A modified immunohistochemical procedure for the detection of estrogen receptor in mouse tissues

Summary A horseradish peroxidase (HRP) labeled antibody method was developed for use with a monoclonal antibody to detect estrogen receptor (ER) in mouse tissue. Combined use of HRP labeled F(ab)₂ fragment absorbed with mouse liver protein to minimize background staining and imidazol-DAB reaction gave the most reliable and sensitive immunostaining.The method was applied to uterine, vaginal, pituitary and liver tissues in ovariectomized adult mice. In uterus and vagina, ER was recognized in nuclei of epithelial cells, stromal cells and smooth muscle cells of the muscle layer and blood vessels. Liver tissue showed positive nuclear immunostaining in parenchymal cells; however, no reaction was present in endothelial cells, Kupffer cells, bile ductal cells, and smooth muscle cells of blood vessels. ER was localized in the nuclei of anterior pituitary cells while weak reaction was also recognized in cells of the intermediate lobe. No staining was detected in the posterior pituitary.Results demonstrate that both occupied and unoccupied ER are localized in the cell nucleus from several target tissues. Weak immunostaining in samples could not be enhanced by multiple procedures. It is suggested that nuclear ER is partially hidden by nuclear components such as nuclei acid and chromatin proteins.     

Localisation du récepteur des androgènes dans le testicule

Whether or not germ cells contain the androgen receptor remains a matter of controversy. In the present study we performed biotinstreptavidin immunoperoxidase using an affinity purified rabbit polyclonal antibody made to a 21 amino acid peptide of the amino terminus of the rat AR to determine androgen receptor (AR) distribution in the rat and mouse testes. Specificity of the antibody was confirmed as follows: 1) Western immunoblots rendered a specific band at approximately 110 kD; 2) preadsorption of the antibody with the 21 amino acid peptide eliminated specifice immunostaining; 3) the intensity of staining in all AR positive cells diminished as a function of antisera dilution; 4) tissues known to express abundant AR (e.g., epididymis, prostate, seminal vesicles) all rendered a robust, nuclear AR immunostaining pattern in the epithelial cells; 5) prostate cell lines known to express AR immunostained positive with the antibody; 6) AR negative COS-7 cells became AR immunopositive when transfected with a vector expressing the rat AR and intracellular AR distribution was a function of androgens. AR immunostaining results revealed the following: Within the interstitial compartment of adult rats, AR was detected in some Leydig cells and all smooth muscle cells forming the walls of blood vessels, but endothelial cells were negative. In the seminiferous tubules AR was observed in all peritubular myoid cell nuelei, but not in the distal layer of Iymphatic endothelial cells. In Sertoli cells, nuclear AR immunostaining was stage specific; moderate AR immunostaining became evident at late stage IV of the cycle, reached a robust peak at stages VII-VIII, and then disappeared completely. Specific AR immunostaining was also discerned in the nuclei of stage XI elongated spermatids, in which nuclear elongation is apparent but chromatin condensation has not yet begun. With onset of chromatin condensation, nuclear AR immunostaining in elongated spermatids was not discerned concomitant with its detection in the cytoplasm. In general, similar observations have now been confirmed in the adult mouse testis, except that an Leydig cells were strongly AR positive. Nucleic acid in situ hybridization studies for AR were performed in adult rat testis using a 236 bp antisense cRNA probe (rat AR cDNA was provided by Dr. C. Chang, U. Wisconsin, Madison, WI) to confirm the AR immunostaining. A prominent hybridization signal at the base of the seminiferous epithelium was observed, in the area occupied by Sertofi and spermatogonia. This led us to re-examine the immunostaining results to determine if spermatogonia were also AR positive. Preliminary results are consistent with the interpretation that AR is present in certain spermatogonial populations. Taken together, these results concur with prior observations suggesting that AR is present in the somatic cells of the testis; thus, it is these cell types that likely respond to circulating androgens to control spermatogenesis. However, they raise anew the controversy of whether germ cells respond directly to androgens.     

An immunocytochemical method for localization of estrogen receptors in rat tissues using a dinitrophenyl (DNP)-labeled rat monoclonal primary antibody.

