Molecular analysis of immunoglobulin expression in variants of murine B lymphoma, 70Z/3

The IkappaB kinase complex and NF-kappaB act as master regulators of lipopolysaccharide-induced gene expression and control subordinate activation of AP-1

Toll-like receptors (TLRs) recognize conserved products of microbial pathogens to initiate the innate immune response. TLR4 signaling is triggered upon binding of lipopolysaccharides (LPS) from gram-negative bacteria. Using comparative gene expression profiling, we demonstrate a master regulatory role of IkappaB kinase (IKK)/NF-kappaB signaling for immediate-early gene induction after LPS engagement in precursor B cells. IKK/NF-kappaB signaling controls a large panel of gene products associated with signaling and transcriptional activation and repression. Intriguingly, the induction of AP-1 activity by LPS in precursor B cells and primary dendritic cells fully depends on the IKK/NF-kappaB pathway, which promotes expression of several AP-1 family members, including JunB, JunD, and B-ATF. In pre-B cells, AP-1 augments induction of a subset of primary NF-kappaB targets, as shown for chemokine receptor 7 (CCR7) and immunoglobulin kappa light chain. Thus, our data illustrate that NF-kappaB orchestrates immediate-early effects of LPS signaling and controls secondary AP-1 activation to mount an appropriate biological response.

Novel NEMO/IkappaB kinase and NF-kappa B target genes at the pre-B to immature B cell transition

The IkappaB kinase (IKK) signaling complex is responsible for activating NF-kappaB-dependent gene expression programs. Even though NF-kappaB-responsive genes are known to orchestrate stress-like responses, critical gaps in our knowledge remain about the global effects of NF-kappaB activation on cellular physiology. DNA microarrays were used to compare gene expression programs in a model system of 70Z/3 murine pre-B cells versus their IKK signaling-defective 1.3E2 variant with lipopolysaccharide (LPS), interleukin-1 (IL-1), or a combination of LPS + phorbol 12-myristate 13-acetate under brief (2 h) or long term (12 h) stimulation. 70Z/3-1.3E2 cells lack expression of NEMO/IKKgamma/IKKAP-1/FIP-3, an essential positive effector of the IKK complex. Some stimulated hits were known NF-kappaB target genes, but remarkably, the vast majority of the up-modulated genes and an unexpected class of repressed genes were all novel targets of this signaling pathway, encoding transcription factors, receptors, extracellular ligands, and intracellular signaling factors. Thirteen stimulated (B-ATF, Pim-2, MyD118, Pea-15/MAT1, CD82, CD40L, Wnt10a, Notch 1, R-ras, Rgs-16, PAC-1, ISG15, and CD36) and five repressed (CCR2, VpreB, lambda5, SLPI, and CMAP/Cystatin7) genes, respectively, were bona fide NF-kappaB targets by virtue of their response to a transdominant IkappaBalphaSR (super repressor). MyD118 and ISG15, although directly induced by LPS stimulation, were unaffected by IL-1, revealing the existence of direct NF-kappaB target genes, which are not co-induced by the LPS and IL-1 Toll-like receptors.

Differentiation of murine pre-B cell line by an adjuvant muramyl peptide via NF-kappa B activation

Muramyl dipeptide (MDP) induces NF-kappa B activation in the murine pre-B cell line 70Z/3, increases the expression of surface immunoglobulins, and potentiates the response to other inducers such as LPS or IL-1. In the present study we investigated whether NF-kappa B activation was related to the MDP-stimulated immunoglobulin expression. In a gel shift assay our results confirmed that MDP but not MDP(D,D), an adjuvant-inactive stereoisomer, could induce a kappa B-binding activity in 70Z/3 cells. The LPS or IL-1 induced NF-kappa B binding activity was increased in the presence of MDP but not of MDP(D,D). A mutant of the cell line called 1.3E2, defective in NF-kappa B activations by LPS, did not respond to MDP. The enhanced surface immunoglobulin expression induced in the wild type 70Z/3 cells by MDP alone or combined to LPS, IL-1 or IFN gamma was not obtained in this variant. The ability of various treatments to activate the kappa gene enhancer was quantitatively evaluated in cells transfected with a kappa-enhancer-luciferase expression plasmid. Treatment of transfected 70Z/3 cells with MDP resulted in a dose-dependent enhancement of luciferase activity, an additive effect to that induced by LPS or IL-1. Treatment of the defective variant transfected with the same construct did not result in luciferase expression after stimulation with the various agents. The transient transfection assays were used to compare the effectiveness of some MDP analogs. Two adjuvant-active compounds unable to enhance kappa light chain expression did not increase the basal response in the transfected 70Z/3 cells, indicating that NF-kappa B activation was not related to the adjuvant potency of MDP but correlated with the kappa induction.

