Proton gradients and pH oscillations emerge from heat flow at the microscale.

Proton gradients are essential for biological systems. They not only drive the synthesis of ATP, but initiate molecule degradation and recycling inside lysosomes. However, the high mobility and permeability of protons through membranes make pH gradients very hard to sustain in vitro.

Steep pH Gradients and Directed Colloid Transport in a Microfluidic Alkaline Hydrothermal Pore.

All life on earth depends on the generation and exploitation of ionic and pH gradients across membranes. One theory for the origin of life proposes that geological pH gradients were the prebiotic ancestors of these cellular disequilibria. With an alkaline interior and acidic exterior, alkaline vents match the topology of modern cells, but it remains unknown whether the steep pH gradients persist at the microscopic scale.

Photochemical Microscale Electrophoresis Allows Fast Quantification of Biomolecule Binding.

Intricate spatiotemporal patterns emerge when chemical reactions couple to physical transport. We induce electrophoretic transport by a confined photochemical reaction and use it to infer the binding strength of a second, biomolecular binding reaction under physiological conditions. To this end, we use the photoactive compound 2-nitrobenzaldehyde, which releases a proton upon 375 nm irradiation.

Generation of the heterodimeric precursor GP3 of the Chlamydomonas cell wall.

The cell wall of the unicellular green alga Chlamydomonas reinhardtii exclusively consists of hydroxyproline-containing glycoproteins. Protein chemical analysis of its polypeptide constituents was hindered by their cross-linking via peroxidase-catalysed intermolecular isodityrosine formation and transaminase-dependent processes. To overcome this problem, we have identified putative soluble precursors using polyclonal antibodies raised against deglycosylation products of the highly purified insoluble wall fraction and analysed their amino acid sequence.

The beta-N-acetylhexosaminidase of Entamoeba histolytica is composed of two homologous chains and has been localized to cytoplasmic granules.

We have purified a beta-N-acetylhexosaminidase from trophozoites of Entamoeba histolytica to homogeneity. In SDS-PAGE, the enzyme yielded a single protein band at an apparent M(r) of 64,000. The elution behaviour of the native enzyme upon molecular sieve chromatography corresponded to a molecular mass of approximately 132,000 suggesting that the enzyme is a dimer.