Identification and characterization of Magmas, a novel mitochondria-associated protein involved in granulocyte-macrophage colony-stimulating factor signal transduction.

OBJECTIVE: The aim of this study was to identify granulocyte-macrophage colony-stimulating factor (GM-CSF) responsive genes. MATERIALS AND METHODS: Potential GM-CSF responsive genes were identified by comparing the mRNA expression pattern of the murine myeloid cell line PGMD1 grown in either interleukin-3 (IL-3) or GM-CSF by differential display. Human and murine cDNA clones of one of the bands having increased expression in GM-CSF were isolated. mRNA expression of the gene was examined by Northern blot. Immunohistochemistry and studies with a green fluorescent fusion protein were used to determine its intracellular location. Growth factor-stimulated proliferation of PGMD1 cells transfected with constitutively expressed sense and anti-sense cDNA constructs of the gene was measured by 3H-thymidine incorporation. RESULTS: A gene, named Magmas (mitochondria-associated granulocyte macrophage CSF signaling molecule), was shown to be rapidly induced when cells were switched from IL-3 to GM-CSF. Analysis of the amino acid sequence of Magmas showed it contained a mitochondrial signal peptide, but not any other known functional domains. The human and murine clones encode nearly identical 13-kDa proteins that localized to the mitochondria. Magmas mRNA expression was observed in all tissues examined. PGMD1 cells that overexpressed Magmas proliferated similarly to untransfected cells when cultured in IL-3 or GM-CSF. In contrast, cells with reduced protein levels grew normally in IL-3, but had impaired proliferation in GM-CSF. CONCLUSION: Magmas is a mitochondrial protein involved in GM-CSF signal transduction.

A single H:CDR3 residue in the anti-digoxin antibody 26-10 modulates specificity for C16-substituted digoxin analogs.

We constructed Fab libraries of bacteriophage-displayed H:CDR3 mutants in the high-affinity anti-digoxin antibody 26-10 to determine structural constraints on affinity and specificity for digoxin. Libraries of mutant Fabs randomized at five or 10 contiguous positions were panned against digoxin and three C16-substituted analogs, gitoxin (16-OH), 16-formylgitoxin and 16-acetylgitoxin. The sequence data from 83 different mutant Fabs showed highly restricted consensus patterns at positions H:100, 100a and 100b for binding to digoxin; these residues contact digoxin in the 26-10:digoxin co-crystal structure. Several mutant Fabs obtained following panning on digoxin-BSA showed increased affinity for digoxin compared with 26-10 and retained the wild-type (wt) Trp at position 100. Those Fabs selected following panning on C16-substituted analogs showed enhanced binding to the analogs. Replacement of H:Trp100 by Arg resulted in mutants that bound better to the analogs than to digoxin. This specificity change was unexpected, as C16 lies on the opposite side of digoxin from H:CDR3. Substitution of wt Trp by Arg appears to alter specificity by allowing the hapten to shift toward H:CDR3, thereby providing room for C16 substituents in the region of H:CDR1.

Selection of peptidic mimics of digoxin from phage-displayed peptide libraries by anti-digoxin antibodies.

Since the initial report of the development of methodology to generate high-affinity digitalis-specific (digoxin) antibodies, these antibodies have proven extremely useful tools to monitor digoxin levels in digitalized patients and, as Fab fragments, to reverse toxic digoxin effects in life-threatening digoxin overdoses. These antibodies (both digoxin-specific and ouabain-specific) have been used extensively by investigators for the identification and characterization of putative endogenous digitalis-like factors. In this study, we used two well-characterized mouse anti-digoxin monoclonal antibodies (mAbs), designated 26-10 and 45-20, as binding templates with which to select short bacteriophage-displayed (pIII protein inserted) peptides that are capable of binding to these mAbs and mimicking the conformational structure of digoxin. Selective enrichment from two phage-displayed random peptide libraries enabled us to isolate and identify distinct 15 and 26 amino acid residue peptide inserts that bind with high avidity and idiotypic specificity to the selecting mAbs. Among these displayed inserts a subset was identified whose mAb binding is inhibited by digoxin and whose corresponding synthetic peptides inhibit phage binding. They, therefore, appear to bind at the mAbs digoxin-binding sites. These data provide the first clear evidence that short polypeptides can serve as surrogates for the low molecular mass hapten digoxin.

