Paul Falmagne

Proteomics as the tool to search for lung disease markers in bronchoalveolar lavage

Most lung disorders are known to be associated to considerable modifications of surfactant composition. Numerous of these abnormalities have been exploited in the past to diagnose lung diseases, allowing proper treatment and follow-up. Diagnosis was then based on phospholipid content, surface tension and cytological features of the epithelial lining fluid (ELF), sampled by bronchoalveolar lavage (BAL) during fiberoscopic bronchoscopy. Today, it appears that the protein content of ELF displays a remarkably high complexity, not only due to the wide variety of the proteins it contains but also because of the great diversity of their cellular origins. The significance of the use of proteome analysis of BAL fluid for the search for new lung disease marker proteins and for their simultaneous display and analysis in patients suffering from lung disorders has been examined.

Localization in diphtheria toxin fragment B of a region that induces pore formation in planar lipid bilayers at low pH

Like diphtheria toxin and the N‐terminal (M r 23 000) region of fragment B, CB1 (M r 13 000), the cyanogen bromide peptide located in the middle region of fragment B is able to induce pore formation in lipid bilayer membrane at low pH. These two peptides (M r 23 000 and 13 000) share a common segment (M r 6300) containing the predicted amphipathic, α‐helical, transverse lipid‐associating domain (M r 2750) of fragment B[J. Cell Biol. (1980) 87, 837–840]. Therefore, we postulated this domain to be responsible for the pore formation ability of diphtheria toxin [Proc. Natl. Acad. Sci. USA (1981) 78, 172–176]. A relationship between the pH dependency of pore formation and the presence of a cluster of prolines in the C‐terminal region of CB1 is proposed.

Diphtheria toxin induces fusion of small unilamellar vesicles at low pH

Model membrane systems such as phospholipid vesicles have been extensively used to study the mechanism of membrane fusion at the molecular level. We report here on the capacity of diphtheria toxin to induce fusion of small unilamellar vesicles of dipalmitoylphosphatidylcholine at low pH. Fluorescence polarization and differential scanning calorimetry make it possible to demonstrate the mixing of the lipid phase. Mixing of the internal aqueous compartments of liposome was established using the terbium fluorescence technique. The analogy of structure and properties between melittin and a diphtheria toxin fragment is discussed.

Evolutionary relationships among bacterial carbamoyltransferases

An immunological approach was used for the study of ornithine carbamoyltransferase (OTCase) evolution in bacteria. Antisera were prepared against the anabolic and catabolic OTCases of Pseudomonas aeruginosa and Aeromonas formicans as well as against OTCase and putrescine carbamoyltransferases from Streptococcus faecalis; these antisera were then tested against the unpurified OTCases, either anabolic or catabolic, of 34 bacterial strains. Extensive cross-reactions were observed between the antisera to catabolic OTCases from P. aeruginosa, A. formicans and S. faecalis and the catabolic enzymes from other species or genera. These antisera cross-reacted also with the anabolic OTCases of strains of the Enterobacteriaceae but not with the anabolic OTCases of the same species or of other species or genera. The cross-reaction measured between the antisera against P. aeruginosa anabolic OTCase and the anabolic OTCases of other Pseudomonas were largely in agreement with the phylogenic subdivision of Pseudomonas proposed by N. J. Palleroni. The correlation was also significantly higher with the anabolic enzyme of an archaeobacterium, Methanobacterium thermoaceticum, than with the catabolic or anabolic OTCases from other genera in the eubacterial line. The antiserum raised against A. formicans anabolic OTCase was quite specific for its antigen and appeared to be raised against the heaviest of the various oligomeric structures of the enzyme.

Tetanus toxin induces fusion and aggregation of lipid vesicles containing phosphatidylinositol at low PH

We report here on the ability of tetanus toxin to induce, at low pH, fusion and aggregation of lipid vesicles containing phosphatidylinositol. It has been shown that diphtheria toxin is internalized in acidic vacuoles (endosomes) and that the low endosomal pH could induce a protein conformational change responsible for the interaction with the endosomal membranes and the toxin translocation into the cytoplasm. The data here reported indicate that tetanus toxin might interact with lipid membrane in a similar way as diphtheria toxin suggesting for the two proteins an identical mechanism of entry into cells.

The complete amino acid sequence of diphtheria toxin fragment B. Correlation with its lipid-binding properties.

The complete amino acid sequence of fragment B from diphtheria toxin has been determined. The polypeptide chain was split with cyanogen bromide, o-iodosobenzoic acid, clostripain and trypsin; all amino acid sequence analyses were made by automated Edman degradation. Fragment B, which corresponds to the carboxy terminus of the toxin molecule, contains 342 amino acids and has an Mr of 37240. The proposed amino acid sequence fully confirms the structure recently deduced from the nucleotide sequence of the structural gene. The complete sequence is analyzed in relationship with the role of fragment B in the transfer of diphtheria toxin fragment A from the extracellular medium into the cell cytoplasm.

