The cause of the characteristic variability in atmospheric CO₂ over glacial-interglacial timescales has been under debate since its discovery in the 1980s. Initially based on the study of Antarctica ice cores, an intriguing parallelism was found between atmospheric CO₂ and global temperature, with high CO₂ levels during warm interglacial periods, and low CO₂ concentrations during cold glacial times. Even though the oceans have often been put forward as the main responsible for this parallelism, their role in sequestering and releasing CO₂ and the mechanisms behind this still remains an open question. In this study, we analyzed the evolution of the ventilation of the Eastern Equatorial Pacific waters over the past 25,000 years aiming at detecting the existence of old water masses which could explain a possible CO₂ sequestration in the deep ocean. To this end, we analyzed the radiocarbon (¹⁴C) preserved in the shells of benthic and planktonic foraminifera fossils accumulated in a deep sea sediment core retrieved in this area. These data demonstrated the existence of a mass of deep water that, during glacial times, was about 1,300 years older than the same water mass today. With the start of the deglaciation, the radiocarbon signal indicated a reactivation of the ocean circulation, coinciding with the increase in atmospheric CO₂ documented in ice cores. Altogether, these results support the hypothesis that the deep oceans, particularly the Pacific Ocean, stored vast amounts of CO₂ during the last glacial period, which was released during the deglaciation. These results lend support to the important role of the deep ocean and ocean ventilation in regulating the atmospheric concentration of CO₂ at glacial/interglacial timescales. Over the last decade, the oceans have been absorbing approximately 26% of the anthropogenic emissions of CO₂. The oceans have been a key element in controlling atmospheric CO₂ levels in the past and at present, and they will certainly also play a very significant role in the future, a role that will be constrained more accurately with data from paleoreconstructions such as this one.

A new study published in the Proceedings of the National Academy of Sciences of the United States of America by scientists from CONICET Bariloche, Institut Pasteur both at Paris and Dakar, IRD-Dakar and the Institut Català de Ciències del Clima (IC3) at Barcelona, shows unequivocally how the incidence of clinical malaria is both influenced by climatic factors and immunity. Disentangling the relative contributions of these factors is a major challenge. The study benefits from a unique long-term follow-up of 2 adjacent populations spanning two decades in Senegal, that have very different levels of malaria endemicity. By using  recently developed mathematical modelling techniques and extremely detailed records from both malaria incidence, parasite inoculation variability within hosts by mosquito population, and local climate data, the study was able to demonstrate how the influence of immunity and climatic factors varies according to the force of infection. A common modelling framework elucidates important information on how immunity influences transmission of the parasite from men to mosquitoes. Notably, the models show how individuals, who are infected without symptoms or infected with parasites at an undetectable level by classical diagnostic methods, contribute significantly to the infectious population. Undetectable but infectious individuals are likely to present a problem for elimination of the parasite reservoir in humans, which is the final step towards elimination of the malaria in a population.