Thursday, July 13, 2023

Butterflies and moths share ancient ‘blocks’ of DNA

UNIVERSITY OF EXETER

A male and female African monarch mating — IMAGE: A MALE AND FEMALE AFRICAN MONARCH MATING view more
CREDIT: UNIVERSITY OF EXETER

Butterflies and moths share “blocks” of DNA dating back more than 200 million years, new research shows.

Scientists from the Universities of Exeter (UK), Lübeck (Germany) and Iwate (Japan) devised a tool to compare the chromosomes (DNA molecules) of different butterflies and moths.

They found blocks of chromosomes that exist in all moth and butterfly species, and also in Trichoptera – aquatic caddisflies that shared a common ancestor with moths and butterflies some 230 million years ago.

Moths and butterflies (collectively called Lepidoptera) have widely varying numbers of chromosomes – from 30 to 300 – but the study’s findings show remarkable evidence of shared blocks of homology (similar structure) going back through time.

“DNA is compacted into individual particles or chromosomes that form the basic units of inheritance,” said Professor Richard ffrench-Constant, from the Centre for Ecology and Conservation on Exeter’s Penryn Campus in Cornwall.

“If genes are on the same ‘string’, or chromosome, they tend to be inherited together and are therefore ‘linked’.

“However, different animals and plants have widely different numbers of chromosomes, so we cannot easily tell which chromosomes are related to which.

“This becomes a major problem when chromosome numbers vary widely – as they do in the Lepidoptera.

“We developed a simple technique that looks at the similarity of blocks of genes on each chromosome and thus gives us a true picture of how they change as different species evolve.

“We found 30 basic units of ‘synteny’ (literally meaning ‘on the same string’ where the string is DNA) that exist in all butterflies and moths, and go back all the way to their sister group the caddisflies or Trichoptera.”

Butterflies are often seen as key indicators of conservation, and many species worldwide are declining due to human activity.

However, this study shows that they are also useful models for the study of chromosome evolution.

The study improves scientific understanding of how moth and butterfly genes have evolved and, importantly, similar techniques may also provide insights about the evolution of chromosomes in other groups of animals or plants.

The paper, published in the journal G3: Genes, Genomes, Genetics, is entitled: “Lepidopteran Synteny Units (LSUs) reveal deep chromosomal conservation in butterflies and moths.”

The chromosomes of the African Monarch butterfly. The red dots highlight the ends of each chromosome using a DNA probe linked to a fluorescent reporter
CREDIT
University of Exeter

JOURNAL

G3 Genes Genomes Genetics

DOI

10.1093/g3journal/jkad134

SUBJECT OF RESEARCH

Animals

ARTICLE TITLE

Lepidopteran Synteny Units reveal deep chromosomal conservation in butterflies and moths

ARTICLE PUBLICATION DATE

13-Jun-2023

Small-winged and lighter colored butterflies likely to be at greatest threat from climate change

The family, wing length and wing color of tropical butterflies all influence their ability to withstand rising temperatures, say a team led by ecologists at the University of Cambridge.

Peer-Reviewed Publication

UNIVERSITY OF CAMBRIDGE

Esme Ashe-Jepson conducing fieldwork in Panama, with a butterfly from the Calephelis genus in the Riodinidae family. — IMAGE: ESME ASHE-JEPSON CONDUCING FIELDWORK IN PANAMA, WITH A BUTTERFLY FROM THE CALEPHELIS GENUS IN THE RIODINIDAE FAMILY. view more
CREDIT: ESME ASHE-JEPSON

Images and paper available at: https://drive.google.com/drive/folders/18XRYP9dHcC1Z8lc3B86j3k6BzgIesqUS?usp=sharing

Small-winged and lighter coloured butterflies likely to be at greatest threat from climate change

The family, wing length and wing colour of tropical butterflies all influence their ability to withstand rising temperatures, say a team led by ecologists at the University of Cambridge. The researchers believe this could help identify species whose survival is under threat from climate change.

Butterflies with smaller or lighter coloured wings are likely to be ‘losers’ when it comes to climate change, with the Lycaenidae family, which contains over 6,000 species of butterflies, the majority of which live in the tropics, found to be particularly vulnerable.

Butterflies with larger or darker coloured wings are likely to fare better under increasing temperatures, but only to a point. Researchers say these butterflies could still experience dramatic declines if there were sudden heatwaves or if cool microclimates were lost through deforestation.

The results are published today in the Journal of Animal Ecology.

Butterflies rely on the sun’s warmth to give them the energy they need to function. They use ‘thermoregulation’ strategies to maintain a balanced body temperature against changing air temperatures.

