Molecular bases of dominant negative and loss of function mutations at the murine c-kit/white spotting locus: W37, Wv, W41 and W

Characteristics of stria vascularis melanocytes of viable dominant spotting (Wv/Wv) mouse mutants

The Wv mutation lies in the kinase domain of the proto-oncogene c-kit which is expressed in a variety of cells including neural crest derived melanoblasts. The mutation results in the abnormal migration, proliferation, survival and/or differentiation of melanoblasts. Viable Dominant Spotting (Wv/Wv) mouse mutants have a white coat due to the absence of melanocytes. The majority of these animals have no melanocytes within the stria vascularis and no endocochlear potential (EP). A proportion of homozygous mutants partially escape the effects of the mutation: 47.2% of pinnae and 21% of vestibular regions were pigmented and 10.8% of ears had an EP. All ears with an EP that were available for histology had some pigmentation of the stria. There was no obvious correlation between external and internal spotting in Wv/Wv mice, and asymmetrical pigmentation of the ears was common. Both light and dark intermediate cells (which are derived from melanocytes) were present in the middle and/or basal turns of these cochlear ducts and they appeared to function normally in enabling the stria to produce an EP (although the EP was usually lower than normal). This suggests that the c-kit gene product is needed only during development of the stria, and not for mature melanocyte function because the melanocytes present in the mutant strias were carrying the mutant version of the c-kit gene. Melanocytes were similar in appearance in controls and mutants, except that fewer melanin granules were observed in the strias of Wv/Wv mice. The observations that strial melanocytes with very few melanin granules in Wv/Wv mutants are able to support EP production, together with previous observations that albino animals with strial melanocytes but no melanin have a normal EP, suggest that melanocytes but not melanin are essential for normal strial function.

Gene expression during oogenesis in mice

A mouse egg is the end-product of oogenesis--a process initiated during fetal development and completed months later at the time of sperm-egg fusion. Oogenesis includes many important events. Among these are formation of female germ cells, initiation and completion of meiosis, and establishment of a maternal store of materials to support fertilization and preimplantation development. The latter takes place largely during germ cell growth in sexually mature females and involves extensive gene expression. Ribonucleic acid and protein accumulate to unusually high levels during this relatively short phase of oogenesis. Recent studies have demonstrated that establishment of a maternal store of materials in the growing mouse egg is both transcriptionally and translationally regulated. Specific examples of both types of regulation are presented here in the context of gene expression during oogenesis in mice.

The gene for dominant white color in the pig is closely linked to ALB and PDGFRA on chromosome 8

White is a widespread coat color among domestic pig breeds and is controlled by an autosomal dominant gene I. The segregation of this gene was analyzed in a reference pedigree for gene mapping developed by crossing the European wild pig and a Large White domestic breed. The gene for dominant white color was shown to be closely linked to the genes for albumin (ALB) and platelet-derived growth factor receptor alpha (PDGFRA) on chromosome 8. An unexpected phenotype with patches of colored and white coat was observed among the F1 and F2 animals. The segregation data indicated that the phenotype was controlled by a third allele, denoted patch (Ip), most likely transmitted by one of the Large White founder animals. It is shown that the ALB, PDGFRA, I linkage group shares homologies with parts of mouse chromosome 5, human chromosome 4, and horse linkage group II, all of which contain dominant genes for white or white spotting. Candidate genes for the dominant white and patch mutations in the pig are proposed on the basis on these linkage homologies and the recent molecular definition of the dominant white spotting (W) and patch (Ph) mutations in the mouse.

Proliferation and neoplastic transformation of pigment cells in metallothionein/ret transgenic mice

Although melanoma is a common human disease, there were few animal models in which melanoma developed at high incidence. To date, the Xiphophorus fish has been used as a model system to study melanoma formation. Studies on this fish showed the presence of a dominant oncogene, Tu, which encodes a transmembrane, tyrosine kinase of epidermal growth factor receptor type (Wittbrodt et al., Nature, 341:415-421, 1989). Recently, we succeeded in establishing novel transgenic mouse lines in which melanosis and melanocytic tumors developed stepwise by introducing another transmembrane tyrosine kinase oncogene, ret (Iwamoto et al., EMBO J., 10:3167-3175, 1991). In our transgenic mice, high levels of expression of the ret transgene induced proliferation and neoplastic transformation of melanin-producing cells. In addition, crossbreeding experiments between transgenic mice and Wv mice showed that the ret oncogene can also induce melanogenesis and melanocyte development in Wv/Wv mice.

