Synthesis, surface deposition and secretion of immunoglobulin M in bone marrow-derived lymphocytes before and after mitogenic stimulation

Alternative splicing: the pledge, the turn, and the prestige : The key role of alternative splicing in human biological systems

Alternative pre-mRNA splicing is a tightly controlled process conducted by the spliceosome, with the assistance of several regulators, resulting in the expression of different transcript isoforms from the same gene and increasing both transcriptome and proteome complexity. The differences between alternative isoforms may be subtle but enough to change the function or localization of the translated proteins. A fine control of the isoform balance is, therefore, needed throughout developmental stages and adult tissues or physiological conditions and it does not come as a surprise that several diseases are caused by its deregulation. In this review, we aim to bring the splicing machinery on stage and raise the curtain on its mechanisms and regulation throughout several systems and tissues of the human body, from neurodevelopment to the interactions with the human microbiome. We discuss, on one hand, the essential role of alternative splicing in assuring tissue function, diversity, and swiftness of response in these systems or tissues, and on the other hand, what goes wrong when its regulatory mechanisms fail. We also focus on the possibilities that splicing modulation therapies open for the future of personalized medicine, along with the leading techniques in this field. The final act of the spliceosome, however, is yet to be fully revealed, as more knowledge is needed regarding the complex regulatory network that coordinates alternative splicing and how its dysfunction leads to disease.

Cutting Edge: Absence of Expression of RAG1 in Peritoneal B-1 Cells Detected by Knocking into RAG1 Locus with Green Fluorescent Protein Gene

It has been proposed that Ig gene rearrangement in the peritoneal cavity (Pc) B-1 cells might be involved in autoantibody generation. To study possible secondary B cell maturation, we prepared mice carrying a target integration of gfp gene into a rag1 locus (rag1/gfp mice). The GFP+ cells express rag1 mRNA and are undergoing Ig gene rearrangement. RAG1 expression was studied in Pc B-1 cells to detect cells during the stage of Ig gene rearrangement. In contrast to previous reports, Pc B-1 cells did not show RAG1 expression in adolescent or elderly mice. RAG1 expression was not induced in Pc B-1 cells in vivo after stimulation by oral or i.p. administration of LPS. Our results suggest that RAG1 expression in Pc B-1 cells is inhibited for a long period under normal condition and that this suppression is an essential state which maintains allelic exclusion of Ig genes.

Recombinant interleukin 2 or 5, but not 3 or 4, induces maturation of resting mouse B lymphocytes and propagates proliferation of activated B cell blasts

Plasmacytoma transformants of the X63-Ag8-653 cell line carrying an expression vector with either IL-2, -3, -4, or -5 cDNA were established that secrete the corresponding ILs at high rates. The four mouse ILs (mILs) were then tested as single ILs and in combinations for their effects on the maturation of resting and proliferation of activated normal mouse splenic B cells. mIL-3 and mIL-4 were inactive in all assays. mIL-2, as well as mIL-5, synergized with Ig-specific antibodies and B cell growth factor alpha (BCGF-alpha) to stimulate successive rounds of B cell division with LPS-activated B cells. This activity as BCGF-beta was effective at concentrations similar to those at which mIL-2 induced proliferation of the CTL-L T cell line, indicating a high-affinity interaction of both mIL-2 and mIL-5 with their corresponding receptors on activated B cells. mIL-5 and maybe IL-2 also induced maturation of resting B cells to Ig-secreting cells without proliferation. This B cell maturation factor (BMF) activity of mIL-5 was as effective as its BCGF-beta activity, while the BMF activity of mIL-2 was at least 10(2)-fold less effective. BMF activity of mIL-2, but not mIL-5, was blocked by anti-Il-2-R antibodies, indicating that mIL-2 and mIL-5 use separate receptors for B cell signaling. mIL-2, as well as mIL-5, furthermore, acted as filler activities when proliferation in the presence of Ig-specific antibodies and BCGF-alpha was measured with as little as 500 B cells. In the case of mIL-5, this was also true for maturation of that few cells. Limiting dilution analyses showed that approximately 1-2% of the resting B cells matured without division, while 30-100-fold fewer cells (0.03-0.06%) proliferated and matured in response to IL-5. A single IL, therefore, is capable of inducing maturation and of stimulating mitotic cell cycle progression of normal B cells.

