-rest\/wp\/v2\/media?parent=157016"}],"wp:term":[{"taxonomy":"category","embeddable":true,"href":"https:\/\/today.uconn.edu\/wp-rest\/wp\/v2\/categories?post=157016"},{"taxonomy":"post_tag","embeddable":true,"href":"https:\/\/today.uconn.edu\/wp-rest\/wp\/v2\/tags?post=157016"},{"taxonomy":"magazine-issue","embeddable":true,"href":"https:\/\/today.uconn.edu\/wp-rest\/wp\/v2\/magazine-issues?post=157016"},{"taxonomy":"author","embeddable":true,"href":"https:\/\/today.uconn.edu\/wp-rest\/wp\/v2\/coauthors?post=157016"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}