科学家成功诱使扁形虫长出其它物种的头部

Biologists at Tufts University have succeeded in inducing one species of flatworm to grow heads and brains characteristic of another species of flatworm without altering genomic sequence. The work reveals physiological ¹ circuits as a new kind of epigenetics - information existing outside of genomic sequence - that determines large-scale anatomy ². The finding that head shape is not hard-wired by the genome but can be overridden ³ by manipulating electrical synapses ⁴ in the body suggests that differences in species could be determined ⁵ in part by the activity of bioelectrical networks. The discovery could help improve understanding of birth defects and regeneration by revealing a new pathway for controlling complex pattern formation. It has long been known that neural ⁶ networks exploit bioelectric synapses to store and re-write information in the brain. , ,The findings are detailed ⁷ in the cover story of the November 2015 edition of the International Journal of Molecular ⁸ Sciences, appearing online Nov. 24., ,"It is commonly thought that the sequence and structure of chromatin - material that makes up chromosomes ⁹ - determine the shape of an organism, but these results show that the function of physiological networks can override ¹⁰ the species-specific default anatomy," says the paper's senior and corresponding author Michael Levin, Ph.D., who holds the Vannevar Bush Chair in biology and directs the Center for Regenerative and Developmental Biology in the School of Arts and Sciences at Tufts. "By modulating ¹¹ the connectivity of cells via electrical synapses, we were able to derive ¹² head morphology and brain patterning belonging to a completely different species from an animal with a normal genome.", ,Knowing how shape is determined and how to influence it is important because biologists could use that knowledge, for example, to fix birth defects or cause new biological structures to grow after an injury, adds Levin. "These findings raise significant questions about how genes ¹³ and bioelectric networks interact to build complex body structures," he says.