Mechanism of suppression of lipopolysaccharide-driven B cell differentiation by anti-mu antibodies. Evidence for a trans-acting repressor of transcription

Bivalent anti-mu antibodies suppress LPS-driven B cell differentiation by inhibiting the coordinate activation of a family of differentiation-related genes, including those encoding the heavy, light, and J chains of IgM. We have shown that the presence of inhibitors of RNA or protein synthesis during a pulse with anti-mu can interfere with induction of suppression. We suggest that suppression is mediated by a trans-acting repressor protein with specificity for common motifs in regulatory regions of each of these genes.

In situ hybridization of immunoglobulin-specific RNA in single cells of the B lymphocyte lineage with radiolabelled DNA probes

A method for in situ hybridization has been developed which detects immunoglobulin-specific mRNA transcripts in single murine B lymphocytes with radiolabelled, immunoglobulin gene-specific single-stranded DNA probes. The method has been applied to myeloma and hybridoma cells and to B lymphocytes at various stages of their maturation from small, resting B cells to Ig-secreting plasma cells. A critical step in the procedure is the treatment of the cells with pronase. The various cell types have been found to be differently susceptible to this treatment. Single-stranded DNA probes of different lengths, i.e., between 26 and 1000 bp, have been employed in the hybridization. The number of silver grains over a cell increases proportionally with the length of the probe and with its concentration in the hybridization reaction. The kinetics of the increase of mu-heavy chain-specific RNA molecules in single cells and the appearance of 'switched', gamma-heavy chain-expressing cells are shown after stimulation of murine B cells with lipopolysaccharide.

Effects of mycoplasma contamination on immunoglobulin biosynthesis by human B lymphoblastoid cell lines

The synthesis and secretion of immunoglobulin M (IgM), as well as the relative ratio of membrane and secretory mu heavy chain (mu m and mu s, respectively), were evaluated in mycoplasma-contaminated B lymphoblastoid cell lines. The ratio of mu m to mu s was drastically lowered in infected cultures, and mu s chains could now combine with light chains. A 50 to 100% increase in IgM synthesis occurred in contaminated cultures, and small amounts of IgM were detectable in the culture media. These molecules possessed mu chains typical of secreted IgM. Reexpression of mu on the surface of B lymphoblastoid cells was substantially delayed in mycoplasma-contaminated cultures. Thus, mycoplasma contamination alters the synthesis and expression of a specific differentiated gene product (immunoglobulin) in B cell lines; such changes could significantly affect the interpretation of data on immunoglobulin synthesis by B cells with different phenotypes. This system may also provide a means of studying how mycoplasma infection alters specific gene expression in B cell lines.

Induction of rheumatoid antibodies in the mouse. Regulated production of autoantibody in the secondary humoral response

A/J mice were found to produce autoreactive IgM anti-IgG1 in response to secondary immunization with a number of protein antigens. No anti-IgG1 was produced after a single such immunization, indicating that antigen: IgG1 antibody complexes were responsible for inducing the autoreactive response. The size of the anti-IgG1 response was in some cases massive and of the same order of magnitude as the response to the foreign immunizing material. No significant anti-IgG2a, anti-IgG2b, or anti-IgG3 response was found in mice producing anti-IgG1. Virtually all of the anti-IgG1 material produced was of the IgM class and bound to the Fc region of autologous IgG1. A component of the anti-IgG1 was shown to be able to distinguish between the two mouse IgG1 allotypes. These results suggest that self-reactive anti-IgG is a common component of the secondary immune response of mice that may have powerful physiological and immunoregulatory effects.

Allelic exclusion of immunoglobulin expression is not caused by somatic segregation

We have investigated the karyotype of immunoglobulin-producing cells in heterozygous animals. Using a karyotypic marker for one homolog of a chromosome carrying immunoglobulin genes, we established that immunoglobulin-producing cells are heterozygous with respect to this chromosome. Therefore, allelic exclusion of immunoglobulin expression cannot be caused by somatic chromosome segregation.

