Lactate shuttles in nature

Once thought to be the consequence of oxygen lack in contracting skeletal muscle, the glycolytic product lactate is formed and utilized continuously under fully aerobic conditions. "Cell-cell" and "intracellular lactate shuttle" concepts describe the roles of lactate in the delivery of oxidative and gluconeogenic substrates, as well as in cell signalling. Examples of cell-cell shuttles include lactate exchanges between white-glycolytic and red-oxidative fibres within a working muscle bed, between working skeletal muscle and heart, and between tissues of net lactate release and gluconeogenesis. Lactate exchange between astrocytes and neurons that is linked to glutamatergic signalling in the brain is an example of a lactate shuttle supporting cell-cell signalling. Lactate uptake by mitochondria and pyruvate-lactate exchange in peroxisomes are examples of intracellular lactate shuttles. Lactate exchange between sites of production and removal is facilitated by monocarboxylate transport proteins, of which there are several isoforms, and, probably, also by scaffolding proteins. The mitochondrial lactate-pyruvate transporter appears to work in conjunction with mitochondrial lactate dehydrogenase, which permits lactate to be oxidized within actively respiring cells. Hence mitochondria function to establish the concentration and proton gradients necessary for cells with high mitochondrial densities (e.g. cardiocytes) to take up and oxidize lactate. Arteriovenous difference measurements on working cardiac and skeletal muscle beds as well as NMR spectral analyses of these tissues show that lactate is formed and oxidized within the cells of formation in vivo. Glycolysis and lactate oxidation within cells permits high flux rates and the maintenance of redox balance in the cytosol and mitochondria. Other examples of intracellular lactate shuttles include lactate uptake and oxidation in sperm mitochondria and the facilitation of beta-oxidation in peroxisomes by pyruvate-lactate exchange. An ancient origin to the utility of lactate shuttling is implied by the observation that mitochondria of Saccharomyces cerevisiae contain flavocytochrome b(2), a lactate-cytochrome c oxidoreductase that couples lactate dehydrogenation to the reduction of cytochrome c. The presence of cell-cell and intracellular lactate shuttles gives rise to the notion that glycolytic and oxidative pathways can be viewed as linked, as opposed to alternative, processes, because lactate, the product of one pathway, is the substrate for the other.     

Phosphorylated HuR shuttles in cycles

HuR is a ubiquitous RNA-binding protein (RBP) that associates with many mRNAs encoding proliferative proteins. Although predominantly nuclear, HuR translocation to the cytoplasm is linked to its ability to stabilize target mRNAs and modulate their translation. We recently reported that HuR phosphorylation by Cdk1 at S202 (within the HuR hinge region that is necessary for nucleocytoplasmic shuttle) increases HuR association with 14-3-3 and contributes to its nuclear retention. In this issue of Cell Cycle we report that residue S242 also regulates HuRÃ?¢Ã?€Ã?Â?s cytoplasmic localization, influences cyclin expression, and modulates cell proliferation. Together with evidence of other post-translational HuR modifications, we propose that HuR phosphorylation ensures the timely mobilization of HuR across the nuclear envelope. In turn, HuR helps to schedule gene expression programs in a cell cycle-dependent manner.     

Microfluidics in biotechnology

Microfluidics enables biotechnological processes to proceed on a scale (microns) at which physical processes such as osmotic movement, electrophoretic-motility and surface interactions become enhanced. At the microscale sample volumes and assay times are reduced, and procedural costs are lowered. The versatility of microfluidic devices allows interfacing with current methods and technologies. Microfluidics has been applied to DNA analysis methods and shown to accelerate DNA microarray assay hybridisation times. The linking of microfluidics to protein analysis techologies, e.g. mass spectrometry, enables picomole amounts of peptide to be analysed within a controlled micro-environment. The flexibility of microfluidics will facilitate its exploitation in assay development across multiple biotechnological disciplines.     

Perfluorochemicals in biotechnology

Gas transport often is a limiting factor in biotechnology. Perfluorochemicals provide a new vehicle for the transport of gases.     

Mosses in biotechnology

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Hydrogen shuttles in air versus water breathing fishes.

1. The malate-aspartate cycle was demonstrable in subcellular preparations of hearts from Arapaima, Lepidosiren, and Synbranchus (obligate air breathers), Hoplerythriunus (facultative air breather), and Osteoglossum and Hoplias (obligate water breathers). 2. Although no respiratory evidence for significant alpha-glycerophosphate cycle participation could be shown in the air breathers, this cycle was demonstrable in hearts of water breathers. 3. In agreement with the O2 uptake studies, it was possible to reconstruct the malate-aspartate, but not the alpha-glycerophosphate cycle, in isolated mitochondria from air breathers, while both shuttles could be reconstructed with heart mitochondria in the case of water breathing fishes.     

Chemical biotechnology pharmaceutical biotechnology. Web alert

A selection of World Wide Web sites relevant to papers published in this issue of Current Opinion in Biotechnology.     

Magnetic separations in biotechnology

Magnetic separation techniques provide probably the most rapid and convenient method of separating certain particles from dilute suspensions, especially those that might block columns or filters. This and other applications of magnetism, including cell sorting and product recovery are discussed.