Cloning of bovine CD34 cDNA.

CD34 is a leukocyte antigen that is expressed in various cell types including hematopoietic cells. Monoclonal antibodies against human, murine, and canine CD34 proteins have been used for the identification of lymphohematopoietic stem/progenitor cells. The cDNA encoding bovine CD34 was cloned, and its nucleotide sequence was determined. The identity of the deduced amino acid sequence of the encoded protein to those of human, murine. and canine CD34 proteins was 61.1%, 56.0%, and 66.1%, respectively. Northern blot hybridization with the cDNA as a probe detected CD34 RNA expression in the cerebrum, spleen, heart, and lung of a fetal calf.

Expression and distribution of the Kit receptor in bovine bone marrow cells.

OBJECTIVE: To characterize the expression and distribution of the Kit receptor in bovine bone marrow cells (BMC) and to define the function of its ligand, stem cell factor (SCF). ANIMALS: Six 7- to 70-day-old healthy male Holstein-Friesian calves. PROCEDURES: Expression and distribution of the Kit receptor were assessed by use of flow cytometry with monoclonal antibodies (mAb) against the bovine Kit protein. Using Giemsa-stained centrifuged preparations, the histologic appearance of Kit receptor positive (Kit+) BMC were evaluated. Semisolid cultures supplemented with granulocyte colony-stimulating factor (G-CSF) and SCF were used to measure the colony formation capacity of Kit+ BMC. RESULTS: The Kit receptor was expressed on approximately 18% of total BMC. Most of Kit+ BMC did not coexpress lineage markers, but a small subset of this population did coexpress CD3. The Kit+CD3- BMC were a heterogeneous cell population comprising blast-like cells such as myeloblasts, promyelocytes, rubriblasts, and prorubricytes. Conversely, Kit+CD3+ BMC had a lymphocyte-like appearance. Kit+ BMC formed colonies in semisolid culture with G-CSF, whereas Kit- BMC failed to grow. Addition of SCF to G-CSF resulted in superadditive enhancement in colony numbers and size. CONCLUSIONS: The Kit receptor is expressed primarily on immature blood cells in bovine bone marrow, and Kit+ BMC contain hematopoietic progenitor cells that are reactive to G-CSF. In addition, SCF synergizes with G-CSF to stimulate colony formation by these cells. Our results suggest that the Kit receptor and its ligand, SCF, are involved in early stages of granulopoiesis in calves.

Expression of Kit, the receptor for stem cell factor, in bovine peripheral blood.

The expression of Kit, the receptor for stem cell factor (SCF), on bovine peripheral blood cells (PBCs) was examined by using monoclonal antibodies against the bovine Kit protein. Flow cytometric analysis showed that approximately 1.5% of PBCs expressed Kit. In cytospin preparations, the morphology of most Kit+ PBCs was similar to that of large lymphocytes. Subsets of Kit+ PBCs coexpressed CD3, IgM, and/or CD11b but not CD14 or G1. SCF did not induce the proliferation of Kit+ PBCs in vitro. These results indicate that Kit is expressed on subsets of lymphocytes in bovine peripheral blood, but the ligand of Kit, SCF, does not directly induce the proliferation of this cell population.

Production and characterization of monoclonal antibodies that recognize bovine Kit receptor.

Kit receptor is a transmembrane tyrosine kinase that is the receptor for stem cell factor (SCF). The extracellular domain of bovine Kit receptor (boKit) was produced by a baculovirus expression system. Six monoclonal antibody (MAb) clones designated as bK-1 to bK-6 were obtained upon immunization of mice with the recombinant protein. Immunoprecipitation and flow cytometric analysis indicated that all of the MAbs specifically bound to boKit expressed in COS-7 cells transfected with boKit cDNA. Four of the six MAbs neutralized the biological activity of recombinant bovine SCF, whereas the other two did not. The boKit-positive and boKit-negative cell fractions were sorted from cryopreserved bovine bone marrow cells by the use of MAb bK-1. Colony formation assays indicated that the cells which were able to grow in response to bovine SCF were enriched in the boKit-positive fraction. These MAbs would be valuable in studying possible boKit-positive cell species such as bovine hematopoietic cells, and in defining the biological role of Kit receptor in cattle.

Ontogeny of inhibin secretion in the rat testis: secretion of inhibin-related proteins from fetal Leydig cells and of bioactive inhibin from Sertoli cells.

The ontogeny of inhibin secretion in the testis of rats was investigated. Testicular localization, content of immunoactive and bioactive inhibin and its molecular size in fetal and neonatal rats (from 16 days of gestation to 5 days of age) were determined. Strong immunostaining with an antiserum against a polypeptide of porcine inhibin alpha-subunit was noted in testicular interstitial cells from 16 days of gestation. Co-localization of inhibin alpha-subunit and 3 beta-hydroxysteroid dehydrogenase (3 beta HSD) was observed in the interstitial cells until 2 days of age. Immunoreactive inhibin alpha-subunit in the interstitial tissue had disappeared by 5 days of age, although 3 beta HSD-positive cells were still detected. Weak immunostaining for the inhibin alpha-subunit was detected in the seminiferous tubules, probably in the cytoplasm of Sertoli cells, from 20 days of gestation onward. No inhibin alpha-subunit immunostaining was observed in germ cells throughout the experimental period. Testicular inhibin was detected at 16 days of gestation (49.5 +/- 6.7 pg per testis) by RIA. Testicular immunoreactive inhibin showed a tendency to increase during fetal life and levels were maintained at a similar value after birth (697.0 +/- 46.9 pg per testis at 5 days of age). Inhibin bioactivity and its molecular size in testicular homogenate was examined at 17 days of gestation and 0 and 5 days of age. Although no bioactivity was detected at 17 days of gestation, bioactivity was noted at 0 and 5 days of age (177.7 and 1303.9 pg per testis respectively). Immunoblot analysis with antiserum against inhibin alpha-subunit revealed only approximately 40 kDa molecular masses in the testis at 17 days of gestation, probably inhibin-related proteins, but not inhibin. At 0 and 5 days of age, a protein of 30 kDa molecular mass, possibly inhibin, was detected as well as material of approximately 40 kDa molecular mass. FSH in the plasma was first detected at 19 days of gestation (1197.0 ng/l), increased towards birth, and thereafter decreased (4588.5 +/- 572.3 ng/l at 21 days of gestation and 2400.0 +/- 179.6 ng/l at 5 days of age). These results indicate that Leydig cells in fetal and neonatal rats produce inhibin-related substances with no inhibin bioactivity, whereas Sertoli cells begin to produce inhibin during the perinatal period as a possible regulator of FSH secretion.

Cloning and characterization of cDNAs encoding two normal isoforms of bovine stem cell factor.

The cDNA clones encoding two isoforms of bovine stem cell factor (bSCF) were obtained using reverse transcriptase-polymerase chain reaction, and their sequences were determined. The deduced amino acid sequences of the longer and shorter isoforms of bSCF consist, respectively, of 274 and 246 residues and show a high degree of identity to those of SCFs of different animal species. Northern blot analysis with the cDNA revealed the expression of a 5.8 kilobase bSCF RNA in fetal bovine tissues.

Sequence of a bovine c-kit proto-oncogene cDNA.

The Kit protein is a cell-surface tyrosine kinase receptor encoded by the c-kit proto-oncogene. cDNA clones encoding a protein homologous to the mouse and human Kit were isolated from a bovine cerebrum cDNA library. The deduced amino-acid sequence shows 83 and 90% identity to the mouse and human Kit, respectively.