Deletion of the KIT and PDGFRA genes in a patient with piebaldism

We have previously shown that human piebaldism results from mutations of the KIT gene, which encodes the receptor for the mast/stem cell growth factor and is located in chromosome segment 4q12. Using DNA of a patient with piebaldism, mental retardation, and multiple congenital anomalies associated with a 46,XY,del(4) (q12q21.1) karyotype, we carried out quantitative Southern blot hybridization analyses of the KIT gene and the adjacent PDGFRA (platelet-derived growth factor receptor alpha subunit) genes. The patient was hemizygous for both the KIT and PDGFRA genes, indicating that both of these genes are included within the deleted region. Therefore, deletion of the KIT and PDGFRA genes may account for the piebald phenotype in this patient.

[Communication between stem cells and the hematopoietic microenvironment. Experimental data and models of interaction]

The aim of this review is to analyze the different ways by which stem cells and microenvironmental cells may interact. Stem cells are defined as immature cells that ensure the continuous renewal of blood cells. This small set of marrow cells comprises different kinds of cells, differing by their degree of maturity, their commitment, self-renewal ability and repopulating capacity. Microenvironmental cells are fixed marrow cells involved in stem cell survival, proliferation and differentiation. In vivo studies on the distribution within spleen or marrow, of stem cells injected to lethally irradiated mice, have suggested that cells of the microenvironment play a significant role in stem cell proliferation and differentiation. This role has been demonstrated using an in vitro model, i.e. the long-term marrow cultures as described in 1976 by M. Dexter. Analysis of stem cell maintenance in this culture system has made it possible to define the different means by which stromal cells and macrophages (the microenvironmental cells) may control stem cell behavior. Different molecules play a critical role: cytokines (growth factors and inhibitors), adhesion molecules (cell adhesion molecules and molecules belonging to the extracellular matrix) and eventually small peptides. It appears nowadays possible to materially represent the hemopoietic niche, whose existence was postulated by R. Schofield 10 years ago for theoretical reasons related to the the physiology of stem cells.

Analyzing mast cell development and function using mice carrying mutations at W/c-kit or Sl/MGF (SCF) loci

Mast cells have been implicated in a wide variety of biological responses, but identifying the nature and importance of the mast cell's specific contributions to these reactions has been difficult. W/Wv mice have mutations affecting the c-kit tyrosine kinase receptor which is encoded at the W locus and which is necessary for normal mast cell development. In W/Wv mice, the cells which ordinarily give rise to normal mast cell populations do not adequately respond to a major migration, survival, proliferation and maturation factor expressed in the microenvironments where mast cells ordinarily develop: the c-kit receptor ligand, SCF. As a result, W/Wv mice virtually lack tissue mast cells. However, adoptive transfer to W/Wv mice of immature mast cells derived in vitro from the bone marrow cells of the congenic normal (+/+) mice selectively repairs the mast cell deficiency of the W/Wv recipients. These "mast cell knock-in" mice can be used to analyze the expression of biological responses in tissues which differ only because they do or do not contain populations of mast cells. This approach permits identification and quantification of the specific contributions of the mast cell to biological responses expressed in the skin, gastrointestinal tract and other anatomical sites, and also greatly facilitates analysis of the mechanisms by which mast cells influence these responses.

Requirement of c-kit for development of intestinal pacemaker system

A discovery that the protooncogene encoding the receptor tyrosine kinase, c-kit, is allelic with the Dominant white spotting (W) locus establishes that c-kit plays a functional role in the development of three cell lineages, melanocyte, germ cell, and hematopoietic cell which are defective in W mutant mice. Recent analyses of c-kit expression in various tissues of mouse, however, have demonstrated that c-kit is expressed in more diverse tissues which are phenotypically normal in W mutant mice. Thus, whether or not c-kit expressed outside the three known cell lineages plays a functional role is one of the important questions needing answering in order to fully elucidate the role of c-kit in the development of the mouse. Here, we report that some of the cells in smooth muscle layers of developing intestine express c-kit. Blockade of its function for a few days postnatally by an antagonistic anti-c-kit monoclonal antibody (mAb) results in a severe anomaly of gut movement, which in BALB/c mice produces a lethal paralytic ileus. Physiological analysis indicates that the mechanisms required for the autonomic pacing of contraction in an isolated gut segment are defective in the anti-c-kit mAb-treated mice, W/Wv mice and even W/+ mice. These findings suggest that c-kit plays a crucial role in the development of a component of the pacemaker system that is required for the generation of autonomic gut motility.

