German Leonov scite author profile

Notch has a well-defined role in controlling cell fate decisions in the embryo and the adult epidermis and immune systems, yet emerging evidence suggests Notch also directs non-cell-autonomous signalling in adult tissues. Here, we show that Notch1 works as a damage response signal. Epidermal Notch induces recruitment of immune cell subsets including RORγ+ ILC3s into wounded dermis; RORγ+ ILC3s are potent sources of IL17F in wounds and control immunological and epidermal cell responses. Mice deficient for RORγ+ ILC3s heal wounds poorly resulting from delayed epidermal proliferation and macrophage recruitment in a CCL3-dependent process. Notch1 upregulates TNFα and the ILC3 recruitment chemokines CCL20 and CXCL13. TNFα, as a Notch1 effector, directs ILC3 localization and rates of wound healing. Altogether these findings suggest that Notch is a key stress/injury signal in skin epithelium driving innate immune cell recruitment and normal skin tissue repair.

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Contribution of proteasome-catalyzed peptidecis-splicing to viral targeting by CD8⁺T cells in HIV-1 infection

Paes

Leonov

Partridge

et al. 2019

Proc. Natl. Acad. Sci. U.S.A.

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Peptides generated by proteasome-catalyzed splicing of noncontiguous amino acid sequences have been shown to constitute a source of nontemplated human leukocyte antigen class I (HLA-I) epitopes, but their role in pathogen-specific immunity remains unknown. CD8 + T cells are key mediators of HIV type 1 (HIV-1) control, and identification of novel epitopes to enhance targeting of infected cells is a priority for prophylactic and therapeutic strategies. To explore the contribution of proteasome-catalyzed peptide splicing (PCPS) to HIV-1 epitope generation, we developed a broadly applicable mass spectrometry-based discovery workflow that we employed to identify spliced HLA-I-bound peptides on HIV-infected cells. We demonstrate that HIV-1-derived spliced peptides comprise a relatively minor component of the HLA-I-bound viral immunopeptidome. Although spliced HIV-1 peptides may elicit CD8 + T cell responses relatively infrequently during infection, CD8 + T cells primed by partially overlapping contiguous epitopes in HIV-infected individuals were able to cross-recognize spliced viral peptides, suggesting a potential role for PCPS in restricting HIV-1 escape pathways. Vaccine-mediated priming of responses to spliced HIV-1 epitopes could thus provide a novel means of exploiting epitope targets typically underutilized during natural infection. peptide splicing | proteasome | immunopeptidome | T cell epitope | human immunodeficiency virus P eptides presented by human leukocyte antigen (HLA) class I and II molecules were originally thought to derive solely from contiguous protein sequences. Two seminal studies then reported T cell responses to noncontiguous (spliced/fusion) peptides in renal cell carcinoma and melanoma patients, although identification of these tumor-derived spliced peptides involved laborintensive in vitro approaches, and validation relied on the serendipitous availability of epitope-specific T cells (1, 2). Thus, only a handful of cis-spliced epitopes were described in more than a decade of subsequent research (3-7). In addition to epitopes generated by cis-splicing, which involves ligation of noncontiguous peptide fragments within the same polypeptide, recognition of HLA-II-restricted epitopes generated by fusion of peptide fragments from 2 different proteins (trans-splicing) by CD4 + T cells from patients with type I diabetes has also been reported (8), although whether the peptide fusion event leading to generation of these trans-spliced epitopes was catalyzed by the proteasome or other enzymes was not explored.More recently, the increased sensitivity of mass spectrometry (MS)-based approaches for characterizing the repertoire of HLAbound peptides (the immunopeptidome) has provided an opportunity for the discovery of spliced peptides on a much larger scale than was previously possible (9-11). Although proteasome-catalyzed peptide splicing (PCPS) had widely been assumed to be a relatively rare event, MS-based profiling of immunopeptidomic datasets has questioned this assumption. However, the proportion o...

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Elucidation of the Signatures of Proteasome-Catalyzed Peptide Splicing

et al. 2020

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Proteasomes catalyze the degradation of endogenous proteins into oligopeptides, but can concurrently create spliced oligopeptides through ligation of previously non-contiguous peptide fragments. Recent studies have uncovered a formerly unappreciated role for proteasome-catalyzed peptide splicing (PCPS) in the generation of non-genomically templated human leukocyte antigen class I (HLA-I)-bound cis-spliced peptides that can be targeted by CD8 + T cells in cancer and infection. However, the mechanisms defining PCPS reactions are poorly understood. Here, we experimentally define the biochemical constraints of proteasome-catalyzed cis-splicing reactions by examination of in vitro proteasomal digests of a panel of viral-and self-derived polypeptide substrates using a tailored mass-spectrometry-based de novo sequencing workflow. We show that forward and reverse PCPS reactions display unique splicing signatures, defined by preferential fusion of distinct amino acid residues with stringent peptide length distributions, suggesting sequence-and size-dependent accessibility of splice reactants for proteasomal substrate binding pockets. Our data provide the basis for a more informed mechanistic understanding of PCPS that will facilitate future prediction of spliced peptides from protein sequences.

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Rewriting nature’s assembly manual for a ssRNA virus

Patel

Wroblewski

Leonov

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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SignificanceViruses composed of a shell of coat proteins enclosing ssRNA genomes are among the simplest biological entities. Their lifecycles include a range of processes, such as specific genome encapsidation and efficient capsid self-assembly. Until recently, these were not linked, but we have shown that many viruses in this class encode multiple, degenerate RNA sequence/structure motifs that bind cognate coat proteins collectively. This simultaneously ensures specific genome packaging and efficient virion assembly via an RNA-encoded instruction manual. Here we extract essential features of this manual in a viral RNA genome, creating a synthetic sequence with an assembly substrate superior to the natural equivalent. Such RNAs have the potential for efficient production of stable virus-like particle vaccines and/or gene/drug delivery vehicles.

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Hamiltonian path analysis of viral genomes

2018

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German Leonov

Epidermal Notch1 recruits RORγ+ group 3 innate lymphoid cells to orchestrate normal skin repair

Contribution of proteasome-catalyzed peptidecis-splicing to viral targeting by CD8⁺T cells in HIV-1 infection

Elucidation of the Signatures of Proteasome-Catalyzed Peptide Splicing

Rewriting nature’s assembly manual for a ssRNA virus

Hamiltonian path analysis of viral genomes

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German Leonov

Epidermal Notch1 recruits RORγ+ group 3 innate lymphoid cells to orchestrate normal skin repair

Contribution of proteasome-catalyzed peptidecis-splicing to viral targeting by CD8+T cells in HIV-1 infection

Elucidation of the Signatures of Proteasome-Catalyzed Peptide Splicing

Rewriting nature’s assembly manual for a ssRNA virus

Hamiltonian path analysis of viral genomes

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Product

Resources

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Contribution of proteasome-catalyzed peptidecis-splicing to viral targeting by CD8⁺T cells in HIV-1 infection