Sample preparation of bronchoalveolar lavage fluid.

Respiratory diseases are important health problem throughout the world. The bronchoalveolar lavage (BAL) fluid obtained by fiber-optic bronchoscopy is a biofluid reflecting the expression of secreted pulmonary proteins and the products of activated cells. The characterization of the BALF proteome provides an opportunity to establish diagnostic and get prognostic indicators of airway diseases. The main part of the chapter is devoted to the description of the most effective and reliable method of BALF sample preparation and processing for proteomic studies. Principal BALF proteome characteristics and the difficulties to work with this fluid are also introduced. Finally, the best conditions for high resolution and high reliability 2-dimensional electrophoresis (DE) of BALF samples are given.

Identification and characterization of new protein chemoattractants in the frog skin secretome.

The vomeronasal organ is a chemosensory organ present in most vertebrates and involved in chemical communication. In the last decade, the deciphering of the signal transduction process of this organ has progressed. However, less is known about the vomeronasal organ ligands and their structure-function relationships. Snakes possess a highly developed vomeronasal system that is used in various behaviors such as mating, predator detection, or prey selection, making this group a suitable model for study of the vomeronasal chemoreception. In this work, we used a proteomics approach to identify and characterize proteins from frog cutaneous mucus proteome involved in prey recognition by snakes of the genus Thamnophis. Herein we report the purification and characterization of two proteins isolated from the frog skin secretome that elicit the vomeronasal organ-mediated predatory behavior of Thamnophis marcianus. These proteins are members of the parvalbumin family, which are calcium-binding proteins generally associated to muscular and nervous tissues. This is the first report that demonstrates parvalbumins are not strictly restricted to intracellular compartments and can also be isolated from exocrine secretions. Purified parvalbumins from frog muscle and mucus revealed identical chemoattractive properties for T. marcianus. Snake bioassay revealed the Ca(2+)/Mg(2+) dependence of the bioactivity of parvalbumins. So parvalbumins appear to be new candidate ligands of the vomeronasal organ.

Global analysis of the Ralstonia metallidurans proteome: prelude for the large-scale study of heavy metal response.

A proteome map of Ralstonia metallidurans strain CH34 was constructed using two-dimensional (2-D) gel electrophoresis in combination with automated Edman degradation and mass spectrometry (MS). R. metallidurans CH34 is the type-strain of a family of highly related strains characterized by their multiple resistance to millimolar amounts of heavy metals, conferred by two large plasmids. The protein content of this bacterium grown in minimal medium was separated by 2-D gel electrophoresis using various pH gradients. Protein identification was carried out via N-terminal amino acid sequencing, matrix assisted laser desorption/ionisation-time of flight-mass spectrometry (MALDI-TOF-MS) and tandem MS. So far, 224 different proteins were characterized from 352 protein spots. Although the proteome map is still not complete, one could appraise the importance of proteomics for genome analyses through (i). the identification of previously undetected open reading frames, (ii). the identification of proteins not encoded by the already sequenced genome fragments, (iii). the characterization of protein-encoding genes spanning two different contigs, enabling their merging, and (iv). the precise delineation of the N-terminus of several proteins. Finally, this map will prove a useful tool in the identification of proteins differentially expressed in the presence of different heavy metals.

Lung hyperpermeability, Clara-cell secretory potein (CC16), and susceptibility to ozone of five inbred strains of mice.

Clara-cell protein (CC16), the predominant protein secreted by bronchiolar Clara cells, increasingly appears to protect the respiratory tract against oxidative stress and inflammation. The aim of this study was to test in inbred strains of mice whether the lung susceptibility to O3 correlates with the transepithelial leakage of CC16, with the mRNA and protein levels of CC16, and possibly with specific isoforms of the protein in the respiratory tract. Five strains of mouse with increasing sensitivity to O3 (C3H, AKR, SJL, CBA, and C57Bl) were exposed to 1.8 ppm O3 for 3 h and examined at 0 and 6 h postexposure. The most sensitive (C57Bl) and resistant (C3H) mice were also continuously exposed to 0.11 ppm O3 for up to 3 days. Lung injury was evaluated by measuring in bronchoalveolar lavage fluid (BALF) the levels of total protein, albumin, lactate dehydrogenase (LDH), and inflammatory cells. The patterns of proteins in BALF were also analyzed by two-dimensional electrophoresis (2-DE). Exposure to 1.8 or 0.11 ppm O3 caused a transient elevation of CC16 in serum that was maximal immediately after exposure and closely correlated with the extent of lung injury evaluated by BALF markers. The epithelial damage assessed on the basis of serum CC16 or BALF markers showed an inverse relation with the preexposure levels of CC16 in BALF. Since preexposure levels of CC16 mRNA were similar between the strains and since lung epithelium damage was also negatively correlated with preexposure levels of albumin in BALF, these findings identify basal lung epithelium permeability as a determinant of susceptibility to O3. The 2-DE mapping of proteins in BALF of these two strains revealed the existence of two distinct isoforms of CC16 with pI values of 4.9 and 5.2. The most acidic form was significantly less concentrated in the C57Bl strain, the most sensitive to O3, a difference that might be related to the higher permeability of the lung epithelium or to some post-transcriptional variations. In conclusion, these results suggest that the permeability of the lung epithelial barrier may be an important determinant of the lung susceptibility to O3, controlling the intrapulmonary levels of CC16 and possibly of other antioxidant/inflammatory proteins.