Structural requirements for a specificity switch and for maintenance of affinity using mutational analysis of a phage-displayed anti-arsonate antibody of Fab heavy chain first complementarity-determining region.

We previously showed that a single mutation at heavy (H) position 35 of Abs specific for p-azophenylarsonate (Ars) resulted in acquisition of binding to the structurally related hapten p-azophenylsulfonate (Sulf). To explore the sequence and structural diversity of the H chain first complementarity-determining region (HCDR1) in modulating affinity and specificity, positions 30-36 in Ab 36-65 were randomly mutated and expressed as Fab in a bacteriophage display vector. Ab 36-65 is germline encoded, lacking somatic mutations. Following affinity selection on Sulf resins, 55 mutant Fab were isolated, revealing seven unique HCDR1 sequences containing different amino acids at position H:35. All Fab bound Sulf, but not Ars. Site-directed mutagenesis in a variety of HCDR1 sequence contexts indicates that H:35 is critical for hapten specificity, independent of the sequence of the remainder of HCDR1. At H:35, Asn is required for Ars specificity, consistent with the x-ray crystal structure of the somatically mutated anti-Ars Ab 36-71, while Sulf binding occurs with at least seven different H:35 residues. All Sulf-binding clones selected following phage display contained H:Gly33, observed previously for Ars-binding Abs that use the same germline V(H) sequence. Site-directed mutagenesis at H:33 indicates that Gly plays an essential structural role in HCDR1 for both Sulf- and Ars-specific Abs.

Contribution of antibody heavy chain CDR1 to digoxin binding analyzed by random mutagenesis of phage-displayed Fab 26-10.

We constructed a bacteriophage-displayed library containing randomized mutations at H chain residues 30-35 of the anti-digoxin antibody 26-10 Fab to investigate sequence constraints necessary for high affinity binding in an antibody of known crystal structure. Phage were selected by panning against digoxin and three C-16-substituted analogues. All antigen-positive mutants selected using other analogues also bound digoxin. Among 73 antigen-positive clones, 26 different nucleotide sequences were found. The majority of Fabs had high affinity for digoxin (Ka 3.4 x 10(9) M-1) despite wide sequence diversity. Two mutants displayed affinities 2- and 4-fold higher than the parental antibody. Analysis of the statistical distribution of sequences showed that highest affinity binding occurred with a restricted set of amino acid substitutions at positions H33-35. All clones save two retained the parental Asn-H35, which contacts hapten and hydrogen bonds to other binding site residues in the parental structure. Positions H30-32 display remarkable diversity, with 10-14 different substitutions for each residue, consistent with high affinity binding. Thus complementarity can be retained and even improved despite diversity in the conformation of the N-terminal portion of the H-CDR1 loop.

Tissue-specific, developmental, hormonal, and dietary regulation of rat phosphoenolpyruvate carboxykinase-human growth hormone fusion genes in transgenic mice.

The cytosolic phosphoenolpyruvate carboxykinase (PEPCK) gene is expressed in multiple tissues and is regulated in a complex tissue-specific manner. To map the cis-acting DNA elements that direct this tissue-specific expression, we made transgenic mice containing truncated PEPCK-human growth hormone (hGH) fusion genes. The transgenes contained PEPCK promoter fragments with 5' endpoints at -2088, -888, -600, -402, and -207 bp, while the 3' endpoint was at +69 bp. Immunohistochemical analysis showed that the -2088 transgene was expressed in the correct cell types (hepatocytes, proximal tubular epithelium of the kidney, villar epithelium of the small intestine, epithelium of the colon, smooth muscle of the vagina and lungs, ductal epithelium of the sublingual gland, and white and brown adipocytes). Solution hybridization of hGH mRNA expressed from the transgenes indicated that white and brown fat-specific elements are located distally (-2088 to -888 bp) and that liver-, gut-, and kidney-specific elements are located proximally (-600 to +69 bp). However, elements outside of the region tested are necessary for the correct developmental pattern and level of PEPCK expression in kidney. Both the -2088 and -402 transgenes responded in a tissue-specific manner to dietary stimuli, and the -2088 transgene responded to glucocorticoid stimuli. Thus, different tissues utilize distinct cell-specific cis-acting elements to direct and regulate the PEPCK gene.

