M. Vermey

Fmr1 knockout mice: A model to study fragile X mental retardation

Male patients with fragile X syndrome lack FMR1 protein due to silencing of the FMR1 gene by amplification of a CGG repeat and subsequent methylation of the promoter region. The absence of FMR1 protein leads to mental retardation, aberrant behavior, and macroorchidism. Hardly anything is known about the physiological function of FMR1 and the pathological mechanisms leading to these symptoms. Therefore, we designed a knockout model for the fragile X syndrome in mice. The knockout mice lack normal Fmr1 protein and show macroorchidism, learning deficits, and hyperactivity. Consequently, this knockout mouse may serve as a valuable tool in the elucidation of the physiological role of FMR1 and the mechanisms involved in macroorchidism, abnormal behavior, and mental retardation.

Inactivation of the HR6B ubiquitin-conjugating DNA repair enzyme in mice causes male sterility associated with chromatin modification.

The ubiquitin-conjugating yeast enzyme RAD6 and its human homologs hHR6A and hHR6B are implicated in postreplication repair and damage-induced mutagenesis. The yeast protein is also required for sporulation and may modulate chromatin structure via histone ubiquitination. We report the phenotype of the first animal mutant in the ubiquitin pathway: inactivation of the hHR6B-homologous gene in mice causes male infertility. Derailment of spermatogenesis becomes overt during the postmeiotic condensation of chromatin in spermatids. These findings provide a parallel between yeast sporulation and mammalian spermatogenesis and strongly implicate hHR6-dependent ubiquitination in chromatin remodeling. Since heterozygous male mice and even knockout female mice are completely normal and fertile and thus able to transmit the defect, similar hHR6B mutations may cause male infertility in man.

Androgen receptor expression in human tissues: an immunohistochemical study.

The cellular localization of the human androgen receptor was visualized immunohistochemically using a mouse monoclonal antibody (MAb) F39.4, directed against a fragment of the N-terminal domain of the androgen receptor. The nuclear immunoreactivity of various human tissues with F39.4 was generally consistent with earlier biochemical and autoradiographic data. However, previously suggested androgen receptor expression in thyroid, pancreatic, gastrointestinal, and bladder tissues was not confirmed immunohistochemically. Stratified squamous epithelia of vagina and cervix showed selective immunostaining of the basal cell layer, whereas in the preputial epithelium the intensity of immunoreactivity decreased gradually with maturation. In contrast, glandular epithelia of the sweat glands, male accessory sex organs, and female breast showed nearly exclusive F39.4 staining of the inner cylindric layer. In the testis, Sertoli cells, peritubular myoid cells, and interstitial cells were immunoreactive with MAb F39.4. Expression of the androgen receptor by smooth muscle tissue was largely confined to the male reproductive organs. The specificity and sensitivity of this simple and rapidly performed immunohistochemical technique in the detection of the human androgen receptor at the cellular and subcellular level makes it worthwhile to study tissue androgen receptor expression by immunohistochemistry in physiological and pathological states.

Pathological features of glycogen storage disease type II highlighted in the knockout mouse model

Glycogen storage disease type II (GSDII; Pompes disease) is an autosomal recessive disease caused by lysosomal α‐glucosidase deficiency. Skeletal muscle weakness is the most conspicuous clinical symptom of patients suffering from GSDII and skeletal muscle also is prominently involved in the knockout mouse model of this disease. Thus far, however, little detailed information has been published on the pathological changes in other mouse tissues. This paper aims to provide these data and gives a record of the clinical course of the mouse model over a 2‐year period. Four‐month‐old affected mice perform worse in a running wheel than their unaffected littermates, but do not yet display other clear signs of disease. The lysosomal glycogen storage, already evident at birth, becomes more severe in time, leading to muscle wasting by 9–10 months of age and then limb girdle weakness and kyphosis. The disease does not markedly shorten the animals life span despite the serious tissue pathology, which is not limited to heart and skeletal muscle, but is also seen in the smooth muscle of blood vessels and of the respiratory, digestive, and urogenital tracts. In addition, the mice have lysosomal glycogen storage in the liver, kidney, spleen, and salivary gland; in Schwann cells of the peripheral nerves, and in a subset of neurons in the central nervous system. By pathological criteria, the knockout mouse model parallels the human infantile form of GSDII and is attractive for studying the possible reversal of tissue pathology and symptomatology under different therapeutic regimes. Copyright

Influence of the microenvironment on invasiveness of human bladder carcinoma cell lines

Abstract To investigate the importance of the microenvironment in bladder cancer invasion, a panel of six bladder carcinoma cell lines (SD, RT112, JON, 1207, T24, and J82) was tested in both in vitro and in vivo invasion assays. Furthermore, invasiveness was correlated with the expression of components of the E-cadherin–catenin complex. The E-cadherin-negative cell lines, T24 and J82, displayed a high in vitro invasive capacity, whereas the E-cadherin-positive cell lines, SD and JON, completely lacked in vitro invasive capacity. In contrast, in vivo invasion was noted for all cell lines, with the exception of cell line JON. Most notably, SD formed highly invasive tumors in vivo. The in vivo invasiveness of the E-cadherin-positive bladder carcinoma cell lines was associated with a heterogeneous expression of the E-cadherin–catenin complex. The discrepancy between in vitro and in vivo invasive behavior implies that, in vivo, the microenvironment plays an important role in the establishment of the invasive phenotype. In addition, it was found that orthotopic xenografting of 1207 and T24 bladder carcinoma cells resulted in site-specific tumor take and an enhanced tumor outgrowth and invasiveness, respectively, compared with heterotopic (i.e., subcutaneous) inoculation. We conclude that the site-specific growth and invasion of the bladder carcinoma cell lines in vivo and the observed assay specific invasion (in vitro vs in vivo) points to an effect of the local (bladder) microenvironment on tumor cell behavior.