We have developed an immunocytochemical method to demonstrate estrogen receptor in hormone-sensitive tissues of the rat using a dinitrophenyl (DNP) hapten-labeled rat antihuman estrogen receptor monoclonal antibody (MAb), H222. Mouse IgM anti-DNP was used secondarily, followed by a DNP/peroxidase conjugate, diaminobenzidine/hydrogen peroxide chromogen, and silver intensification. This method was applied to tissues from intact female rats and showed that estrogen receptor was localized in the nuclei of the stromal and glandular components of the uterine endometrium. Reduced receptor staining was observed in the luminal epithelium, with minimal myometrial staining. Anterior pituitary glands showed heterogeneous immunostaining and ovaries expressed the receptor predominantly in the interstitial cells; fallopian tubes demonstrated substantial epithelial staining. Uteri from chemically castrated rats showed reduced estrogen receptor immunostaining in both stromal and luminal cells, whereas staining was enhanced in the glandular elements. Classical estrogen-unresponsive tissues (heart, lung, and spleen) were unstained. Antibody controls involved pre-blocking antibody recognition sites on the receptor with unlabeled antibodies to estrogen receptor (H222, H226, and D547), as well as use of an inappropriate DNP-labeled antibody to metallothionein. These controls illustrated the specific nature of the DNP-H222 binding.     

Immunohistochemical localization of estrogen receptor in rat brain, pituitary and uterus with monoclonal antibodies

Localization of estrogen receptor (ER) in rat brain, pituitary and uterus is shown by the avidin-biotin complex technique using a monoclonal antibody, JS34/32. Immunostaining is observed in nuclei of certain neurons in the preoptic-septal region, hypothalamus and amygdala, and in cells of the anterior pituitary and uterus after estradiol stimulation. Staining is specific since preadsorbed JS34/32 antibody with purified cytoplasmic ER as well as a control monoclonal antibody do not show positive immunoreaction. In the brain, neither cytoplasmic nor nuclear staining is seen in the absence of estradiol stimulation, nor with the progesterone and dihydrotestosterone treatments. The distribution of ER-containing neurons in specific areas of the brain overlaps with the distribution of estrogen target neurons demonstrated by autoradiography. The results demonstrate the usefulness of the monoclonal antibody for the detection of ER in target tissues.     

Sex hormone binding globulin expression and colocalization with estrogen receptor in the human Fallopian tube.

The detection of sex hormone binding globulin (SHBG) or SHBG mRNA in several sex steroid target tissues, has raised the possibility that SHBG modulates the action of sex steroids outside the vascular compartment. The presence of SHBG mRNA was investigated by RT-PCR in the poly (A+) RNA fraction of the human Fallopian tube. Human and rat liver were used as positive and negative control tissues, respectively. The electrophoretic analysis of the amplified PCR products showed bands at 219 bp, corresponding to the expected size of the SHBG cDNA, in the Fallopian tube and human liver but not in rat liver, indicating that SHBG might be synthesized by the Fallopian tube. The cellular localization of SHBG and of estrogen receptor (ER) was examined by immunohistochemistry in consecutive sections of Fallopian tube tissues for individual staining or double immunostaining in the same section. Specific immunostaining of SHBG was present in the epithelial, vascular and muscle cells of the ampullary and isthmic region. In epithelial cells, immunoreactive SHBG was present in the apical end with the highest concentration close to the luminal membrane. The ER was localized in the nuclei of epithelial, stromal and muscle cells of the ampulla and isthmus. Double immunostaining showed that SHBG and ER are colocalized principally in epithelial cells of the ampulla and in muscle cells of the isthmus. In conclusion, the detection of SHBG and SHBG mRNA and the localization of SHBG in estrogen target cells was shown. These findings support the hypothesis that SHBG might regulate sex steroid action at the tissue level.     

Localization of phospholamban in smooth muscle using immunogold electron microscopy

Phospholamban, the putative regulator of the Ca2+-ATPase in cardiac sarcoplasmic reticulum, was immunolocalized in canine visceral and vascular smooth muscle. Gently disrupted tissues were labeled with an affinity-purified phospholamban polyclonal antibody and indirect immunogold, using preembedding techniques. The sarcoplasmic reticulum of smooth muscle cells was specifically labeled with patches of immunogold distributed in a nonuniform fashion, while the sarcolemma did not appear to contain any phospholamban. The outer nuclear envelopes were also observed to be heavily labeled with the affinity-purified phospholamban polyclonal antibody. These findings suggest that phospholamban may play a role in the regulation of cytoplasmic and intranuclear calcium levels in smooth muscle cells.     