Diphosphoryl lipid A from Rhodobacter sphaeroides transiently activates NF-kappa B but inhibits lipopolysaccharide induction of kappa light chain and Oct-2 in the B-cell lymphoma line 70Z/3

Lipopolysaccharide (LPS) is implicated in much of the pathophysiology associated with gram-negative septic shock. One approach to this serious clinical problem is to develop new drugs that antagonize the action of toxic LPS. A model system to study LPS action and test for potential antagonists is readily provided by LPS regulation of the kappa gene in the murine B-cell line 70Z/3. Rhodobacter sphaeroides diphosphoryl lipid A (RsDPLA) effectively blocked toxic LPS induction of kappa light-chain immunoglobulin expression in 70Z/3 cells. Induction of kappa expression by LPS is dependent on the activation of at least two transcription factors, Oct-2 and NF-kappa B. RsDPLA completely repressed the long-term activation of NF-kappa B observed after 24 h of Salmonella typhosa LPS treatment and antagonized activation of oct-2 mRNA expression. However, RsDPLA was not an inert competitor of LPS. RsDPLA alone strongly activated NF-kappa B binding activity by 30 min but not beyond 9 h of treatment. It also induced a small increase in oct-2 mRNA levels. RsDPLA is not simply a weak agonist; we found no graded increase in kappa expression with increasing RsDPLA concentrations up to 50 micrograms/ml. The NF-kappa B complexes activated by RsDPLA and S. typhosa LPS were both composed of the p50-p65 heterodimer. These results suggest that the physiological LPS receptor(s) on B cells transmits qualitatively different signals depending on the nature of the binding ligand and that the fatty acyl groups of LPS play an important role in activating signal transduction.

Two different IFN-gamma nonresponsive variants derived from the B-cell lymphoma 70Z/3

The kappa immunoglobulin (Igk) light chain locus is transcriptionally silent in the mouse B-cell lymphoma 70Z/3. However, exposure to lipopolysaccharide (LPS) or interferon-gamma (IFN) causes a marked increase in Igk transcription. By immunoselection, we isolated two variants that are nonresponsive to IFN. One variant, AT7.2, has retained its response to LPS (IFN-LPS+), whereas the other, AT3.3, is also nonresponsive to LPS (IFN-LPS-). Stable transfection of an intact Igk gene does not rescue the phenotype of either variant. Both variants have intact Igk genes and neither is deficient in the binding or uptake of IFN. Nuclear extracts from LPS-treated wild-type 70Z/3 cells show strong increases in three transcription factors: OTF-2, NF-kappa B, and kBF-A. Remarkably, when the IFN-LPS- variant is treated with LPS, all three transcription factors are still observed in the nuclear extracts. Treatment of wild-type cells with either LPS or IFN also causes a decrease in nuclear complexes that bind to two other regions of the Igk intron enhancer, the octenh and the E kappa MHCIC regions. Both of these changes are also observed after LPS or IFN treatment of the IFN-LPS- variant. Thus, this variant transduces the IFN and LPS signals at least into the nuclear compartment, but still fails to activate Igk transcription. In contrast, the IFN-LPS+ variant decreases neither the octenh nor the E kappa MHCIC binding complexes in response to IFN. This variant may be defective in transducing the IFN signal to the nucleus. These variants will be useful in studying the activation of Igk transcription and the IFN signaling pathway in B cells.

Interferon-gamma arrests proliferation and causes apoptosis in stromal cell/interleukin-7-dependent normal murine pre-B cell lines and clones in vitro, but does not induce differentiation to surface immunoglobulin-positive B cells

Normal pre-B cells from fetal liver or bone marrow of the mouse proliferate for long periods of time in tissue culture on stromal cells in the presence of interleukin-7 (IL-7). Their IgH loci are partly in germ-line, partly in DHJH-rearranged configuration, while their light chain loci are in germ-line configuration. They express the pre-B cell-specific genes VpreB and lambda 5. Proliferation of these pre-B cells is inhibited by interferon (IFN)-gamma, with half-maximal inhibition at concentrations between 0.1 and 1 unit/ml. Normal pre-B cells exposed to IFN-gamma die by apoptosis, as is evidenced by the disintegration of pre-B cell DNA into oligonucleosomal multimers of 180-200 bp. While the proliferation of pre-B cells from E mu-bcl-2 transgenic (tg) mice is inhibited by IFN-gamma, these cells do not die by apoptosis. IFN-gamma does not induce differentiation to more mature B lineage cells. In the absence of IL-7 normal pre-B cells differentiate to VHDHJH/VLJL-rearranged, surface immunoglobulin-positive B cells expressing the alpha chain of the IL-2 receptor. They also down-regulate the expression of VpreB and lambda 5, and lose the capacity to proliferate on stromal cells in the presence of IL-7. In contrast, both normal and E mu-bcl-2 tg pre-B cells exposed to IFN-gamma in the presence of stromal cells and IL-7 fail to differentiate, i.e. do not express surface immunoglobulin, retain expression of VpreB and lambda 5, do not express the alpha chain of the IL-2 receptor, and retain the capacity to proliferate on stromal cells in the presence of IL-7, once IFN-gamma is removed. The potential usefulness of a treatment of acute lymphocytic leukemia of the B cell lineage (pre B-ALL) with IFN-gamma is discussed.

