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Cognitive decline is a feared aspect of growing old. It is a major contributor to lower quality of life and loss of independence in old age. We investigated the genetic contribution to individual differences in nonpathological cognitive ageing in five cohorts of older adults. We undertook a genome-wide association analysis using 549 692 single-nucleotide polymorphisms (SNPs) in 3511 unrelated adults in the Cognitive Ageing Genetics in England and Scotland (CAGES) project. These individuals have detailed longitudinal cognitive data from which phenotypes measuring each individual’s cognitive changes were constructed. One SNP—rs2075650, located in TOMM40 ( translocase of the outer mitochondrial membrane 40 homolog )—had a genome-wide significant association with cognitive ageing ( P =2.5 × 10 −8 ). This result was replicated in a meta-analysis of three independent Swedish cohorts ( P =2.41 × 10 −6 ). An Apolipoprotein E ( APOE ) haplotype (adjacent to TOMM40 ), previously associated with cognitive ageing, had a significant effect on cognitive ageing in the CAGES sample ( P =2.18 × 10 −8 ; females, P =1.66 × 10 −11 ; males, P =0.01). Fine SNP mapping of the TOMM40/APOE region identified both APOE (rs429358; P =3.66 × 10 −11 ) and TOMM40 (rs11556505; P =2.45 × 10 −8 ) as loci that were associated with cognitive ageing. Imputation and conditional analyses in the discovery and replication cohorts strongly suggest that this effect is due to APOE (rs429358). Functional genomic analysis indicated that SNPs in the TOMM40/APOE region have a functional, regulatory non-protein-coding effect. The APOE region is significantly associated with nonpathological cognitive ageing. The identity and mechanism of one or multiple causal variants remain unclear.

Liver cirrhosis is a major cause of death worldwide and is characterized by extensive fibrosis. There are currently no effective antifibrotic therapies available. To obtain a better understanding of the cellular and molecular mechanisms involved in disease pathogenesis and enable the discovery of therapeutic targets, here we profile the transcriptomes of more than 100,000 single human cells, yielding molecular definitions for non-parenchymal cell types that are found in healthy and cirrhotic human liver. We identify a scar-associated TREM2 + CD9 + subpopulation of macrophages, which expands in liver fibrosis, differentiates from circulating monocytes and is pro-fibrogenic. We also define ACKR1 + and PLVAP + endothelial cells that expand in cirrhosis, are topographically restricted to the fibrotic niche and enhance the transmigration of leucocytes. Multi-lineage modelling of ligand and receptor interactions between the scar-associated macrophages, endothelial cells and PDGFRα + collagen-producing mesenchymal cells reveals intra-scar activity of several pro-fibrogenic pathways including TNFRSF12A, PDGFR and NOTCH signalling. Our work dissects unanticipated aspects of the cellular and molecular basis of human organ fibrosis at a single-cell level, and provides a conceptual framework for the discovery of rational therapeutic targets in liver cirrhosis. Single-cell RNA sequencing is used to characterize and compare the functional diversity of cells from liver biopsies of human scarred and normal liver, and identifies markers for scar-associated macrophages and endothelial cells.

ELIXIR-UK is the UK node of ELIXIR, the European infrastructure for life science data. Since its foundation in 2014, ELIXIR-UK has played a leading role in training both within the UK and in the ELIXIR Training Platform, which coordinates and delivers training across all ELIXIR members. ELIXIR-UK contributes to the Training Platform’s coordination and supports the development of training to address key skill gaps amongst UK scientists. As part of this work it acts as a conduit for nationally-important bioinformatics training resources to promote their activities to the ELIXIR community. ELIXIR-UK also leads ELIXIR’s flagship Training Portal, TeSS, which collects information about a diverse range of training and makes it easily accessible to the community. ELIXIR-UK also works with others to provide key digital skills training, partnering with the Software Sustainability Institute to provide Software Carpentry training to the ELIXIR community and to establish the Data Carpentry initiative, and taking a lead role amongst national stakeholders to deliver the StaTS project – a coordinated effort to drive engagement with training in statistics.