A comparative evaluation of various invasion assays testing colon carcinoma cell lines

SummaryVarious colon carcinoma cell lines were tested in different invasion assays, i.e. invasion into Matrigel, into confluent fibroblast layers and into chicken heart tissue. Furthermore, invasive capacity and metastatic potential were determined in nude mice. The colon carcinoma cells used were the human cell lines Caco-2, SW-480, SW-620 and HT-29, and the murine lines Colon-26 and -38. None of the human colon carcinoma cells migrated through porous membranes coated with Matrigel; of the murine lines, only Colon-26 did. When incubated in a mixture of Matrigel and culture medium non-invading cells formed spheroid cultures, whereas invading cells showed a stellate outgrowth. Only the heterogeneously shaped (epithelioid and stellate) cells of SW-480 and SW-620 and the spindle-shaped cells of Colon-26 invaded clearly confluent skin and colon fibroblasts as well as chicken heart tissue. However, when transplanted into the caecum of nude and syngeneic mice, all the lines tested were invasive with the exception of Caco-2 cells. We conclude that the outcome of in vitro tests measuring the invasive capacity of neoplastic cells is largely dependent on the test system used. Invasive capacity in vitro is strongly correlated with cells having a spindle cell shape, vimentin expression and E-cadherin down regulation. In contrast, HT-29 and Colon-38 cells having an epithelioid phenotype were clearly invasive and metastatic in vivo, but not in vitro.

DMSO-induced terminal differentiation and trisomy 15 in myeloid cell line transformed by the Rauscher murine leukemia virus

A new myeloid cell line was isolated from a myeloid leukemia obtained after infection of BALB/c mice with Rauscher murine leukemia virus (R-MuLV). After syngeneic transplantation of leukemic cells tumor formation was induced. Of one of these tumors a permanent cell line could be established. The cells grow in suspension culture with a doubling time of 18 h and morphologically and cytochemically show all the characteristics of myelocytes. The cells carry trisomy of chromosome 15. These cells prove to be completely independent of colony stimulating activity (CSA) regarding both their growth and their differentiation capacity. One of the main characteristics of this cell line is its inducibility for terminal differentiation after treatment with dimethylsulfoxide varying in concentrations from 0.5% to 1.5%. After two days metamyelocytes and after three to four days granulocytes and macrophages formed. The differentiation of these cells goes together with an increase of lysosomal enzyme activities like β-N-acetylglucosaminidase and lysozyme.

Clonal growth of colorectal-carcinoma cell lines transplanted to nude mice.

It is generally assumed that tumor progression is a micro‐evolutionary process in which increasingly aggressive clones, generated through genetic instability, emerge in an initially monoclonal lesion. The present study was undertaken to determine how rapidly a dominant clone will emerge from an initial polyclonal situation, and whether dominance of these clones is a prerequisite for the onset of metastasis. To this end, colon‐carcinoma cells were infected in culture with an amphotropic retroviral vector containing the neomycin‐phosphotransferase gene, which makes cells resistant to neomycin. A heterogeneous population of neomycin‐resistant cells carrying random retroviral integrations was xenografted to the subcutis and to the cecum of nude mice. The xenografts obtained, as well as the available metastases, were analyzed as to viral integrations by Southern blotting. The results show that, (i) clonal selection already takes place during growth of the primary tumor; (ii) dominant clones also generate metastases. The retroviral integration pattern of metastases turned out to be identical to that found in the primary xenografts. This pattern remained unchanged in tumors obtained after serial transplantations of cells cultured from metastases. Int. J. Cancer 72:1137–1141, 1997.

Multiparameter analysis of primary epithelial cultures grown on cyclopore membranes.

The use of porous membranes as culture support for epithelial cells has previously been shown to cause functional differentiation of these cells mimicking an in vivo condition, in contrast to culture on plastic. The different materials of which the membranes are made also have different properties, such as transparency, rigidity, and retention of molecules. Cyclopore membranes (polyethylene terephtalate) are permeable, transparent, rigid, and have low protein retention. In this study we examined the applicability of assessing multiple parameters on a single culture of primary epithelial cells on a Cyclopore membrane. Cultures of transitional epithelial cells on these membranes differentiate into an organoid-like epithelium. We were able to perform morphometric analysis during and after cell culture and to quantitate proliferation and differentiation by double immunoenzymatic staining. On these cultures, quantitative radiochemical analysis could also be achieved, retaining the morphology and the immunohistochemical staining. Cross-sections of paraffin-embedded and plastic-embedded cultures were analyzed qualitatively by light and transmission electron microscopy, respectively. Finally, cytokeratins in these cultures could also be visualized by immunofluorescence analysis. This suitability for simultaneous assessment of both qualitative and quantitative parameters on a single cell culture grown on a Cyclopore membrane reduces the need of biological materials and may lead to better insight into physiological processes.

Epithelial Regeneration of Transposed Intestine after High Doses of X-irradiation

The regeneration capacities of normal and transposed small bowel epithelium were compared in rats after applying high doses of X-irradiation. It has been shown that the potency of the mucosa to regenerate is much higher than assumed and that the mucosa can regenerate after single doses varying from 2000-5000 R. Even in the villus epithelium and in flat epithelium covering infiltrates of the lamina propria cells survive, which are still able to resume proliferative activity several days after irradiation.