Measurement of interleukin 7.

This unit describes an assay system to detect biologically active interleukin 7 (IL-7). The target or indicator cells are a clonally derived long-term pre-B cell line designated IxN/2bx (or, more simply, 2bx). These cells demonstrate an absolute specificity for IL-7 for continued growth and viability and are used to establish a thymidine-uptake proliferation assay similar to those established for other interleukins. A Support Protocol describes maintenance of the IxN/2bx cell line.

Interleukin 7 is produced by murine and human keratinocytes.

Interleukin 7 (IL-7) was originally identified as a growth factor for B cell progenitors, and subsequently has been shown to exert proliferative effects on T cell progenitors and mature peripheral T cells as well. Constitutive IL-7 mRNA expression so far had been demonstrated in bone marrow stromal cell lines, thymus, spleen, and among nonlymphoid tissues in liver and kidney. Here we show that both murine and human keratinocytes express IL-7 mRNA and release IL-7 protein in biologically relevant amounts. The physiological or pathological relevance of keratinocyte-derived IL-7 is presently unknown. Our finding that keratinocytes can produce IL-7 in concert with reports that IL-7 is a growth factor for in vivo primed antigen-specific T cells, as well as for T lymphoma cells suggests, however, that keratinocyte-derived IL-7 is important in the pathogenesis of inflammatory skin diseases and cutaneous T cell lymphoma.

Inhibition of murine B and T lymphopoiesis in vivo by an anti-interleukin 7 monoclonal antibody.

The effects of interleukin 7 (IL-7) on the growth and differentiation of murine B cell progenitors has been well characterized using in vitro culture methods. We have investigated the role of IL-7 in vivo using a monoclonal antibody that neutralizes IL-7. We find that treatment of mice with this antibody completely inhibits the development of B cell progenitors from the pro-B cell stage forward. We also provide evidence that all peripheral B cells, including those of the B-1 and conventional lineages, are derived from IL-7-dependent precursors. The results are consistent with the rapid turnover of B cell progenitors in the marrow, but a slow turnover of mature B cells in the periphery. In addition to effects on B cell development, anti-IL-7 treatment substantially reduced thymus cellularity, affecting all major thymic subpopulations.

The Steel factor.

Steel factor (SLF) is a recently identified growth factor which is the gene product of the murine Steel locus and a ligand for the c-kit tyrosine kinase receptor, the product of the dominant white spotting locus (W). Defects at these genetic loci result in aberrant melanocyte, germ cell, and hematopoietic development. Both the receptor (c-kit) and the ligand (SLF) have been shown to undergo tissue-specific mRNA splicing to produce distinct isoforms which have unique biological functions. As predicted by the phenotype of these mutations, SLF influences the growth and differentiation of melanocytes, primordial germ cells, and a broad spectrum of cell types in the hematopoietic progenitor and stem cell hierarchy. SLF has also been shown to have effects on hematopoietic lineages not predicted by defects seen in the Steel mouse.

In vivo evaluation of the effects of interleukins 2, 4 and 7 on enhancing the immunotherapeutic efficacy of anti-tumor cytotoxic T lymphocytes.

The draining lymph nodes of mice injected with viable syngeneic tumor cells contain lymphoid cells capable of generating anti-tumor cytotoxic T lymphocytes (CTL) during a 4-day in vitro culture period and intravenous infusion of relatively low numbers of these CTL can effectively eliminate a challenge of fibrosarcoma cells at distal skin sites that would otherwise result in the death of the host. Using this model system the effects of addition of interleukin (IL) 2, IL4 or IL7 to the culture medium on the therapeutic efficacy of the anti-tumor CTL generated was investigated. In this regard, IL7 was found to be the most potent of the cytokines tested. Addition of IL7 either alone, or in combination with low doses of IL2, resulted in the generation of CTL with significantly (6-8-fold) enhanced therapeutic efficacy in vivo. Anti-tumor effector cells generated in the presence of IL7 were also found to be at least 4-fold more effective at eliminating established tumors than CTL generated in medium alone. Of the other cytokines tested, addition of IL2 resulted in elevated CTL activity in vitro, but only a modest (approximately 2-3-fold) enhancement of the therapeutic efficacy in vivo. Addition of IL4, either alone or in combination with IL2, also resulted in the generation of effector cells with enhanced tumoricidal activity in vitro and yet the therapeutic efficacy of these cells was decreased compared to that of CTL generated in medium alone. These observations indicate that (a) inclusion of IL7 in the medium in which tumor-reactive T cells are cultured can markedly enhance the immunotherapeutic efficacy of the resulting effector cell populations; and (b) in vitro assays of tumoricidal activity cannot be used as a reliable predictor of therapeutic efficacy in vivo.