Localization of mRNA for c-kit receptor and its ligand in the brain of adult rats: an analysis using in situ hybridization histochemistry

Localization of mRNA for the c-kit receptor and its ligand (Sl factor) in the brain of adult rats was studied using in situ hybridization histochemistry. The mRNA for the c-kit receptor was detected in the forebrain, the lower brain stem and the cerebellum. In the forebrain, the c-kit mRNA signals were detected in the olfactory bulb, the caudate-putamen, throughout the superficial cortex, the accumbens nucleus, the nucleus of vertical limb diagonal band, the bed nucleus of anterior commissure, Ammon's horn, the entopeduncular nucleus, the subthalamic nucleus, the dorsal raphe nucleus, the parasubiculum, the presubiculum, the ventricular nucleus of lateral lemniscus, and the entorhinal cortex. In the lower brain stem, the signals were detected in the inferior colliculus, the spinal vestibular nucleus, the spinal tract nucleus of trigeminal nerve, and the pyramidal tract. In the cerebellum, the signals were detected in the molecular layer of the cortex and cerebellar nuclei. By contrast, the signals of mRNA for Sl factor were detected in the forebrain and the cerebellum. In the forebrain, the signals were detected in the olfactory bulb, the endopiriform nucleus, the septohippocampal nucleus, the habenular nuclei, and most of the thalamic nuclei. In the cerebellum, the signals were detected in Purkinje cells. Several pairs of structures were found in which mRNA of either the c-kit receptor or the Sl factor was expressed and between which the synaptic connection had been reported, suggesting that the interaction between the c-kit receptor and the Sl factor may play some roles in the development of such synaptic connections.

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.

The ret oncogene can induce melanogenesis and melanocyte development in Wv/Wv mice

We recently reported the establishment of transgenic mouse lines carrying the mouse metallothionein/ret fusion gene in which severe melanosis and melanocytic tumors developed. In the present study, we demonstrate that a significant number of pigmented hairs developed in Wv/Wv mice crossed to one of the transgenic mouse lines. The pigmented hair of Wv/Wv mice carrying the ret oncogene did not lose color during aging and reappeared after shaving, indicating that the melanocytes in the hair follicle function. The melanocytic tumors also developed in these mice, although the incidence was lower than that in the wild transgenic mice. Furthermore, the neutral tube culture of mouse embryos indicated that neural crest cells of the transgenic mice gave rise to a cell population that autonomously produced melanin even in the absence of melanocyte stimulating hormone. These results strongly suggested that the introduced ret oncogene could compensate for the defect of c-kit in Wv mice during both embryogenesis and postnatal life and induce a high level of melanin synthesis in the process of melanocyte development.

Dominant negative and loss of function mutations of the c-kit (mast/stem cell growth factor receptor) proto-oncogene in human piebaldism

Piebaldism is an autosomal dominant disorder of melanocyte development and is characterized by congenital white patches of skin and hair from which melanocytes are completely absent. A similar disorder of the mouse, "dominant white spotting" (W), results from mutations of the c-kit proto-oncogene, which encodes the cellular tyrosine kinase receptor for the mast/stem cell growth factor. We have identified c-kit gene mutations in three patients with piebaldism. A missense substitution (Phe----Leu) at codon 584, within the tyrosine kinase domain, is associated with a severe piebald phenotype, whereas two different frameshifts, within codons 561 and 642, are both associated with a variable and relatively mild piebald phenotype. This is consistent with a possible "dominant negative" effect of missense c-kit polypeptides on the function of the dimeric receptor.

The kit ligand encoded at the murine Steel locus: a pleiotropic growth and differentiation factor

The c-kit receptor and its recently identified ligand are allelic with the murine White Spotting and Steel loci, respectively. These observations brought to light the functions of the c-kit receptor system in melanogenesis, gametogenesis and hematopoeisis during embryogenesis and in postnatal life. The recent molecular analysis of several White Spotting and Steel alleles has provided insights into the mechanism of c-kit ligand-mediated processes, including cell proliferation, cell migration and cell survival. Furthermore, the availability of the kit ligand has allowed in vitro investigations of the pleiotropic functions of c-kit in development and cell differentiation to be carried out.

