Spontaneous canine mast cell tumors express tandem duplications in the proto-oncogene c-kit.

Spontaneous mast cell tumors (MCT) are the most common malignant neoplasm in the dog, representing between 7% and 21% of all canine tumors, an incidence much higher than that found in humans. These tumors often behave in an aggressive manner, metastasizing to local lymph nodes, liver, spleen, and bone marrow. The proto-oncogene c-kit is known to play a critical role in the development and function of mast cells. Point mutations in the kinase domain of c-kit leading to tyrosine phosphorylation in the absence of ligand binding have been identified in three mastocytoma lines, (P815, RBL, and HMC-1), and some human patients with various forms of mastocytosis. We now demonstrate that although c-kit derived from canine MCT did not contain the previously described activating point mutations, 5 of the 11 tumors analyzed possessed novel mutations consisting of tandem duplications involving exons 11 and 12. We also show that one such duplication, detected in a canine mastocytoma cell line, was associated with constitutive phosphorylation of c-kit protein (KIT), suggesting that these mutations may contribute to the development or progression of canine MCT.

Expression of stem cell factor receptor (c-kit) by the malignant mast cells from spontaneous canine mast cell tumours.

Stem cell factor receptor (SCFR, c-kit), normally expressed on haematopoietic and mast cells, plays a regulatory role in cellular growth and differentiation. Dysregulated expression of SCFR may contribute to neoplastic transformation. We investigated expression of SCFR on malignant canine mast cells obtained directly from spontaneous canine mast cell neoplasms, in an attempt to determine whether these undifferentiated cells maintained expression of this growth-promoting cytokine receptor. Malignant mast cells (histological grade 2) from skin tumours or lymph node metastases were collected from canine patients, and SCFRs were detected by flow cytometric analysis of these cells. All of the tumours bound mouse and canine recombinant stem cell factor (SCF), indicating that the cells not only expressed SCFRs, but that the receptors possessed the functional property of ligand binding. Immunoglobulin Fc receptors for canine IgE were identified on these cells by flow cytometry, a further indication that the cells analysed were mast cells and retained some differentiated features. Immunohistochemical analysis of formalin-fixed, paraffin wax-embedded mast cell tumour biopsies confirmed expression of SCFRs by malignant cells from each tumour. The relative binding of SCF to suspensions of tumour cells, as assessed by flow cytometry, correlated with the intensity of immunolabelling for SCFR in sections of the same tumours, suggesting variability in SCFR expression between tumours. Agarose gel electrophoresis of the products of SCFR reverse transcription-polymerase chain reaction derived from each tumour had the molecular weight predicted for canine SCFR cDNA on the basis of the mouse and human counterparts. This further confirmed SCFR expression by malignant canine mast cells. Taken together, these results show that a membrane receptor capable of triggering cell growth is expressed by malignant canine mast cells, suggesting a role for this receptor in the aetiology of canine mast cell cancer. This relatively common malignancy of the dog would seem to present an opportunity for the investigation of the potential role of the SCF/SCFR pathway in the development of spontaneous malignancies of mast cells.

Cloning and functional analysis of the mouse c-kit promoter.

The c-kit protooncogene encodes a tyrosine kinase receptor expressed during ontogeny and adult life by several important and developmentally distinct cell lineages. Mice carrying germ line c-kit mutations exhibit deficiencies in most of these lineages, demonstrating that c-kit function is necessary for their normal development. To facilitate the identification of cis-acting elements which regulate tissue-specific c-kit expression, we cloned and characterized a mouse c-kit promoter which is functional in different cell types. A major c-kit transcription initiation site (TIS), located 58 bp upstream from the translation initiation codon, is utilized in mouse mast cells and in c-kit-positive cells in the mouse cerebellum. The effects of deletions in the 5' flanking region on reporter gene activity identify three short regulatory regions which function in both mouse and human c-kit positive cell lines. The nucleotide sequence of this region does not include CCAAT or TATA boxes but contains consensus binding sites for Sp1, Ap-2 and several short GA-rich elements which resemble binding sites for the ETS-domain proteins.

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.

The rat c-kit ligand, stem cell factor, induces c-kit receptor-dependent mouse mast cell activation in vivo. Evidence that signaling through the c-kit receptor can induce expression of cellular function.

