Micro-connectomics: probing the organization of neuronal networks at the cellular scale.

Defining the organizational principles of neuronal networks at the cellular scale, or micro-connectomics, is a key challenge of modern neuroscience. In this Review, we focus on graph theoretical parameters of micro-connectome topology, often informed by economical principles that conceptually originated with Ramón y Cajal's conservation laws. First, we summarize results from studies in intact small organisms and in samples from larger nervous systems. We then evaluate the evidence for an economical trade-off between biological cost and functional value in the organization of neuronal networks. Various results suggest that many aspects of neuronal network organization are indeed the outcome of competition between these two fundamental selection pressures.This work was supported by the National Institute of Health Research (NIHR) Cambridge Biomedical Research Centre.This is the author accepted manuscript. It is currently under an indefinite embargo pending publication by the Nature Publishing Group

Direct repeats in the 3' untranslated regions of mosquito-borne flaviviruses: possible implications for virus transmission

Direct repeats (DRs) of 20–45 nucleotide conserved sequences (CS) and repeated CS (RCS), separated by non-conserved sequences up to 100 nucleotides long, were previously described in the 3' untranslated region (3'UTR) of the three major mosquito-borne flavivirus (MBFV) subgroups, represented by Japanese encephalitis virus, Yellow fever virus and Dengue virus. Each subgroup exhibits a specific pattern of DRs, the biological significance of which has not yet been adequately addressed. The DRs were originally identified using conventional alignment programs based on the assumption that genetic variation is driven primarily by nucleotide substitutions. Since there are no recognized alignment programs that can adequately accommodate very divergent sequences, a method has been devised to construct and analyse a substantially improved 3'UTR alignment between these highly divergent viruses, based on the concept that deletions and/or insertions, in addition to substitutions, are important drivers of 3'UTR evolution. This ‘robust alignment’ approach demonstrated more extensive homologies in the 3'UTR than had been recognized previously and revealed the presence of similar DRs, either intact or as sequence ‘remnants’, in all the MBFV subgroups. The relevance of these observations is discussed in relation to (i) the function of DRs as elements of replication enhancement, (ii) the evolution of RNA secondary structures and (iii) the significance of DRs and secondary structures in MBFV transmissibility between vertebrate and invertebrate hosts