The effects of interleukin 7 (IL-7) on human bone marrow in vitro.

Interleukin 7 (IL-7) stimulates the proliferation of pre-B cells from long-term murine lymphoid cultures and normal bone marrow. In addition, IL-7 stimulates the proliferation of murine T cells, including fetal and adult thymocytes as well as peripheral T cells. Flow cytometry and cell enumeration analyses were carried out on light-density human bone marrow cells incubated in the presence or absence of IL-7. The data showed no evidence for a proliferative effect of IL-7 on B-lineage cells expressing CD24 or on myeloid cells expressing CD15; however, IL-7 did stimulate the growth of T cells expressing CD3. After 16 days of stimulation the number of CD3+ cells in marrow cultures increased 350% in the presence of IL-7. In contrast, cultures incubated in the absence of IL-7 showed a 50% decrease in the number of T cells, with a preponderance of myeloid lineage cells. Flow cytometry indicated that cells from IL-7-stimulated cultures were mature T cells because they also expressed cell surface antigens for either CD4 or CD8. These studies show that in contrast to the murine system, IL-7 does not appear to stimulate the growth of human pre-B cells from adult human bone marrow. This is consistent with other experiments that suggest that human pro-B cells and not human pre-B cells respond to IL-7. It appears that IL-7 preferentially promotes the growth of T cells from human marrow.

Administration of IL-7 to normal mice stimulates B-lymphopoiesis and peripheral lymphadenopathy.

Normal mice were injected with IL-7 (500 ng, twice daily) for various periods of time up to 6 days and the cellularity and phenotypic composition of the thymus, spleen, lymph node, and bone marrow was assessed. After 6 days of treatment, significant increases in the cellularity of the spleen, lymph node, and bone marrow were observed which returned to the normal range within 6 days after cessation of treatment. After 3 days of IL-7 treatment, increased numbers of B220+/surface(s) IgM- bone marrow cells were observed. After 6 days of treatment, these numbers were still further increased and a significant population of B220+/sIgM- cells were observed in the spleen. The numbers of c mu+/sIgM- cells were also increased in the IL-7-treated mice. Analysis of the expression of B220 and BP-1 on the sIgM- bone marrow cells revealed that the B220+/BP-1+ population was dramatically increased after IL-7 treatment and the size of the B220+/BP-1- population did not differ from control mice. The pre-B cell numbers declined rapidly after the cessation of IL-7 treatment. After 6 days of IL-7 treatment, a twofold increase in the number of B cells in the spleen and lymph node was observed. The B cell numbers declined to normal values within 6 days after the cessation of IL-7 administration. In the spleens of the IL-7-treated mice, there was a significant increase in the number of B cells with an immature phenotype (e.g., sIgMhi/sIgDlo, decreased levels of Ia and FcR expression). The numbers of CD8+ and CD4+ T cells were also increased in the lymph node and spleen of the IL-7-treated mice. These numbers declined to normal levels after the cessation of IL-7 treatment.

Interleukin-7 retroviruses transform pre-B cells by an autocrine mechanism not evident in Abelson murine.