Activation of the human c-kit product by ligand-induced dimerization mediates circular actin reorganization and chemotaxis

The proto-oncogene c-kit is allelic with the murine white spotting (W) locus and encodes a transmembrane protein tyrosine kinase that is structurally related to the receptors for platelet-derived growth factor (PDGF) and colony-stimulating factor-1 (CSF-1). Recently the ligand for the c-kit product, stem cell factor (SCF), was identified in both transmembrane and soluble forms. In order to examine the mechanism for receptor activation by SCF and biological properties of the activated c-kit product, we transfected the wild-type human c-kit cDNA into porcine aortic endothelial cells. We found that the receptor was down-regulated and transmitted a mitogenic signal in response to stimulation with soluble SCF. We also demonstrate that SCF induces dimerization of the c-kit product in intact cells, and that dimerization of the receptor is correlated with activation of its kinase. Activation of the c-kit product by SCF was found to induce circular actin reorganization indistinguishable from that mediated by the PDGF beta-receptor in response to PDGF-BB. Furthermore, soluble SCF was a potent chemotactic agent for cells expressing the c-kit product, a property which might be of importance during embryonic development.

The ret oncogene products are membrane-bound glycoproteins phosphorylated on tyrosine residues in vivo

We identified ret oncogene products in NIH 3T3 cells transformed by the ret oncogene (NIH(ret)) and a cell line (Lym-ret) established from pre-B cell lymphoma which developed in E mu-ret transgenic mice. Using the polyclonal antibody against the kinase domain of ret, two glycoproteins with apparent molecular weights of 100 kd and 96 kd were found in both cell lines, although the expression level of the 100 kd protein was much higher than that of the 96 kd protein. Cell fractionation experiments indicated that the 100 kd protein was present predominantly in the membrane fraction while the 96 kd protein was found in both membrane and cytosol fractions. Western blot analysis indicated that the 100 kd ret protein was phosphorylated on tyrosine residues in vivo.

Dissecting the activating mutations in v-erbB of avian erythroblastosis virus strain R

The v-erbB oncogene isolated from the R (or ES4) strain of avian erythroblastosis virus is capable of inducing erythroleukemia and fibrosarcomas. This oncogene differs from the proto-oncogene c-erbB, the avian homolog of the epidermal growth factor receptor, by its lack of an intact ligand-binding domain as well as additional alterations in its cytoplasmic coding sequences. By contrast, the insertionally activated c-erbB, a variant oncogene, which encodes a product that also lacks the ligand-binding domain but is otherwise unaltered in its cytoplasmic coding sequences, is capable of inducing leukemia but cannot induce sarcomas. In this report, we show that the critical changes for activating the sarcomagenic potential displayed by v-erbB R are two point mutations within the tyrosine kinase domain and an internal deletion of 21 amino acids in the carboxyl-terminal regulatory domain. The removal of the carboxyl-terminal autophosphorylation sites is not obligatory. These activating mutations (Arg-263 to His, Ile-384 to Ser, and the deletion of residues 494 to 514), when introduced singly into the insertionally activated c-erbB, all dramatically increase fibroblast-transforming potential. Arg-263 resides near the highly conserved HRD motif of the kinase domain, and its mutation to His increases the autophosphorylation activity. The other two mutations do not alter the intrinsic kinase activity and presumably affect other aspects of the receptor involved in growth signaling. Therefore, the high transforming potential of v-erbB R is a consequence of synergism among multiple activating mutations.

Susceptibility of multipotent haemopoietic stem cell deficient W/Wv mice to Plasmodium berghei-infection

The susceptibility of haemopoietic stem cell deficient W/Wv mice to infection with Plasmodium berghei was examined. The mean survival time of W/Wv mice after the infection was shorter than that of the +/+ mice. Splenomegaly, a characteristic pathological change of the host after infection with malaria parasites was not observed in W/Wv mice. When haemopoietic activity of the infected mice was examined, a substantial increase in number of multipotent haemopoietic stem cells (CFU-S) and the committed stem cells for granulocytes and macrophages (CFU-GM) or for erythrocytes (CFU-E) was observed in the bone marrow and spleen of +/+ but not of W/Wv mice. CFU-S were not detected in W/Wv mice before or after infection. The number of CFU-GM and CFU-E in bone marrow and spleen of W/Wv mice decreased after infection. Bone marrow grafting from +/+ to W/Wv mice 8 weeks before infection prolonged the mean survival time of the mice and effectively restored the number of CFU-S in the spleen of W/Wv mice. These results indicate that multi-potent haemopoietic stem cells play an important role in the host's defence mechanisms against P. berghei-infection.