We present a draft genome sequence of the platypus, Ornithorhynchus anatinus. This monotreme exhibits a fascinating combination of reptilian and mammalian characters. For example, platypuses have a coat of fur adapted to an aquatic lifestyle; platypus females lactate, yet lay eggs; and males are equipped with venom similar to that of reptiles. Analysis of the first monotreme genome aligned these features with genetic innovations. We find that reptile and platypus venom proteins have been co- opted independently from the same gene families; milk protein genes are conserved despite platypuses laying eggs; and immune gene family expansions are directly related to platypus biology. Expansions of protein, non- protein- coding RNA and microRNA families, as well as repeat elements, are identified. Sequencing of this genome now provides a valuable resource for deep mammalian comparative analyses, as well as for monotreme biology and conservation.

We present here a draft genome sequence of the red jungle fowl, Gallus gallus. Because the chicken is a modern descendant of the dinosaurs and the first non-mammalian amniote to have its genome sequenced, the draft sequence of its genome—composed of approximately one billion base pairs of sequence and an estimated 20,000–23,000 genes—provides a new perspective on vertebrate genome evolution, while also improving the annotation of mammalian genomes. For example, the evolutionary distance between chicken and human provides high specificity in detecting functional elements, both non-coding and coding. Notably, many conserved non-coding sequences are far from genes and cannot be assigned to defined functional classes. In coding regions the evolutionary dynamics of protein domains and orthologous groups illustrate processes that distinguish the lineages leading to birds and mammals. The distinctive properties of avian microchromosomes, together with the inferred patterns of conserved synteny, provide additional insights into vertebrate chromosome architecture.

Plasma membrane calcium ATPases (PMCAs) are believed to function exclusively at the plasma membrane where they expel calcium from the cytosol. We have unexpectedly identified a splice variant-dependent localisation of the PMCA isoform PMCA2 to the lysosome, where it forms an evolutionarily conserved complex with NPC1, the lysosomal membrane protein defective in the rare lysosomal storage disease Niemann-Pick disease type C (NPC). This interaction is required for lysosomal Ca2+ homeostasis and implicates PMCA2 as a mediator of Ca2+ uptake into lysosomes. Disruption of the NPC1-PMCA2 complex contributes to the pathophysiology of both Niemann-Pick disease type C and Parkinson's disease, revealing an unrecognised intracellular function for PMCA2 and a shared mechanism linking lysosomal Ca2+ and lipid regulation in neurodegeneration.Competing Interest StatementThe authors have declared no competing interest.Footnotes* Fig. 2 was modified to add three subfigures. One subfigure in Fig. 2 was moved to Supplementary Fig. 3. Fig. 4 and 5 were fused into a new Fig. 4. Previous Fig. 6 is now labelled as Fig.5. The text was modified to reflect these changes. The main conclusions of the study haven't changed.Funder Information DeclaredAligning Science Across Parkinson's, https://ror.org/03zj4c476, ASAP-000478Royal Society, https://ror.org/03wnrjx87, NF171121

During thymic negative selection, medullary thymic epithelial cells (mTEC) collectively express most protein coding genes, a process termed promiscuous gene expression (PGE). Although PGE is crucial for inducing central T-cell tolerance, this process has not been established definitively as being either stochastic or coordinated. To resolve this question, we sequenced the transcriptomes of 6,894 single mTEC, including 1,795 rare cells expressing either of two tissue-restricted antigens, TSPAN8 or GP2. Transcriptional heterogeneity allowed partitioning of mTEC into 15 robustly-defined subpopulations representing distinct maturational stages and subtypes. Although 50 gene co-expression groups were robustly identified, few could be explained by chromosomal location, biological pathway, or tissue specificity. Further, GP2+ mTEC were randomly dispersed spatially within medullary islands. Thus although PGE exhibits ordered co-expression, biologically it is indeterminate. This likely enhances the presentation of diverse antigens to passing thymocytes during their medullary residency, while simultaneously maintaining mTEC identity throughout PGE.