Faculty Bibliography
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person:Karim-Jean Armache (armack01) or Joel Belasco (belasj01) or bhabhg01 or burdes01 or cadwek01 or chaom01 or ekierd01 or froemr01 or gelmaj01 or jah12 or hubbas01 or knauth01 or lafaij01 or littmd01 or nancej01 or narask01 or neubet01 or novicr01 or ringsn01 or schwas13 or sfeira01 or skolne01 or smiths04 or stoked01 or torrej12 or treisj01 or turnbd01 or wangd01 or rifkid01 or ryooh01 or wilsoe01
Total Results:
2585
LetA defines a structurally distinct transporter family
Membrane transport proteins translocate diverse cargos, ranging from small sugars to entire proteins, across cellular membranes1-3. A few structurally distinct protein families have been described that account for most of the known membrane transport processes4-6. However, many membrane proteins with predicted transporter functions remain uncharacterized. Here we determined the structure of Escherichia coli LetAB, a phospholipid transporter involved in outer membrane integrity, and found that LetA adopts a distinct architecture that is structurally and evolutionarily unrelated to known transporter families. LetA localizes to the inner membrane, where it is poised to load lipids into its binding partner, LetB, a mammalian cell entry (MCE) protein that forms an approximately 225 Å long tunnel for lipid transport across the cell envelope. Unexpectedly, the LetA transmembrane domains adopt a fold that is evolutionarily related to the eukaryotic tetraspanin family of membrane proteins, including transmembrane AMPA receptor regulatory proteins (TARPs) and claudins. Through a combination of deep mutational scanning, molecular dynamics simulations, AlphaFold-predicted alternative states and functional studies, we present a model for how the LetA-like family of membrane transporters facilitates the transport of lipids across the bacterial cell envelope.
PMID: 41565823
ISSN: 1476-4687
CID: 5988502
Microbiota-induced T cell plasticity enables immune-mediated tumour control
Therapies that harness the immune system to target and eliminate tumour cells have revolutionized cancer care. Immune checkpoint blockade (ICB), which boosts the anti-tumour immune response by inhibiting negative regulators of T cell activation1-3, is remarkably successful in a subset of cancer patients. Yet a significant proportion do not respond to treatment, emphasizing the need to understand factors influencing the therapeutic efficacy of ICB4-9. The gut microbiota, consisting of trillions of microorganisms residing in the gastrointestinal tract, has emerged as a critical determinant of immune function and response to cancer immunotherapy, with several studies demonstrating association of microbiota composition with clinical response10-16. However, a mechanistic understanding of how gut commensal bacteria influence the efficacy of ICB remains elusive. Here we use a gut commensal microorganism, segmented filamentous bacteria (SFB), which induces an antigen-specific T helper 17 (TH17) cell effector program in the small intestine lamina propria (SILP)17, to investigate how colonization with this microbe affects the efficacy of ICB in restraining distal growth of tumours sharing antigen with SFB. We find that anti-programmed cell death protein 1 (PD-1) treatment effectively inhibits the growth of implanted SFB antigen-expressing melanoma only if mice are colonized with SFB. Through T cell receptor (TCR) clonal lineage tracing, fate mapping and peptide-major histocompatability complex (MHC) tetramer staining, we identify tumour-associated SFB-specific T helper 1 (TH1)-like cells derived from the homeostatic TH17 cells induced by SFB colonization in the SILP. These gut-educated ex-TH17 cells produce high levels of the pro-inflammatory cytokines interferon (IFN)-γ and tumour necrosis factor (TNF) within the tumour microenvironment (TME), enhancing antigen presentation and promoting recruitment, expansion and effector functions of CD8+ tumour-infiltrating cytotoxic lymphocytes and thereby enabling anti-PD-1-mediated tumour control. Conditional ablation of SFB-induced IL-17A+CD4+ T cells, precursors of tumour-associated TH1-like cells, abolishes anti-PD-1-mediated tumour control and markedly impairs tumour-specific CD8+ T cell recruitment and effector function within the TME. Our data, as a proof of principle, define a cellular pathway by which a single, defined intestinal commensal imprints T cell plasticity that potentiates PD-1 blockade, and indicate targeted modulation of the microbiota as a strategy to broaden ICB efficacy.
