Hearing loss in Waardenburg syndrome: a systematic review.

Waardenburg syndrome (WS) is a rare genetic disorder characterized by hearing loss (HL) and pigment disturbances of hair, skin and iris. Classifications exist based on phenotype and genotype. The auditory phenotype is inconsistently reported among the different Waardenburg types and causal genes, urging the need for an up-to-date literature overview on this particular topic. We performed a systematic review in search for articles describing auditory features in WS patients along with the associated genotype. Prevalences of HL were calculated and correlated with the different types and genes of WS. Seventy-three articles were included, describing 417 individual patients. HL was found in 71.0% and was predominantly bilateral and sensorineural. Prevalence of HL among the different clinical types significantly differed (WS1: 52.3%, WS2: 91.6%, WS3: 57.1%, WS4: 83.5%). Mutations in SOX10 (96.5%), MITF (89.6%) and SNAI2 (100%) are more frequently associated with hearing impairment than other mutations. Of interest, the distinct disease-causing genes are able to better predict the auditory phenotype compared with different clinical types of WS. Consequently, it is important to confirm the clinical diagnosis of WS with molecular analysis in order to optimally inform patients about the risk of HL.

A novel RIPK4-IRF6 connection is required to prevent epithelial fusions characteristic for popliteal pterygium syndromes.

Receptor-interacting protein kinase 4 (RIPK4)-deficient mice have epidermal defects and fusion of all external orifices. These are similar to Bartsocas-Papas syndrome and popliteal pterygium syndrome (PPS) in humans, for which causative mutations have been documented in the RIPK4 and IRF6 (interferon regulatory factor 6) gene, respectively. Although genetically distinct, these syndromes share the anomalies of marked pterygia, syndactyly, clefting and hypoplastic genitalia. Despite the strong resemblance of these two syndromes, no molecular connection between the transcription factor IRF6 and the kinase RIPK4 was known and the mechanism underlying the phenotype was unclear. Here we describe that RIPK4 deficiency in mice causes epithelial fusions associated with abnormal periderm development and aberrant ectopic localization of E-cadherin on the apical membrane of the outer peridermal cell layers. In Xenopus, RIPK4 depletion causes the absence of ectodermal epiboly and concomitant gastrulation defects that phenocopy ectopic expression of dominant-negative IRF6. We found that IRF6 controls RIPK4 expression and that wild-type, but not kinase-dead, RIPK4 can complement the gastrulation defect in Xenopus caused by IRF6 malfunctioning. In contrast to the mouse, we observed only minor effects on cadherin membrane expression in Xenopus RIPK4 morphants. However, gastrulation defects were associated with a virtual absence of cortical actin in the ectodermal cells that face the blastocoel cavity and this was phenocopied in embryos expressing dominant-negative IRF6. A role for RIPK4 in actin cytoskeleton organization was also revealed in mouse epidermis and in human epithelial HaCaT cells. In conclusion, we showed that in mice RIPK4 is implicated in cortical actin organization and in E-cadherin localization or function, which can explain the characteristic epithelial fusions observed in PPSs. In addition, we provide a novel molecular link between IRF6 and RIPK4 that unifies the different PPSs to a common molecular pathway.

The chronic toxicity of molybdate to freshwater organisms. I. Generating reliable effects data.

The European Union regulation on Registration, Evaluation, Authorization and Restriction of Chemical substances (REACH) (EC, 2006) requires the characterization of the chronic toxicity of many chemicals in the aquatic environment, including molybdate (MoO(4)(2-)). Our literature review on the ecotoxicity of molybdate revealed that a limited amount of reliable chronic no observed effect concentrations (NOECs) for the derivation of a predicted no-effect concentration (PNEC) existed. This paper presents the results of additional ecotoxicity experiments that were conducted in order to fulfill the requirements for the derivation of a PNEC by means of the scientifically most robust species sensitivity distribution (SSD) approach (also called the statistical extrapolation approach). Ten test species were chronically exposed to molybdate (added as sodium molybdate dihydrate, Na(2)MoO(4)·2H(2)O) according to internationally accepted standard testing guidelines or equivalent. The 10% effective concentrations (EC10, expressed as measured dissolved molybdenum) for the most sensitive endpoint per species were 62.8-105.6 (mg Mo)/L for Daphnia magna (21day-reproduction), 78.2 (mg Mo)/L for Ceriodaphnia dubia (7day-reproduction), 61.2-366.2 (mg Mo)/L for the green alga Pseudokirchneriella subcapitata (72h-growth rate), 193.6 (mg Mo)/L for the rotifer Brachionus calyciflorus (48h-population growth rate), 121.4 (mg Mo)/L for the midge Chironomus riparius (14day-growth), 211.3 (mg Mo)/L for the snail Lymnaea stagnalis (28day-growth rate), 115.9 (mg Mo)/L for the frog Xenopus laevis (4day-larval development), 241.5 (mg Mo)/L for the higher plant Lemna minor (7day-growth rate), 39.3 (mg Mo)/L for the fathead minnow Pimephales promelas (34day-dry weight/biomass), and 43.2 (mg Mo)/L for the rainbow trout Oncorhynchus mykiss (78day-biomass). These effect concentrations are in line with the few reliable data currently available in the open literature. The data presented in this study can serve as a basis for the derivation of a PNEC(aquatic) that can be used for national and international regulatory purposes and for setting water quality criteria. Using all reliable data that are currently available, a HC(5,50%) (median hazardous concentration affecting 5% of the species) of 38.2 (mg Mo)/L was derived with the statistical extrapolation approach.

