Publication highlights

This work reveals that amino acids, rather than fructose 1,6-bisphosphate, are the relevant cellular regulators of pyruvate kinase M2 (PKM2), a critical node in cancer metabolism. It further elucidates the molecular mechanism of PKM2 regulation by amino acids with a new algorithm that predicts allosteric pathways in proteins, a major and difficult problem in structural biology.

Intestinal homeostasis requires a continuous dialogue between commensal bacteria and intestinal immune cells. Natural Killer T (NKT) cells are a population of CD1d-restricted lipid-reactive lymphocytes contributing to the regulation of mucosal immunity, but the mechanisms underlying this are poorly understood. Here we show that lipid presentation by CD1d+ intestinal dendritic cells and macrophages controls NKT cell function and activation which in turn regulates commensal bacteria and immune cell populations in the gut. These results reveal an NKT cell-dendritic cell crosstalk as a key mechanism for the regulation of intestinal homeostasis.

This study defined the mechanism leading to critically short telomeres in the absence of RTEL1 and showed that telomerase, which extends telomeres in normal cells, is pathological when forks encounter an obstacle within the telomere. We showed that replication forks stall and reverse at persistent t-loops, which creates a pseudo-telomere substrate that is inappropriately stabilised by telomerase. Removing telomerase or blocking replication fork reversal rescued telomere dysfunction in Rtel1 deficient cells. We proposed that when persistent t-loops stall the replisome, telomerase inhibits fork restart, triggering the excision of the t-loop by SLX1/4 and loss of a substantial part of the telomere.

Evidence suggested that the telomere adopts a lasso-like t-loop configuration, which safeguards chromosome ends from being recognised as DNA double strand breaks. However, the regulation and physiological importance of t-loops in end-protection was uncertain. This study uncovered a phospho-switch in TRF2 that coordinates the timely assembly and disassembly of t-loops during the cell cycle, which protects telomeres from replication stress and an unscheduled DNA damage response. These results were the first to definitively establish the t-loop as a physiologically important structure required to suppress checkpoint activation at telomere ends.

Like many developing tissues, the vertebrate neural tube is patterned by antiparallel morphogen gradients. Using quantitative gene expression and signalling measurements we derived and validated a characteristic decoding map that relates morphogen input to the positional identity of neural progenitors. This revealed a strategy that minimises patterning errors in response to the joint input of noisy opposing gradients. The study illustrates how we integrate quantitative data, developmental and microfluidic experiments with phenological and mechanistic models.

The prevailing view of neural induction in vertebrate embryos had been that cells are initially induced with anterior (forebrain) identity and then caudalising signals convert a proportion to posterior fates (spinal cord). Using chromatin accessibility, to define how cells adopt region-specific neural fates, combined with genetic and biochemical perturbations, we found that contrary to the established model, cells commit to a regional identity before acquiring neural identity. These findings prompt a revision to textbook models of neural induction. The study illustrates our adoption of new genomic methods (ATACseq) to address long-standing questions, and our capacity to productively collaborate with computational biologists.

Lentiviral IN proteins are notoriously poorly behaved in vitro, and the HIV 1 intasome has eluded structural biologists for over two decades. Prior research resulted in a collection of partial crystal and NMR structures that did not explain how lentiviral integrase synapses viral DNA ends. This paper described the first structure of the lentiviral intasome, solving the long-standing mystery and reconciling years of HIV-1 integrase structural biology and biochemistry.

Oesophageal adenocarcinoma shows high genetic heterogeneity making the identification of cancer drivers challenging. We developed a machine learning algorithm to identify cancer drivers in 261 oesophageal adenocarcinomas. Although most predicted drivers were rare or patient-specific, they all perturbed well-known cancer pathways. Using the recurrence of the same pathway perturbations rather than individual genes, we stratified patients into six groups different for their clinical features. We validated experimentally the contribution of these genes to disease progression and revealed acquired dependencies exploitable in therapy. This study described a new way to identify cancer drivers that we have recently further developed for application in precision oncology.