PMID: 41535459
ISSN: 1476-4687
CID: 5986392
Proceedings of the National Academy of Sciences of the United States of America (PNAS). 2026:123(2).DOI: 10.1073/pnas.2500723123
Elevator mechanism dynamics in a sodium-coupled dicarboxylate transporter
VcINDY, the sodium-dependent dicarboxylate transporter from
PMID: 41490488
ISSN: 1091-6490
CID: 5980652
Neuropeptides in control of left-right neural circuits
Despite extensive research on hemispheric asymmetries, the mechanisms regulating lateralized brain functions are incompletely understood. Growing evidence suggests that lateralized neural circuits are side-specifically controlled, in part, by neuropeptides acting as neuromodulators, paracrine factors, and neurohormones. This review highlights evidence supporting this concept in the contexts of lateralized pain processing in the amygdala, control of auditory signaling, lateralized interoceptive signaling, and side-specific endocrine regulation. Our focus is primarily on rodent studies, with supporting data from humans and nonmammalian species, including turtles and nematodes. Left-right side-specific control may be rooted in a bipartite, lateralized organization of neuropeptide systems. Neuropeptides with asymmetric actions may act locally within specific brain regions or be coordinated across the neuraxis. These findings converge on a model in which neuropeptides enable lateralized control through interconnected mechanisms spanning gene expression, neural circuits, and behavioral outcomes.
PMID: 41519618
ISSN: 1878-108x
CID: 5981622
On the mechanism of K+ transport through the inter-subunit tunnel of KdpFABC
KdpFABC is an ATP-dependent membrane complex that enables prokaryotes to maintain potassium homeostasis under potassium-limited conditions. It features a unique hybrid mechanism combining a channel-like selectivity filter in KdpA with the ATP-driven transport functionality of KdpB. A key unresolved question is whether K+ ions translocate through the inter-subunit tunnel as a queue of ions or individually within a hydrated environment. Using molecular dynamics simulations, metadynamics, anomalous X-ray scattering, and biochemical assays, we demonstrate that the tunnel is predominantly occupied by water molecules rather than multiple K+ ions. Our results identify only one stable intermediate binding site for K+ within the tunnel, apart from the canonical sites in KdpA and KdpB. Free energy calculations reveal a substantial barrier (∼22 kcal/mol) at the KdpA-KdpB interface, making spontaneous K+ translocation unlikely. Furthermore, mutagenesis and functional assays confirm previous findings that Phe232 at this interface plays a key role in coupling ATP hydrolysis to K+ transport. These findings challenge previous models containing a continuous wire of K+ ions through the tunnel and suggest the existence of an as-yet unidentified intermediate state or mechanistic detail that facilitates K+ movement into KdpB.
PMID: 41384914
ISSN: 1540-7748
CID: 5978042
Integrin is required for basement membrane crossing and branching of an invading intracellular tube
The narrowest biological tubes are comprised of cells that hollow to form an intracellular lumen. Here, we examine early lumenogenesis of the C. elegans excretory cell, which branches to form an H-shaped intracellular tube spanning the length of the worm. Using genetically paralyzed embryos to freeze movement, we describe lumen initiation and branching for the first time using time-lapse fluorescence microscopy. We show that the excretory cell lumen forms through a plasma membrane invasion mechanism when a nascent lumen grows from the plasma membrane into the cytoplasm. The lumen subsequently extends along the left-right axis before branching to form anterior-posterior projections. Through a genetic screen, we identify mutations in ina-1/⍺-integrin and pat-3/β-integrin that block lumenogenesis at the anterior-posterior branching step, and we show that integrin function is required within the excretory cell. Finally, we find that the excretory cell crosses the epidermal basement membrane where anterior-posterior branches form and demonstrate that basement membrane crossing fails in integrin mutant embryos. Our findings reveal how an intracellular lumen initiates and branches and identify integrins and basement membrane as key branching regulators.