Synthesis and processing of the alpha heavy chains of secreted and membrane-bound IgA

We have compared the synthesis and processing of immunoglobulin alpha chains in two murine cell lines, a B cell lymphoma that expresses membrane-bound IgA and a hybridoma that secretes IgA. Results of biosynthetic labeling experiments demonstrated that membrane-bound and secreted alpha chains have two distinct intracellular precursors, of different molecular weights and isoelectric points. RNAs from both of these cell lines direct the synthesis in vitro of two alpha polypeptides of Mr 59,000 and 62,000, the larger one being the precursor for membrane-bound alpha chain and the smaller one being the precursor for secreted alpha chain. These cell lines each contain three RNAs, 1.7, 2.1, and 3.1 kilobases in length, which hybridize with cDNA for the alpha constant region and which are present in different concentrations. Our results suggest that the smallest RNA encodes the secreted alpha chain and one or both of the larger RNAs encode(s) the membrane-bound alpha chain.

Lymphocyte membrane IgG and secreted IgG are structurally and allotypically distinct

We have demonstrated that there are structurally distinct membrane and secreted IgG2a immunoglobulin molecules. The membrane heavy chain is both larger and more acidic than the secreted molecule. This difference is not a result of different N-glycosidic-linked oligosaccharide chains. The membrane heavy chain also is antigenically different from its secreted homologue. This is based on the fact that secreted IgG2a molecules express an allotypic determinant absent on membrane molecules. We discussed the genetic control and gene organization of membrane and secreted immunoglobulin heavy chain sequences and suggest mechanisms controlling the expression of the simian virus 40 genome as models for alternate gene expression of membrane and secreted heavy chain polypeptide chains from the same DNA sequence. The possible biological significance of the membrane immunoglobulin acting as a recognition site for regulatory T cells also is discussed. The difference between membrane and secreted immunoglobulin is proposed as a possible explanation for the manner in which T cells interact with IgG on memory B cells in the presence of a large excess of IgG present in body fluids.

Specific T helper cells that activate B cells polyclonally. In vitro enrichment and cooperative function

C3H/HeJ T cells which specifically recognize B cell-surface antigens of the related, major histocompatibility complex-compatible C3H/Tif strain, can be substantially enriched in vitro by long-term exposure (2--6 wk) of primed lymph node cells to the relevant cellular antigens. These enriched T cells contain functional helper cells as demonstrated by their capacity to induce large numbers of Ig-secreting plaque-forming cells (PFC) in cultures of antigenic B cells. The cooperative interaction results in activation of a large fraction of all splenic B cells, with consequent exponential growth and maturation to high rate secretion of IgM, IgG1, and IgG2, but not IgG3. The IgM PFC response includes antibody specificities to a number of different antigens and can be considered, therefore, as polyclonal. The T helper cell-dependent B-cell response is insensitive to inhibition by anti-delta antibodies, and in contrast with lipopolysaccharide-induced PFC responses, is only partially sensitive to the inhibitory effects of anti-mu antibodies. Finally, B-cell activation to growth and maturation by helper T cells strictly required direct T-cell recognition of antigens on the surface of responding B cells, leading us to the conclusions that if any soluble factors are generated in the collaborative process, they are either antigen specific or incompetent to initiate B-cell growth.

Mouse intracellular immunoglobulin M. Structure and identification of a free thiol group

Monomeric intracellular mouse immunoglobulin M (hereafter designated IgMs) was purified in milligram quantities from the plasma cells of mouse plasmacytoma MOPC 104E after lysis either in the presence or in the absence of iodoacetate. Peptide ;mapping' analysis of the IgMs after partial reduction and carboxy[(14)C]methylation to label the interchain disulphide bridges showed that the heavy-light bridge and the interheavy bridge present in the Cmu2 region were already formed at lysis. The cysteine residues in the C-terminal region of the heavy chains, which in pentameric IgM form an intersubunit bridge, had free thiol groups at lysis that were reversibly oxidized during isolation in the absence of iodoacetate, probably forming an intrasubunit inter-heavy-chain disulphide bridge. Isoelectric-focusing studies complemented the above findings, showing that all the intracellular IgMs carried free thiol groups that could be carboxymethylated at lysis, and that in non-alkylated preparations these had reversibly oxidized. On the basis of sodium dodecyl sulphate/polyacrylamide-slab-gel electrophoresis intracellular mu-chains had a consistently lower apparent molecular weight than did secreted mu-chains, and the estimated difference could be accounted for by the known difference in carbohydrate content. We present evidence that in a position homologous to that of a complex oligosaccharide in the Cmu2 region of secreted human mu-chains there is a simple oligosaccharide in intracellular mouse mu-chains that becomes complex on secretion. On the basis of the above findings, we present a model for the mouse intracellular IgM subunit and suggest a mechanism for its assembly into secreted IgM pentamers.