The p300/CBP acetyltransferases function as transcriptional coactivators of beta-catenin in vertebrates.

Wnt growth factors regulate a variety of developmental processes by altering specific gene expression patterns. In vertebrates beta-catenin acts as transcriptional activator, which is needed to overcome target gene repression by Groucho/TLE proteins, and to permit promoter activation as the final consequence of Wnt signaling. However, the molecular mechanisms of transcriptional activation by beta-catenin are only poorly understood. Here we demonstrate that the closely related acetyltransferases p300 and CBP potentiate beta-catenin-mediated activation of the siamois promoter, a known Wnt target. beta-catenin and p300 also synergize to stimulate a synthetic reporter gene construct, whereas activation of the cyclin D1 promoter by beta-catenin is refractory to p300 stimulation. Axis formation and activation of the beta-catenin target genes siamois and Xnr-3 in Xenopus embryos are sensitive to the E1A oncoprotein, a known inhibitor of p300/CBP. The C-terminus of beta-catenin interacts directly with a region overlapping the CH-3 domain of p300. p300 could participate in alleviating promoter repression imposed by chromatin structure and in recruiting the basal transcription machinery to promoters of particular Wnt target genes.

Cadherins and tissue formation: integrating adhesion and signaling.

Cadherins and other cell-substrate and cell-cell adhesion molecules play an essential role during development. Through their cytoplasmic interaction with the cytoskeleton, cell adhesion molecules physically link cells with the extracellular matrix and/or with each other. These interactions create architectural and structural entities that enable the tissues in the embryo to restrain the physical forces encountered during development. Regulated cell adhesion is also often the driving force of morphogenetic movements. This review goes beyond the adhesive aspect of cadherins, focusing on their roles as signaling molecules in development. We discuss how cadherins, through their effects on cell proliferation, cell death, cell polarization, and differentiation, play a role in the formation of tissues and organs in the developing embryo.

The C-terminal transactivation domain of beta-catenin is necessary and sufficient for signaling by the LEF-1/beta-catenin complex in Xenopus laevis.

Beta-catenin is a multifunctional protein involved in cell adhesion and communication. In response to signaling by Wnt growth factors, beta-catenin associates with nuclear TCF factors to activate target genes. A transactivation domain identified at the C-terminus of beta-catenin can stimulate expression of artificial reporter genes. However, the mechanism of target gene activation by TCF/beta-catenin complexes and the physiological relevance of the beta-catenin transactivation domain still remain unclear. Here we asked whether the beta-catenin transactivation domain can generate a Wnt-response in a complex biological system, namely axis formation during Xenopus laevis embryogenesis. We show that a chimeric transcription factor consisting of beta-catenin fused to the DNA-binding domain of LEF-1 induces a complete secondary dorsoanterior axis when expressed in Xenopus. A LEF-1-beta-catenin fusion lacking the C-terminal transactivation domain is impaired in signaling while fusion of just the beta-catenin transactivator to the DNA-binding domain of LEF-1 is sufficient for axis-induction. The latter fusion molecule is blocked by dominant negative LEF-1 but not by excess cadherin indicating that all events parallel or upstream of the transactivation step mediated by beta-catenin are dispensable for Wnt-signaling. Moreover, beta-catenin can be replaced by a heterologous transactivator. Apparently, the ultimate function of beta-catenin in Wnt signaling is to recruit the basal transcription machinery to promoter regions of specific target genes.

