Critical evaluation of phosphate solubilizing pseudomonads isolated from a partially recultivated potash tailings pile.

Ten phosphate solubilizing pseudomonads isolated from a partially recultivated potash tailings pile in Germany were characterized and tested for their potential to assist in the ongoing recultivation process. Despite fertilization, the plants which are grown for recultivation show phosphate deficiency symptoms, and therefore the isolates are intended to be used as biofertilizer inoculants. On agar plates incubated at five different temperatures, some of the strains showed a temperature-dependent ability to solubilize tricalcium phosphate, while others performed the same at any given temperature. In liquid medium, the isolates solubilized between 271 and 730 µg ml(-1) of phosphate from tricalcium phosphate. Both the weakest (designated S10) and the strongest solubilizing strain (S06) were further tested for their viability during solubilization. In an assay over the course of 1 week, both strains released their maximum amount of phosphate after 2-4 days. At that later point of time, however, viable cells of isolate S06 were no longer detectable, whereas the weaker strain S10 could be cultured after 1 week in broth. Taking all in vitro observations into account, the usability of the isolates as biofertilizers is critically discussed regarding both the in situ conditions on the tailings pile and the lowered viability due to the excess production of organic acids.

The high biofilm-encoding Bee locus: a second pilus gene cluster in Enterococcus faecalis?

An Enterococcus faecalis mutant strain with a reduced ability for biofilm formation and primary attachment when compared to the high biofilm-forming wild-type strain was characterized by molecular biological and proteomic approaches. A point mutation in the srt-1 gene, which encodes a sortase-type enzyme and is part of the recently described bee (biofilm enhancer in Enterococcus) gene cluster, could be identified in the mutant strain. The Srt-1 deficiency resulted in a loss of the Bee-2 protein within a high molecular weight complex in cell surface protein extracts, as determined by mass spectrometry. These findings strongly suggest a specific linkage of Bee-2 to Bee-1 and Bee-3 within a complex by Srt-1. Furthermore, the identification of specific pilin motifs conserved in surface proteins of gram-positive bacteria indicated a possible involvement of the bee genes in the formation of pili structures, and may thus play a role in enhancing biofilm formation in Enterococcus faecalis.

CDw50 and ICAM-3: two names for the same molecule.

CDw50 differentiation antigen is a molecule broadly expressed on hematopoetic cells but not on other cells. Previous experiments showed that CDw50 monoclonal antibodies (mAb) inhibited primary mixed lymphocyte culture (MLC). To understand the function of CDw50 better, we purified it and obtained peptide sequence. At the same time, intercellular adhesion molecule (ICAM)-3, the third ligand of lymphocyte function-associated molecule 1, was described by mAb and subsequent cDNA cloning. Immunochemical, functional, and protein sequencing studies show that ICAM-3 and CDw50 are the same glycoprotein, a 120-kDa surface molecule with presumably an important role in the immune responses.

The gamma subunit of the B cell antigen-receptor complex is a C-terminally truncated product of the B29 gene.

The predominant Ag-receptor complex of B cells consists of mIgM or mIgD noncovalently associated with glycosylated heterodimers of Ig-alpha and Ig-beta or Ig-alpha and Ig-gamma. Upon B cell stimulation the associated proteins are phosphorylated, giving rise to pp32/33 (alpha), pp37 (beta), and pp34 (previously designated gamma). Ig-alpha and Ig-beta contain extended cytoplasmic structure (61 and 48 amino acids, respectively) and associate with cytoplasmic effectors indicating that they are directly involved in signal transduction. Here we report analysis of the structural relationship of mIgM- and mIgD-associated Ig-beta and Ig-gamma chains from mice. N-terminal sequence, immunoblotting, and physicochemical analyses show that both Ig-beta and Ig-gamma are products of the B cell-specific B29 gene and demonstrate that the 37-kDa Ig-beta protein is the full length predicted product of the B29 gene. The Ig-associated protein that migrates in the 34-kDa range is actually two distinct species. The minor species is a phosphorylatable and underglycosylated form of full length Ig-beta, and the major species is a C-terminally truncated form of B29, which we now designate Ig-gamma. This conclusion is based on the observations that Ig-gamma is composed of a core protein which is 3 to 4 kDa smaller than deglycosylated Ig-beta, it is not phosphorylated, unlike Ig-beta, and it does not react with an antiserum raised against a peptide of the seven C-terminal amino acids of B29. Based on these findings we estimate that Ig-gamma is truncated by about 30 to 36 amino acid residues and hypothesize that the most 3' B29 exon, which encodes the 32 C-terminal residues, may not be expressed in Ig-gamma. All of the documented B29 products are found in association with both mIgM and mIgD. Interestingly, Ig-gamma is found in intermediate and low density splenic B cells, but is not detectable in resting B cells. This raises the possibility that it may confer some distinct signaling function on the Ag receptors of these cells.