The c-kit-encoded tyrosine kinase regulates the proliferation of early pre-B cells

A monoclonal antibody (mAb; ACK2) recognizing the extracellular domains of the c-kit-encoded tyrosine kinase has been employed to demonstrate that c-kit is involved in B lymphocyte development. The c-kit-encoded tyrosine kinase is expressed on the surface of normal DHJH-rearranged murine pre-B cell clones which proliferate continuously at that stage in vitro on stromal cells and in the presence of recombinant interleukin 7. These pre-B cell clones, capable of differentiation to surface immunoglobulin-positive B cells in vitro and in vivo, are inhibited by the mAb in their proliferation while remaining capable of differentiation to surface immunoglobulin-positive B cells. Stimulation of mature B cells by mitogens is unimpaired by the mAb. This indicates that c-kit regulates early antigen-independent, but not late antigen-dependent, B cell development.

Interallelic complementation among DER/flb alleles: implications for the mechanism of signal transduction by receptor-tyrosine kinases

The large number of available embryonic lethal alleles in the Drosophila EGF receptor homolog (DER)/faint little ball locus allowed us to test the possibility of positive or negative interactions among different DER alleles. These interactions were monitored by examining the embryonic cuticular phenotypes of different heteroallelic combinations. Several positive interactions were identified, while negative interactions were restricted to a single allele. This is the first example of positive interactions within the same cell type among alleles of a receptor tyrosine kinase gene. The basis for these interactions is likely to arise from the mechanism of signal transduction by receptor tyrosine kinases, which involves receptor aggregation. A combination of two different DER mutant proteins defective in temporally distinct stages of the signal transduction process, may thus form a functional heterodimer. The mutation sites in four alleles showing positive interactions were localized. They identify regions within the protein which are likely to be important for these temporally distinct signal transduction processes.

Expression of c-kit encoded at the W locus of mice in developing embryonic germ cells and presumptive melanoblasts

The W locus of mice encodes the c-kit tyrosine kinase receptor. In embryos homozygous for severe W mutations, the number of germ cells does not increase after 8 days of development, melanocytes do not appear, and production of erythrocytes and mast cells is deficient. To gain some insight into the role of the c-kit receptor, we have used in situ hybridization to explore the time period of expression of c-kit transcripts in early germ cells and melanoblasts. At 6 1/2 days of development, expression was not seen in the embryonic cylinder, but did appear in parietal endoderm. Germ cells displayed a low level of c-kit transcripts from their first appearance in the 7 1/2 -day embryo, continuing through early proliferation and migration to the gonad. During migration, surrounding tissues also expressed c-kit. Expression increased in gonia and then ceased as they became nonproliferative. Expression in presumptive melanoblasts was first seen in the cervical region of 10-day embryos and continued as they spread over the surface of the body, entered the epidermis, and differentiated in hair follicles after birth. The effects of mutations of c-kit on germ cells and melanoblasts can be interpreted as an absence of a proliferative signal shortly after their segregation from other cell types. This signal may be required throughout the proliferative phase of early germ cells [and also in postnatal stages of germ cell development (Manova et al. (1990). Development 110, 1057-1069]. In melanoblasts, c-kit may play a role during both proliferation and differentiation.

Molecular basis of mouse developmental mutants

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Expression of the mRNA for the ligand of c-kit in mouse Sertoli cells

The expression of the mRNA for SLF (the c-kit ligand), a product of the "steel" locus, has been investigated in postnatal mouse testis and homogeneous populations of testicular cells. The message was found expressed in postnatal mouse testis but not in germ cells. Studies on primary mouse Sertoli cell cultures from 18 day old mice show that Sertoli cells are the site of SLF mRNA expression in the seminiferous tubules. Treatment of Sertoli cell cultures with cAMP analogs led to a significant increase in the SLF mRNA levels.

Colony-stimulating factors and cytokine receptor network

Cytokines play a vital role in coordinating immune and inflammatory responses. As many cytokine gene hunters have begun to focus their efforts on receptors, novel aspects of hemopoietic growth factor receptors have emerged. Two types of growth factor receptors have been classified--the cytokine receptor family and growth factor receptor family with tyrosine kinase activity. The two types of receptors may have unique roles in 'inducible' and 'constitutive' hemopoiesis which are controlled by immunological stimuli and by interaction with stromal cells, respectively.