Adenomatous polyposis coli tumor suppressor protein has signaling activity in Xenopus laevis embryos resulting in the induction of an ectopic dorsoanterior axis.

Mutations in the adenomatous polyposis coli (APC) tumor suppressor gene are linked to both familial and sporadic human colon cancer. So far, a clear biological function for the APC gene product has not been determined. We assayed the activity of APC in the early Xenopus embryo, which has been established as a good model for the analysis of the signaling activity of the APC-associated protein beta-catenin. When expressed in the future ventral side of a four-cell embryo, full-length APC induced a secondary dorsoanterior axis and the induction of the homeobox gene Siamois. This is similar to the phenotype previously observed for ectopic beta-catenin expression. In fact, axis induction by APC required the availability of cytosolic beta-catenin. These results indicate that APC has signaling activity in the early Xenopus embryo. Signaling activity resides in the central domain of the protein, a part of the molecule that is missing in most of the truncating APC mutations in colon cancer. Signaling by APC in Xenopus embryos is not accompanied by detectable changes in expression levels of beta-catenin, indicating that it has direct positive signaling activity in addition to its role in beta-catenin turnover. From these results we propose a model in which APC acts as part of the Wnt/beta-catenin signaling pathway, either upstream of, or in conjunction with, beta-catenin.

Syndecan-1 expression in mammary epithelial tumor cells is E-cadherin-dependent.

E-cadherin is a Ca(2+)-dependent cell-cell adhesion molecule, which is mainly expressed in epithelial cells. Recent studies have shown that E-cadherin has an important role as an invasion suppressor molecule in epithelial tumor cells. Syndecan-1 is a cell surface proteoglycan that has been implicated in a number of cellular functions including cell-cell adhesion, cell-matrix anchorage and growth factor presentation for signalling receptors. Its suppression has also been shown to be associated with malignant transformation of epithelial cells. In order to better understand the coordinated regulation of cell-cell and cell-matrix interactions during malignant transformation, we have studied the expression of syndecan-1 in malignant mammary tumor cells genetically manipulated for E-cadherin expression. In invasive NM-e-ras-MAC1 cells, where E-cadherin was partially downregulated by specific antisense RNA, syndecan-1 expression was suppressed. Furthermore, transfection of E-cadherin cDNA into invasive NM-f-ras-TD cells resulted in the upregulation of syndecan-1 expression in association with decreased invasiveness. In both cases, regulation of syndecan-1 occurred post-transcriptionally, since syndecan-1 mRNA levels remained unchanged. Instead, a translational regulation is suggested, since syndecan-1 core protein synthesis was E-cadherin dependent. Another cell adhesion protein, beta 1-integrin was not affected by E-cadherin expression. The data provide an example of coordinated changes in the expression of two cell adhesion molecules, syndecan-1 and E-cadherin during epithelial cell transformation.

Morphotypic plasticity in vitro and in nude mice of epithelial mouse mammary cells (NMuMG) displaying an epithelioid (e) or a fibroblastic (f) morphotype in culture.

Transition from an epithelioid (e-) to a fibroblastic (f-) morphotype marks invasiveness in clinical and experimental cancer. To understand better the factors influencing such transitions, we have subcloned and manipulated mouse mammary gland (NMuMG) cell cultures and compared the invasive phenotype of multiple subclones in vitro and in vivo. Cell lines with an e-morphotype expressed E-cadherin homogeneously and were not invasive in vitro. Cells with an f-morphotype were E-cadherin-negative and became fully invasive in vitro upon expression of the ras oncogene. Invasive tumors were produced in node mice after subcutaneous injection of e-type or f-type cells. These tumors showed cystic, glandular and undifferentiated structures. Tumors from f-type cells were E-cadherin-negative whereas e-type tumors stained heterogeneously in immunohistochemical preparations. Our observations demonstrate the impact of the micro-ecosystem on the invasive phenotype, with in vivo downregulation of E-cadherin and stimulation of the e- to f-morphotype transition.

Transition from the noninvasive to the invasive phenotype and loss of alpha-catenin in human colon cancer cells.

