Christelle Bonod-Bidaud

Netrin-1 controls colorectal tumorigenesis by regulating apoptosis.

The expression of the protein DCC (deleted in colorectal cancer) is lost or markedly reduced in numerous cancers and in the majority of colorectal cancers due to loss of heterozygosity in chromosome 18q, and has therefore been proposed to be a tumour suppressor. However, the rarity of mutations found in DCC, the lack of cancer predisposition of DCC mutant mice, and the presence of other tumour suppressor genes in 18q have raised doubts about the function of DCC as a tumour suppressor. Unlike classical tumour suppressors, DCC has been shown to induce apoptosis conditionally: by functioning as a dependence receptor, DCC induces apoptosis unless DCC is engaged by its ligand, netrin-1 (ref. 3). Here we show that inhibition of cell death by enforced expression of netrin-1 in mouse gastrointestinal tract leads to the spontaneous formation of hyperplastic and neoplastic lesions. Moreover, in the adenomatous polyposis coli mutant background associated with adenoma formation, enforced expression of netrin-1 engenders aggressive adenocarcinomatous malignancies. These data demonstrate that netrin-1 can promote intestinal tumour development, probably by regulating cell survival. Thus, a netrin-1 receptor or receptors function as conditional tumour suppressors.

Development of a Functional Skin Matrix Requires Deposition of Collagen V Heterotrimers

ABSTRACT Collagen V is a minor component of the heterotypic I/III/V collagen fibrils and the defective product in most cases of classical Ehlers Danlos syndrome (EDS). The present study was undertaken to elucidate the impact of collagen V mutations on skin development, the most severely affected EDS tissues, using mice harboring a targeted deletion of the α2(V) collagen gene (Col5a2). Contrary to the original report, our studies indicate that the Col5a2 deletion (a.k.a. the pN allele) represents a functionally null mutation that affects matrix assembly through a complex sequence of events. First the mutation impairs assembly and/or secretion of the α1(V)2α2(V) heterotrimer with the result that the α1(V) homotrimer is the predominant species deposited into the matrix. Second, the α1(V) homotrimer is excluded from incorporation into the heterotypic collagen fibrils and this in turn severely impairs matrix organization. Third, the mutant matrix stimulates a compensatory loop by the α1(V) collagen gene that leads to additional deposition of α1(V) homotrimers. These data therefore underscore the importance of the collagen V heterotrimer in dermal fibrillogenesis. Furthermore, reduced thickness of the basement membranes underlying the epidermis and increased apoptosis of the stromal fibroblasts in pN/pN skin strongly indicate additional roles of collagen V in the development of a functional skin matrix.

Identification of binding partners interacting with the α1-N-propeptide of type V collagen.

The predominant form of type V collagen is the [α1(V)]₂α2(V) heterotrimer. Mutations in COL5A1 or COL5A2, encoding respectively the α1(V)- and α2(V)-collagen chain, cause classic EDS (Ehlers-Danlos syndrome), a heritable connective tissue disorder, characterized by fragile hyperextensible skin and joint hypermobility. Approximately half of the classic EDS cases remain unexplained. Type V collagen controls collagen fibrillogenesis through its conserved α1(V)-N-propeptide domain. To gain an insight into the role of this domain, a yeast two-hybrid screen among proteins expressed in human dermal fibroblasts was performed utilizing the N-propeptide as a bait. We identified 12 interacting proteins, including extracellular matrix proteins and proteins involved in collagen biosynthesis. Eleven interactions were confirmed by surface plasmon resonance and/or co-immunoprecipitation: α1(I)- and α2(I)-collagen chains, α1(VI)-, α2(VI)- and α3(VI)-collagen chains, tenascin-C, fibronectin, PCPE-1 (procollagen C-proteinase enhancer-1), TIMP-1 (tissue inhibitor of metalloproteinases-1), MMP-2 (matrix metalloproteinase 2) and TGF-β1 (transforming growth factor β1). Solid-phase binding assays confirmed the involvement of the α1(V)-N-propeptide in the interaction between native type V collagen and type VI collagen, suggesting a bridging function of this protein complex in the cell-matrix environment. Enzymatic studies showed that processing of the α1(V)-N-propeptide by BMP-1 (bone morphogenetic protein 1)/procollagen C-proteinase is enhanced by PCPE-1. These interactions are likely to be involved in extracellular matrix homoeostasis and their disruption could explain the pathogenetic mechanism in unresolved classic EDS cases.