In this study, we have constructed retroviral vectors expressing the interleukin-7 (IL-7) cDNA and have used infection with these retroviruses to express this cytokine endogenously in an IL-7-dependent pre-B-cell line. Infection with IL-7 retroviruses, but not with a control retrovirus, resulted in the conversion of the cells to IL-7 independence. The frequency at which this occurred, together with data on vector expression levels, indicated that secondary events were required for factor independence in this system. Southern analysis showed that the IL-7-dependent clones harbored unrearranged copies of the vector proviruses. The factor-independent cells produced variable quantities of IL-7 as measured by an IL-7-specific bioassay, and their proliferation could be substantially inhibited by a neutralizing antibody directed against IL-7, indicating that a classical autocrine-mechanism was responsible for their transformation. These IL-7-independent cells were tumorigenic, in contrast to the parental IL-7-dependent cells or those infected with a control vector. These results showed that IL-7 could participate in the malignant transformation of pre-B cells. However, neither of two Abelson murine leukemia virus (A-MuLV)-transformed pre-B-cell lines expressed detectable IL-7 mRNA, at a level of sensitivity corresponding to less than one molecule of mRNA per cell. Moreover, the proliferation of the A-MuLV transformants was unaffected by addition of the IL-7 antisera under conditions in which parallel experiments with IL-7 virus-infected cells resulted in greater than 70% growth inhibition. Thus, transformation of pre-B cells by A-MuLV was not associated with a demonstrable autocrine loop of IL-7 synthesis. These results show that IL-7 can participate in the malignant transformation of pre-B cells and suggest studies aimed at assessing the role of autocrine production of IL-7 in the generation of human leukemias and lymphomas.

Administration of IL-7 to mice with cyclophosphamide-induced lymphopenia accelerates lymphocyte repopulation.

Lymphopenia was induced in mice by a single injection of cyclophosphamide. IL-7 or a control protein were administered to the mice twice daily and the cellularity and composition of the spleen, lymph node, bone marrow, and thymus were determined at various time points thereafter. In comparison to the control cyclophosphamide-treated mice, animals receiving cyclophosphamide and IL-7 had an accelerated regeneration of splenic and lymph node cellularity. There was no significant difference in the rate of recovery of the bone marrow and thymus of the control and IL-7-treated mice. Assessment of the pre-B cell compartment revealed a dramatic increase in total pre-B cell numbers in the spleen and bone marrow of the IL-7-treated mice as measured by both flow microfluorimetry and a pre-B cell colony-forming assay. This was followed in a few days by a significant increase in surface IgM+B cell numbers to levels above normal values in both the spleen and lymph node. IL-7 administration to cyclophosphamide-treated mice also resulted in an accelerated recovery of peripheral CD4+ and CD8+ cell numbers in the spleen and lymph node. The numbers of CD8+ cells were increased by twofold over normal levels in cyclophosphamide-treated mice receiving IL-7. Myeloid recovery was determined in cyclophosphamide treated mice by assessing the numbers of CFU-granulocyte-macrophage and Mac 1+ cells. There was no significant difference in myeloid recovery between cyclophosphamide-treated mice receiving IL-7 or control protein. These results suggest that administration of IL-7 after chemical-induced lymphopenia may have therapeutic benefits in shortening the period required to achieve normal lymphoid cellularity.

Stromal-cell and cytokine-dependent lymphocyte clones which span the pre-B- to B-cell transition.