Loss of epithelioid organization in carcinoma cell lines has been related to invasiveness and poor differentiation of tumors. We investigated the invasion in vitro of various human colon cancer cell lines. Most cell lines were noninvasive into chick heart fragments, and this correlated with an epithelioid morphotype. Only cell lines COLO320DM, SW620, and variants of HCT-8 and DLD-1 were invasive and nonepithelioid. We examined in these cell lines whether invasiveness was related to changes in the structure and function of the E-cadherin/catenin complex. E-cadherin functions as an invasion suppressor and as a cell-cell adhesion molecule when linked to the cytoskeleton via alpha-catenin plus beta- or gamma-catenin. All noninvasive cell lines showed E-cadherin linked to these catenins. The E-cadherin-dependent cell-cell adhesion function in these cell lines was demonstrated by two assays in vitro. It was interesting that all invasive cell lines showed a dysfunctional E-cadherin/catenin complex. COLO320DM, SW480, and SW620 cells were defective in E-cadherin expression, whereas the invasive variants of HCT-8 and DLD-1 lacked the alpha-catenin protein. From clonal epithelioid HCT-8 cultures with functional E-cadherin/catenin complexes, we subcloned, repeatedly, round cell variants that were again invasive and expressed no alpha-catenin protein. Our data suggest that reproducible transformations toward a more invasive phenotype in HCT-8 cells are associated with down-regulation of alpha-catenin. The mechanisms of this transformation and the level of alpha-catenin down-regulation are currently investigated.

Micro-encapsulation of MDCK-ras-e cells prevents loss of E-cadherin invasion-suppressor function in vivo.

The invasion-suppressor molecule E-cadherin mediates Ca(2+)-dependent cell aggregation and prevents invasion. E-cadherin-positive Madin-Darby canine kidney (MDCK) cells that were non-invasive in vitro formed, upon i.p. injection, tumors that were invasive. Differentiated tubular tumor areas showed an intense immuno-signal for E-cadherin at intercellular contacts, whereas undifferentiated structures did not. Cell lines derived from such tumors turned out to be invasive in vitro and showed decreased Ca(2+)-dependent cell aggregation but no change in E-cadherin immunopositivity. This combination of phenotypes indicated a loss of the E-cadherin invasion-suppressor function. Micro-encapsulation of i.p.-injected cells prevented the loss of the E-cadherin invasion-suppressor function. We concluded that this loss in vivo was dependent upon immediate contacts between tumor cells and host cells or upon host factors that could not cross the capsule membrane.

Enlarged cell-associated proteoglycans abolish E-cadherin functionality in invasive tumor cells.

Mouse and dog epithelial cell lines, expressing high levels of the Ca(2+)-dependent cell-cell adhesion molecule E-cadherin in vitro, generated invasive and metastatic tumors in athymic mice. From these tumors, neoplastic cell lines were isolated. All ex vivo isolates retained high expression levels of E-cadherin at their surface. Nevertheless, some showed a fusiform morphotype, were defective in Ca(2+)-dependent cell aggregation, and were invasive in vitro, indicating that E-cadherin was not functional. Cell-associated proteoglycans were found to be enlarged in these variants as compared to their counterparts with functional E-cadherin. Treatment of the cells with the drug 4-methylumbelliferyl beta-D-xyloside specifically reduced the amount and size of cell-associated proteoglycans. This same drug induced an epithelial morphotype, increased Ca(2+)- and E-cadherin-dependent cell aggregation, and abrogated invasiveness without influencing E-cadherin expression levels. Our results indicate that enlarged proteoglycans can prevent the homophilic binding of E-cadherin, probably by steric hindrance. This is one more mechanism by which carcinomas may counteract invasion-suppressor genes and acquire malignancy.

Downregulation in vivo of the invasion-suppressor molecule E-cadherin in experimental and clinical cancer.

