Dragonfly wing patterns, new study

This 2014 video says about itself:

The colorful, acrobatic dragonfly may seem familiar, but this stunning macro film reveals the mysteries behind its metamorphic life cycle—and some surprising adaptations.

Learn about the making of this film: here.

From the Harvard John A. Paulson School of Engineering and Applied Sciences in the USA:

How dragonfly wings get their patterns

New model sheds light on how nature generates diverse patterns

September 17, 2018

For many species of insects, wings are like fingerprints — no two patterns are the same. These insects, like many other organisms from leopards to zebrafish, benefit from nature’s seemingly endless ability to generate diverse shapes and patterns. But how do these patterns form?

Researchers from Harvard University have developed a model that can recreate, with only a few parameters, the wing patterns of a large group of insects, shedding light on how these complex patterns form.

The research is published in Proceedings of the National Academy of Sciences.

“We have developed a simple model, with only a few assumptions about how wings grow, that can recapitulate patterns that look close to life-like and can do so for species that are distantly related to each other, from grasshoppers to dragonflies, damselflies and lacewings,” said Christopher Rycroft, Associate Professor of Applied Mathematics at the Harvard John A. Paulson School of Engineering and Applied Sciences and senior author of the paper. “This model could be useful for studying the evolution of wing structure and other patterned shapes.”

While the shape and pattern of insect wings vary tremendously across species, nearly all insect wings have veins — thick, strut-like structures embedded on the wing surface. Some insects, such as the well-studied fruit fly, only have a few, large primary veins. The position and shape of these veins are shared between left and right wings of the same individual and among individuals of the same species.

But other insects, such as dragonflies, have a complex network of secondary veins that crisscross the entire wing, partitioning the wing into hundreds or thousands of small, simple shapes. The shape and position of these secondary veins are endlessly variable, generating unique patterns on each individual wing.

These patterns have fascinated biologists and artists for centuries. Leonardo di Vinci, famously inspired by dragonfly flight, sketched dragonfly wings in the early 1500s. Dutch biologist Jan Swammerdam made extraordinarily detailed illustrations of wing patterns in his research on insect development in the mid-1600s. Since then, naturalists and biologists have continued to carefully document insect wings as a basic step in describing and identifying different species.

The researchers drew on this deep well of data to compile a large database of wing specimens.

Kathy Li, B.A. ’16, co-author of the paper, began the project as her undergraduate thesis. She collected more than 500 specimens of dragonflies and damselflies from 215 different species, including representatives from 17 families.

She compiled specimens from Harvard entomology classes, illustrations from 20th century reference books, and existing entomological databases. Li separated the wings from the bodies and imaged them to produce 2D images — not exactly what she imagined herself doing as an applied math major.

“I was always interested in biology, so the interdisciplinary aspect of the project was really exciting,” said Li, who is currently pursuing her Ph.D. in applied math at Columbia University. “I like the idea of being able to look at something and connect its geometry to a conclusion about biology.”

Once the database was compiled, the researchers differentiated, or segmented, each individual polygonal shape made from the intersecting veins.

“We wanted to take this complex shape and turn it into something simpler so we could ask specific questions and compare its geometry across species,” said Jordan Hoffmann, co-author of the paper and Ph.D. candidate at SEAS. “We looked at the geometric properties of these individual shapes, which we called domains. We looked at how elongated each domain was, how many sides it had, how it touched its neighbors.”

Hoffmann and the team found that a lot of the variation in geometry could be described by the size of the domain and its circularity. They also found that while each wing’s pattern is unique, the distribution of domain shapes is strikingly similar across families and species. For example, the size of the domains tends to decrease as they move away from the body, while the shape of the domains tends to become more circular towards the trailing edge of the wing.

“This is like geometric natural history, in which we are looking at how these shapes are distributed across many species,” said Seth Donoughe, co-author of the paper and postdoctoral fellow at the University of Chicago. “Once we had a good way to assess the similarity of wings, we built a simplified model for the development of wing veins.”