Interactions between products of the mouse W locus, which encodes the c-kit tyrosine kinase receptor, and the Sl locus, which encodes a ligand for c-kit receptor, which we have designated stem cell factor (SCF), have a critical role in the development of mast cells. Mice homozygous for mutations at either locus exhibit several phenotypic abnormalities including a virtual absence of mast cells. Moreover, the c-kit ligand SCF can induce the proliferation and maturation of normal mast cells in vitro or in vivo, and also can result in repair of the mast cell deficiency of Sl/Sld mice in vivo. We now report that administration of SCF intradermally in vivo results in dermal mast cell activation and a mast cell-dependent acute inflammatory response. This effect is c-kit receptor dependent, in that it is not observed when SCF is administered to mice containing dermal mast cells expressing functionally inactive c-kit receptors, is observed with both glycosylated and nonglycosylated forms of SCF, and occurs at doses of SCF at least 10-fold lower on a molar basis than the minimally effective dose of the classical dermal mast cell-activating agent substance P. These findings represent the first demonstration in vivo that a c-kit ligand can result in the functional activation of any cellular lineage expressing the c-kit receptor, and suggest that interactions between the c-kit receptor and its ligand may influence mast cell biology through complex effects on proliferation, maturation, and function.

Induction of mast cell proliferation, maturation, and heparin synthesis by the rat c-kit ligand, stem cell factor.

We investigated the effects of a newly recognized multifunctional growth factor, the c-kit ligand stem cell factor (SCF), on mouse mast cell proliferation and phenotype. Recombinant rat SCF164 (rrSCF164) induced the development of large numbers of dermal mast cells in normal mice in vivo. Many of these mast cells had features of "connective tissue-type mast cells" (CTMC), in that they were reactive both with the heparin-binding fluorescent dye berberine sulfate and with safranin. In vitro, rrSCF164 induced the proliferation of cloned interleukin 3 (IL-3)-dependent mouse mast cells and primary populations of IL-3-dependent, bone marrow-derived cultured mast cells (BMCMC), which represent immature mast cells, and purified peritoneal mast cells, which represent a type of mature CTMC. BMCMC maintained in rrSCF164 not only proliferated but also matured. Prior to exposure to rrSCF164, the BMCMC were alcian blue positive, safranin negative, and berberine sulfate negative; had a histamine content of 0.08 +/- 0.02 pg per cell; and incorporated [35S]sulfate into chondroitin sulfates. After 4 wk in rrSCF164, the BMCMC were predominantly safranin positive and berberine sulfate positive, had a histamine content of 2.23 +/- 0.39 pg per cell, and synthesized 35S-labeled proteoglycans that included substantial amounts (41-70%) of [35S]heparin. These findings identify SCF as a single cytokine that can induce immature, IL-3-dependent mast cells to mature and to acquire multiple characteristics of CTMC. These findings also directly demonstrate that SCF can regulate the development of a cellular lineage expressing c-kit through effects on both proliferation and maturation.

The rat c-kit ligand, stem cell factor, induces the development of connective tissue-type and mucosal mast cells in vivo. Analysis by anatomical distribution, histochemistry, and protease phenotype.

Mast cell development is a complex process that results in the appearance of phenotypically distinct populations of mast cells in different anatomical sites. Mice homozygous for mutations at the W or S1 locus exhibit several phenotypic abnormalities, including a virtual absence of mast cells in all organs and tissues. Recent work indicates that W encodes the c-kit tyrosine kinase receptor, whereas S1 encodes a c-kit ligand that we have designated stem cell factor (SCF). Recombinant or purified natural forms of the c-kit ligand induce proliferation of certain mast cell populations in vitro, and injection of recombinant SCF permits mast cells to develop in mast cell-deficient WCB6F1-S1/S1d mice. However, the effects of SCF on mast cell proliferation, maturation, and phenotype in normal mice in vivo were not investigated. We now report that local administration of SCF in vivo promotes the development of connective tissue-type mast cells (CTMC) in the skin of mice and that systemic administration of SCF induces the development of both CTMC and mucosal mast cells (MMC) in rats. Rats treated with SCF also develop significantly increased tissue levels of specific rat mast cell proteases (RMCP) characteristic of either CTMC (RMCP I) or MMC (RMCP II). These findings demonstrate that SCF can induce the expansion of both CTMC and MMC populations in vivo and show that SCF can regulate at least one cellular lineage that expresses c-kit, the mast cell, through complex effects on proliferation and maturation.

