High-affinity peptides developed against calprotectin and their application as synthetic ligands in diagnostic assays.

Common inflammatory disorders such as ulcerative colitis and Crohn's disease are non-invasively diagnosed or monitored by the biomarker calprotectin. However, current quantitative tests for calprotectin are antibody-based and vary depending on the type of antibody and assay used. Additionally, the binding epitopes of applied antibodies are not characterized by structures and for most antibodies it is unclear if they detect calprotectin dimer, tetramer, or both. Herein, we develop calprotectin ligands based on peptides, that offer advantages such as homogenous chemical composition, heat-stability, site-directed immobilization, and chemical synthesis at high purity and at low cost. By screening a 100-billion peptide phage display library against calprotectin, we identified a high-affinity peptide (Kd = 26 ± 3 nM) that binds to a large surface region (951 Å2) as shown by X-ray structure analysis. The peptide uniquely binds the calprotectin tetramer, which enabled robust and sensitive quantification of a defined species of calprotectin by ELISA and lateral flow assays in patient samples, and thus offers an ideal affinity reagent for next-generation inflammatory disease diagnostic assays.

Mec1, INO80, and the PAF1 complex cooperate to limit transcription replication conflicts through RNAPII removal during replication stress.

Little is known about how cells ensure DNA replication in the face of RNA polymerase II (RNAPII)-mediated transcription, especially under conditions of replicative stress. Here we present genetic and proteomic analyses from budding yeast that uncover links between the DNA replication checkpoint sensor Mec1-Ddc2 (ATR-ATRIP), the chromatin remodeling complex INO80C (INO80 complex), and the transcription complex PAF1C (PAF1 complex). We found that a subset of chromatin-bound RNAPII is degraded in a manner dependent on Mec1, INO80, and PAF1 complexes in cells exposed to hydroxyurea (HU). On HU, Mec1 triggers the efficient removal of PAF1C and RNAPII from transcribed genes near early firing origins. Failure to evict RNAPII correlates inversely with recovery from replication stress: paf1Δ cells, like ino80 and mec1 mutants, fail to restart forks efficiently after stalling. Our data reveal unexpected synergies between INO80C, Mec1, and PAF1C in the maintenance of genome integrity and suggest a mechanism of RNAPII degradation that reduces transcription-replication fork collision.

INO80-C and SWR-C: guardians of the genome.

The double membrane of the eukaryotic nucleus surrounds the genome, constraining it to a nuclear sphere. Proteins, RNA protein particles and artificial chromosome rings diffuse rapidly and freely throughout the nucleoplasm, while chromosomal loci show subdiffusive movement with varying degrees of constraint. In situ biochemical approaches and live imaging studies have revealed the existence of nuclear subcompartments that are enriched for specific chromatin states and/or enzymatic activities. This sequestration is thought to enhance the formation of heterochromatin, particularly when factors of limited abundance are involved. Implicit in the concept of compartmentation is the idea that chromatin is able to move from one compartment to another. Indeed, in budding yeast, gene activation, repression and the presence of persistent DNA double-strand breaks each has been shown to provoke subnuclear relocalization of chromatin. In some cases, movement has been linked to the action of ATP-dependent chromatin remodeling complexes, more specifically to the Snf2-related ATPase-containing complexes, SWR-C and INO80-C. Here we examine how these multi-subunit remodelers contribute to chromatin-based processes linked to the DNA damage response. We review recent evidence that supports a role for yeast SWR-C and INO80-C in determining the subnuclear position of damaged domains and finally, we recap the multiple ways in which these remodelers contribute to genomic integrity.

Swi2/Snf2 remodelers: hybrid views on hybrid molecular machines.

Swi2/Snf2 (switch/sucrose non-fermentable) enzymes form a large and diverse class of proteins and multiprotein assemblies that remodel nucleic acid:protein complexes, using the energy of ATP hydrolysis. The core Swi2/Snf2 type ATPase domain belongs to the 'helicase and NTP driven nucleic acid translocase' superfamily 2 (SF2). It serves as a motor that functionally and structurally interacts with different targeting domains and functional modules to drive a plethora of remodeling activities in chromatin structure and dynamics, transcription regulation and DNA repair. Recent progress on the interaction of Swi2/Snf2 enzymes and multiprotein assemblies with their substrate nucleic acids and proteins, using hybrid structural biology methods, illuminates mechanisms for complex chemo-mechanical remodeling reactions. For Mot1, a hybrid mechanism of remodeler and chaperone emerged.