The invasion-suppressor molecule E-cadherin (E-CAD) can be regulated at multiple levels: synthesis, processing and stability of mRNA; synthesis, processing and stability of protein; localization and posttranslational modification of protein; binding to catenins (E-CAD-associated proteins); and size and charge of cell surface glycosaminoglycans. Loss of E-CAD antigen and of E-CAD function in vivo has been observed with cell lines that homogeneously expressed functional E-CAD in vitro. These observations led to the idea that factors in the host may downmodulate E-CAD on the cancer cells, thereby promoting cell invasion. Nude mouse cancers that were homogeneously E-CAD-positive and noninvasive in vitro, formed by epithelioid MDCK or NMuMG cells, stained heterogeneously for E-CAD; such cancers were invasive and metastatic. The in vivo downmodulation appeared to be transient. Ex vivo cultures from primary cancers, as well as from metastases, produced homogeneously E-CAD-positive and noninvasive cells. Downmodulation did not occur when cells were micro-encapsulated and then implanted in the mouse, suggesting a role for immediate cancer cell-host cell contact. Similar in vitro/in vivo/ex vivo experiments with mouse MO4 fibrosarcoma cells, transfected with E-CAD cDNA under the control of a b-actin promotor, showed downregulation at the transcriptional or mRNA stability level. This downregulation was rapidly reversible upon ex vivo culture of the tumor cells. TGF-bl and IGF-I were found, respectively, to downregulate and upregulate the expression or the function of E-CAD. We speculate that IGF-1 restores the function of E-CAD through interaction of the IGF-I tyrosine kinase receptor with the catenin-actin cytoskeletal complex. In human cancers, immunohistochemistry has revealed changes in E-cadherin that agree with the experimental data on transient downmodulation of the invasion-suppressor function of E-cadherin by host factors.

Neoplastic progression of human and rat intestinal cell lines after transfer of the ras and polyoma middle T oncogenes.

BACKGROUND: Activation of the p21ras and pp60c-src oncoproteins occurred at high incidence in the early stage of human colorectal carcinogenesis. Our study aimed to investigate the role of these signal-transduction pathways in the process of initiation and promotion of the malignant phenotype in intestinal cells. METHODS: The human Ha-ras and the polyoma middle T (Py-MT) viral oncogenes were transferred into large T oncogene of simian virus 40 immortalized rat intestinal epithelial SLC-44 cells and human colonic adenocarcinoma Caco-2 cells. RESULTS: These transfers conferred the tumorigenic and invasive phenotypes on immortalized SLC-44 cells and potentiated the tumorigenicity of Caco-2 cells and markedly repressed the terminal differentiation of this cell line. In SLC-44T cells, induction of the invasive phenotype by the activated Ha-ras oncogene correlated with weak expression of E-cadherin and reduced accumulation of the transcripts encoding the basement membrane components alpha 1 (IV) collagen, nidogen, and BM40, which might result partly from the inactivation of the transforming growth factor beta signaling pathway. The down-regulation of the alpha 1 (IV) collagen messenger RNA in SLC-44T cells was not due to the protein kinase C-dependent pathways or the secretion of autocrine factor(s). CONCLUSIONS: These results suggest that the activation of the p21ras and Py-MT/pp60c-src oncogenic pathways are critical effectors at different stages of colorectal carcinogenesis and in Caco-2 cells interferes with the program of enterocyte differentiation.

Insulin-like growth factor I activates the invasion suppressor function of E-cadherin in MCF-7 human mammary carcinoma cells in vitro.

The calcium-dependent cell-cell adhesion molecule E-cadherin has been shown to counteract invasion of epithelial neoplastic cells. Using three monoclonal antibodies, we have demonstrated the presence of E-cadherin at the surface of human MCF-7/6 mammary carcinoma cells by indirect immunofluorescence coupled to flow cytometry and by immunocytochemistry. Nevertheless, MCF-7/6 cells failed to aggregate in a medium containing 1.25 mM CaCl2, and they were invasive after confrontation with embryonic chick heart fragments in organ culture. Treatment of MCF-7/6 cells with 0.5 microgram ml-1 insulin-like growth factor I (IGF-I) led to homotypic aggregation within 5 to 10 min and inhibited invasion in vitro during at least 8 days. The effect of IGF-I on cellular aggregation was insensitive to cycloheximide. However, monoclonal antibodies that interfered with the function of either the IGF-I receptor (alpha IR3) or E-cadherin (HECD-1, MB2) blocked the effect of IGF-I on aggregation. The effects of IGF-I on aggregation and on invasion could be mimicked by 1 microgram ml-1 insulin, but not by 0.5 microgram ml-1 IGF-II. The insulin effects were presumably not mediated by the IGF-I receptor, since they could not be blocked by an antibody against this receptor (alpha IR3). Our results indicate that IGF-I activates the invasion suppressor role of E-cadherin in MCF-7/6 cells.

E-cadherin expression: a counterbalance for cancer cell invasion.

