Publication highlights

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.

This study was the first to demonstrate that RAD51 paralogues bind to and structurally remodel the pre-synaptic RAD-51-ssDNA filament to a stabilised, “open”, and flexible conformation, which facilitates strand exchange with the template duplex. We showed that RAD51 paralogues act by binding the end of the presynaptic filament, which induces a conformational change that stabilises RAD-51 bound to ssDNA and primes the filament for strand exchange. These observations established for the first time the underlying mechanism of HR stimulation by Rad51 paralogues and revealed a new paradigm for the action of HR mediator proteins.

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.

Despite evolutionarily conservation of molecular mechanisms, the speed of development varies substantially between species. Using in vitro directed differentiation of embryonic stem cells to motor neurons, we show that the programme of motor neuron differentiation runs twice as fast in mouse as in human. We provide evidence that a two-fold increase in protein stability and cell cycle duration in human cells compared to mouse can account for the slower pace of human development, indicating that global differences in kinetic parameters play a major role in interspecies differences in developmental tempo. This study establishes a new experimental system in which to address fundamental questions.

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.

Memory B cells (MBCs) are key for protection from reinfection. However, it is mechanistically unclear how germinal center (GC) B cells differentiate into MBCs. MYC is transiently induced in cells fated for GC expansion and plasma cell (PC) formation, so-called positively selected GC B cells. We found that these cells coexpressed MYC and MIZ1 (MYC-interacting zinc-finger protein 1 [ZBTB17]). MYC and MIZ1 are transcriptional activators; however, they form a transcriptional repressor complex that represses MIZ1 target genes. Mice lacking MYC-MIZ1 complexes displayed impaired cell cycle entry of positively selected GC B cells and reduced GC B cell expansion and PC formation. Notably, absence of MYC-MIZ1 complexes in positively selected GC B cells led to a gene expression profile alike that of MBCs and increased MBC differentiation. Thus, at the GC positive selection stage, MYC-MIZ1 complexes are required for effective GC expansion and PC formation and to restrict MBC differentiation. We propose that MYC and MIZ1 form a module that regulates GC B cell fate.

D-cycloserine is an antibiotic used for decades to treat drug resistant tuberculosis. Its inhibition mechanism came into question when in a previous paper we determined alanine racemase activity in “fully inhibited” cells. This study demonstrated a previously unknown path during the assumed irreversible inhibition of alanine racemase that leads to the destruction of the antibiotic, meaning that alanine racemase is not irreversibly inhibited by the drug. The paper highlights the complexity of studying the chemical mechanisms of inhibition of enzymes and points to a novel strategy to design D-cycloserine analogues with improved properties.

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.

Here, we described a cryo-EM structure of a retroviral intasome in a functional complex with a nucleosome. The structure revealed a multivalent interface of the viral integration machinery and chromatin, involving both gyres of nucleosomal DNA and histones. Whilst the histone octamer remains intact, the DNA is lifted from its surface to allow for strand transfer at highly preferred integration sites. These data provided a unique snapshot of an enzyme recognizing and acting upon nucleosomal DNA. The structure was the first to illustrate nucleosome flexibility facilitating a biological process and, as such, had far-reaching implications for chromosome biology.

HIV integrase inhibitors represent some of the most impactful antimicrobial inhibitors. The second-generation drugs display improved barriers to the emergence of resistance, which spearheaded their worldwide rollout. Yet not even the most advanced compounds are immune to viral resistance. Our results explained the mechanism of viral resistance associated with the most common drug resistance mutations. Furthermore, we established the key difference between the first and second-generation strand transfer inhibitors, which will inform further development of this drug class.

This paper decribes how we were able to successfully repurpose the Crick to increase the capacity for Sars-CoV-2 testing in unpredented times.

This important paper showed very high levels of infection amongst healthcare workers in a local hospital. It has influenced government policy – asymptomatic healthcare workers are to be screened as per our recommendation (announced October 12th).

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.

Here we showed that Sld3, which we previously identified as being one of two essential cyclin dependent kinase (CDK) substrates in replication, is a phosphopeptide binding protein which binds specifically to Mcm4 and Mcm6 when they have been phosphorylated by Dbf4 dependent kinase (DDK). Sld3 then directly recruits Cdc45 to MCM and, via CDK phosphorylation, recruits the remaining firing factors. We had previously shown that Sld3 is also one of two targets of the DNA damage checkpoint kinase involved in inhibiting origin firing in response to DNA damage. Thus, Sld3 plays key roles with all three kinases that regulate replication (CDK, DDK, Rad53).