Immunological analysis of the biochemical properties of the uterine estrogen receptor

Immunohistochemical and immunochemical analysis using Western blot techniques were carried out with estrogen receptor (ER) monoclonal antibody H-222 to 1) clarify the "nuclear translocation" phenomenon of ER, 2) elucidate the primary nuclear binding site of ER, and 3) to evaluate the binding force between ER and its nuclear binding site in the uterus of ovariectomized adult mice. Exclusive nuclear localization of ER was recognized in the epithelial cells, stroma cells, and smooth muscle cells. Uterine tissues prepared from animals injected with saline, 17 beta-estradiol (E2), estriol (E3), and diethylstilbestrol (DES) exhibited almost the same ER immunostaining when they were fixed prior to sectioning (prefixation method) and frozen sections were used. On the other hand, when fresh-frozen sections were fixed before or after incubation with various solutions (postfixation method) and then treated with various salt solutions, greater differences were seen in immunostaining of ER between saline-injected and hormone-treated animals. Immunostaining of ER in control animals was low after incubation with PBS (0.01 M phosphate buffer containing 0.16 M NaCl, pH 7.2), whereas uterine tissue from hormone-injected mice showed strong nuclear immunostaining after this treatment. After treatment with 0.4 M KCl or 0.5 M NaCl, immunostaining in the uterus of both hormone-injected and control animals was completely abolished. DNase treatment caused an almost complete loss of immunostaining of ER; however, RNase digestion slightly increased immunoreactivity in both E2-injected and control animals. Quantitative analysis using sodium dodecyl sulfate-polyacrylamide gel electrophoresis and Western blot techniques showed that after incubation of tissue sections for 30 min with PBS, 0.4 M KCl, or DNase, 60%, 10%, and 30% of ER were present, respectively, compared to amount of ER present in unincubated sections. These findings suggest the following for the ER in uterine tissue; nuclear occupancy is a phenomenon that occurs due to a differential affinity between occupied and unoccupied receptors in the nucleus; after hormone treatment, the receptor levels do not fluctuate in the nucleus to the extent demonstrated by binding assays; and the properties of the ER detected in the immunohistochemical analysis are identical to those observed in biochemical studies.     

Nuclear location of hormone-free estrogen receptors by monoclonal antibodies could be a tissue-fixation dependent artifact

The 'two-step' model proposed by Jensen and his collaborators for explaining estrogen action conceptualized hormone-free estrogen receptors (ER) to be cytoplasmic, and hormone-filled, transformed ER to be nuclear. Applying monoclonal antibodies which recognized epitopes in ER and formaldehyde-fixed tissues, King et al demonstrated exclusively nuclear staining in target tissues utilizing immunoperoxidase technique. Recently these antibodies have become commercially available enabling other investigators to conduct studies. In this report, using these monoclonal antibodies we have demonstrated that a change in the concentration of formaldehyde alters the staining pattern yielding cytoplasmic instead of nuclear staining in calf uterus, MCF-7 cells, and ER(+) human breast cancer. In addition, neutralization of the antibody activity was not achieved with freshly prepared ER(+) cytosols. Formaldehyde-treated cytosols were essential. These results ought to caution investigators in determining in vivo location of antigens based on the staining pattern obtained in fixed tissues. Furthermore, this effect of formaldehyde on estrogen receptors may be applicable to other steroid hormone receptors.     