Susceptibility to oxidative stress: proteomic analysis of bronchoalveolar lavage from ozone-sensitive and ozone-resistant strains of mice.

Previous studies have shown that the pulmonary response to ozone (O(3)) varies greatly among strains of mice, but the factor(s) and the mechanism(s) that are responsible for this differential susceptibility have not yet been clearly identified. The present study explores the molecular bases for this differential O(3) susceptibility by studying the expression of proteins associated to the epithelial lining fluid (ELF) from two strains of mice, C57BL/6J and the C3H/HeJ, respectively described as O(3)-sensitive and O(3)-resistant. The ELF proteins of these two strains were displayed by two-dimensional gel electrophoresis (2-DE) of bronchoalveolar lavage fluids (BALFs) and the protein patterns obtained with BALF samples of both strains were compared. Two major differences were observed between the BALF 2-DE protein maps obtained from C57BL/6J and C3H/HeJ strains. First, two isoforms of the antioxidant protein 2 (AOP2) were detected in a strain-dependent manner: C3J/HeJ possesses only AOP2a (isoelectric point 5.7) and C57BL/6J exhibits only AOP2b (isoelectric point 6.0). Second, the levels of anti-inflammatory and immunosuppressive Clara cell protein-16 (CC16) were 1.3 times higher in the BALF from resistant C3H/HeJ than from sensitive C57BL/6 mice. Moreover, two 6 kDa isoforms of CC16 with isoelectric points of 4.9 (CC16a) and 5.2 (CC16b) are detected in both strains. Interestingly, the C57BL/6J strain had a twice decreased level of the acidic isoform of CC16 compared to C3H/HeJ. Our results suggest that AOP2 and CC16 might participate in the protection of the pulmonary tract to O(3)-induced lung injury. The possible differential contribution of specific protein isoforms in the differential susceptibility to oxidative stress is discussed.

Eubacterial HslV and HslU subunits homologs in primordial eukaryotes.

ATP-dependent protease complexes are present in all three kingdoms of life, where they rid the cell of misfolded or damaged proteins and control the level of certain regulatory proteins. They include the proteasome in Eukaryotes, Archea, and Actinomycetales and the HslVU (ClpQY) complex in other eubacteria. We showed that genes homologous to eubacterial HslV (ClpQ) and HslU (ClpY) are present in the genome of trypanosomatid protozoa and are expressed. The features of the cDNAs indicated that bona fide trypanosomatid messengers had been cloned and ruled out bacterial contamination as the source of the material. The N-terminal microsequence of HslV from Leishmania infantum (Protozoa: Kinetoplastida) permitted the identification of the propeptide cleavage site and indicated that an active protease is present. High similarities (> or =57.5%) with the prototypical HslV and HslU from Escherichia coli and conservation of residues essential for biochemical activity suggested that a functional HslVU complex is present in trypanosomatid protozoa. The structure of the N-termini of HslV and HslU further suggested mitochondrial localization. Phylogenetic analysis indicated that HslV and HslU from trypanosomatids clustered with eubacterial homologs but did not point to any particular bacterial lineage. Because typical eukaryotic 20S proteasomes are present in trypanosomatids, we concluded that the eubacterial HslVU and the eukaryotic multicatalytic protease are simultaneously present in these organisms. To our knowledge this is the first report of a eubacterial HslVU complex in eukaryotes and, consequently, of the simultaneous occurrence of both a proteasome and HslVU in living cells.

Database of bronchoalveolar lavage fluid proteins.

Bronchoalveolar lavage during fiberoptic bronchoscopy is extensively used for investigating cellular and biochemical alterations of the epithelial lining fluid in various lung disorders. Two-dimensional electrophoresis (2-DE) offers the possibility to simultaneously display and analyze proteins contained in bronchoalveolar lavage fluid (BALF). We present the current status of 2-DE of BALF samples with an updated listing of the proteins already identified and of their level and/or posttranslational alterations in lung disorders. Alternatives to 2-DE of BALF samples and future prospects of proteomics to unravel lung functions and pathologies are discussed.