Stem cell factor (SCF), a novel hematopoietic growth factor and ligand for c-kit tyrosine kinase receptor, maps on human chromosome 12 between 12q14.3 and 12qter.

Recently a novel hematopoietic growth factor, stem cell factor (SCF), was cloned and demonstrated to be the ligand for the c-kit tyrosine kinase receptor. In the mouse, SCF is encoded by Sl (steel), a gene critical to the development of several distinct cell lineages during embryonic life and which has important effects on hematopoiesis in the adult animal. The Sl/SCF locus maps to the distal region of mouse chromosome 10, in the vicinity of genes that have been mapped to human chromosome 12. Here we report the use of somatic cell hybrid lines to localize SCF to the long arm of human chromosome 12, between 12q14.3 and 12qter. In addition to localizing the Sl homolog in man, these data provide further evidence for the conservation of synteny between the long arm of human chromosome 12 and the distal end of mouse chromosome 10.

Functional expression of the genomic DNA sequences encoding mouse Na,K-ATPase alpha 1 gene by cotransfection of overlapping genomic DNA segments.

The entire 33-kb coding region of the mouse Na,K-ATPase alpha 1 subunit gene was cloned in two overlapping cosmids which contain inserts of 40 kb. To assess the functional expression of the mouse alpha 1 gene, the two cosmids were cotransfected into ouabain-sensitive CV-1 monkey cells yielding an average of 64 resistant colonies per 10(6) cells per microgram of DNA. Analysis of the DNA transferred to the ouabain-resistant transformants by the two cosmids suggests that the generation of a functional gene can occur by homologous recombination between the two introduced segments, as demonstrated by generation of a novel diagnostic restriction fragment. The ability to reconstruct the intact mouse alpha 1 gene in a heterologous host cell and to monitor its functional expression with a selection protocol permits direct identification and isolation of regulatory sequences for the gene.

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 expression of the proto-oncogene C-kit in the blast cells of acute myeloblastic leukemia.

The oncogene kit has been shown genetically to map in the W locus of the mouse. This locus is known to have an important role in the regulation of normal hemopoietic stem cell growth. The blast cells of acute myeloblastic leukemia may be considered to arise in predeterministic stem cells. Accordingly, we sought evidence that kit was involved in the regulation of AML blast growth, using a cDNA probe to the external domain of c-kit. With this probe the gene was found to be in germline configuration in blast cells from AML, ALL, and continuous myeloblastic cell lines. However, expression could be detected by Northern analysis or RNA dot blots only in fresh AML blast cells. Fresh cells from ALL patients, normal bone marrow, PHA-stimulated lymphocytes, and four myeloblastic continuous cell lines were expression negative by the same techniques.

Genetic analysis of the dominant white-spotting (W) region on mouse chromosome 5: identification of cloned DNA markers near W.

We have assigned several mouse cDNA and genomic clones to the W region of mouse chromosome 5, established their position with respect to various marker loci in the region, and provided molecular verification that the W19H mutation is a deletion. Meiotic recombination analysis of an interspecific mouse backcross indicated the following gene order and distances [in centimorgans (cM)]: centromere-Emv-1-(13 cM)-D4S76-(17 cM)-D5SC25-(5 cM)-alpha-casein-(1 cM)-beta- casein-(6 cM)-alpha-fetoprotein-(18 cM)-beta-glucuronidase. D5SC25, an anonymous locus defined by a mouse brain cDNA, maps near the map position of W and within the breakpoints of the presumed genetic deletion that causes the W19H phenotype. Southern analysis of DNAs of W19H/+ interspecific F1 hybrid mice and somatic cell hybrid lines carrying the W19H deletion chromosome showed the deletion of D5SC25. In fact, analysis of other mutations at or near the W locus, which had been transferred from the strain of origin for many backcross generations, revealed the retention of donor restriction fragment length polymorphisms at the D5SC25 locus. Such evidence confirms close linkage between D5SC25 and W (within 1 cM) and indicates that the D5SC25 cDNA clone could serve as a starting point in a chromosome "walk" to W and other closely linked loci that affect development.

The dominant-white spotting (W) locus of the mouse encodes the c-kit proto-oncogene.