Immunolocalization of a nuclear protein bound to the sphere organelle during oogenesis and embryogenesis inPleurodeles waltl

Summary The distribution of a nuclear antigen ofPleurodeles waltl oocytes, recognized by the monoclonal antibody B24/1, has been studied during oogenesis and early embryonic development. In stage I oocytes the antigen was localized in the nucleoplasm and on two atypical structures of lampbrush chromosomes, the spheres (S) and the mass (M). The immunostaining increased as the oocyte developed. In stage VI oocytes, the nucleoplasm and spheres showed intense staining. At this stage, the nucleoplasm often contained free spheres which were also labelled. The staining of M diminished during oogenesis, as did its size. Immunoblots of nuclear proteins of oocytes at different stages confirmed that there was an accumulation of this protein during oogenesis. During embryonic development, the nuclei of all the cells of blastula and gastrula were labelled by this antibody: there was no embryonic regionalization. Starting from the neurula stage, the staining progressively disappeared from the nuclei of ectodermal and mesodermal cells. In the tailbud stage, only the endodermal cell nuclei showed faint staining. Immunoblots of proteins from embryos of different stages showed that the quantity of this protein was constant until the young gastrula stage and then decreased progressively; in the young tailbud stage, this protein was practically absent. B24/1 is the first described protein of the sphere. This protein is accumulated in the oocyte nucleus and behaves like a maternal polypeptide, shifting early in the nuclei during embryonic development. Thus, B24/1 probably has a function required from the early developmental stages, perhaps in relation with small nuclear ribonucleoproteins.     

Changes in the distribution of the 34-kdalton tyrosine kinase substrate during differentiation and maturation of chicken tissues

We examined the distribution of the 34-kilodalton (34-kD) tyrosine kinase substrate in tissues of adult and embryonic chicken using both a mouse monoclonal antibody and a rabbit polyclonal antibody raised against the affinity purified 34 kD protein. We analyzed the localization by immunoblotting of tissue extracts, by immunofluorescence staining of frozen tissue sections, and by staining sections of paraffin-embedded organs by the peroxidase antiperoxidase method. The 34-kD protein was present in a variety of cells, including epithelial cells of the skin, gastrointestinal, and respiratory tracts, as well as in fibroblasts and chondrocytes of connective tissue and mature cartilage, and endothelial cells of blood vessels. The 34-kD protein was also found in subpopulations of cells in thymus, spleen, bone marrow, and bursa. The protein was not detected in cardiac, skeletal, or smooth muscle cells, nor in epithelial cells of liver, kidney, pancreas, and several other glands. Although most neuronal cells did not contain the 34-kD protein, some localized brain regions did contain detectable amounts of this protein. The 34-kD protein was not detected in actively dividing cells of a number of tissues. Changes in the distribution of the 34-kD protein were observed during the differentiation or maturation of cells in several tissues including epithelial cells of the skin and gastrointestinal tract, fibroblasts of connective tissue, and chondroblasts.     

Cyclin/PCNA immunostaining as an alternative to tritiated thymidine pulse labelling for marking S phase cells in paraffin sections from animal and human tissues

Paraffin sections from animal or human tissues fixed in different fixatives were submitted to immunostaining with the mouse monoclonal antibody 19A2, developed by Ogata et al. (1987a) against cyclin/PCNA. Detection of the bound antibody was performed by the indirect method with biotinylated sheep antibody and streptavidin-biotin-peroxidase complexes. No, or faint, nuclear staining was seen in material fixed in ethanol, Bouin, Bouin-Hollande, Carnoy or formaldehyde, whereas readily detectable immunocytochemical reaction was constantly observed over nuclei of methanol-fixed tissues. Hydrolysis with 2 N HCl prior to immunocytochemistry (as currently performed to render incorporated BrdU accessible to antibodies) somewhat improved the results with Bouin or Carnoy and markedly augmented the intensity of the peroxidase reactions in formaldehyde and in methanol-fixed tissues. The distribution of the positive nuclei in the two latter cases coincided with the proliferative compartment. On the other hand, double labelling with [3H]-thymidine and with the cyclin/PCNA antibody revealed that in methanol-fixed tissues the cyclin/PCNA labelling index did not differ by more than 6% from the [3H]-thymidine index. Besides the two labels overlapped in a proportion of labelled cells that was in reasonable agreement with expectation considering cells flow in and out of S phase since the time of [3H]-thymidine injection. This indicates that both labels recognize the same cells in this material. In contrast, in formaldehyde-fixed tissues, the cyclin/PCNA labelling index markedly exceeded the [3H]-thymidine labelling index. From this it is concluded that cyclin/PCNA immunostaining can be used: (1) In formaldehyde-fixed tissues (including existing material stored as paraffin blocks): for defining and mapping the proliferative (or germinative) compartment. (2) In methanol-fixed tissues as a substitute to the [3H]-thymidine autoradiographic labelling index. From this, a method is proposed (derived from classical 'double-labelling' technique) for measuring S phase duration in tissues fixed at a known interval time after a single labelling with [3H]-thymidine (or BrdU) and submitted to cyclin/PCNA immunocytochemical detection and to autoradiography (or to BrdU immunostaining).     