Five stromal-cell-dependent lymphocyte clones are described that correspond to late pre-B or early B-cell stages of differentiation. They are useful for determining the molecular requirements for pre-B replication, for studying the stromal cells that supply those factors, and for delineating the final sequence of differentiation events as newly formed lymphocytes prepare to exit the bone marrow. The efficiency of lymphocyte growth at limiting dilution varied substantially on different stromal-cell clones and may reflect functional heterogeneity of stromal cells. Most lymphocyte clones were similar to uncloned lymphocytes from Whitlock-Witte cultures in that they responded only transiently to interleukin-7 (IL-7) and then died, unless maintained on a stromal-cell clone. One unusual lymphocyte clone (2E8) was propagated for more than 1 year in IL-7 alone and was selectively responsive to that cytokine. Most of the lymphocyte clones were not tumorigenic in immunodeficient mice. However, one pre-B clone (1A9) grew autonomously in culture when held at high density, responded to conditioned medium from a number of cell lines, and was tumorigenic. Tumors derived from this clone were infiltrated by stromal cells and lymphocytes taken from the tumors' retained characteristics of the original clone. Ly-6 antigens were inducible on 2E8 and 1A9 cells, but the lymphocytes were otherwise arrested in differentiation. The 2E8 cells had rearranged and expressed kappa light-chain genes but displayed them on the surface along with surrogate light chains and mu heavy chains. Thus, expression of authentic light chain need not coincide with termination of surrogate light-chain utilization in newly formed B cells. Several glycoproteins have recently been demonstrated to be associated with surface immunoglobulin (Ig) on mature B-lineage cells and plasma-cell tumors. We now show that one member of this family (approximately 33 kD) was associated with the mu+surrogate light-chain complex on the 1A9 pre-B-cell clone. When compared to mature B lymphomas, fewer bands coprecipitated with the surface-labeled Ig isolated from pre-B- and early B-cell lines, suggesting that components of the antigen receptor are sequentially acquired during development. The normal replication and differentiation of pre-B cells is probably regulated by complex interactions with multiple cytokines and matrix components of the marrow microenvironment. Cloned lymphocyte lines that are dependent on stromal cells should continue to be important tools for molecular definition of those interactions.

Regulation of T cell proliferation by IL-7.

The regulation of murine T cell proliferation by IL-7 was investigated. Highly purified resting splenic T cells were induced to proliferate in a short term assay by IL-7 in the presence of the comitogen, Con A. The proliferation of these resting T cells showed both IL-2-dependent and -independent components as determined by the susceptibility of the response to the blocking effects of anti-IL-2 mAb. Furthermore, IL-7 was found to augment the Con A-induced production of IL-2 and expression of IL-2R by resting splenic T cells. In contrast, Con A blasts and long term, Ag-dependent cloned T cells proliferated in response to IL-7 independently of any involvement of IL-2. Finally, differences were observed between IL-7 and IL-6 with regard to the regulation of T cell growth and activation. As with IL-7, IL-6 stimulated resting splenic T cells to proliferate in the presence of comitogen. However, in contrast to IL-7, IL-6 failed to stimulate the proliferation of Con A blasts or T cell clones and did not augment the Con A-induced expression of IL-2R on resting T cells.

Murine interleukin 7 (IL-7) receptor. Characterization on an IL-7-dependent cell line.

A murine cell line (IxN/2b) absolutely dependent upon exogenous IL-7 for continued growth has been obtained that expresses lymphoid precursor and class I MHC antigens and also contains a rearranged mu heavy chain. This cell line has been used to define the binding and structural characteristics of the murine IL-7 receptor using 125I-labeled recombinant murine IL-7. 125I-IL-7 binding to IxN/2b cell was rapid and saturable at both 4 degrees and 37 degrees C. Equilibrium binding studies produced curvilinear Scatchard plots at both temperatures with high and low affinity Ka values of approximately 1 x 10(10) M-1 and 4 x 10(8) M-1, respectively, and a total of 2,000-2,500 IL-7 binding sites expressed per cell. Experiments measuring inhibition of binding of 125I-IL-7 by unlabeled IL-7 also produced data consistent with the existence of two classes of IL-7 receptors. Evidence concerning the possible molecular nature of two classes of IL-7 receptors was provided by dissociation kinetics and affinity crosslinking experiments. The dissociation rate of 125I-IL-7 was markedly increased when measured in the presence of unlabeled IL-7 at both 37 degrees and 4 degrees C, which is diagnostic of a receptor population displaying negative cooperativity. Crosslinking studies showed that under both reducing and nonreducing conditions, the major crosslinked species observed corresponded to a receptor size of 75-79 kD while a less intense higher molecular mass crosslinked species was also seen which corresponded to a receptor size approximately twice as large (159-162 kD). Both types of experiments suggest that the IL-7 receptor may form noncovalently associated dimers in the membrane. The IL-7 receptor was expressed on pre-B cells, but not detected on several murine B cell lines or primary mature B cells. It was also expressed on murine thymocytes, some T lineage cell lines, and on bone marrow-derived macrophage. All cells binding 125I-IL-7 exhibited curvilinear Scatchard plots. No cytokines or growth factors tested were able to inhibit binding of 125I-IL-7 to its receptor. These results define the initial binding and structural characteristics, and the cellular distribution, of the murine IL-7 receptor.