Mutations at the W locus in the mouse have pleiotropic effects on embryonic development and hematopoiesis. The characteristic phenotype of mutants at this locus, which includes white coat color, sterility, and anemia, can be attributed to the failure of stem cell populations to migrate and/or proliferate effectively during development. Mapping experiments suggest that the c-kit proto-oncogene, which encodes a putative tyrosine kinase receptor, is a candidate for the W locus. We show here that the c-kit gene is disrupted in two spontaneous mutant W alleles, W44 and Wx. Genomic DNA that encodes amino acids 240 to 342 of the c-kit polypeptide is disrupted in W44; the region encoding amino acids 342 to 791 is disrupted in Wx. W44 homozygotes exhibit a marked reduction in levels of c-kit mRNA. These results strongly support the identification of c-kit as the gene product of the W locus.

Analysis of the hematopoietic effects of new dominant spotting (W) mutations of the mouse. I. Influence upon hematopoietic stem cells.

Mice carrying two mutant W alleles usually have severe macrocytic anemias which result from deficiencies of hematopoietic stem cells (CFUs) (1). Anemic W39/W39 and W41/W41 homozygotes (2) have deficiencies in the numbers of femoral stem cells which correspond to the severities of their anemias. The non-anemic W44/W44 homozygote (2) has a few stem cells as the W41/W41 mouse. Nevertheless, bone marrow implants from W44/W44 donors cure the anemias of W/Wv recipients while implants from anemic W39/W39 and W41/W41 donors do not. The peripheral hematologic differences between W41/W41 and W44/W44 homozygotes probably arise from qualitative differences intrinsic to their stem cells rather than from extrinsic hematopoietic factors. The hematopoietic environments of all three W homozygotes are relatively normal in that they support normal erythropoiesis when injected with congenic +/+ marrow. Even non-anemic W44/W44 recipients are repopulated with +/+ donor red cells, indicating that W44/W44 stem cells are at a disadvantage when competing with normal counterparts.

Analysis of the hematopoietic effects of new dominant spotting (W) mutations of the mouse. II. Effects on mast cell development.

In addition to their anemia, sterility and lack of coat pigment (1,2), W/Wv mice are mast cell deficient (3,4). Our analysis of three recently described W alleles (5) confirms reports (3,6) that (a) W mutations alter skin mast cell number in parallel with their influence on red cell number (but not with pigmentation), (b) that mast cells arise from hematopoietic tissue (7) and (c) that injections of normal bone marrow cells, which cure the anemias of W/Wv recipients, also alleviate the deficiency of skin mast cells in these mice. Transplants of bone marrow cells from mice homozygous for two new anemia-causing W alleles, W39 and W41, fail to cure the anemias of W/Wv recipients (companion paper) or increase the number of mast cells in their skin. Marrow cell implants from non-anemic W44/W44 mice cure the anemia, but do not change the number of mast cells in the skin of W/Wv recipients. The fact that the bone marrows of all three new homozygotes have fewer than normal numbers of CFUs hematopoietic stem cells (see companion paper) and have reduced mast cell-regenerating capacities, supports Kitamura's contention (8) that mast cell precursors may be closely related to or identical with the CFUs.

Analysis of pleiotropism at the dominant white-spotting (W) locus of the house mouse: a description of ten new W alleles.

Characterization of the pleiotropic effects of ten new putative W locus mutations, nine co-isogenic and one highly congenic with the C57BL/6J strain, reveals a wide variety of influences upon pigmentation, blood formation and gametogenesis. None of the putative alleles, each of which is closely linked to Ph, a gene 0.1 cM from W, gave evidence of complementation with W39, a new allele previously shown to be allelic to Wv. All W/W39 genotypes resulted in black-eyed-white anemics with reduced gametogenic activity. Homozygotes for seven of these mutations are lethal during perinatal life; anemic embryos have been identified in litters produced by intercross matings involving each of these alleles.--Phenotypes of mice of several mutant genotypes provide exceptions to the frequent observation that a double dose of dominant W alleles (e.g., W/Wv or W/W) results in defects of corresponding severity in each of the three affected tissues. One viable homozygote has little or no defect in blood formation, and another appears to have normal fertility. The phenotypes of these homozygotes support the conclusion that the three tissue defects are not dependent on each other for their appearance and probably do not result from a single physiological disturbance during the development of the embryo.--Although homozygosity for members of this series results in a wide range of phenotypes, the absence of complementation of any allele with W39, the close proximity of each mutant to Ph, and the fact that all alleles produce detectable (though sometimes marginal) defects in the same tissues affected by W and Wv, support the hypothesis that each new mutant gene is a W allele.