Optimal strategies in immunology. I. B-cell differentiation and proliferation

The optimal strategy available to the immune system for responding to a non-replicating thymus-independent antigen is examined. By applying Pontryagin's maximum principle to a set of mathematical models of lymphocyte populations and their antibody production, it is found that the optimal strategy of bang-bang control appears robust. In a variety of structurely related biological models, similar behaviour is observed. The models that we consider assume that antigen triggers a population of B-lymphocytes. These triggered lymphocytes can either proliferate and secrete modest amounts of antibody or differentiate into nondividing plasma cells which secrete large amounts of antibody. For biologically reasonable parameter values it is found that for low doses of antigen, immediate differentiation into plasma cells is optimal, while for high antigen doses a proliferative state followed by differentiation is the best strategy.

Cell surface immunoglobulin. XVIII. Functional differences of B lymphocytes bearing different surface immunoglobulin isotypes

Three populations of murine splenic B lymphocytes have been characterized previously (6, 7, 9) as those bearing only IgM, those bearing only IgD, and a population bearing both isotopes. These studies were designed to test the response of the IgM+ cells (IgM-only or IgM plus IgD) vs. the IgD-only cells to the B-cell mitogen, lipopolysaccharide. Results that after 1-4 days of culture, in the presence of mitogen, the IgM+ cells enlarge and elaborate an IgM polyclonal response. The IgD-only cells, in contrast, do not exhibit an IgM polyclonal response, but instead undergo blastogenesis and proliferation.

Immunoglobulin formation in B lymphoid cells

A considerable amount is known about Ig biosynthesis by mature plasma cells, which form large amounts of Ig for secretion from the cell. A brief summary is given of the formation of light (L) and heavy (H) chains by polyribosomes aligned on the endoplasmic reticulum and the rapid assembly of the chains into 7S molecules (H2L2) by disulphide bonding. There is a time-ordered secretion from the cell of 7S Ig molecules; the polymeric forms of Ig, ie, IgM and IgA, are formed from monomers by disulphide bond interchange and J chain incorporation at the time of secretion. Myeloma cells from mouse and man have proved very useful in this type of study but such malignant cells show many defects in regulatory mechanisms; therefore, no conclusions can be drawn about normal control mechanisms without analysis of lymphoid tissues from normal or immunized animals. The pattern of Ig synthesis by the mature cell contrasts with that by small B lymphocytes which form 1/50 to 1/100 the amount of Ig produced by mature cells. Most of the small lymphocyte Ig is associated with the cell surface, and in IgM-producing cells the surface receptors are 7S monomer subunits of IgM. Such receptors turn over slowly (24-48 hours); they may be gradually shed from the cell surface but the small lymphocyte does not actively secrete Ig. Antigen- and cell-cell interactions stimulate small B lymphocytes to divide and mature into Ig-secreting cells. Little is known about the associated intracellular events, but preliminary data on lipopolysaccaride-stimulated mouse spleen cells indicate that transcription of m-RNA for H-chain mirrors the kinetics of DNA synthesis. A translational block then occurs during cell maturation and there is a lag of at least 24 hours before Ig production rises sharply and reaches peak levels.

Membrane immunoglobulins of B lymphocytes: inability to detect certain characteristic IgM and IgD antigens

Hemagglutination and fluorescent antibody studies have provided strong evidence for the unavailability or absence of specific antigenic sites on membrane-bound IgM which are present in serum and intracellular IgM. Antisera specific for different parts of the molecule indicated that a portion but not all of the Fc was involved. Absorption experiments with normal and leukemic viable B lymphocytes failed to remove a population of Fc antibodies found in IgM-specific antisera. Similar findings were made for IgD, the other major membrane immunoglobulin of human peripheral blood B cells. Various interpretations of these observations are discussed. The most likely possibility appears that the C-terminal portion of the heavy chains of the immunoglobulin molecule is buried in the membrane.

IgM-producing tumors in the BALB-c mouse: a model for B-cell maturation

Five adjuvant induced BALB/c tumors producing IgM-McPc 1748, W 3469, TEPC 183, McPc 774, and Y 5781-were characterized morphologically by electron microscopy, analysis of the distribution of surface-bound and intracytoplasmic IgM using immunofluorescence, and by biochemical study of IgM synthesis, turnover, and secretion. The cells of different tumors appear to represent different stages in B-cell maturation when compared to normal, lipopolysaccharide-stimulated B cells. Thus, McPc 1748 tumor cells resemble 10-25-h stimulated normal B cells, 3469 cells resemble 20-35-h stimulated B cells, TEPC 183 cells resemble 45-65-h stimulated B cells, Y 5781 cells resemble 80-110-h stimulated B cells, and McPc 774 cells resemble 100-130-h stimulated B cells.

