Subproteomic analysis of metal-interacting proteins in human B cells.

Metal-protein interactions are vitally important in all living organisms. Metalloproteins, including structural proteins and metabolic enzymes, participate in energy transfer and redox reactions or act as metallochaperones in metal trafficking. Among metal-associated diseases, T cell mediated allergy to nickel (Ni) represents the most common form of human contact hypersensitivity. With the aim to elucidate disease-underlying mechanisms such as Ni-specific T cell activation, we initiated a proteomic approach to identify Ni-interacting proteins in human B cells. As antigen presenting cells, B cells are capable of presenting MHC-associated Ni-epitopes to T cells, a prerequisite for hapten-specific T cell activation. Using metal-affinity enrichment, 2-DE and MS, 22 Ni-interacting proteins were identified. In addition to known Ni-binding molecules such as tubulin, actin or cullin-2, we unexpectedly discovered that at least nine of these 22 proteins belong to stress-inducible heat shock proteins or chaperonins. Enrichment was particularly effective for the hetero-oligomeric TRiC/CCT complex, which is involved in MHC class I processing. Blue Native/SDS electrophoresis analysis revealed that Ni-NTA-beads specifically retained the complete protein machinery, including the associated chaperonin substrate tubulin. The apparent Ni-affinity of heat shock proteins suggests a new function of these molecules in human Ni allergy, by linking innate and adaptive immune responses.

Two-dimensional Blue native/SDS gel electrophoresis of multi-protein complexes from whole cellular lysates: a proteomics approach.

Identification and characterization of multi-protein complexes is an important step toward an integrative view of protein-protein interaction networks that determine protein function and cell behavior. The limiting factor for identifying protein complexes is the method for their separation. Blue native PAGE (BN-PAGE) permits a high-resolution separation of multi-protein complexes under native conditions. To date, BN-PAGE has only been applicable to purified material. Here, we show that dialysis permits the analysis of multi-protein complexes of whole cellular lysates by BN-PAGE. We visualized different multi-protein complexes by immunoblotting including forms of the eukaryotic proteasome. Complex dynamics after gamma interferon stimulation of cells was studied, and an antibody shift assay was used to detect protein-protein interactions in BN-PAGE. Furthermore, we identified defined protein complexes of various proteins including the tumor suppressor p53 and c-Myc. Finally, we identified multi-protein complexes via mass spectrometry, showing that the method has a wide potential for functional proteomics.

Importance of class II transactivator leucine-rich repeats for dominant-negative function and nucleo-cytoplasmic transport.

Class II transactivator (CIITA), the master regulator of MHC class II (MHC-II) gene transcription, shows a complex behavior in terms of self-association, nucleo-cytoplasmic transport and MHC-II gene transactivation. Here, we analyzed the mechanisms of dominant-negative function and nucleo-cytoplasmic transport of CIITA with emphasis on the role of the C-terminal leucine-rich-repeat (LRR) region in these processes. First, we determined nucleo-cytoplasmic transport of endogenous CIITA and thus validated results obtained with epitope-tagged CIITA constructs. LRR mutations in potential protein-protein contact positions lead to either completely blocked or reduced nuclear import, but can also give rise to increased nuclear export. Surprisingly, N-terminally truncated CIITA mutants show dominant-negative inhibition of wild-type CIITA, whether they are located in the nucleus or in the cytoplasm. Integrity of the LRR is necessary for the dominant-negative function of both types of mutants. LRR mutations are dominant over the effect of an exogenously added N-terminal nuclear localization signal (NLS) leading to cytoplasmic localization. Taken together, our results show that the LRR regulate the function of one or several NLS within CIITA, and control both nuclear import and export. Self-association is not affected in these mutants; we therefore suggest that interaction of the LRR with an unknown protein partner may be necessary for import and transactivation function of CIITA.

N-terminal destruction signals lead to rapid degradation of the major histocompatibility complex class II transactivator CIITA.

Major histocompatibility complex (MHC) class II molecules play an essential role for the cellular immune response by presenting peptide antigens to CD4(+) T cells. MHC class II molecules and genes show a highly complex expression pattern, which is orchestrated through a master regulatory factor, called CIITA (class II transactivator). CIITA controls MHC class II expression not only qualitatively, but also quantitatively, and has therefore a direct influence on the CD4 T cell-dependent immune response. CIITA is itself tightly regulated not only on the transcriptional level, but as we show here also on the protein level. CIITA is subjected to a very rapid protein turnover and shows a half-life of about 30 min. Inhibition of degradation by proteasome inhibitors and the identification of ubiquitylated CIITA intermediates indicate that the degradation of CIITA is mediated by the ubiquitin-proteasome system. We identified two regions mediating degradation within the N-terminal domain of CIITA. N-terminal fusions or deletions stabilized CIITA, indicating that the N termini contribute to degradation. Several non-functional CIITA mutants are partially stabilized, but we provide evidence that transcriptional activity of CIITA is not directly linked to degradation.

Characterization of NADH dehydrogenases of Pseudomonas fluorescens WCS365 and their role in competitive root colonization.

The excellent-root-colonizing Pseudomonas fluorescens WCS365 was selected previously as the parental strain for the isolation of mutants impaired in root colonization. Transposon mutagenesis of WCS365 and testing for root colonization resulted in the isolation of mutant strain PCL1201, which is approximately 100-fold impaired in competitive tomato root colonization. In this manuscript, we provide evidence that shows that the lack of NADH dehydrogenase I, an enzyme of the aerobic respiratory chain encoded by the nuo operon, is responsible for the impaired root-colonization ability of PCL1201. The complete sequence of the nuo operon (ranging from nuoA to nuoN) of P. fluorescens WCS365 was identified, including the promoter region and a transcriptional terminator consensus sequence downstream of nuoN. It was shown biochemically that PCL1201 is lacking NADH dehydrogenase I activity. In addition, the presence and activity of a second NADH dehydrogenase, encoded by the ndh gene, was identified to our knowledge for the first time in the genus Pseudomonas. Since it was assumed that low-oxygen conditions were present in the rhizosphere, we analyzed the activity of the nuo and the ndh promoters at different oxygen tensions. The results showed that both promoters are up-regulated by low concentrations of oxygen and that their levels of expression vary during growth. By using lacZ as a marker, it was shown that both the nuo operon and the ndh gene are expressed in the tomato rhizosphere. In contrast to the nuo mutant PCL1201, an ndh mutant of WCS365 appeared not to be impaired in competitive root tip colonization.