Receptor tyrosine kinases: genetic evidence for their role in Drosophila and mouse development

Receptor tyrosine kinases (RTKs) and their ligands are important components of the signalling pathways by which cells interact. This review summarizes a growing body of genetic evidence showing that many developmentally important mutations in Drosophila and the mouse are in the genes that encode RTKs or their ligands, indicating that these molecules play central roles during both invertebrate and vertebrate development.

Molecular cloning of mast cell growth factor, a hematopoietin that is active in both membrane bound and soluble forms

We have previously reported the identification of a novel mast cell growth factor (MGF) that was shown to be a ligand for c-kit and is encoded by a gene that maps near the steel locus on mouse chromosome 10. We now report the cloning of cDNAs encoding the MGF protein. The MGF protein encoded by this cDNA can be expressed in a biologically active form as either a membrane bound protein or as a soluble factor. The soluble protein promotes the proliferation of MGF-responsive cell lines and, in the presence of erythropoietin, stimulates the formation of macroscopic [corrected] erythroid and multilineage hematopoietic colonies.

Stem cell factor is encoded at the Sl locus of the mouse and is the ligand for the c-kit tyrosine kinase receptor

We have cloned a partial cDNA encoding murine stem cell factor (SCF) and show that the gene is syntenic with the Sl locus on mouse chromosome 10. Using retroviral vectors to immortalize fetal liver stromal cell lines from mice harboring lethal mutations at the Sl locus (Sl/Sl), we have shown that SCF genomic sequences are deleted in these lines. Furthermore, two other mutations at Sl, Sld and Sl12H, are associated with deletions or alterations of SCF genomic sequences. In vivo administration of SCF can reverse the macrocytic anemia and locally repair the mast cell deficiency of Sl/Sld mice. We have also provided biological and physical evidence that SCF is a ligand for the c-kit receptor.

The hematopoietic growth factor KL is encoded by the Sl locus and is the ligand of the c-kit receptor, the gene product of the W locus

Mutations at the steel locus (Sl) of the mouse affect the same cellular targets as mutations at the white spotting locus (W), which is allelic with the c-kit proto-oncogene. We show that KL, a hematopoietic growth factor obtained from conditioned medium of BALB/c 3T3 fibroblasts that stimulates the proliferation of mast cells and early erythroid progenitors, specifically binds to the c-kit receptor. The predicted amino acid sequence of isolated KL-specific cDNA clones suggests that KL is synthesized as an integral transmembrane protein. Linkage analysis maps the KL gene to the Sl locus on mouse chromosome 10, and KL sequences are deleted in the genome of the Sl mouse. These results indicate that the Sl locus encodes the ligand of the c-kit receptor, KL.

Identification of a ligand for the c-kit proto-oncogene

We report the purification and N-terminal amino acid sequence of a novel mast cell growth factor, termed MGF, from the supernatants of a murine stromal cell line. A panel of interleukin 3-dependent cell lines were screened for responsiveness to partially purified MGF in [3H]thymidine incorporation assays; proliferative stimulation of these cells in response to MGF correlated with expression of mRNA for the c-kit protooncogene. MGF was shown to be a ligand for c-kit by cross-linking 125I-labeled MGF to c-kit-expressing cells with subsequent immunoprecipitation of the complex with antiserum specific for the C-terminus of c-kit. This establishes MGF as a ligand for the c-kit protein.

Mast cell growth factor maps near the steel locus on mouse chromosome 10 and is deleted in a number of steel alleles

Many spontaneous, chemical-induced, and radiation-induced dominant white spotting (W) and steel (Sl) mutations have been identified in the mouse. W and Sl mutations have similar phenotypic effects including deficiencies in pigment cells, germ cells, and blood cells, Numerous studies have suggested that W acts within the affected cell while Sl instead exerts its effects in the extracellular environment. Recent findings demonstrating that W encodes the c-kit proto-oncogene, a tyrosine kinase membrane receptor, have suggested that Sl encodes a ligand for c-kit. In the accompanying article we report the identification and purification of mast cell growth factor (MGF), a c-kit ligand. Here we describe the cloning of sequences encoding MGF. Furthermore, we show that Mgf maps near Sl in the distal region of mouse chromosome 10 and is deleted in a number of Sl alleles. These findings strongly support the notion that Sl encodes the mast cell growth factor.