Cloning of the human and murine interleukin-7 receptors: demonstration of a soluble form and homology to a new receptor superfamily.

cDNA clones encoding the human and murine interleukin-7 (IL-7) receptor were isolated and expressed in COS-7 cells. Binding of radiolabeled IL-7 to the recombinant IL-7 receptors produced curvilinear Scatchard plots containing high and low affinity classes. These binding properties, as well as the molecular size of the cloned receptor, were comparable to the native forms of the IL-7 receptor. In addition, several cDNA clones were isolated that encode a secreted form of the human IL-7 receptor capable of binding IL-7 in solution. Analysis of the sequence of the IL-7 receptor revealed significant homology in the extracellular domain to several recently cloned cytokine receptors, demonstrating that the IL-7 receptor is a member of a new receptor superfamily.

Clonal growth of murine pre-B colony-forming cells and their targeted infection by a retroviral vector: dependence on interleukin-7.

The cDNA for interleukin-7 (IL-7) was recently isolated from a stromal cell line derived from a long-term B-lymphoid culture. We report that purified recombinant murine IL-7 can promote the clonal growth in semi-solid culture of a subpopulation of cells expressing the B220 surface antigen from normal murine bone marrow. These colony-forming cells (CFC-Pre-B) give rise to colonies of 20 to 1,000 cells after 7 days in culture. Morphologic examination of cells within the colonies showed a characteristic lymphoid morphology, and histochemical examination demonstrated an absence of markers associated with granulocyte, macrophage, eosinophil, or megakaryocyte differentiation, as well as an absence of hemoglobinization (indicative or erythroid differentiation). IL-7 was found to specifically enhance the infection of CFC-Pre-B but not CFU-GM when the cytokine was present during a 48-hour co-cultivation period between irradiated, retrovirus-producing psi 2 clones and normal mouse bone marrow cells. In contrast, IL-3 enhanced the infection of CFU-GM but not CFC-Pre-B. Thymidine suiciding studies suggest that this targeted infection is due to specific induction of cycling of CFC-Pre-B by IL-7 and CFU-GM by IL-3. These data demonstrate that IL-7 can target retroviral infection into a specific subpopulation of early B-lymphoid cells (CFC-Pre-B), and that IL-7 cannot directly promote the in vitro clonal growth of myeloid committed progenitor cells (ie, CFU-GM).

Regulation of human T cell proliferation by IL-7.

The regulation of human T cell proliferation by rIL-7 was investigated. Purified peripheral blood T cells were stimulated to proliferate in a short-term assay by IL-7 in the presence of CD3 mAb or lectin. This stimulation was accompanied by a significant increase in the expression of IL-2R on both CD4+ and CD8+ T cells over that seen with mitogen alone. The proliferation of these cells in the presence of exogenous IL-7 involved both IL-2-dependent and - independent mechanisms as shown by the ability of neutralizing IL-2 antibody to partially inhibit the response. Anti-IL-4 and anti-IL-6 antibodies had no effect on IL-7-induced T cell growth. These results suggest that the costimulatory effect of IL-7 on human T cells is primarily direct, not involving other intermediate T cell growth factors. IL-7 was also found to be mitogenic in a long-term assay in the absence of any costimulus, with the onset of proliferation occurring later than that seen in the presence of mitogen. These results demonstrate that IL-7 provides a potent T cell stimulus either alone or in the presence of co-mitogen and, although this stimulus is accompanied by an increase in the level of IL-2R expression, it is not dependent on the action of IL-2 for its effect.

Lymphopoiesis and IL-7.