DEFINITION OF A CONSENSUS DNA-BINDING SITE FOR THE ESCHERICHIA COLI PLEIOTROPIC REGULATORY PROTEIN, FRUR

The FruR regulator of Escherichia coli controls the initiation of transcription of several operons encoding a variety of proteins involved in carbon and energy metabolism. The sequence determinants of the FruR‐binding site were analysed by using 6× His‐tagged FruR and a series of double‐stranded randomized oligonucleotides. FruR consensus binding sites were selected and characterized by several consecutive rounds of the polymerase chain reaction‐assisted binding‐site selection method (BSS) using nitrocellulose‐immobilized DNA‐binding protein. FruR was demonstrated to require, for binding, an 8 bp left half‐site motif and a 3 bp conserved right half‐site with the following sequence: 5′‐GNNGAATC/GNT‐3′. In this sequence, the left half‐site AATC/ consensus tetranucleotide is a typical motif of the DNA‐binding site of the regulators of the GalR–LacI family. On the other hand, the high degree of degeneracy found in the right half‐site of this palindrome‐like structure indicated that FruR, which is a tetramer in solution, interacts asymmetrically with the two half‐sites of its operator. However, potentially FruR‐target sites showing a high degree of symmetry were detected in 13 genes/operons. Among these, we have focused our interest on the pfkA gene, encoding phosphofructokinase‐1, which is negatively regulated by FruR.

The Collagen V Homotrimer [α1(V) ] 3 Production Is Unexpectedly Favored over the Heterotrimer [α1(V)]2α2(V) in Recombinant Expression Systems

Collagen V, a fibrillar collagen with important functions in tissues, assembles into distinct chain associations. The most abundant and ubiquitous molecular form is the heterotrimer [α1(V)]2α2(V). In the attempt to produce high levels of recombinant collagen V heterotrimer for biomedical device uses, and to identify key factors that drive heterotrimeric chain association, several cell expression systems (yeast, insect, and mammalian cells) have been assayed by cotransfecting the human proα1(V) and proα2(V) chain cDNAs. Suprisingly, in all recombinant expression systems, the formation of [α1(V)]3 homotrimers was considerably favored over the heterotrimer. In addition, pepsin-sensitive proα2(V) chains were found in HEK-293 cell media indicating that these cells lack quality control proteins preventing collagen monomer secretion. Additional transfection with Hsp47 cDNA, encoding the collagen-specific chaperone Hsp47, did not increase heterotrimer production. Double immunofluorescence with antibodies against collagen V α-chains showed that, contrary to fibroblasts, collagen V α-chains did not colocalized intracellularly in transfected cells. Monensin treatment had no effect on the heterotrimer production. The heterotrimer production seems to require specific machinery proteins, which are not endogenously expressed in the expression systems. The different constructs and transfected cells we have generated represent useful tools to further investigate the mechanisms of collagen trimer assembly.

Ex vivo multiscale quantitation of skin biomechanics in wild-type and genetically-modified mice using multiphoton microscopy

Soft connective tissues such as skin, tendon or cornea are made of about 90% of extracellular matrix proteins, fibrillar collagens being the major components. Decreased or aberrant collagen synthesis generally results in defective tissue mechanical properties as the classic form of Elhers-Danlos syndrome (cEDS). This connective tissue disorder is caused by mutations in collagen V genes and is mainly characterized by skin hyperextensibility. To investigate the relationship between the microstructure of normal and diseased skins and their macroscopic mechanical properties, we imaged and quantified the microstructure of dermis of ex vivo murine skin biopsies during uniaxial mechanical assay using multiphoton microscopy. We used two genetically-modified mouse lines for collagen V: a mouse model for cEDS harboring a Col5a2 deletion (a.k.a. pN allele) and the transgenic K14-COL5A1 mice which overexpress the human COL5A1 gene in skin. We showed that in normal skin, the collagen fibers continuously align with stretch, generating the observed increase in mechanical stress. Moreover, dermis from both transgenic lines exhibited altered collagen reorganization upon traction, which could be linked to microstructural modifications. These findings show that our multiscale approach provides new crucial information on the biomechanics of dermis that can be extended to all collagen-rich soft tissues.

In vivo evidence for a bridging role of a collagen V subtype at the epidermis-dermis interface.

