Casimir Bamberger

F508 CFTR interactome remodelling promotes rescue of cystic fibrosis

Deletion of phenylalanine 508 of the cystic fibrosis transmembrane conductance regulator (∆F508 CFTR) is the major cause of cystic fibrosis, one of the most common inherited childhood diseases. The mutated CFTR anion channel is not fully glycosylated and shows minimal activity in bronchial epithelial cells of patients with cystic fibrosis. Low temperature or inhibition of histone deacetylases can partly rescue ∆F508 CFTR cellular processing defects and function. A favourable change of ∆F508 CFTR protein–protein interactions was proposed as a mechanism of rescue; however, CFTR interactome dynamics during temperature shift and inhibition of histone deacetylases are unknown. Here we report the first comprehensive analysis of the CFTR and ∆F508 CFTR interactome and its dynamics during temperature shift and inhibition of histone deacetylases. By using a novel deep proteomic analysis method, we identify 638 individual high-confidence CFTR interactors and discover a ∆F508 deletion-specific interactome, which is extensively remodelled upon rescue. Detailed analysis of the interactome remodelling identifies key novel interactors, whose loss promote ∆F508 CFTR channel function in primary cystic fibrosis epithelia or which are critical for CFTR biogenesis. Our results demonstrate that global remodelling of ∆F508 CFTR interactions is crucial for rescue, and provide comprehensive insight into the molecular disease mechanisms of cystic fibrosis caused by deletion of F508.

Activin Controls Skin Morphogenesis and Wound Repair Predominantly via Stromal Cells and in a Concentration-Dependent Manner via Keratinocytes

The transforming growth factor-beta family member activin is a potent regulator of skin morphogenesis and repair. Transgenic mice overexpressing activin in keratinocytes display epidermal hyper-thickening and dermal fibrosis in normal skin and enhanced granulation tissue formation after wounding. Mice overexpressing the secreted activin antagonist follistatin, however, have the opposite wound-healing phenotype. To determine whether activin affects skin morphogenesis and repair via activation of keratinocytes and/or stromal cells, we generated transgenic mice expressing a dominant-negative activin receptor IB mutant (dnActRIB) in keratinocytes. The architecture of adult skin was unaltered in these mice, but delays were observed in postnatal pelage hair follicle morphogenesis and in the first catagen-telogen transformation of hair follicles. Although dnActRIB-transgenic mice showed slightly delayed wound re-epithelialization after skin injury, the strong inhibition of granulation tissue formation seen in follistatin-transgenic mice was not observed. Therefore, although endogenous activin appeared to affect skin morphogenesis and repair predominantly via stromal cells, overexpressed activin strongly affected the epidermis. The epidermal phenotype of activin-overexpressing mice was partially rescued by breeding these animals with dnActRIB-transgenic mice. These results demonstrate that activin affects both stromal cells and keratinocytes in normal and wounded skin and that the effect on keratinocytes is dose-dependent in vivo.

Differential regulation of transcription and induction of programmed cell death by human p53‐family members p63 and p73

The p53 tumor suppressor acts as a transcription factor and has a central function in controlling apoptosis. With p63 and p73 two genes coding for proteins homologous to p53 have been identified. We describe the properties of seven human p63 and p73 proteins as transcriptional activators of p21WAF1/CIP1 expression and apoptotic inducers in direct comparison to p53 in the same assay systems employing DLD‐1‐tet‐off colon cells. Programmed cell death is detected in cells expressing high levels of p53 and p73α. Cells overexpressing TAp63α, TAp63γ, TA*p63α, TA*p63γ, ΔNp63α, and ΔNp63γ display low or no detectable apoptosis.