Cell surface immunoglobulin. IX. A new method for the study of synthesis, intracellular transport, and exteriorization in murine splenocytes

A new method for the detection of cell surface immunoglobulin labeled with isotopic precursors is described. The method consists of the aggregation of surface Ig on cells with specific antibody (heterologous) and the subsequent removal of antigen-antibody complexes by the combination of high speed centrifugation and immunoprecipitation of remaining soluble complexes using antibody to the heterologous Ig. Using this method, the kinetics of appearance of cell surface Ig and its turnover were studied in murine splenocytes. The results suggest that cell surface Ig is synthesized and transported in the same manner as secretory Ig rather than being synthesized on the plasma membrane. The turnover of intracellular and cell surface Ig in lymphocytes is slow. In contrast, intracellular Ig in plasma cells is rapidly secreted and usually without a cell surface phase. Cell surface Ig was shown to be radiolabeled with [(3)H]glucosamine, -galactose, and -fucose. The proportion of cell surface to intracellular (nonsurface) Ig labeled with these precursors suggests the same sequence of addition of sugars to Ig destined to be on the surface of lymphocytes as with Ig which will be secreted by plasma cells. Results with this new method also confirm earlier conclusions based on experiments using cell surface iodination: 8S IgM is the predominant Ig on the surface of murine splenocytes and the molecule appears to be attached by its micro-chains.

Cell surface immunoglobulin. VII. Synthesis, shedding, and secretion of immunoglobulin by lymphoid cells of germ-free mice

Lymphoid cells from the spleen, lymph nodes, and thoracic duct of axenic and control mice were incubated with [(3)H]tyrosine and synthesis and secretion of protein and Ig studied. It was found that only IgM was synthesized by cells from axenic mice whereas cells from control mice also synthesized IgG. Splenocytes from both axenic and control mice had 8S IgM on their surface. Radiolabeled splenocytes from axenic mice were incubated to determine the kinetics of release of (125)I-labeled cell surface IgM and [(3)H]tyrosine-labeled IgM. Cell surface IgM was shed as 8S with an initial half-life of release of 5-8 h whereas [(3)H]tyrosine-labeled Ig was secreted as 19S with an initial half-life of 2-3 h. These findings suggest that two independent pathways are involved. It is suggested that small lymphocytes shed 8S IgM and plasma cells secrete 19S IgM. It was observed that lymphoid cells from axenic mice synthesize a higher proportion of IgM relative to total protein. Electron microscopic examination of splenocytes from such mice revealed a markedly higher proportion of plasma cells and a paucity of lymphoblasts compared to controls. It was suggested, therefore, that axenic mice lack a population of stimulated T cells which can induce a switch from IgM to IgG synthesis and which is capable of suppressing IgM synthesis. Lymphoid cells from axenic mice synthesize and secrete less protein that coprecipitates with antigen-antibody complexes.

Induction of IgG by lipid A in the newborn mouse

IgG of paternal allotype first becomes detectable in the serum of (BALB/c x C57BL/6)F(1) mice between day 12 and 14 after birth and reaches adult levels at an age of 5 wk. Since in mice there is a transfer of maternal IgG molecules through the placenta and via milk, F(1) heterozygous at the allotype locus were used and the concentrations of IgG with paternal allotype were measured. This was done by a sensitive method capable of detecting IgG concentrations as low as 5 x 10(-4) of normal adult serum levels. It is based on the quantitative inhibition of allotype-specific facilitation of hemolysis. When lipid A or Salmonella bacteria were injected into neonatal mice, a stimulation of IgG synthesis was observed. Thus IgG levels were enhanced 10-30-fold compared to the nontreated mice. No increase in IgG levels was obtained in adult mice after treatment with lipid A. Whether the newborns were injected at birth, on day 2, 4, or 7, IgG was first demonstrable in the treated mice at an age of 6-11 days. The increase in IgG levels was not paralleled by a demonstrable antibody activity against lipid A, SRBC, and LPS. Thus the bulk of newly induced IgG is probably a statistical distribution of different specificities.