Human pre-B and B cell membrane mu-chains are noncovalently associated with a disulfide-linked complex containing a product of the B29 gene.

B cell activation after Ag binding to membrane Ig (mIg) is mediated by a complex series of events that involves proximal activation of a tyrosine kinase and phospholipase C. Until recently it was unclear how mIgM and mIgD, with their limited cytoplasmic domains (three amino acids on each H chain), were able to couple to these secondary signal transducers. Studies of murine B cells conducted in several laboratories, including our own, suggest that products of the mb-1 (IgM-alpha or IgD-alpha) and B29 (Ig-beta, Ig-gamma) genes occur as disulfide-linked alpha/beta and alpha/gamma heterodimers that are noncovalently associated with mIgM and mIgD. Although studies utilizing Daudi and Raji cell lines indicate that human mIgM is also associated with a dimer containing the mb-1 gene product, the other molecules associated with the human receptor have not been identified. In this report we characterize the phosphoproteins that are noncovalently associated with mIgM on human tonsillar B cells and human pre-B cell lines. mIgM is noncovalently associated with a disulfide-linked heterodimer composed of variably glycosylated forms of two core proteins with apparent molecular mass of 26.5 and 27 kDa. Western blotting analysis reveals that the lower m.w. component of each of the mIgM-associated heterodimers and its 27-kDa deglycosylated core protein are reactive with antibodies against the murine B29 gene product. Thus, a product of the B29 gene is a component of the AgR complex in human and murine B cells, occurring as a disulfide linked dimer with product(s) of the mb-1 gene. Interestingly, mb-1 and B29 gene products expressed on human cells are much more heterogenously N-glycosylated than their murine B cell counterparts.

The complete amino-acid sequence of the heavy chain of the human myeloma protein WIE, an immunoglobulin D.

The human myeloma protein WIE is a lambda-type immunoglobulin D; the amino-acid sequence of its Fc part and aminoethylated heavy chain was completely determined. The VH-part (subgroup III) begins N-terminally with 5-oxoproline, and it contains a long, unique CDR3 region. Since the constant part differs from known delta chains by one amino-acid substitution in the hinge region, IgD WIE probably represents an allotypic variant. As in other protein delta chains, O-glycosylations are confined to the hinge region. Furthermore, the ratios of N-glycosylations at the three positions are identical in IgD WAH [Takahashi, N. et al. (1984) J. Chromatogr. 317, 11-26.] and IgD WIE (100%, 50%, 100%). From the most conserved constant domain, C delta 3, a three-dimensional model was constructed to clarify the role of its delta-specific substitutions and glycosylation.

IgM antigen receptor complex contains phosphoprotein products of B29 and mb-1 genes.

Membrane immunoglobulin M (mIgM) and mIgD are major B-lymphocyte antigen receptors, which function by internalizing antigens for processing and presentation to T cells and by transducing essential signals for proliferation and differentiation. Although ligation of mIgM or mIgD results in rapid activation of a phospholipase C and a tyrosine kinase(s), these receptors have cytoplasmic tails of only three amino acid residues (Lys-Val-Lys), which seem ill suited for direct physical coupling with cytoplasmic signal transduction structures. In this report, we identify the alpha, beta, and gamma components of the mIgM-associated phosphoprotein complex, which may play a role in signal transduction. Proteolytic peptide mapping demonstrated that the IgM-alpha chain differs from Ig-beta and Ig-gamma. The chains were purified, and amino-terminal sequencing revealed identity with two previously cloned B-cell-specific genes. One component, IgM-alpha, is a product of the mb-1 gene, and the two additional components, Ig-beta and Ig-gamma, are products of the B29 gene. Immunoblotting analysis using rabbit antibodies prepared against predicted peptide sequences of each gene product confirmed the identification of these mIgM-associated proteins. The deduced sequence indicates that these receptor subunits lack inherent protein kinase domains but include common tyrosine-containing sequence motifs, which are likely sites of induced tyrosine phosphorylation.