Insights into the evolutionary history of the most skilled tool-handling platyrrhini monkey: Sapajus libidinosus from the Serra da Capivara National Park.

Sapajus libidinosus members of the Pedra Furada group, living in the Serra da Capivara National Park, use stone tools in a wider variety of behaviors than any other living animal, except humans. To rescue the evolutionary history of the Caatinga S. libidinosus and identify factors that may have contributed to the emergence and maintenance of their tool-use culture, we conducted fieldwork seasons to obtain biological samples of these capuchin monkeys. UsingCYTBsequences, we show a discrete but constant population growth from the beginning of the Holocene to the present, overlapping the emergence of the Caatinga biome. Our habitat suitability reconstruction reports the presence of plants whose hard fruits, seeds, or roots are processed by capuchins using tools. TheS. libidinosusindividuals in the Caatinga were capable of dynamically developing and maintaining their autochthonous culture thanks to: a) cognitive capacity to generate and execute innovation under selective pressure; b) tolerance favoring learning and cultural inheritance; c) an unknown genetic repertoire that underpins the adaptive traits; d) a high degree of terrestriality; e) presence and abundance of natural resources, which makes some places "hot spots" for innovation, and cultural diversification within a relatively short time.

Enzymes of glycerol-3-phosphate pathway in triacylglycerol synthesis in plants: Function, biotechnological application and evolution.

Triacylglycerols (TAG) are the major form of energy storage in plants. TAG are primarily stored in seeds and fruits, but vegetative tissues also possess a high capacity for their synthesis and storage. These storage lipids are essential to plant development, being used in seedling growth during germination, pollen development, and sexual reproduction, for example. TAG are also an important source of edible oils for animal and human consumption, and are used for fuel and industrial feedstocks. The canonical pathway leading to TAG synthesis is the glycerol-3-phosphate, or Kennedy, pathway, which is an evolutionarily conserved process in most living organisms. The enzymatic machinery for synthesizing TAG is well known in several plant species, and the genes encoding these enzymes have been the focus of many studies. Here, we review recent progress on the understanding of evolutionary, functional and biotechnological aspects of the glycerol-3-phosphate pathway enzymes that produce TAG. We discuss current knowledge about their functional aspects, and summarize valuable insights into genetically engineered plants for enhancing TAG accumulation. Also, we highlight the evolutionary history of these genes and present a meta-analysis linking positive selection to gene family and plant diversification, and also to the domestication processes in oilseed crops.