Isolation and characterization of the cyanogen bromide peptides from the B fragment of diphtheria toxin.

Homogeneous fragment B, obtained through nicking of diphtheria toxin with insoluble trypsin, was cleaved with cyanogen bromide in 70% formic acid. After citraconylation, the cleavage products were separated by gel filtration on Sephadex G--75 and purified by gel filtration, ion-exchange and thin-layer or paper chromatography. Six CNBr peptides were characterized, the composition of which account for the total amino acid content of fragment B. Their apparent molecular weights are: CB 1, 12 000; CB 2, 14 000; CB 3, 8000; CB 4a, 2400; CB 4b, 2200; CB 5, 2200. CB 4a is the NH2--terminal peptide; it contains the cysteine residue of the disulfide bridge linking fragment B to fragment A. CB 3 is the COOH--terminal peptide; it bears the disulfide bridge of fragment B. Characterization of two CNBr--derived overlapping peptides provided the positioning of CB 4b and CB 2 and allowed an alignment of the CNBr peptides of fragment B to be proposed.

Demonstration of estrogen receptors and of estrogen responsiveness in the HKT-1097 cell line derived from diethylstilbestrol-induced kidney tumors

SummaryThis study was undertaken in order to examine the estrogen sensitivity of HKT-1097, an established cell line recently derived from diethylstilbestrol (DES)-induced kidney tumors in Syrian hamsters. Estrogen receptor (ER) level in HKT-1097, determined by enzyme-linked immunoassay, was 67 fmol/mg protein, i.e., a value approx. 30% lower than that found in Syrian hamster kidney tumors. ER immunostaining in cells fixed with Carnoys mixture, as well as ER demonstration by Western blotting, suggested DES-induced nuclear translocation or stabilization of the receptor within the nucleus. Kinetic parameters of estrogen binding to ER in HKT-1097 cells were 8.4×10−11M and 60.8 fmol/mg protein for Kd and Bmax, respectively. The Kd of estrogen binding to ER in HKT-1097 was close to that evaluated for the receptor in breast cancer-derived MCF-7 cell line, whereas the Bmax value was approx. seven times lower in HKT-1097 as compared to MCF-7. In HKT-1097 cells, antiestrogens ICI 182,780 and RU 58,668 induced ER downregulation and competed with estrogen binding to the receptor. As demonstrated by Western blot analysis, DES exposure led to an increased expression of progesterone receptor (PgR) in HKT-1097 cells. Addition of DES to estrogen-free medium produced a stimulation of growth in both HKT-1097 and MCF-7 cells, but the mitogenic effect was less marked for HKT-1097. Despite the fact that ICI 182,780 and RU 58,668 clearly interact with HKT-1097 cell ER, they appeared unable to suppress DES-induced stimulation of growth and increase of PgR expression.

Secondary structure changes of diphtheria toxin interacting with asolectin liposomes: an infrared spectroscopy study

Until now, the study of the secondary structure of diphtheria toxin (DT) in the presence of phospholipid vesicles as a function of the pH has been prevented by the optical turbidity of the solution. In the present paper, this problem has been overcome by the use of IR attenuated total reflection (IR-ATR) spectroscopy. Incubation of DT with asolectin liposomes at pH 7.3 results in the binding of DT on to the liposomes and in a 10% increase in its alpha-helix content. At pH 4, in the presence of asolectin liposomes, the secondary structure of DT is characterized by the appearance of a beta-sheet structure with strengthened hydrogen bonds, which did not exist before lowering of the pH. This new type of beta-sheet (low frequency beta-sheet) involves 25% of the amino acid residues of the protein.

A CNBR peptide located in the middle region of diphtheria toxin fragment B induces conductance change in lipid bilayers: Possible role of an amphipathic helical segment

Abstract Conductance measurements on planar lipid bilayers demonstrate that CB1, a CNBr peptide of diphtheria toxin fragment B located in its middle region, possesses the unique property to destabilize the lipid bilayer organization. It is suggested that a segment of 25 amino acids in the N-terminal sequence of CB1 could be responsible for this effect. Its very low polarity, its predicted amphipathic helical structure and a helix length corresponding to the thickness of the hydrocarbon region of the lipid bilayer should specifically favor its insertion in the membrane. The existence of such a transverse lipid-associating domain could confer upon the molecule the properties leading to the anchoring of diphtheria toxin in the cytoplasmic membrane.