Production and characterization of a monoclonal antibody to human type III collagen

Human type III collagen from placenta was isolated and purified for use as an immunogen. A monoclonal antibody was produced which specifically recognizes epitopes unique to type III collagen. The specificity of the antibody was determined by inhibition ELISA, an immunoblot assay, and by immunoprecipitation. Results indicated that the monoclonal antibody recognized only the alpha 1(III) polypeptide chains and did not crossreact with type I, IV, or V collagen. The monoclonal antibody was also used for immunohistochemical localization of type III collagen in tissue sections of human placenta, bovine spleen, and lymph node. In placenta, both large and small blood vessels showed pronounced staining of the tunica media, which contains largely smooth muscle cells, known to synthesize type III collagen. In contrast, the intimal areas and endothelial cells showed no staining with the antibody. In the placental villi, staining was limited to the villous core, where fine fibrillar structures showed strong staining. In lymph nodes, the capsule and pericapsular adipose cells were surrounded by a covering of type III collagen. Within the parenchyma of the node, staining was localized to a branching, reticular array of fine fibers. In the spleen, staining was pronounced in the capsule, splenic trabeculae, and white pulp, where blood vessel staining was especially prominent. The red pulp and splenic sinuses contain little or no type III collagen. The fine network-like or reticular staining pattern found in the lymph node parenchyma is consistent with the staining pattern of the protein reticulin, and suggests that type III collagen may be closely associated with reticulin in certain tissues. Since the role of type III in tissues is unclear, this reagent will be useful in providing new information in this regard.     

Evolutionary conservation in various mammalian species of the human proliferation-associated epitope recognized by the Ki-67 monoclonal antibody

The human proliferation-associated epitope recognized by the Ki-67 monoclonal antibody (MAb) was detected in proliferating normal and neoplastic cells of many mammalian species (lamb, calf, dog, rabbit, rat) besides human. In contrast, Ki-67 stained proliferating cells from other species weakly (mouse) or not at all (swine, cat, chicken, pigeon). The immunostaining pattern of Ki-67 in animal tissues was identical to that previously described in human: Ki-67 reacted only with cells known to proliferate (e.g., germinal center cells, cortical thymocytes) but not with resting cells (e.g., hepatocytes, brain cells, renal cells); this MAb produced a characteristic nuclear staining pattern (e.g., stronger labeling of nucleoli than of the rest of the nuclei and staining of chromosomes in mitotic figures); and Ki-67 crossreacted with the squamous epithelium in both animal and human tissues. In vitro studies showed that when quiescent (Ki-67-negative) NIH 3T3 fibroblasts or bovine peripheral blood lymphocytes were induced to proliferate, the appearance of Ki-67-positive cells paralleled the induction of cell proliferation caused by addition of fetal calf serum or PHA, respectively, to the cultures, and in both human and rat proliferating cells the Ki-67 expression closely paralleled the incorporation of [3H]-thymidine. These findings indicate that the epitope recognized by the Ki-67 MAb in human and animal species is the same. The widespread evolutionary conservation of the human proliferation-associated epitope recognized by the Ki-67 MAb suggests that it and/or its carrier molecule may play an important role in regulation of cell proliferation.     

Chick myotendinous antigen. I. A monoclonal antibody as a marker for tendon and muscle morphogenesis

