G. di Prisco

Antarctic climate change and the environment

Abstract The Antarctic climate system varies on timescales from orbital, through millennial to sub-annual, and is closely coupled to other parts of the global climate system. We review these variations from the perspective of the geological and glaciological records and the recent historical period from which we have instrumental data (∼the last 50 years). We consider their consequences for the biosphere, and show how the latest numerical models project changes into the future, taking into account human actions in the form of the release of greenhouse gases and chlorofluorocarbons into the atmosphere. In doing so, we provide an essential Southern Hemisphere companion to the Arctic Climate Impact Assessment.

The impacts of climate change on circumpolar biodiversity

Some of the most rapidly changing ecosystems on our planet are located in the polar regions (IPCC 2007; Turner et al. 2009; SWIPA 2011). In some areas of the Arctic and Antarctic, atmospheric temperatures are rising at rates more than double the global average. In addition, there are other direct human impacts on polar regions such as pollution, exploitation and development. Polar ecosystems and the biodiversity they support are already responding to this change and it is expected that even more profound impacts will occur this century. Compounding the risk to polar biodiversity is the fact that many polar ecosystems have limited functional redundancy; in the event of the loss of a single keystone species, they may potentially be exposed to cascading effects and complete ecosystem restructuring (Post et al. 2009). Rapid climate change affecting the polar regions will also have profound physical and ecological consequences for the rest of the planet since the ice-covered Arctic Ocean, the Antarctic continent, and the globally significant Antarctic Circumpolar Current (ACC) serve a key role in regulating the Earths climate and ocean systems. This special issue is intended to provide an overview of circumpolar change that crosses disciplines, systems, taxonomic groups and regions, and integrates papers that address a range of topics including: the monitoring of freshwater, marine, and terrestrial organisms in both the northern and southern polar regions, the role of protected areas in monitoring change in a warming world, polar resource management and development, impacts on northern indigenous peoples, case studies of the biodiversity of selected polar organisms, impacts of sea ice loss on terrestrial and marine organisms and ecosystems, interconnections with lower latitudes, and the influence of historical processes that have impacted polar diversity. This keynote paper is intended to provide background and insight into the issue by comparing and contrasting the Arctic and Antarctic regions in terms of their physical environment, human influences, indications of climate change and impacts on their biodiversity.

Cross-disciplinarity in the advance of Antarctic ecosystem research

The biodiversity, ecosystem services and climate variability of the Antarctic continent and the Southern Ocean are major components of the whole Earth system. Antarctic ecosystems are driven more strongly by the physical environment than many other marine and terrestrial ecosystems. As a consequence, to understand ecological functioning, cross-disciplinary studies are especially important in Antarctic research. The conceptual study presented here is based on a workshop initiated by the Research Programme Antarctic Thresholds - Ecosystem Resilience and Adaptation of the Scientific Committee on Antarctic Research, which focussed on challenges in identifying and applying cross-disciplinary approaches in the Antarctic. Novel ideas and first steps in their implementation were clustered into eight themes. These ranged from scale problems, through risk maps, and organism/ecosystem responses to multiple environmental changes and evolutionary processes. Scaling models and data across different spatial and temporal scales were identified as an overarching challenge. Approaches to bridge gaps in Antarctic research programmes included multi-disciplinary monitoring, linking biomolecular findings and simulated physical environments, as well as integrative ecological modelling. The results of advanced cross-disciplinary approaches can contribute significantly to our knowledge of Antarctic and global ecosystem functioning, the consequences of climate change, and to global assessments that ultimately benefit humankind.

Hemoproteins in the cold.

This review highlights some aspects of the biochemistry of cold-adapted hemoproteins in fish and bacteria, without claiming to be exhaustive. Heme hexacoordination where the sixth ligand is provided by an internal amino-acid residue, in cold-adapted hemoproteins will be discussed.

BLOOD | Erythropoiesis in Fishes

This article summarizes the current knowledge of hematopoietic stem-cell development in fish and suggests new study areas. The interpretation of the complex transcriptional changes that occur during hematopoiesis poses many challenges because the relationship between the molecular mechanisms regulating lineage-specific differentiation and other levels of biological organization is poorly understood.

TRANSPORT AND EXCHANGE OF RESPIRATORY GASES IN THE BLOOD | Hemoglobin Differentiation in Fishes

Fish hemoglobins have been extensively studied, not only for their structural and functional properties, but also because they offer the possibility of investigating functional differentiation and molecular adaptations in marine and freshwater species living in a large variety of environmental conditions. The number of available amino-acid sequences of fish hemoglobins yields enough material to study evolutionary, structural, and functional aspects. Unlike most mammals, including humans, fish often exhibit hemoglobin multiplicity, due to gene-related heterogeneity and gene-duplication events. Here, we review and discuss some new insights about hemoglobin functional differentiation in fish. In this context, the contributions of structural biology extend well beyond the elucidation of mechanisms and hemoglobin-structure/function relationships.