Differences in activities of murine retroviral long terminal repeats in cytotoxic T lymphocytes and T-lymphoma cells.

Transcriptional activities of the long terminal repeats (LTRs) of various murine leukemia viruses were tested in the cytotoxic T-cell lines CTLL-1 and CTLL-2. In contrast to T-lymphoma cells, in which the LTRs of T-lymphomagenic virus SL3-3 and Moloney murine leukemia virus are more active than those of other viruses, transcriptional activity in these mature, interleukin-2-dependent cells is not correlated with the specificity of viral leukemogenicity. Several approaches were used to investigate the molecular basis for LTR activity differences in lymphoma cells and mature cytotoxic T cells. Deletion analysis of the Moloney virus LTR showed that the direct repeats associated with enhancer activity have, at most, a slight effect on expression in CTLL-1 cells, whereas they stimulate expression six- to eightfold in T-lymphoma cells. This suggests that the mature T-cell line lacks one or more factors present in T-lymphoma cells that function to augment transcription from the Moloney murine leukemia virus LTR. We also used recombinant viral LTRs to investigate the role of the enhancer core element of SL3-3 in CTLL-1 and CTLL-2 cells. A one-base-pair difference between the core sequences of SL3-3 and nonleukemogenic Akv virus, which is important for SL3-3 activity in T-lymphoma cells, had no effect in these cells. The inability to distinguish the single-base-pair difference in expression assays was correlated with the absence of binding of a cellular factor, S-CBF, to the SL3-3 enhancer core in extracts of CTLL-1 and CTLL-2 nuclei. These studies may have implications for identification of the target cells for viral leukemogenesis, as well as for tracing of changes in the transcriptional machinery during T-lymphocyte differentiation.

Correlation of leukemogenic potential of murine retroviruses with transcriptional tissue preference of the viral long terminal repeats.

Recombination studies have established that retroviral long terminal repeats (LTRs) are important genetic determinants of the viral capacity to induce hematopoietic tumors and to specify the type of cell making up the tumor. Plasmids containing LTRs of several murine leukemia viruses linked to the chloramphenicol acetyltransferase gene were tested in transient assays to measure relative rates of transcriptional activity in different types of hematopoietic cells. LTRs of the thymomagenic viruses SL3-3, Moloney leukemia virus, and a Moloney mink cell focus-forming virus all expressed to higher levels than other LTRs in T-lymphocyte cell lines. Conversely, the LTRs of Friend leukemia virus and a polycythemic spleen focus-forming virus expressed to higher levels than other LTRs in erythroleukemia cells. The LTR of nonleukemogenic Akv virus induced a relatively low level of activity compared with the others in all cells tested. Thus the relative level of LTR-driven expression in various types of cells corresponds to the type of tumor caused by the intact virus in vivo. These results provide direct evidence that the tissue specificity of the transcriptional activity of LTRs plays a critical role in determining the target cell for retroviral oncogenesis.

Replicative properties of lipopolysaccharide-induced murine B lymphocytes: detection of three different responses to mitogenic restimulation.

A number of investigators have reached different conclusions regarding the proliferative behavior of murine B lymphocytes stimulated by lipopolysaccharide (LPS). We examined the replicative properties of LPS-stimulated splenic B cells in primary culture using a density transfer technique to detect DNA replication. The method selectively monitors those lymphocytes that synthesized DNA in a first division and determines whether their progeny undergo subsequent replication, providing information about the growth characteristics of the first generation of LPS-responsive cels. Three different proliferative responses were observed. In one type, the initial signal that stimulated parental cells to divide was perpetuated in their progeny in that daughter cell proliferation occurred in the absence of mitogen (19 to 37% of the parental cells, mode I). In another type of response, the proliferation of daughter cells depended on further exposure to mitogen (10 to 17% of the parental cells, mode II). In a third response, proliferation of daughter cells did not occur even in the presence of mitogen (54 to 64% of the parental cells, mode III). Three types of growth responses were also observed for Con A-stimulated T cells. A larger proportion of T cells, however, were restimulated to an additional round of DNA replication (40 to 55% of the cells, mode II) when compared to LPS-stimulated B cells. These in vitro growth responses suggest alternate pathways by which antigens may regulate immune reactions.