The MCM replicative helicase is loaded onto duplex DNA as a double hexamer. Here we use time-resolved cryo-EM to show that ORC binds to its high affinity binding site to load the first MCM hexamer. ORC then releases this site and it, or another ORC molecule then binds the B2 element, which contains a degenerate ORC binding site. This binding is stabilised by a novel interaction between the Orc6 subunit of ORC and the N-terminus of the MCM hexamer. ORC then recruits and loads the second hexamer by the same mechanism as the first hexamer. We employed newly developed in silico reconstitution approaches to describe the full context of the helicase loading reaction, studied on a near-native, chromatinised origin of replication. This study radically changes our approach to investigating chromosome replication with cryo-EM.

This paper shows that loading of the MCM double hexamer is a quasi-symmetrical reaction: two ORC molecules bound at two opposing sites of different affinity each recruit and load a single hexamer. The distance between the ORC binding sites is not critical. Subsequent work has provided further evidence for this from cryo-EM.

This paper provided the first view of how the inactive MCM double hexamer is converted to two active CMG helicases. We showed MCM remains bound to ADP after loading; firing factors trigger ADP-ATP exchange; ATP rebinding causes double hexamer splitting, initial DNA melting and CMG formation. Active helicases then translocate N-terminus first.

In this and the accompanying paper (Yeeles et al. 2017 Mol Cel 65, 105-116) we describe the reconstitution of full chromatin replication. We first identified all of the factors required for complete and rapid replication of naked DNA. Then we identified and characterised factors required to replicate chromatinised templates. We showed FACT is essential for chromatin replication, whilst nucleosome remodellers and histone acetylases help chromatin replication. In addition, chromatin enforces origin specificity and Okazaki fragment processing. Finally, we found that histones are efficiently transferred to nascent DNA.

This work establishes for the first time a link between oncogenic RAS signalling and increased immuno-suppressive expression of the immune checkpoint protein PD-L1. RAS signalling results in phosphorylation and inactivation of TTP, a factor involved in degrading PD-L1 mRNA transcripts. As TTP inactivation causes accumulation of PD-L1 mRNA, interfering with the RAS pathway increases TTP binding to AU-rich elements of the transcripts, decreases PD-L1 protein production, and leads to enhanced antitumor immunity.

Metastatic melanoma is a lethal disease, in part because of rapid acquisition of resistance to therapy. Using genetically engineered mouse models, we demonstrate that the activating RAC1 P29S mutation, present in up to 5% of melanoma patients, cooperates with BRAF as a driver of melanoma initiation and promotes BRAF inhibitor resistance. The critical RAC1 effector pathway in melanoma is shown to be the transcription factor complex SRF/MRTF, which initiates a switch to a mesenchymal-like state characterized by therapy resistance. Therapeutic targeting of SRF/MRTF may have potential to reverse BRAF inhibitor resistance in melanoma patients bearing the oncogenic RAC1 P29S mutation

KRAS is the most commonly mutated oncogene in human lung cancer, but direct targeting of RAS proteins has proved difficult. A recently developed inhibitor of G12C mutant KRAS protein inhibits lung cancer progression in mouse models but does not provide durable regressions. By studying signalling pathways required for survival of KRAS mutant cells, we demonstrate a strong and selective potentiation of the effects of G12C KRAS inhibitors when mTOR and/or IGF1R are also inhibited. Using mutant specific G12C KRAS inhibitors rather than MEK inhibitors in these combinations is associated with greater specificity and lower toxicity. We propose that adding IGF1R and mTOR inhibitors will increase the impact of G12C KRAS inhibitors in clinical trials.

Protein aggregation drives neuronal death in Parkinson’s disease, although how transition of monomeric protein structures to aggregated forms causes toxicity is unknown. We demonstrate that aggregation of the protein α-synuclein generates beta sheet-rich oligomers, which localise to the mitochondrial inner membrane, where they impair complex I-dependent respiration, induce oxidation of ATP synthase and cause mitochondrial lipid peroxidation. These oxidation events result in opening of the permeability transition pore, triggering mitochondrial swelling, and ultimately cell death. This work highlights how structural conversion of a protein changes its physiological interaction with proteins and lipids, and induces pathology in human cell models of disease.