Cloning and chromosomal mapping of the human p53-related KET gene to Chromosome 3q27 and its murine homolog Ket to mouse Chromosome 16

Abstract. KET is a member of the newly discovered family of proteins that is related to the tumor suppressor p53. Here we describe the molecular cloning of a human cDNA of 4846 bp encoding a protein of 680 amino acids. The human KET protein shares 98% identity with the previously characterized rat homolog. The remarkably high degree of conservation lends support to the notion that KET proteins have important basic functions in development and differentiation. Using the GeneBridge 4 radiation hybrid panel, we have mapped KET to human Chromosome (Chr) 3q27. KET is located between the somatostatin gene SST (proximal) and the apolipoprotein D gene APOD (distal) in a region of conserved synteny to mouse Chr 16. This chromosomal region is deleted in early stages of tumorigenesis of mouse islet cell carcinomas and contains the hitherto unidentified Loh2 gene, a putative suppressor of angiogenesis. The murine homolog Ket was mapped in an interspecific backcross panel and falls into this region of loss of heterozygosity. From our mapping data we infer that KET might act as a tumor suppressor and is considered as a candidate for Loh2.

The p53 Tumor Suppressor-Like Protein nvp63 Mediates Selective Germ Cell Death in the Sea Anemone Nematostella vectensis

Here we report the identification and molecular function of the p53 tumor suppressor-like protein nvp63 in a non-bilaterian animal, the starlet sea anemone Nematostella vectensis. So far, p53-like proteins had been found in bilaterians only. The evolutionary origin of p53-like proteins is highly disputed and primordial p53-like proteins are variably thought to protect somatic cells from genotoxic stress. Here we show that ultraviolet (UV) irradiation at low levels selectively induces programmed cell death in early gametes but not somatic cells of adult N. vectensis polyps. We demonstrate with RNA interference that nvp63 mediates this cell death in vivo. Nvp63 is the most archaic member of three p53-like proteins found in N. vectensis and in congruence with all known p53-like proteins, nvp63 binds to the vertebrate p53 DNA recognition sequence and activates target gene transcription in vitro. A transactivation inhibitory domain at its C-terminus with high homology to the vertebrate p63 may regulate nvp63 on a molecular level. The genotoxic stress induced and nvp63 mediated apoptosis in N. vectensis gametes reveals an evolutionary ancient germ cell protective pathway which relies on p63-like proteins and is conserved from cnidarians to vertebrates.

Regulation of epidermal homeostasis and repair by phosphoinositide 3-kinase

The epidermis undergoes continuous self-renewal to maintain its protective function. Whereas growth factors are known to modulate overall skin homeostasis, the intracellular signaling pathways, which control the delicate balance between proliferation and differentiation in keratinocytes, are largely unknown. Here we show transient upregulation of the phosphoinositide 3-kinase (PI3K) catalytic subunits p110α and p110β in differentiating keratinocytes in vitro, expression of these subunits in the epidermis of normal and wounded skin, and enhanced Akt phosphorylation in the hyperproliferative wound epidermis. Stimulation of PI3K activity in cultured keratinocytes by stable expression of an inducible, constitutively active PI3K mutant promoted cell proliferation and inhibited terminal differentiation in keratinocyte monocultures and induced the formation of a hyperplastic, disorganized and poorly differentiated epithelium in organotypic skin cultures. Activation of PI3K signaling also caused reorganization of the actin cytoskeleton and induced keratinocyte migration in vitro and in skin organ cultures. The identification of 122 genes, which are differentially expressed after induction of PI3K signaling provides insight into the molecular mechanisms underlying the observed effects of active PI3K on keratinocytes and indicates that hyperproliferation may be achieved at the expense of genome integrity. These results identify PI3K as an important intracellular regulator of epidermal homeostasis and repair.