Extracellular matrix components are likely to be involved in the interaction of muscle with nonmuscle cells during morphogenesis and in adult skeletal muscle. With the aim of identifying relevant molecules, we generated monoclonal antibodies that react with the endomysium, i.e., the extracellular matrix on the surface of single muscle fibers. Antibody M1, which is described here, specifically labeled the endomysium of chick anterior latissimus dorsi muscle (but neither the perimysium nor, with the exception of blood vessels and perineurium, the epimysium ). Endomysium labeling was restricted to proximal and distal portions of muscle fibers near their insertion points to tendon, but absent from medial regions of the muscle. Myotendinous junctions and tendon fascicles were intensely labeled by M1 antibody. In chick embryos, " myotendinous antigen" (as we tentatively call the epitope recognized by M1 antibody) appeared first in the perichondrium of vertebrae and limb cartilage elements, from where it gradually extended to the premuscle masses. Around day 6, tendon primordia were clearly labeled. The other structures labeled by M1 antibody in chick embryos were developing smooth muscle tissues, especially aorta, gizzard, and lung buds. In general, tissues labeled with M1 antibody appeared to be a subset of the ones accumulating fibronectin. In cell cultures, M1 antibody binds to fuzzy, fibrillar material on the substrate and cell surfaces of living fibroblast and myogenic cells, which confirms an extracellular location of the antigenic site. The appearance of myotendinous antigen during limb morphogenesis and its distribution in adult muscle and tendon are compatible with the idea that it might be involved in attaching muscle fibers to tendon fascicles. Its biochemical characterization is described in the accompanying paper ( Chiquet , M., and D. Fambrough , 1984, J. Cell Biol. 98:1937-1946).     

Application of a unique monoclonal antibody as a marker for nonproliferating subpopulations of cells of some tissue

A monoclonal antibody (clone S-30), directed to a protein of 57,000 daltons, was developed from the fusion of mouse myeloma cells and the spleen cells of mice injected with cytoskeletal extracts of fibroblasts that have been aged in in vitro culturing conditions according to a schedule of serial passaging (Cristofalo VJ, Charpentier R: J Tissue Culture Meth 6:117, 1981; Wang E: J Cell Biol, submitted). The staining activity of S-30 antibody was observed exclusively in the nuclei of nonproliferating senescent fibroblasts, but not in their young counterparts. Immunolocalization of S-30 antibody in frozen tissues from various sites reveals the positive staining reaction in the nuclear envelope region in those cells that are at the final stage of differentiation and are no longer replicating. These tissue sites include epithelial cells of the suprabasal layer of epidermis, hair sheath, and tongue, a subpopulation of fibroblasts in the dermis, chondrocytes, hepatocytes, and cells of cardiac muscle. The absence of S-30 staining activity was noted in tissues such as simple epithelium located in the gastrointestinal tract and kidney, and keratinocytes in the basal layer. These results suggest that the S-30 antibody can be used as a marker for nonproliferating cells both in cultured fibroblasts and in some tissues. It seems that the mechanism that controls the cessation of cell proliferation is related, in part, to the postmitotic expression of the 57,000 dalton protein.     

Characterization of a family of nuclear and chromosomal proteins identified by a monoclonal antibody

A monoclonal antibody (3C5) isolated from a mouse immunized with human chromatin stained the nuclei of all cultured cell types tested by indirect immunofluorescence. Experiments with HeLa and PtK1 cells demonstrated striking cell-cycle-related changes in the staining properties of the target antigen. A rapid increase in nuclear fluorescence was seen in prophase, with antigen located between the condensing chromosomes. In metaphase and anaphase cells antigen was present throughout the cytoplasm with the chromosomes apparently unstained. However, isolated metaphase chromosomes showed intense, peripheral staining. In telophase cells immunofluorescent staining was most intense among the decondensing chromosomes and by early G1 staining was predominantly nuclear. Nuclear fluorescence faded as cells progressed through interphase. By protein blotting and immunostaining, 3C5 recognized protein bands with subunit molecular weights of 130, 73, 50, 38, 32 and 22 to 25 kDa. These bands were present in all human and rodent cultured cell types tested. All bands were extracted by 6 M urea or 1% sodium dodecyl sulfate (SDS) but not by Triton X-100. Our results provide evidence against the involvement of a common carbohydrate moiety, in vitro proteolysis or non-specific cross reaction in this multi-banded pattern. The same family of proteins was detected in mitotic and interphase cells, suggesting that the changes in immunofluorescent staining through mitosis are due to changes in antigen accessibility. Subcellular fractionation experiments showed that all major bands were present in the nuclear fraction. Only two (50 and 32 kDa) were detected also in the post-nuclear membrane fraction and none were present in the soluble cytoplasmic fraction.(ABSTRACT TRUNCATED AT 250 WORDS)     

