Pre-B cell receptor-mediated selection of pre-B cells synthesizing functional mu heavy chains.

Ig gene rearrangements could generate V(H)-D-J(H) joining sequences that interfere with the correct folding of a mu-chain, and thus, its capability to pair with IgL chains. Surrogate light (SL) chain might be the ideal molecule to test the capacity of a mu-chain to pair with a L chain early in development, in that only pre-B cells that assemble a membrane mu-SL complex would be permitted to expand and further differentiate. We have previously identified two SL chain nonpairing V(H)81X-mu-chains with distinct V(H)-D-J(H) joining regions. Here, we show that one of these V(H)81X-mu-chains does not rescue B cell development in J(H) knock-out mice, because flow cytometric analysis of bone marrow cells from V(H)81X-mu transgenic J(H) knock-out mice revealed normal numbers of pro-B cells, but essentially no pre-B and surface IgM+ B cells. Immunoprecipitation analysis of transfected pre-B and hybridoma lines revealed that the same mu-chain fails to pair not only with SL chain but also with four distinct kappa L chains. These findings demonstrate that early pre-B cells are selected for maturation on the basis of the structure of a mu-chain, in particular its V(H)-D-J(H) joining or CDR3 sequence, and that one mechanism for this selection is the capacity of a mu-chain to assemble with SL chain. Therefore, we propose a new function of SL chain in early B cell development: SL chain is part of a quality control mechanism that tests a mu-chain for its ability to pair with conventional L chains.

Surrogate light chain-dependent selection of Ig heavy chain V regions.

Bone marrow B cell precursors frequently rearrange the Ig heavy chain variable (VH) gene segment VH81X. It is puzzling, therefore, that mature B cells in adult mice rarely express mu-heavy chains bearing this VH gene segment. We show in this work in transformed pre-B cell lines that two VH81X/mu-chains that differ in their VH-D-JH joining sequences are not assembled covalently with the B cell precursor-specific surrogate light (SL) chain and are not expressed on the cell surface. From these findings, we propose that a B cell precursor clonally expands and proceeds to the next developmental stage only if it expresses a mu-chain with a VH domain that, together with the SL chain, directs the formation of a signal-transducing mu/SL chain membrane complex. Therefore, a checkpoint exists early in B cell development, at which SL chain not only screens B cell precursors for the presence of a full-length mu-chain, but also for a VH domain that promotes the assembly of a mu/SL chain complex.

Sequence of the rabbit glyceraldehyde-3-phosphate dehydrogenase-encoding cDNA.

Two full-length cDNA clones encoding rabbit glyceraldehyde-3-phosphate dehydrogenase (GAPDH) were isolated from a lambda gt10 rabbit spleen cDNA library and sequenced. As predicted from the open reading frame (ORF) in vitro translation of a sense orientation GAPDH cDNA clone yielded a protein product with a molecular mass of 37 kDa. Rabbit GAPDH exhibits a high degree of homology to the mouse, rat, hamster, chicken and human GAPDH on both the nucleotide (nt) and amino acid (aa) levels.

Differential effects of transferrin receptor antibodies on growth and receptor expression of human lymphocytic and myelocytic cell lines.

J64, a monoclonal antibody against the human transferrin receptor, has been shown to induce interleukin-2 production by HUT78 cells. It also causes growth inhibition of several cell lines and stimulated lymphocytes. These effects were also present using transferrin-free culture conditions. In this paper, we dissect cell membrane and intracellular events after binding of J64 and other transferrin receptor antibodies. Incubation of HUT78 and several other cell lines with J64 resulted in an increased number of receptor molecules expressed on the cell surface in contrast to a downmodulation seen with other monoclonal antibodies to the transferrin receptor. This upregulation after treatment with J64 was not due to an increased concentration of transferrin receptor mRNA in these cells or a higher protein synthesis rate. We therefore suggest that J64 causes a redistribution of transferrin receptor molecules from intracellular pools to the cell surface. Additional experiments investigating signal transduction mechanisms revealed no influence of J64 on intracellular Ca2+ concentrations or translocation of protein kinase C. However, an increase of transferrin receptor phosphorylation was seen in HL60 cells after treatment with phorbolester or J64. This phosphorylation of the transferrin receptor might be a signal transduction pathway involved in activation and growth control.

The role of the transferrin receptor for the activation of human lymphocytes.

The proliferative response of peripheral blood mononuclear cells (PBMC) in synthetic serum-free media depends on the presence of sufficient amounts of transferrin (Tf). In the present communication we show that the reduction of Tf concentration in culture media results in a decreased proliferation, whereas lymphokine production and the expression of activation markers (IL-2 receptor; transferrin receptor, (TfR); HLA class II) remain unchanged. To examine whether this effect is due to iron depletion we added iron chelates (ferric citrate, FeCi; ferric nitrilotriacetic acid, FeNTA) which can be internalized by cells without the requirement for Tf. The iron chelates could fully restore the proliferative response even in complete absence of Tf, suggesting that the observed inhibitory effect was indeed caused by iron depletion. Addition of a monoclonal TfR antibody, J 64, also caused a marked inhibition of proliferation of PBMC in regular serum-containing medium as well as in Tf-free synthetic medium; this effect could not be overcome by any of the tested iron chelates. Therefore, growth inhibition caused by J 64 cannot simply be attributed to iron starvation. These data suggest that J 64 may interfere with processes others than iron uptake and that the TfR might confer a necessary promoting signal for lymphocyte proliferation.