Collagen V is the defective product in most cases of classical Ehlers-Danlos syndrome (EDS), a connective tissue disorder typically characterized by skin fragility and abnormal wound healing. Collagen V assembles into diverse molecular forms. The predominant α1(V)(2)α2(V) heterotrimer controls fibrillogenesis in skin and other tissues. The α1(V)(3) minor form is thought to occur in skin, but its function is unknown. To elucidate its role, we generated transgenic mice that overexpress the human α1(V)(3) homotrimer in the epidermis. The transgene-derived product is deposited as thin unstriated fibrillar material in the basement membrane zone of embryonic and perinatal epidermis and hair follicles. Accumulation of α1(V)(3)-containing fibrils leads to ultrastructural modifications at the epidermis-dermis interface and provokes changes in biomechanical properties, although not statistically significant. Using superparamagnetic immunobeads to isolate authentic suprastructures and protein-binding assays, we demonstrate that the homotrimer is part of a protein network containing collagen IV, laminin-111, and the dermal collagen VI. Our data show that the homotrimer serves as a bridging molecule that contributes to the stabilization of the epidermal-dermal interface. This finding strongly suggests that collagen V may be expressed in skin as different subtypes with important but distinct roles in matrix organization and stability.

Overproduction, purification and structural characterization of the functional N-terminal DNA-binding domain of the fru repressor from Escherichia coli K-12

A DNA fragment encoding the DNA-binding domain (amino acids 1-60) of the Escherichia coli fru transcriptional regulator was cloned into the pGEX-KT vector and expressed in frame with the fused gene encoding glutathione S-transferase. The fusion protein was purified to homogeneity by affinity chromatography on immobilized glutathione, and then cleaved with thrombin. After separation by a cation-exchange chromatography step, the DNA-binding domain exhibited proper folding, as shown by proton NMR analysis. Furthermore, it showed specific interaction with the operator region of the ace operon, as checked by gel retardation and DNA methylation-protection experiments.

A novel microstructural interpretation for the biomechanics of mouse skin derived from multiscale characterization

Skin is a complex, multi-layered organ, with important functions in the protection of the body. The dermis provides structural support to the epidermal barrier, and thus has attracted a large number of mechanical studies. As the dermis is made of a mixture of stiff fibres embedded in a soft non-fibrillar matrix, it is classically considered that its mechanical response is based on an initial alignment of the fibres, followed by the stretching of the aligned fibres. Using a recently developed set-up combining multiphoton microscopy with mechanical assay, we imaged the fibres network evolution during dermis stretching. These observations, combined with a wide set of mechanical tests, allowed us to challenge the classical microstructural interpretation of the mechanical properties of the dermis: we observed a continuous alignment of the collagen fibres along the stretching. All our results can be explained if each fibre contributes by a given stress to the global response. This plastic response is likely due to inner sliding inside each fibre. The non-linear mechanical response is due to structural effects of the fibres network in interaction with the surrounding non-linear matrix. This multiscale interpretation explains our results on genetically-modified mice with a simple alteration of the dermis microstructure. STATEMENT OF SIGNIFICANCE Soft tissues, as skin, tendon or aorta, are made of extra-cellular matrix, with very few cells embedded inside. The matrix is a mixture of water and biomolecules, which include the collagen fibre network. The role of the collagen is fundamental since the network is supposed to control the tissue mechanical properties and remodeling: the cells attach to the collagen fibres and feel the network deformations. This paper challenges the classical link between fibres organization and mechanical properties. To do so, it uses multiscale observations combined to a large set of mechanical loading. It thus appears that the behaviour at low stretches is mostly controlled by the network structural response, while, at large stretches, the fibre inner-sliding dominate.

Caspase cleavage of the transcription factor FLI-1 during preB leukemic cell death

Programmed cell death (apoptosis) is a complex phenomenon that is mediated in mammals mainly via the selective cleavage of intracellular proteins by the large family of cysteine aspartate protease caspases. Apoptosis is tightly regulated by the competitive effect of numerous proteins displaying either pro-apoptotic or anti-apoptotic activity. The ETS-family transcription factor FLI-1, frequently associated with malignant transformation, has been shown to display anti-apoptotic activity in several cell types including avian erythroblasts, mouse fibroblasts or lymphoid cells. We show here that apoptosis of murine preB leukemic cells is accompanied with the specific cleavage of FLI-1 by a caspase-like activity. We also demonstrate that the two isoforms of FLI-1 are indeed cleaved at three conserved sites by caspase 3 in vitro. The conservation of these cleavage sites among species suggests that the caspase cleavage of the anti-apoptotic transcription factor FLI-1 may represent a critical step to ensure irreversible cell death.