Steroid receptors in the developing and the adult rabbit endocervix and in endocervical epithelial cells isolated by flow cytometry

Immunocytochemistry with monoclonal antibodies H222 and JZB39 was used to study nuclear estrogen (ER) and progesterone (PgR) receptors, respectively, in the cervix during differentiation and in the adult rabbit. The undifferentiated state of the cervix of 2-week-old rabbits correlates with a paucity of immunoreactive nuclear ER, while the epithelium of most of these animals showed moderate immunostaining for the nuclear PgR. The cervical epithelium, stroma and muscle cells of 1-month-old rabbits, showed weak immunostaining for the ER, while staining for PgR remained comparable to that of 2-week-old rabbits. For 2-4-month old rabbits the epithelium was characterized by moderate immunostaining for the nuclear ER and strong immunostaining for the PgR. Strong, heterogeneous immunostaining for nuclear ER and PgR receptors in endocervical epithelial cells from 6-month-old (adult), estrous rabbits suggested there are subpopulations of cells that express differential sensitivity to steroid hormones. In order to characterize such subpopulations, live endocervical epithelial cells were sorted with a flow cytometer on the basis of forward angle light scatter (FSC) and side scatter (SSC) signals which correlated with cell size and secretory granule content, respectively. Secretory cells, as verified by ultrastructural analysis and histochemical staining, expressed the highest FSC and SSC signals and were designated fraction "a". Changes in the hormonal status of the animals altered the intrinsic light scatter properties of fraction "a" cells as follows: maximum FSC and SSC signals were reported for cells from estrous animals; ovariectomy or progesterone-dominance decreased cell size (FCS) and secretory granule content (SSC), while treatment of ovariectomized rabbits with estradiol increased both parameters. When fraction "a" cells from estrous rabbits were incubated with the monoclonal antibodies, two distinct subpopulations of secretory cells were identified by intensity and pattern of nuclear staining for the ER and PgR. Changes in the hormonal status of the animals produced changes in the intensity of nuclear immunostaining, however both cell types remained distinguishable on the basis of immunostain pattern reflecting either permanent or transitory differences in them, and differential hormone sensitivity. The presence of nuclear ER and PgR proteins in these cells confirms their function is bireceptor-mediated.     

Subcellular immunolocalization of protein kinase CK2 in normal and carcinoma cells.

CK2 is a messenger-independent protein serine/threonine kinase that has been implicated in cell growth and proliferation. Our recent analysis of squamous cell carcinomas of the head and neck (SCCHN) revealed a significant elevation in CK2 activity in these tumor cells relative to normal mucosa of the upper aerodigestive tract and suggested a correlation with aggressive tumor behavior and poor clinical outcome. In order to further define the distribution of CK2 in these tissues, we have examined the immunohistochemical staining pattern of surgical specimens of both SCCHN tumors and normal upper aerodigestive tract mucosa using a monoclonal antibody directed against the catalytic subunit CK2-alpha of the kinase, and have compared these data with the subcellular distribution of CK2 activity in these same tissues. These measurements showed that CK2 is predominantly localized to the nuclei of the tumor cells, which agreed closely with the immunohistochemical staining pattern of CK2-alpha in tumor cells. The chiefly nuclear distribution of CK2-alpha immunostaining found consistently in SCCHN tumor cells and tumor-infiltrating lymphocytes contrasted with a relatively more predominant cytosolic staining pattern exhibited by various cellular constituents of normal oropharyngeal mucosa. The immunostaining pattern of CK2-alpha revealed that staining was observed in the cells stained for the proliferation-marker Ki-67; however, strong distinct immunostaining for CK2-alpha was also observed in large numbers of other cells in these same tumors, suggesting that CK2 elevation in these tumors is not a reflection of proliferative activity alone, but may also relate to the pathobiological behavior of the tumor.     

Localization of tropomyosin in mouse embryo fibroblasts.

Antiserum to chick skeletal muscle tropomyosin was used to localize tropomyosin in mouse embryo fibroblasts by the indirect fluorescein labeled antibody technique. Specific staining was observed cytoplasmic fibers, which extended out into the cell processes. The staining pattern in these cells is similar to that previously described by others for actin. This observation suggests that in fibroblasts tropomyosin, like actin, is localized in fibers in the cytoplasm.