Interleukin 7 (IL-7) is a cytokine initially referred to as pre-B cell growth factor because of its growth-promoting activity for cells early in the B lymphocyte lineage. Subsequent to IL-7 gene cloning and expression, IL-7 was also found to influence the activity of cells in the T lineage. Some of the effects of IL-7 on B and T lymphocyte behavior, both in vitro and in vivo, are discussed here. The growth of pre-B cells in Whitlock-Witte long-term bone marrow cultures [1] provided the basis for the cloning of IL-7 [2]. Such cultures consist of at least two cellular elements: 1) a stromal cell layer and 2) lymphoid cells growing in clusters around the stromal cells. A cDNA encoding IL-7 was cloned utilizing a direct expression cloning strategy. A transformed stromal cell line was used as a source of RNA from which a cDNA library was constructed, inserted into a mammalian expression vector and expressed in COS 7 cells. The COS cells were then screened for secretion of IL-7 into the culture medium as defined by the ability to support stromal cell-independent growth of the lymphoid elements from long-term Whitlock-Witte cultures. In addition to its effects on cells from long-term marrow cultures, IL-7 stimulates growth of cells in cultures of fresh bone marrow [3]. Cells from whole bone marrow plated in semisolid agar form colonies in the presence of IL-7. If the marrow is first enriched for cells expressing the B220 antigen before culture in IL-7, the plating efficiency is increased dramatically.(ABSTRACT TRUNCATED AT 250 WORDS)

Interleukin-7: a new hematopoietic growth factor.

IL-7 is a regulator of early lymphoid progenitors of both the T cell and B cell lineages. The high level of expression of IL-7 mRNA under steady state conditions in the thymus suggest that IL-7 is an important regulator of basal lymphoid development. Early pre-clinical data also suggests that IL-7 may have a role in platelet production.

Interleukin 7 stimulates growth of fetal thymic precursors of cytolytic cells: induction of effector function by interleukin 2 and inhibition by interleukin 4.

Interleukin 7 (IL-7) and interleukin 2 (IL-2) stimulate the outgrowth of distinct populations of thymocytes in lobe submersion cultures (LSC) established with day 12-14 murine fetal thymus. Analysis of the expression of cell surface markers in previous studies showed that IL-7 favors the expansion of a more immature population. In the experiments reported here, populations grown in IL-7 and IL-2 were found to differ functionally as assessed by the expression of cytolytic activity. Whereas cells derived from IL-2-supplemented LSC were highly cytolytic for a broad panel of targets, cells that emerged in IL-7-supplemented cultures exhibited little or no such activity, even in the presence of facilitating lectin. However, there were cells with cytolytic potential present in IL-7-grown populations, as demonstrated by the abrupt appearance of effector function 3 days after their exposure to IL-2. Limiting dilution analysis showed that the absolute number of cells in the cytolytic lineage in fetal thymic lobes increased during culture in LSC. Interestingly, identical increases occurred in IL-7-supplemented and IL-2-supplemented LSC, despite the fact that only the latter population exhibited appreciable lytic activity. Collectively, these results suggest that IL-7 stimulates outgrowth of cell populations which contain functionally inactive cytolytic precursors whose activity is inducible by IL-2. In contrast to IL-2, IL-4 failed to stimulate the appearance of a lytic population from IL-7-supplemented LSC. Furthermore, IL-4 interfered with cell proliferation and acquisition of lytic activity normally induced by IL-2.(ABSTRACT TRUNCATED AT 250 WORDS)

Human IL-7: a novel T cell growth factor.

IL-7 is a hemopoietic growth factor that induces the proliferation of early B lineage cells. In the course of studies to determine its effect on human bone marrow cells, we noted a marked outgrowth of mature T cells. When T cells from the circulation were cultured with IL-7, a dose-dependent proliferative response was observed. The target cells included both the CD4+ and CD8+ subpopulations of T cells, but the memory T cells (CD45R-) were better responders than unprimed T cells (CD45R+). IL-7 induced the expression of receptors for IL-2 and transferrin and higher levels of the 4F2 activation Ag. Although T cell responses to suboptimal concentrations of IL-7 were enhanced by the addition of IL-2, the proliferative response to IL-7 was not inhibited by neutralizing antibody to the IL-2R (Tac), nor was IL-2 secretion detected in this response. This response pattern of mature T cells suggests an important role for IL-7 in normal T cell physiology in humans.