Mechanochemical basis of protein degradation by a double-ring AAA+ machine

Molecular machines containing double or single AAA+ rings power energy-dependent protein degradation and other critical cellular processes, including disaggregation and remodeling of macromolecular complexes. How the mechanical activities of double-ring and single-ring AAA+ enzymes differ is unknown. Using single-molecule optical trapping, we determine how the double-ring ​ClpA enzyme from Escherichia coli, in complex with the ​ClpP peptidase, mechanically degrades proteins. We demonstrate that ​ClpA unfolds some protein substrates substantially faster than does the single-ring ​ClpX enzyme, which also degrades substrates in collaboration with ​ClpP. We find that ​ClpA is a slower polypeptide translocase and that it moves in physical steps that are smaller and more regular than steps taken by ​ClpX. These direct measurements of protein unfolding and translocation define the core mechanochemical behavior of a double-ring AAA+ machine and provide insight into the degradation of proteins that unfold via metastable intermediates.Howard Hughes Medical InstituteNational Institutes of Health (U.S.) (Grant AI-16892

The elegans of spindle assembly

The Caenorhabditis elegans one-cell embryo is a powerful system in which to study microtubule organization because this large cell assembles both meiotic and mitotic spindles within the same cytoplasm over the course of 1 h in a stereotypical manner. The fertilized oocyte assembles two consecutive acentrosomal meiotic spindles that function to reduce the replicated maternal diploid set of chromosomes to a single-copy haploid set. The resulting maternal DNA then unites with the paternal DNA to form a zygotic diploid complement, around which a centrosome-based mitotic spindle forms. The early C. elegans embryo is amenable to live-cell imaging and electron tomography, permitting a detailed structural comparison of the meiotic and mitotic modes of spindle assembly

Pan-cancer analysis of whole genomes

Cancer is driven by genetic change, and the advent of massively parallel sequencing has enabled systematic documentation of this variation at the whole-genome scale(1-3). Here we report the integrative analysis of 2,658 whole-cancer genomes and their matching normal tissues across 38 tumour types from the Pan-Cancer Analysis of Whole Genomes (PCAWG) Consortium of the International Cancer Genome Consortium (ICGC) and The Cancer Genome Atlas (TCGA). We describe the generation of the PCAWG resource, facilitated by international data sharing using compute clouds. On average, cancer genomes contained 4-5 driver mutations when combining coding and non-coding genomic elements; however, in around 5% of cases no drivers were identified, suggesting that cancer driver discovery is not yet complete. Chromothripsis, in which many clustered structural variants arise in a single catastrophic event, is frequently an early event in tumour evolution; in acral melanoma, for example, these events precede most somatic point mutations and affect several cancer-associated genes simultaneously. Cancers with abnormal telomere maintenance often originate from tissues with low replicative activity and show several mechanisms of preventing telomere attrition to critical levels. Common and rare germline variants affect patterns of somatic mutation, including point mutations, structural variants and somatic retrotransposition. A collection of papers from the PCAWG Consortium describes non-coding mutations that drive cancer beyond those in the TERT promoter(4); identifies new signatures of mutational processes that cause base substitutions, small insertions and deletions and structural variation(5,6); analyses timings and patterns of tumour evolution(7); describes the diverse transcriptional consequences of somatic mutation on splicing, expression levels, fusion genes and promoter activity(8,9); and evaluates a range of more-specialized features of cancer genomes(8,10-18).Peer reviewe

Examining Cell-Cell Interactions in the Kidney Using AFM Single-Cell Force Spectroscopy

The ability of individual cells to synchronize activity is a basic feature of efficient and appropriate tissue function. Central to this is the physicochemical binding between cells through multiprotein complexes that functionally mediate adhesion. Importantly, the direct connection of physical properties and intercellular signaling is of great importance to certain pathologies including diabetes. Atomic force microscopy (AFM) single-cell force spectroscopy (SCFS) is a high-resolution technique that provides a statistically reliable measurement of the minute forces involved in cell tethering and membrane dynamics. Detection of altered nanoscale forces underlying the loss of adhesion in early tubular injury is pivotal for the development of novel therapeutic strategies for diabetic nephropathy. Here we describe the step-by-step use of an integrated AFM-SCFS system designed to measure functional force-displacement in separating renal tubular epithelial cells. Parameters such as unbinding forces, detachment energy, and distance to complete separation can be obtained from force-displacement (F-d) curves and are critical in assessing how physical changes of cellular adhesion contribute to cell contact, coupling, and communication in the diabetic kidney

Bacterial chromatin organization by H-NS protein unravelled using dual DNA manipulation

Both prokaryotic and eukaryotic organisms contain DNA bridging proteins, which can have regulatory or architectural functions. The molecular and mechanical details of such proteins are hard to obtain, in particular if they involve non-specific interactions. The bacterial nucleoid consists of hundreds of DNA loops, shaped in part by non-specific DNA bridging proteins such as histone-like nucleoid structuring protein (H-NS), leucine-responsive regulatory protein (Lrp) and SMC (structural maintenance of chromosomes) proteins. We have developed an optical tweezers instrument that can independently handle two DNA molecules, which allows the systematic investigation of protein-mediated DNA-DNA interactions. Here we use this technique to investigate the abundant non-specific nucleoid-associated protein H-NS, and show that H-NS is dynamically organized between two DNA molecules in register with their helical pitch. Our optical tweezers also allow us to carry out dynamic force spectroscopy on non-specific DNA binding proteins and thereby to determine an energy landscape for the H-NS-DNA interaction. Our results explain how the bacterial nucleoid can be effectively compacted and organized, but be dynamic in nature and accessible to DNA-tracking motor enzymes. Finally, our experimental approach is widely applicable to other DNA bridging proteins, as well as to complex DNA interactions involving multiple DNA molecules. ©2006 Nature Publishing Group