Axel Ducret

Identification of proteins by capillary electrophoresis-tandem mass spectrometry evaluation of an on-line solid-phase extraction device

Capillary electrophoresis-tandem mass spectrometry has been used successfully for the analysis of complex peptide mixtures. The method is limited by a relatively high concentration limit of detection and by matrix effects. Here we describe on-line coupling of a solid-phase microextraction device to a capillary electrophoresis-tandem mass spectrometry system. The performance of the integrated instrument was evaluated for the identification of proteins by their amino acid sequence. We report that the concentration limit of detection was improved at least 1000 fold to the low attomole/microliter range and that matrix effects were minimized by extensive sample clean-up during solid-phase extraction. We demonstrate that the implementation of a solid-phase extraction device significantly enhances capillary electrophoresis-tandem mass spectrometry as a method for the identification of low abundance proteins isolated from high-resolution two-dimensional polyacrylamide gels.

Red algal LHC I genes have similarities with both Chl a/b- and a/c-binding proteins: A 21 kDa polypeptide encoded by LhcaR2 is one of the six LHC I polypeptides

Polypeptides from the PS I holocomplex of the red alga P. cruentum, purified for microsequencing, confirmed that six LHC I polypeptides from SDS-PAGE are distinct apoproteins. Analysis of a cDNA clone, designated as LhcaR2, from a cDNA library, indicates that it shares major structural features with the recently cloned first red algal gene LhcaR1. The LhcaR2 is believed to encode the 21.0 kDa polypeptide of the LHC I complex from comparison of the deduced amino acid sequence and the microsequences of several tryptic digest fragments from the isolated polypeptide. As in chlorophytic and chromophytic LHCs, the essential residues for Chl-binding and helix stabilization in helices 1 and 3 are highly conserved. Relatedness between rhodophytes and the chlorophytes is also inferred from sequence conservation in the N-flanking regions of helices 1 and 3. Conversely, helix 2 exhibited the highest similarity between LHC sequences of Chl a/c-binding chromophytes and the Chl a-binding rhodophytes, with 11 of 22 residues identical or conservatively substituted. Moreover, whereas in chlorophytes, the Q and E Chl-binding residues are separated by seven amino acid residues, they are always separated by 8 residues in rhodophytes and chromophytes. Superimposition of the predicted LhcaR2 sequence with the LHC II model [Kühlbrandt et al. (1994) Nature 367: 614–621] shows the same structural features except shortened connecting sequence between helices 1 and 2 on the lumenal side. The chimeric nature of rhodophyte genes, with both chromophytic and chlorophytic features, leads to the suggestion that they reflect attributes of an intermediate stage in LHC apoprotein evolution.

High-Sensitivity Detection of 4-(3-Pyridinylmethylamino-carboxypropyl) Phenylthiohydantoins by Capillary Liquid Chromatography–Microelectrospray Ion Trap Mass Spectrometry

We describe the separation and detection at the low-femtomole level of 4-(3-pyridinylmethylaminocarboxypropyl) phenylthiohydantoins (311-PTHs) by capillary liquid chromatography–microelectrospray ion trap mass spectrometry. Highest sensitivity was obtained in the multiple-ion monitoring operating mode in which we detected 311-PTHs at the 5-fmol level with a signal-to-noise ratio of approximately 10. We investigated the fragmentation patterns of the isobaric 311-PTH isoleucine and 311-PTH leucine by electrospray ionization ion trap tandem mass spectrometry. The compounds could be differentiated by a fragment ion of mass m/z=366.1 which was specific for the breakdown of 311-PTH leucine, thus allowing for the unambiguous identification of the 311-PTH derivatives of all 20 naturally occurring amino acids by their masses and fragmentation patterns.

Axonal Proteins Involved in Myelination: Characterization of a Collagen-Like Protein

An anti-axolemma monoclonal antibody, designated G21.3, has been isolated in order to understand molecular mechanisms involved in myelination. Both biochemical and morphological studies showed that the monoclonal antibody inhibits myelin production by oligodendrocytes in cerebellar slice cultures. On Western blots of axolemma preparations, the antibody recognized 140- and 120-kD proteins. The present study involves the isolation and characterization of the G21.3 antigen. The G21.3-immunoreactive proteins of 140 and 120 kD were purified from the adult rat sciatic nerve and amino acid sequencing of these proteins revealed significant homology to alpha I and alpha II chains of collagen type I. Biochemical and Western blot analysis using pure collagen, collagen I antibody and collagenase D suggest that the antigen isolated from sciatic nerve is collagen. However, immunofluorescence studies using the G21.3 antibody, collagen I antibody, collagenase D and Northern blot analysis using a collagen probe do not fully support the view that the G21.3 antigen in the CNS is also a collagen. We conclude that the G21.3 antigen is a collagen-like protein involved in CNS myelination.

Characterization of an Axonal Protein Involved in Myelination

The mechanisms controlling myelination at the cellular level are not fully understood. Myelin is formed by an ordered process whereby the myelinating cell, the oligodendroglia in the central nervous system (CNS) and the Schwann cell in the peripheral nervous system (PNS), produces and extends membranous extensions which envelop axonal processes. Studies on peripheral nerve regeneration have indicated that axons are the major regulator of myelin protein gene expression by Schwann cells (Politis et al. 1982). On the other hand, oligodendroglia are capable of myelin membrane lipid and protein synthesis in the absence of neuronal signals in vitro (Poduslo, 1978; Mirsky et al. 1980; Szuchet et al. 1980; Poduslo et al. 1982; Bradel and Prince, 1983; Bressler et al. 1983; Rome et al. 1986), suggesting differences between the PNS and the CNS in the myelination process. Although some of the signals for myelination reside within the oligodendroglia itself or can be replaced by environmental cues (Knapp et al. 1987) present in the cultures, there are several reports of neuronal influences on oligodendroglial proliferation and differentiation both in vivo and in vitro (Hardy and Reynolds 1993).