Invasion, eventually leading to metastasis, is presented as the result of a balance between the activation of 2 sets of genes, coined i+ (invasion promotor) and i- (invasion suppressor) genes. Experiments in vitro have indicated that the homotypic homophilic epithelial cell--cell adhesion molecule E-cadherin (L-CAM; uvomorulin; cell CAM 120/80; Arc-1; rrl antigen) is an i- gene product. In several cell families, manipulation of E-cadherin at the level of the protein by antibody-mediated inactivation, at the level of the mRNA by antisense DNA transfection, and at the level of the genome by sense DNA transfection respectively resulted in induction and suppression of invasiveness. Nude mouse tumors from non-invasive homogeneously E-cadherin-positive cell populations were found to be invasive and metastatic. These tumors expressed E-cadherin in a heterogeneous manner, the undifferentiated cells being negative; but tumor-derived cells in culture were again E-cadherin-positive, indicating downregulation of this protein by host factors. Several types of human cancers showed a similar heterogeneity suggesting a relationship between downregulation of E-cadherin and invasion. Our current research focus is on the factors responsible for E-cadherin downregulation in experimental and human cancers.

Genetic manipulation of E-cadherin expression by epithelial tumor cells reveals an invasion suppressor role.

A cDNA encoding the cell-cell adhesion molecule E-cadherin was transfected into highly invasive epithelial tumor cell lines of dog kidney or mouse mammary gland origin. Transfectants with a homogeneously high expression of E-cadherin showed a reproducible loss of activity in two types of in vitro invasion assays. Invasiveness of these transfectants could be reinduced specifically by treatment with anti-E-cadherin antibodies. In vivo, they formed partly differentiated tumors, instead of fully undifferentiated tumors. Alternatively, a plasmid encoding E-cadherin-specific anti-sense RNA was introduced into noninvasive ras-transformed cells with high endogenous E-cadherin expression. The resulting down-regulation, albeit partial, rendered the cells invasive. These data provide direct evidence that E-cadherin acts as an invasion suppressor molecule.

Down-regulation of E-cadherin expression in Madin Darby canine kidney (MDCK) cells inside tumors of nude mice.

The 120-kDa cell-cell adhesion molecule E-cadherin is localized at the epithelial junctional complex and participates in the organization and maintenance of epithelia. The Madin Darby canine kidney (MDCK) cell line expresses E-cadherin in a stable way and forms polarized epitheloid structures in vitro. Harvey-murine-sarcoma-virus-transformed derivatives (MDCK-ras) produce malignant (i.e., invasive and metastatic) tumors in nude mice. We obtained evidence that E-cadherin is down-regulated in nude mouse tumors and that this down-regulation is reversible. MDCK-ras-e cell lines were cloned in vitro from MDCK-ras cell cultures. They showed an epithelioid morphotype and expressed E-cadherin at homogeneously high level. This characteristic has been conserved for at least 60 passages in vitro. MDCK-ras-e cells were not invasive in vitro. When injected into nude mice, however, they produced invasive and metastatic tumors. Primary tumors as well as large metastases were heterogeneous, showing E-cadherin-positive well differentiated epithelial structures and E-cadherin-negative undifferentiated areas. Metastasis-derived cell cultures contained both E-cadherin-positive and E-cadherin-negative MDCK-ras-e cells during early passages in vitro. During further culture, however, they regained the homogeneous E-cadherin-positive characteristic of the original MDCK-ras-e cell line. The behavior of MDCK-ras-e cells in vitro, as compared with its in vivo behavior, points to the existence of host factors which are able to down-regulate E-cadherin expression. We hypothesize that this down-regulation plays a basic role in invasion.

Numerical evaluation of the invasion of closely related cell lines into collagen type I gels.

Cells were seeded on top of a reconstituted collagen gel layer, and their migration into the gel was evaluated as an assay for invasive behavior. The method was standardized by measuring the depth of migration of each cell in a defined volume of the gel. We developed a microscope stage, controlled by a computer program. This semiautomatic counting method allowed precise vertical localization of each cell in a collagen gel with an error of less than 0.1 micron. To test the discriminative power of the assay, we used cell lines which were known to be invasive or noninvasive in other assays. Closely related variants of 2 cell families were chosen: (1) one family derived from a mouse mammary gland (NMuMG), and (2) one derived from a mouse T cell lymphoma (BW5147). The assay could discriminate between invasive and noninvasive variants of related cell lines within the same family. The profile of the number of cells in each layer of the gel provided additional discrimination between the different cell lines. Furthermore, the assay allowed direct microscopic observation of cells migrating in the collagen gel. The present standardization makes the collagen assay suitable for semiautomatic testing of the invasive phenotypes in cell populations from the same as well as from different cell families.