Examination of B lymphoid cell lines for membrane immunoglobulin-stimulated tyrosine phosphorylation and src-family tyrosine kinase mRNA expression

Crosslinking of membrane immunoglobulin (mIg) on B cells induces two signal transduction pathways: protein tyrosine phosphorylation and phosphoinositide turnover. A panel of murine and human B cell-lines, representing different stages of B cell development, was examined for the presence of anti-immunoglobulin-induced protein tyrosine phosphorylation. Of 10 B cell lines examined, only one, the human Raji cell line, had no detectably induced protein tyrosine phosphorylation. The pattern of proteins that were phosphorylated on tyrosine in response to mIg crosslinking differed somewhat in cell lines representing different stages of B cell development. Differences in the levels of constitutive phosphorylation of proteins were also observed between the cell lines. The identity of the tyrosine kinase(s) activated by membrane immunoglobulin ligation is not known. However, members of the src family of intracellular tyrosine kinases have been implicated as signal transduction molecules. As the tyrosine phosphorylation of proteins is a general phenomenon of signal transduction by membrane immunoglobulin, the tyrosine kinase(s) activated by it might be expected to be present in all cell lines in which the tyrosine phosphorylation signalling occurs. Therefore we examined these B cells for expression of mRNAs encoding the eight known src-like tyrosine kinases. Surprisingly, all eight kinase mRNAs were expressed in at least some of the B cell lines examined. The expression pattern of the fyn, hck, and lck genes suggests that expression of these kinases may be developmentally regulated in the B cell lineage. Three of the kinases, p55blk, p53/p56lyn and p60src, were detected in all 10 B cell lines. Whereas the src gene shows a ubiquitous pattern of expression, the expression of the blk and lyn genes is mostly restricted to cells of hematopoietic origin, and more especially B lymphoid cells. Thus, p55blk and p53/p56lyn may be particularly good candidates for the membrane immunoglobulin-activated tyrosine kinase.

A gamma interferon-unresponsive variant of cell line 70Z/3, IFN-4, can be partially rescued by phorbol myristate acetate

Lipopolysaccharide (LPS) and gamma interferon (IFN-gamma) induce kappa transcription in 70Z/3 cells by different mechanisms; LPS treatment induces both NF-kappa B and OTF-2 transcription factors, but IFN-gamma treatment does not. We have dissected these two activation pathways by selecting and analyzing an LPS+ IFN- variant of 70Z/3.

Lipopolysaccharide-unresponsive mutant pre-B-cell lines blocked in NF-kappa B activation

NF-kappa B activation is a crucial late step in the induction of immunoglobulin kappa light-chain gene expression in pre-B cells by lipopolysaccharide (LPS). We have analyzed NF-kappa B activation in three independent mutant lines of 70Z/3 pre-B cells which are unresponsive to LPS. All three variant cell lines failed to activate NF-kappa B when induced with LPS or the phorbol ester 12-O-tetradecanoylphorbol 13-acetate. However, all three cell lines contained functional NF-kappa B, as revealed by detergent treatment of cytoplasmic extracts. Moreover, cycloheximide induced limited activation of NF-kappa B comparable to that in wild-type 70Z/3 pre-B cells in two of the three variant lines. These results indicate that the mutations blocking kappa gene induction in these variant 70Z/3 pre-B-cell lines affect NF-kappa B activation.