Expression of different p63 variants in healing skin wounds suggests a role of p63 in reepithelialization and muscle repair

Healing of skin wounds in mammals involves partial reconstruction of the dermis and coverage of the injured site by keratinocytes. The latter process is achieved by extensive migration and hyperproliferation of keratinocytes at the wound rim. Because the p53 protein family member p63 is expressed in human hyperproliferative epidermis, this study determined whether enhanced keratinocyte proliferation correlates with the expression of p63. Therefore, we investigated the temporal and spatial distribution of four major variants of the p63 transcription factor—TAp63α, TAp63γ, ΔNp63α and ΔNp63γ—during normal skin wound healing in mice. Transcripts encoding amino‐terminally truncated ΔNp63 variants were found at high levels in basal and suprabasal keratinocytes of the hyperproliferative wound epithelium. Interestingly, TAp63 variants, which include the conserved transactivation domain TA at their amino‐terminus, were also expressed in wound keratinocytes as well as at the edge of the injured subcutaneous muscle panniculus carnosus. These findings suggest splice‐variant specific functions of p63 in reepithelialization and muscle repair.

Identification and tissue distribution of novel KET/p63 splice variants

The human p53 protein family comprises three members – p53, p63 and p73. Whereas only one p53 variant is known multiple isoforms of p63 and p73 have been described. Depending on the isoform p63 influences p53‐responsive genes in a p53‐like or ‐distinct manner. We have cloned multiple splice variants of keratinocyte transcription factor (KET), the rat ortholog of human p63. Several tissue specific variations of exon 1 resulting in different amino‐terminal ends were identified. Transactivation properties of the splice variants inversely correlated with the length of the N‐termini as determined by activation of the p53‐responsive p21 promotor. Multiple KET isoforms are colocalized in different rat tissues. The amino‐terminal truncated form ΔNKETα is expressed in epithelial tissues, while expression of the most p53‐like KET isotype TAKETγ was detected in skeletal muscle. Expression of a major KET variant appears to be a cell‐type specific rather than a differentiation specific phenomenon.

Interference-Free Proteome Quantification with MS/MS-based Isobaric Isotopologue Detection

Chemical labeling of peptides prior to shotgun proteomics allows relative quantification of proteins in biological samples independent of sample origin. Current strategies utilize isobaric labels that fragment into reporter ions. However, quantification of reporter ions results in distorted ratio measurements due to contaminating peptides that are co-selected in the same precursor isolation window. Here, we show that quantitation of isobaric peptide fragment isotopologues in tandem mass spectra reduces precursor interference. The method is based on the relative quantitation of isobaric isotopologues of dimethylated peptide fragments in tandem mass spectra following higher energy collisional dissociation (HCD). The approach enables precise quantification of a proteome down to single spectra per protein and quantifies >90% of proteins in a MudPIT experiment and accurately measures proteins in a model cell line for cystic fibrosis.

Deep interactome profiling of membrane proteins by co-interacting protein identification technology

Affinity purification coupled to mass spectrometry (AP–MS) is the method of choice for analyzing protein–protein interactions, but common protocols frequently recover only the most stable interactions and tend to result in low bait yield for membrane proteins. Here, we present a novel, deep interactome sequencing approach called CoPIT (co-interacting protein identification technology), which allows comprehensive identification and analysis of membrane protein interactomes and their dynamics. CoPIT integrates experimental and computational methods for a coimmunoprecipitation (Co-IP)-based workflow from sample preparation for mass spectrometric analysis to visualization of protein–protein interaction networks. The approach particularly improves the results for membrane protein interactomes, which have proven to be difficult to identify and analyze. CoPIT was used successfully to identify the interactome of the cystic fibrosis transmembrane conductance regulator (CFTR), demonstrating its validity and performance. The experimental step in this case achieved up to 100-fold-higher bait yield than previous methods by optimizing lysis, elution, sample clean-up and detection of interacting proteins by multidimensional protein identification technology (MudPIT). Here, we further provide evidence that CoPIT is applicable to other types of proteins as well, and that it can be successfully used as a general Co-IP method. The protocol describes all steps, ranging from considerations for experimental design, Co-IP, preparation of the sample for mass spectrometric analysis, and data analysis steps, to the final visualization of interaction networks. Although the experimental part can be performed in <3 d, data analysis may take up to a few weeks.