
It may be the closest scientists have yet come to creating Frankenstein鈥檚 monster. Living pieces of dozens of individual animals known as comb jellies have been fused together to create an array of new forms that, in some cases, survived for more than a week.
These chimeric animals are more than just physically connected bits of different individuals, says at the University of Florida. Their nervous systems also fuse together, creating entities that heand his colleague Tigran Norekian, also at the University of Florida, call 鈥渘eurobots鈥. 鈥淲e were able to directly prove that the neural system fused,鈥 he says.
This kind of experiment offers 鈥渦nprecedented鈥 opportunities for synthetic biology, says Moroz. The researchers鈥 ultimate aim is to improve our understanding of biology to the point where we will be able to grow tissues and organs聽for treating various diseases.
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鈥淚f you are a good engineer, you can eventually make a bridge or airplane,鈥 says Moroz. 鈥淚n biology and medicine, we鈥檙e far, far away. Biology is much more complicated.鈥
His work was inspired by a recent study by who is now at the National Institute for Basic Biology in Japan, and his colleagues. When Jokura was studying a species of comb jelly, or ctenophore, called Mnemiopsis leidyi, he noticed a strange animal that seemed to consist of two fused individuals.
Further experiments showed that when pairs of injured individuals were put together, they fused with each other 9 times out of 10.
Moroz and Tigran Norekian, also at the University of Florida, have now gone much further, fusing various different parts of individual ctenophores together. For instance, they took the part of a comb jelly that contains its primitive brain from one individual and used it to replace that part on another individual 鈥 the ctenophore equivalent of a head transplant. 鈥淰irtually all possible combinations were able to produce [moving] animals,鈥 says Moroz.
By using a stain that binds to a component in neurons, the pair confirmed that nerve cells grew connections across the fusion scar and connected the neural networks of different individuals.
The researchers have also combined parts from more than two individuals.聽Moroz says they have now fused 鈥渕any dozen鈥 into single entities.
Moroz and Norekian have also shown that this fusion works in at least two other species of ctenophores, Bolinopsis microptera and Pleurobrachia bachei. They are now testing whether a part of one species can be fused with a part from another species. 鈥淲hen you called, I was doing this experiment,鈥 says Moroz, who wouldn鈥檛 give anything anyway about the results so far.
Parts of other kinds of animals can鈥檛 usually be fused together because their immune system will attack 鈥渘on-self鈥 cells 鈥 this is why organ transplants usually require immune suppression. But ctenophores branched off from other animals very early on, and it appears their immune systems never evolved the ability to distinguish self from non-self.
鈥淚鈥檓 thrilled to hear that our work has inspired further research,鈥 says Jokura. 鈥淚鈥檓 particularly excited to learn about Leonid Moroz鈥檚 efforts to push the boundaries of this phenomenon by exploring cross-species fusion and the potential for fusing multiple individuals.鈥
A lot of biological research is subtractive, says Jokura:聽genes are disabled or removed to see what happens. With this kind of fusion, it is possible to do 鈥渁dditive鈥 research, he says, to see how things work when put together.
鈥淔usion experiments could provide an entirely new lens through which to study physiological phenomena and may indeed lead to innovative approaches in synthetic biology,鈥 says Jokura.
bioRxiv