Elizabeth A Ferrer

Bio: Elizabeth A Ferrer is an academic researcher from University of California, Berkeley. The author has contributed to research in topics: Medicine & Biology. The author has an hindex of 1, co-authored 1 publications receiving 2528 citations.

Has the Earth’s sixth mass extinction already arrived?

Abstract: Palaeontologists characterize mass extinctions as times when the Earth loses more than three-quarters of its species in a geologically short interval, as has happened only five times in the past 540 million years or so. Biologists now suggest that a sixth mass extinction may be under way, given the known species losses over the past few centuries and millennia. Here we review how differences between fossil and modern data and the addition of recently available palaeontological information influence our understanding of the current extinction crisis. Our results confirm that current extinction rates are higher than would be expected from the fossil record, highlighting the need for effective conservation measures.

PI4K2A deficiency causes innate error in intracellular trafficking with developmental and epileptic‐dyskinetic encephalopathy

Abstract: Intracellular signaling networks rely on proper membrane organization to control an array of cellular processes such as metabolism, proliferation, apoptosis, and macroautophagy in eukaryotic cells and organisms. Phosphatidylinositol 4‐phosphate (PI4P) emerged as an essential regulatory lipid within organelle membranes that defines their lipid composition and signaling properties. PI4P is generated by four distinct phosphatidylinositol 4‐kinases (PI4K) in mammalian cells: PI4KA, PI4KB, PI4K2A, PI4K2B. Animal models and human genetic studies suggest vital roles of PI4K enzymes in development and function of various organs, including the nervous system. Bi‐allelic variants in PI4KA were recently associated with neurodevelopmental disorders (NDD), brain malformations, leukodystrophy, primary immunodeficiency, and inflammatory bowel disease. Here, we describe patients from two unrelated consanguineous families with PI4K2A deficiency and functionally explored the pathogenic mechanism.

Acute Manipulation of Outer Membrane Phospholipid Composition Directly Alters Mitochondrial Dynamics and Ultrastructure

Abstract: Mitochondria undergo coordinated rounds of fusion and fission that are critical for maintaining the functional integrity of this essential organelle. While a growing number of proteins have been identified as important regulators of mitochondrial dynamics, the direct role of membrane lipid composition during the fusion and fission processes is poorly understood. To address these shortcomings, we devised a protein‐engineering platform that allows for the acute remodeling of structural phospholipids within the outer mitochondrial membrane (OMM) of intact cells. Specifically, we modified a bacterial phospholipase C (Bacillus cereus (Bc)PI‐PLC) to initiate the rapid hydrolysis of phosphatidylinositol (PI) and locally generate diacylglycerol (DAG); an important intracellular signaling molecule and metabolic precursor that is used in diverse lipid biosynthetic pathways. Spatial restriction of enzyme activity was achieved using a chemically inducible system consisting of a rapamycin‐dependent dimerization module (FKBP‐BcPI‐PLC) along with an OMM targeting sequence tagged with the FKBP‐rapamycin binding domain (OMM‐FRB). Using these unique molecular tools, we show that recruitment of FKBP‐BcPI‐PLC to the OMM not only causes the expected local accumulation of DAG, but also initiates the rapid and uniform fragmentation of the mitochondrial network. Mitochondrial fission induced by FKBP‐BcPI‐PLC is accompanied by profound swelling of the mitochondrial matrix along with vesiculation of the inner mitochondrial membrane (IMM) and a general loss of cristae, which all occur within minutes of tethering FKBP‐BcPI‐PLC to the OMM. Expression of dominant‐negative constructs targeting essential GTPases known to regulate OMM fission suggest that both dynamin‐related protein 1 (Drp1) and dynamin 2 (Dnm2) work together to drive efficient BcPI‐PLC‐induced mitochondrial division. However, results using a validated Drp1 knockout cell line show that the loss of Drp1 alone is sufficient to prevent the mitochondrial fragmentation initiated by FKBP‐BcPI‐PLC recruitment, indicating that Drp1 likely functions upstream or independent of Dnm2 in this context. Interestingly, unlike the induced OMM fission, removal of Drp1 from cells does not prevent the matrix swelling or OMM constrictions observed in response to acute generation of DAG within the OMM. Ongoing experiments are now focused on characterizing new methods to sequentially metabolize the DAG generated within the OMM as well as investigate how local lipid composition influences the binding and oligomerization of membrane‐shaping proteins that may function in concert with Drp1 to regulate mitochondrial remodeling. Overall, these studies establish a direct relationship between lipid metabolism within the OMM and clinically relevant morphological changes that are known to manifest in mitochondrial‐associated diseases.

