Single-molecule fluorescence reveals sequence-specific misfolding in multidomain proteins

A large range of debilitating medical conditions is linked to protein misfolding, which may compete with productive folding particularly in proteins containing multiple domains. Seventy-five per cent of the eukaryotic proteome consists of multidomain proteins, yet it is not understood how interdomain misfolding is avoided. It has been proposed that maintaining low sequence identity between covalently linked domains is a mechanism to avoid misfolding. Here we use single-molecule F?rster resonance energy transfer to detect and quantify rare misfolding events in tandem immunoglobulin domains from the I band of titin under native conditions. About 5.5 per cent of molecules with identical domains misfold during refolding in vitro and form an unexpectedly stable state with an unfolding half-time of several days. Tandem arrays of immunoglobulin-like domains in humans show significantly lower sequence identity between neighbouring domains than between non-adjacent domains. In particular, the sequence identity of neighbouring domains has been found to be preferentially below 40 per cent. We observe no misfolding for a tandem of naturally neighbouring domains with low sequence identity (24 per cent), whereas misfolding occurs between domains that are 42 per cent identical. Coarse-grained molecular simulations predict the formation of domain-swapped structures that are in excellent agreement with the observed transfer efficiency of the misfolded species. We infer that the interactions underlying misfolding are very specific and result in a sequence-specific domain-swapping mechanism. Diversifying the sequence between neighbouring domains seems to be a successful evolutionary strategy to avoid misfolding in multidomain proteins.     

Selective dendritic transport of RNA in hippocampal neurons in culture

Typical neurons of the central nervous system (CNS) elaborate tens of thousands of membrane specializations at sites of synaptic contacts on their dendrites. To construct, maintain, and modify these specializations, neurons must produce and deliver the appropriate molecular constituents to particular synaptic sites. Previous studies have revealed that polyribosomes are selectively positioned beneath postsynaptic sites, suggesting that in neurons, as in other cell types, protein synthetic machinery is located at or near the sites where particular proteins are needed. The mechanisms that deliver ribosomes and messenger RNA to their specific destinations in cells are therefore of considerable interest. Here we describe a system for RNA transport in dendrites that could provide a mechanism for the delivery of ribosomes and mRNA to synaptic sites in dendrites. Hippocampal neurons grown in culture incorporate 3H-uridine in the nucleus, then selectively transport the newly synthesized RNA into dendrites at a rate of about 0.5 mm day-1. The transport is inhibited by metabolic poisons, suggesting that it is an active, energy-dependent process. The RNA may be transported in association with the cytoskeleton.     

Unicellular cyanobacteria fix N2 in the subtropical North Pacific Ocean

Fixed nitrogen (N) often limits the growth of organisms in terrestrial and aquatic biomes, and N availability has been important in controlling the CO2 balance of modern and ancient oceans. The fixation of atmospheric dinitrogen gas (N2) to ammonia is catalysed by nitrogenase and provides a fixed N for N-limited environments. The filamentous cyanobacterium Trichodesmium has been assumed to be the predominant oceanic N2-fixing microorganism since the discovery of N2 fixation in Trichodesmium in 1961 (ref. 6). Attention has recently focused on oceanic N2 fixation because nitrogen availability is generally limiting in many oceans, and attempts to constrain the global atmosphere-ocean fluxes of CO2 are based on basin-scale N balances. Biogeochemical studies and models have suggested that total N2-fixation rates may be substantially greater than previously believed but cannot be reconciled with observed Trichodesmium abundances. It is curious that there are so few known N2-fixing microorganisms in oligotrophic oceans when it is clearly ecologically advantageous. Here we show that there are unicellular cyanobacteria in the open ocean that are expressing nitrogenase, and are abundant enough to potentially have a significant role in N dynamics.