PMID: 41321174
ISSN: 1477-9129
CID: 5974502
Author Correction: Unravelling cysteine-deficiency-associated rapid weight loss
PMID: 41388205
ISSN: 1476-4687
CID: 5978162
Specialized Dendritic Cells Mediating Peripheral Tolerance to Intestinal Antigens
The immune system is tasked with mounting effective responses to pathogens while preventing inflammation triggered by innocuous antigens, including those derived from self, food, and commensal microbes. This balance is especially critical in the intestine, where dietary and microbial antigens are constantly encountered. Peripherally induced regulatory T cells (pTreg or iTreg) play a key role in suppressing inappropriate immune activation and maintaining gut homeostasis. Elucidating how pTreg cells are generated along the gastrointestinal tract is therefore critical to understanding peripheral tolerance. Recent studies have revealed that intestinal antigen-specific pTreg cell differentiation is induced by a distinct lineage of antigen-presenting cells (APCs) requiring expression of the transcription factors RORγt and PRDM16. Genetic perturbation of these APCs results not only in microbiota-specific proinflammatory T cell responses but also in the breakdown of oral tolerance, which in turn predisposes to allergic inflammation. In this review, we summarize the discovery of these tolerance-inducing APCs, highlight their role in instructing pTreg cell differentiation in response to microbiota and dietary antigens, and discuss the regulatory networks that support their function during intestinal immune tolerance.
PMCID:12670995
PMID: 41328802
ISSN: 1600-065x
CID: 5974842
Palaeometabolomes yield biological and ecological profiles at early human sites
The science of metabolic profiling exploits chemical compound byproducts of metabolism called metabolites1 that explain internal biological functions, physiological health and disease, and provide evidence of external influences specific to an organism's habitat. Here we assess palaeometabolomes from fossilized mammalian hard tissues as a molecular ecological strategy to provide evidence of an ancient organism's relationship with its environment. From eastern, central and southern African Plio-Pleistocene localities of palaeoanthropological significance, we study six fossils from Olduvai Gorge, Tanzania, one from the Chiwondo Beds, Malawi, and one from Makapansgat, South Africa. We perform endogeneity assessments by analysing palaeometabolomes of palaeosols and the effects of owl digestion on rodent bones to enable prudent ecological inferences. Diagenesis is indicated by metabolites of collagenase-producing bacteria2, whereas the preservation of peptides including those of collagen are identified by proteomics. Endogenous metabolites document biological functions and exogenous metabolites render environmental details including soil characteristics and woody cover, and enable annual minimum and maximum rainfall and temperature reconstructions at Olduvai Gorge, supporting the freshwater woodland and grasslands of Olduvai Gorge Bed I3-5, and the dry woodlands and marsh of Olduvai Gorge Upper Bed II6. All sites denote wetter and/or warmer conditions than today. We infer that metabolites preserved in hard tissues derive from an extravasated vasculature serum filtrate that becomes entombed within developing mineralized matrices, and most probably survive palaeontological timeframes in the nanoscopic 'pool' of structural-bound water that occurs in hard tissue niches7.
PMID: 41407854
ISSN: 1476-4687
CID: 5979502
4EHP and NELF-E regulate physiological ATF4 induction and proteostasis in disease models of Drosophila
Cells adapt to proteostatic and metabolic stresses, in part, through stress activated eIF2α kinases that stimulate the translation of ATF4. Stress-induced ATF4 translation is regulated through elements at ATF4 mRNA's 5' leader. In addition to eIF2α kinases, ATF4 induction requires other regulators that remain poorly understood. Here, we report an ATF4 regulatory network consisting of eIF4E-Homologous Protein (4EHP), NELF-E, the 40S ribosome, and eIF3 subunits. Specifically, we found that the mRNA cap-binding protein, 4EHP, was required for ATF4 signaling in the Drosophila larval fat body and in disease models associated with abnormal ATF4 signaling. NELF-E mRNA, encoding a regulator of pol II-mediated transcription, was identified as a top interactor of 4EHP in a TRIBE (Targets of RNA Binding through Editing) screen. Quantitative proteomics analysis revealed that the knockdown of NELF-E or 4EHP commonly reduced several subunits of the 40S ribosome (RpS) and the eIF3 translation initiation factor. Moreover, reduction of NELF-E, 4EHP, RpS12, eIF3l, or eIF3h suppressed the expression of ATF4 and its target genes. These results uncover a previously unrecognized ATF4 regulatory network consisting of 4EHP and NELF-E that impacts proteostasis during normal development and in disease models.
PMCID:12816580
PMID: 41436469
ISSN: 2041-1723
CID: 5987942
