Cell-type specific, inducible and acute degradation of targeted protein in mice by two degron systems.

Despite its broad application in in vitro studies, the application of targeted protein degradation (TPD) to animal models faces considerable challenges. Here, we develop inducible and cell-type specific TPD systems in mice using two degron systems: Oryza sativa TIR1 (OsTIR1)-auxin-inducible degron 2 (AID2) and human cereblon (hCRBN)-SALL4 degron (S4D). Efficient degradation of Satb1 protein by these systems recapitulates phenotypes observed in the Satb1-deficient mice.

Protocol for quantitative proteomic analysis of heterogeneous adipose tissue-residing progenitor subpopulations in mice.

Recent studies have revealed cellular heterogeneity of mesenchymal stromal cells and immune cells in adipose tissue and emphasized the need for quantitative analysis of small numbers of functionally distinct cells using state-of-the-art "omics" technologies. Here, we present an optimized protocol for precise protein quantification from minute amounts of samples. We describe steps for isolation of mouse adipose progenitor cells, proteomics sample preparation, mass spectrometry measurement, and computational analysis.

Multilayered omics reveal sex- and depot-dependent adipose progenitor cell heterogeneity.

Single-cell RNA sequencing (scRNA-seq) has revealed that adult white adipose tissue (WAT) harbors functionally diverse subpopulations of mesenchymal stromal cells that differentially impact tissue plasticity. To date, the molecular basis of this cellular heterogeneity has not been fully defined. Here, we describe a multilayered omics approach to dissect adipose progenitor cell heterogeneity in three dimensions: progenitor subpopulation, sex, and anatomical localization.

The FlaG regulator is involved in length control of the polar flagella of Campylobacter jejuni.

Campylobacter jejuni cells have bipolar flagella. Both flagella have similar lengths of about one helical turn, or 3.53±0.

An intrinsically disordered linker controlling the formation and the stability of the bacterial flagellar hook.

Background: In a macro-molecular complex, any minor change may prove detrimental. For a supra-molecular nano-machine like the bacterial flagellum, which consists of several distinct parts with specific characteristics, stability is important. During the rotation of the bacterial flagellar motor, which is located in the membrane, the flagella rotate at speeds between 200 and 2000 rpm, depending on the bacterial species.

Complete structure of the bacterial flagellar hook reveals extensive set of stabilizing interactions.

The bacterial flagellar hook is a tubular helical structure made by the polymerization of multiple copies of a protein, FlgE. Here we report the structure of the hook from Campylobacter jejuni by cryo-electron microscopy at a resolution of 3.5 Å.

Structural insights into bacterial flagellar hooks similarities and specificities.

Across bacteria, the protein that makes the flagellar hook, FlgE, has a high variability in amino acid residue composition and sequence length. We hereby present the structure of two fragments of FlgE protein from Campylobacter jejuni and from Caulobacter crescentus, which were obtained by X-ray crystallography, and a high-resolution model of the hook from Caulobacter. By comparing these new structures of FlgE proteins, we show that bacterial hook can be divided in two distinct parts.

Function of the conserved FHIPEP domain of the flagellar type III export apparatus, protein FlhA.

The Type III flagellar protein export apparatus of bacteria consists of five or six membrane proteins, notably FlhA, which controls the export of other proteins and is homologous to the large family of FHIPEP export proteins. FHIPEP proteins contain a highly-conserved cytoplasmic domain. We mutagenized the cloned Salmonella flhA gene for the 692 amino acid FlhA, changing a single, conserved amino acid in the 68-amino acid FHIPEP region.

Assembling flagella in Salmonella mutant strains producing a type III export apparatus without FliO.

The type III export apparatus of the Salmonella flagellum consists of six transmembrane proteins (FlhA, FlhB, FliO, FliP, FliQ, and FliR) and three soluble proteins (FliH, FliI, and FliJ). Deletion of the fliO gene creates a mutant strain that is poorly motile; however, suppressor mutations in the fliP gene can partially rescue motility. To further understand the mechanism of suppression of a fliO deletion mutation, we isolated new suppressor mutant strains with partially rescued motility.

Randomly selected suppressor mutations in genes for NADH : quinone oxidoreductase-1, which rescue motility of a Salmonella ubiquinone-biosynthesis mutant strain.

The primary mobile electron-carrier in the aerobic respiratory chain of Salmonella is ubiquinone. Demethylmenaquinone and menaquinone are alternative electron-carriers involved in anaerobic respiration. Ubiquinone biosynthesis was disrupted in strains bearing deletions of the ubiA or ubiE genes.

Function of FlhB, a membrane protein implicated in the bacterial flagellar type III secretion system.

The membrane protein FlhB is a highly conserved component of the flagellar secretion system, and it plays an active role in the regulation of protein export. In this study conserved properties of FlhB that are important for its function were investigated. Replacing the flhB gene (or part of the gene) in Salmonella typhimurium with the flhB gene of the distantly related bacterium Aquifex aeolicus greatly reduces motility.

Cross-complementation study of the flagellar type III export apparatus membrane protein FlhB.

The bacterial type III export apparatus is found in the flagellum and in the needle complex of some pathogenic Gram-negative bacteria. In the needle complex its function is to secrete effector proteins for infection into Eukaryotic cells. In the bacterial flagellum it exports specific proteins for the building of the flagellum during its assembly.

Refining the binding of the Escherichia coli flagellar master regulator, FlhD4C2, on a base-specific level.

The Escherichia coli flagellar master regulator, FlhD(4)C(2), binds to the promoter regions of flagellar class II genes, yet, despite extensive analysis of the FlhD(4)C(2)-regulated promoter region, a detailed consensus sequence has not emerged. We used in vitro and in vivo experimental approaches to determine the nucleotides in the class II promoter, fliAp, required for the binding and function of FlhD(4)C(2). FlhD(4)C(2) protects 48 bp (positions -76 to -29 relative to the σ(70)-dependent transcriptional start site) in the fliA promoter.

FliO regulation of FliP in the formation of the Salmonella enterica flagellum.

The type III secretion system of the Salmonella flagellum consists of 6 integral membrane proteins: FlhA, FlhB, FliO, FliP, FliQ, and FliR. However, in some other type III secretion systems, a homologue of FliO is apparently absent, suggesting it has a specialized role. Deleting the fliO gene from the chromosome of a motile strain of Salmonella resulted in a drastic decrease of motility.

Increased motility of Escherichia coli by insertion sequence element integration into the regulatory region of the flhD operon.

The flhD operon is the master operon of the flagellar regulon and a global regulator of metabolism. The genome sequence of the Escherichia coli K-12 strain MG1655 contained an IS1 insertion sequence element in the regulatory region of the flhD promoter. Another stock of MG1655 was obtained from the E.