Generally, strategies to keep cool involve adaptive behaviours like flying to a shady spot or angling wings away from the sun (thermal buffering). But when this is not possible or temperatures become too hot, species have to rely on physiological mechanisms such as the production of heat shock proteins to withstand high temperatures (thermal tolerance). Both of these strategies are needed to cope with climate change.

Researchers collaborated with the Smithsonian Tropical Research Institute (STRI) to study the thermal buffering and thermal tolerance strategies of tropical butterflies. They collected data from multiple habitats in Panama.

Equipped with hand-held nets, ecologists took the temperature of over 1,000 butterflies using a tiny thermometer-like probe. They compared each butterfly’s temperature to that of the surrounding air or the vegetation it was perched on. This gave a measurement of thermal buffering – the ability to maintain a steady body temperature against fluctuating air temperatures.

A second experiment was conducted at STRI Gamboa facilities and involved assessing butterflies’ thermal tolerance – their ability to withstand extreme temperatures, such as those they may experience during a heatwave. This was assessed by capturing a subset of butterflies and placing them in glass jars within a water bath – the temperature of which was steadily increased. Thermal tolerance was assessed as the temperature at which butterflies could no longer function.

Butterflies that had large wings tended to have greater thermal buffering ability but less thermal tolerance than smaller butterflies. Indeed, in a further study conducted by the same research team, butterflies with larger, longer and narrower wings were found to be better at thermal buffering.

Thermal buffering abilities were found to be stronger in darker-winged butterflies who could also tolerate higher temperatures than paler-winged butterflies.

Butterflies from the Lycaenidae family which have small, bright, and often iridescent, wings had the poorest thermal buffering and low thermal tolerance. If temperatures continue to rise at the current rate, forests continue to be cut down, and cool microclimates are lost, there is a very real threat that we could lose many species in this family in the future, say the researchers.

A trade-off in terms of butterflies’ cooling strategies was observed: those that were good at thermal buffering were less good at thermal tolerance and vice versa.

Scientists say this suggests that tropical butterflies have evolved to cope with temperature changes using one of these strategies at the expense of the other, and that this is likely to be due to selective pressures.

Lead author Esme Ashe-Jepson, a PhD student at Cambridge’s Department of Zoology, said: “Butterflies with physical characteristics that may help them to avoid the sun’s heat, like having large wings that enable them to fly quickly into shade, rarely experience high temperatures, and so have not evolved to cope with them. On the other hand, species which can cope with higher temperatures physiologically have experienced less selective pressure to evolve heat-avoiding behaviours.

“As temperatures continue to rise, and forest fragments get smaller and further apart because of deforestation, butterflies which rely on their surroundings to avoid high temperatures may not be able to travel between forest fragments, or cope with increasingly common heatwaves.”

The researchers say this means that species with large dark wings that are good at thermal buffering may initially be unaffected by warming temperatures, as they can continue to thermoregulate effectively using behaviour and microclimates, but their survival could be at risk if there are sudden heatwaves, or they can no longer escape to cool vegetation.

“Ultimately all insects, including butterflies, the world over are likely to be affected by climate change,” said Ashe-Jepson. “Adaptation to climate change is complex and can be impacted by other factors such as habitat destruction. We need to address these two global challenges together.”

Further research is needed to investigate the effect a warming climate may have on other life stages of butterflies, such as caterpillars and eggs, and other insect groups.

Senior author Greg Lamarre, at the Czech Academy of Science and Research Associate at STRI said: “Worldwide, most entomologists are observing drastic declines in insect biodiversity. Understanding the causes and consequences of insect decline has become an important goal in ecology, particularly in the tropics, where most of terrestrial diversity occurs.”

The research was funded by the GACR Czech Science Foundation, an ERC Starting Grant, a Smithsonian Tropical Research Institute short-term fellowship, and the Sistema Nacional de Investigación (SENACYT), Panama.

ENDS.

Esme Ashe-Jepson conducing fieldwork in Panama, with a butterfly from the Calephelis genus in the Riodinidae family.

Esme Ashe-Jepson conducing fieldwork in Panama, with a Juditha caucana butterfly from the Riodinidae family.

CREDIT

Esme Ashe-Jepson

Reference:

Esme Ashe-Jepson et al. Tropical butterflies use thermal buffering and thermal tolerance as alternative strategies to cope with temperature increase. Journal of Animal Ecology DOI: 10.1111/1365-2656.13970

Contact details:

Charis Goodyear, University of Cambridge: Charis.Goodyear@admin.cam.ac.uk

Esme Ashe-Jepson, University of Cambridge: ea483@cam.ac.uk

About the University of Cambridge

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