Slow response variant of the B lymphoma 70Z/3 defective in LPS activation of NF-kappa B

The mouse B cell lymphoma 70Z/3 is membrane immunoglobulin M (mIgM) negative, but treatment of the cells with bacterial lipopolysaccharide (LPS) induces the expression of kappa (kappa) light chain synthesis, and the cells become mIgM+. In wild type cells, this reaction is maximal after 24 h; we have isolated a variant, 1B8, which becomes mIgM+ only after a more prolonged incubation with LPS. This delayed response results from a reduced rate of accumulation of (kappa) mRNA and protein. The transcription factor, NF-kappa B is present in the cytoplasm of both the wild type and the variant cells in its inactive form. The delay in kappa expression is correlated with the failure of NF-kappa B to be activated and translocated to the nucleus. Although NF-kappa B cannot be activated by LPS, it can be activated by treatment with phorbol ester (PMA). In contrast to the clear defect in NF-kappa B, LPS treatment of 1B8 cells causes the octamer-binding factor OTF-2 to increase normally. We conclude that the defect in 1B8 cells is in an early part of the LPS activation pathway, prior to the activation of NF-kappa B, but after the signal for OTF-2 induction. The phenotype of 1B8 demonstrates that an increase in OTF-2 alone is sufficient to cause a large increase in kappa transcription in 70Z/3 cells, but that without NF-kappa B, the response is slow to develop. In this view, NF-kappa B functions to facilitate kappa transcription and to speed its rate of increase, but is not required for the long-term response of 70Z/3 cells to LPS.

Lipopolysaccharide-unresponsive mutant pre-B-cell lines blocked in NF-kappa B activation

NF-kappa B activation is a crucial late step in the induction of immunoglobulin kappa light-chain gene expression in pre-B cells by lipopolysaccharide (LPS). We have analyzed NF-kappa B activation in three independent mutant lines of 70Z/3 pre-B cells which are unresponsive to LPS. All three variant cell lines failed to activate NF-kappa B when induced with LPS or the phorbol ester 12-O-tetradecanoylphorbol 13-acetate. However, all three cell lines contained functional NF-kappa B, as revealed by detergent treatment of cytoplasmic extracts. Moreover, cycloheximide induced limited activation of NF-kappa B comparable to that in wild-type 70Z/3 pre-B cells in two of the three variant lines. These results indicate that the mutations blocking kappa gene induction in these variant 70Z/3 pre-B-cell lines affect NF-kappa B activation.

1.3E2, a variant of the B lymphoma 70Z/3, defective in activation of NF-kappa B and OTF-2

The mouse B-cell cell lymphoma 70Z/3 is a convenient model system in which to study the regulation of immunoglobulin synthesis. Three transcriptional activators of kappa (kappa) light chain synthesis have been identified for these cells: bacterial lipopolysaccharide (LPS), interferon-gamma (IFN), and interleukin-1 (IL-1). The response of the kappa gene in 70Z/3 cells to LPS is mediated by increases in two transcription factors: NF-kappa B and OTF-2. In contrast, IFN has no effect on either of these factors in 70Z/3 cells. We have isolated by immunoselection an LPS- IFN+ variant of 70Z/3 called 1.3E2. We show here that LPS treatment of these cells causes no increase in nuclear localization of either NF-kappa B or OTF-2. Although they have normal levels of cytoplasmic NF-kappa B, it cannot be activated by LPS or by phorbol 12-myristate 13-acetate (PMA) treatment of the cells. These experiments expand the genetic dissection of the molecular pathways of activation of kappa transcription in 70Z/3 cells.

A gamma interferon-unresponsive variant of cell line 70Z/3, IFN-4, can be partially rescued by phorbol myristate acetate

Lipopolysaccharide (LPS) and gamma interferon (IFN-gamma) induce kappa transcription in 70Z/3 cells by different mechanisms; LPS treatment induces both NF-kappa B and OTF-2 transcription factors, but IFN-gamma treatment does not. We have dissected these two activation pathways by selecting and analyzing an LPS+ IFN- variant of 70Z/3.

Induction of kappa transcription by interferon-gamma without activation of NF-kappa B

The induction of immunoglobulin kappa light chain expression in 70Z/3 pre-B cells treated with bacterial lipopolysaccharide (LPS) requires the activation of the B cell-specific factor NF-kappa B, which binds to the kappa enhancer motif, GGGACTTTCC. This sequence alone can function as a tissue-specific enhancer for LPS-induced gene expression. A potent inhibitor of B lymphopoiesis [transforming growth factor-beta (TGF-beta)] was used to explore the mechanisms in the activation of kappa transcription by LPS and by interferon-gamma (IFN-gamma). TGF-beta inhibited LPS-induced kappa transcription but not the activation and in vitro binding of NF-kappa B. This indicates that NF-kappa B activation, while necessary, is not sufficient for LPS-induced kappa transcription. TGF-beta had no effect on IFN-gamma-induced kappa transcription, and NF-kappa B was not activated by IFN-gamma. These results reveal that LPS and IFN-gamma activate transcription through different mechanisms.