The researchers proposed that an unknown inhibitory signal diffuses from multiple signaling centers in the regions between the primary veins. These inhibitory zones emerge randomly and repel one another, and then prevent secondary veins from growing in certain areas. As the wing grows and stretches during development, those zones could form the complex geometries of the wing as the veins grew around them.

The researchers tested the model on many different insect species — including distantly related insects — and generated life-like reproductions of wings.

“If we’re not careful, even we are sometimes fooled by the simulated wings,” said Donoughe.

“The overall approach could be applied to natural patterns that have delighted us for ages, especially in this age where information from many different sources is readily accessible,” said Hoffman. “Problems like these are an exciting springboard for successful collaborations between biology and math.”

This research was co-authored by Mary Salcedo. It was supported by a U.S. Department of Energy (DOE) Computational Science Graduate Fellowship, U.S. National Science Foundation Graduate Training Fellowships, and the Applied Mathematics Program of the U.S. DOE Office of Advanced Scientific Computing Research, the NSF-Simons Center for Mathematical and Statistical Analysis of Biology at Harvard University, and the Harvard Quantitative Biology Initiative.


The biggest dinosaurs of all time

This 16 September 2018 video says about itself:

The Biggest Dinosaurs Of All Time

Some dinosaurs were the biggest land-dwelling animals to ever exist on Earth. When you picture a dinosaur, you might imagine a 13-meter long T. rex or a Titanosaur the size of an airplane.

But the first dinosaurs would have only come up to your knee. It turns out that sauropods, like Brontosaurus, developed special adaptations that allowed them to tower over the competition.

New coral species discovery in Panama

This 2011 video is called Coral reefs near Bocas Del Toro, Panama.

From the Smithsonian Tropical Research Institute:

New soft coral species discovered in Panama

September 14, 2018

Summary: Another new coral found in Panama’s Coiba National Park, a UNESCO National Heritage Site, the location of the Smithsonian’s newest research site.

A study in the journal Bulletin of Marine Science describes a new, blood-red species of octocoral found in Panama. The species in the genus Thesea was discovered in the threatened low-light reef environment on Hannibal Bank, 60 kilometers off mainland Pacific Panama, by researchers at the Smithsonian Tropical Research Institute in Panama (STRI) and the Centro de Investigación en Ciencias del Mar y Limnología (CIMAR) at the University of Costa Rica.

Scientists established the new species, Thesea dalioi, by comparing its physical traits, such as branch thickness and the bright red colony color, with the only other species in the genus in the eastern Pacific, T. variabilis.

T. dalioi is named for Ray Dalio, a supporter of marine exploration. Its name is intended to recognize Dalio’s valuable contributions to marine research and public outreach. Hannibal Bank, part of the Coiba National Park and a UNESCO World Heritage Site, is a coastal seamount and a biodiversity hot spot that has only been explored recently. “After just two expeditions using submersibles down to 300 meters, we have identified 17 species of octocorals for the Hannibal Bank, including the discovery and description of three new species”, said Hector M. Guzman, marine ecologist at STRI and one of the authors of the study.

Light-dependent coral and algae, as well as other life-forms found in low-light environments, live on mesophotic reefs: meso means middle and photic means light. These reefs, such as the one where T. dalioi was found, are considered fragile habitats with a high diversity of corals, algae and sponges. They are also generally neglected in most environmental and conservation policies because they are difficult to reach. Hannibal Bank is one of the spots requiring more attention for its protection. “The present study should provide the basis for further research on the genus and contributes to the diversity and distribution knowledge of octocorals from the mesophotic zone in the eastern Pacific Ocean”, said Odalisca Breedy, marine biologist at CIMAR and one of the authors of the study.

“Medical researchers have identified therapeutic benefits derived from both soft and hard corals such as anti-inflammatory and anti-cancer properties, bone repair and neurological benefits”, said Guzman. “But our ability to contribute to the understanding of soft corals and their habitats, depends not only on steady funding for the use of submersibles, but also on our continued ability to obtain permission to work in Coiba National Park.”