Planetary boundaries: Guiding human development on a changing planet

Abstract: The planetary boundaries framework defines a safe operating space for humanity based on the intrinsic biophysical processes that regulate the stability of the Earth system. Here, we revise and update the planetary boundary framework, with a focus on the underpinning biophysical science, based on targeted input from expert research communities and on more general scientific advances over the past 5 years. Several of the boundaries now have a two-tier approach, reflecting the importance of cross-scale interactions and the regional-level heterogeneity of the processes that underpin the boundaries. Two core boundaries—climate change and biosphere integrity—have been identified, each of which has the potential on its own to drive the Earth system into a new state should they be substantially and persistently transgressed.

Impacts of climate change on the future of biodiversity.

Abstract: Many studies in recent years have investigated the effects of climate change on the future of biodiversity. In this review, we first examine the different possible effects of climate change that can operate at individual, population, species, community, ecosystem and biome scales, notably showing that species can respond to climate change challenges by shifting their climatic niche along three non-exclusive axes: time (e.g. phenology), space (e.g. range) and self (e.g. physiology). Then, we present the principal specificities and caveats of the most common approaches used to estimate future biodiversity at global and sub-continental scales and we synthesise their results. Finally, we highlight several challenges for future research both in theoretical and applied realms. Overall, our review shows that current estimates are very variable, depending on the method, taxonomic group, biodiversity loss metrics, spatial scales and time periods considered. Yet, the majority of models indicate alarming consequences for biodiversity, with the worst-case scenarios leading to extinction rates that would qualify as the sixth mass extinction in the history of the earth.

Defaunation in the Anthropocene

Abstract: We live amid a global wave of anthropogenically driven biodiversity loss: species and population extirpations and, critically, declines in local species abundance. Particularly, human impacts on animal biodiversity are an under-recognized form of global environmental change. Among terrestrial vertebrates, 322 species have become extinct since 1500, and populations of the remaining species show 25% average decline in abundance. Invertebrate patterns are equally dire: 67% of monitored populations show 45% mean abundance decline. Such animal declines will cascade onto ecosystem functioning and human well-being. Much remains unknown about this “Anthropocene defaunation”; these knowledge gaps hinder our capacity to predict and limit defaunation impacts. Clearly, however, defaunation is both a pervasive component of the planet’s sixth mass extinction and also a major driver of global ecological change.

Accelerated modern human-induced species losses: Entering the sixth mass extinction

Abstract: The oft-repeated claim that Earth’s biota is entering a sixth “mass extinction” depends on clearly demonstrating that current extinction rates are far above the “background” rates prevailing between the five previous mass extinctions. Earlier estimates of extinction rates have been criticized for using assumptions that might overestimate the severity of the extinction crisis. We assess, using extremely conservative assumptions, whether human activities are causing a mass extinction. First, we use a recent estimate of a background rate of 2 mammal extinctions per 10,000 species per 100 years (that is, 2 E/MSY), which is twice as high as widely used previous estimates. We then compare this rate with the current rate of mammal and vertebrate extinctions. The latter is conservatively low because listing a species as extinct requires meeting stringent criteria. Even under our assumptions, which would tend to minimize evidence of an incipient mass extinction, the average rate of vertebrate species loss over the last century is up to 100 times higher than the background rate. Under the 2 E/MSY background rate, the number of species that have gone extinct in the last century would have taken, depending on the vertebrate taxon, between 800 and 10,000 years to disappear. These estimates reveal an exceptionally rapid loss of biodiversity over the last few centuries, indicating that a sixth mass extinction is already under way. Averting a dramatic decay of biodiversity and the subsequent loss of ecosystem services is still possible through intensified conservation efforts, but that window of opportunity is rapidly closing.