Vitauts I. Kalnins

Ocular retardation mouse caused by Chx10 homeobox null allele: Impaired retinal progenitor proliferation and bipolar cell differentiation

Ocular retardation (or) is a murine eye mutation causing microphthalmia, a thin hypocellular retina and optic nerve aplasia. Here we show that mice carrying the orJ allele have a premature stop codon in the homeobox of the Chx1O gene, a gene expressed at high levels in uncommitted retinal progenitor cells and mature bipolar cells. No CHX10 protein was detectable in the retinal neuroepithelium of orJ homozygotes. The loss of CHX10 leads both to reduced proliferation of retinal progenitors and to a specific absence of differentiated bipolar cells. Other major retinal cell types were present and correctly positioned in the mutant retina, although rod outer segments were short and retinal lamination was incomplete. These results indicate that Chx10 is an essential component in the network of genes required for the development of the mammalian eye, with profound effects on retinal progenitor proliferation and bipolar cell specification or differentiation

Developmental expression of a novel murine homeobox gene (Chx10): Evidence for roles in determination of the neuroretina and inner nuclear layer

Few potential regulatory proteins of vertebrate retinal development have been identified. We describe a 39 kDa murine polypeptide (Chx10) with a homeodomain 82% identical to that of the nematode protein ceh-10. In the developing mouse, the Chx10 transcript is expressed throughout the anterior optic vesicle and all neuroblasts of the optic cup. In the mature retina, the Chx10 protein is restricted to the inner nuclear layer, in which its expression decreases from the outer to the inner margin. Chx10 transcripts are also detected in regions of the developing thalamus, hindbrain, and ventral spinal cord. The data suggest that Chx10 plays critical roles in the formation of the neuroretina and in the development and maintenance of the inner nuclear layer.

Human microphthalmia associated with mutations in the retinal homeobox gene CHX10.

Isolated human microphthalmia/anophthalmia, a cause of congenital blindness, is a clinically and genetically heterogeneous developmental disorder characterized by a small eye and other ocular abnormalities. Three microphthalmia/anophthalmia loci have been identified, and two others have been inferred by the co-segregation of translocations with the phenotype. We previously found that mice with ocular retardation (the or-J allele), a microphthalmia phenotype, have a null mutation in the retinal homeobox gene Chx10 (refs 7,8). We report here the mapping of a human microphthalmia locus on chromosome 14q24.3, the cloning of CHX10 at this locus and the identification of recessive CHX10 mutations in two families with non-syndromic microphthalmia (MIM 251600), cataracts and severe abnormalities of the iris. In affected individuals, a highly conserved arginine residue in the DNA-recognition helix of the homeodomain is replaced by glutamine or proline (R200Q and R200P, respectively). Identification of the CHX10 consensus DNA-binding sequence (TAATTAGC) allowed us to demonstrate that both mutations severely disrupt CHX10 function. Human CHX10 is expressed in progenitor cells of the developing neuroretina and in the inner nuclear layer of the mature retina. The strong conservation in vertebrates of the CHX10 sequence, pattern of expression and loss-of-function phenotypes demonstrates the evolutionary importance of the genetic network through which this gene regulates eye development.

Cloning of the CDNA for a novel photoreceptor membrane protein (rom-1) identifies a disk rim protein family implicated in human retinopathies

The molecules essential to the continual morphogenesis and shedding of the opsin-containing disks of vertebrate photoreceptors are largely unknown. We describe a 37 kd protein, rom-1, which is 35% identical and structurally similar to peripherin/retinal degeneration slow (rds). Like peripherin, rom-1 is a retina-specific integral membrane protein localized to the photoreceptor disk rim. The two proteins are similarly oriented in the membrane, and each has a highly conserved (15/16 residues) cysteine- and proline-rich domain in the disk lumen. Although both rom-1 and peripherin form disulfide-linked dimers, they do not form heterodimers with each other, but appear to associate noncovalently. These results suggest both that rom-1 and peripherin are functionally related members of a new photoreceptor-specific protein family and that rom-1, like peripherin, is likely to be important to outer segment morphogenesis. The association of mutations in RDS with retinitis pigmentosa indicates that ROM1 is a strong candidate gene for human retinopathies.

Role of cadherins in the transendothelial migration of melanoma cells in culture.

Transmigration of cancer cells through the vascular endothelium (diapedesis) is a key event in tumor metastasis. To investigate mechanisms involved in diapedesis, we used laser scanning confocal microscopy to examine the distribution of cadherins of WM239 melanoma cells as they migrated through a monolayer of activated human umbilical vein endothelial cells (EC) cultured on matrigel. Cadherins, including VE-cadherin, but not N-cadherin, were enriched in contacts between EC, whereas N-cadherin, but not VE-cadherin, was found in contacts between melanoma cells. During the early stages of diapedesis, EC located below the attached melanoma cells decreased in height and VE-cadherin disappeared from the EC contact located underneath the melanoma cell. Transendothelial migration began with small melanoma cell processes penetrating the VE-cadherin-negative regions between the EC. Subsequently, melanoma cells became intercalated between EC. Despite the absence of both VE-cadherin and N-cadherin, other members of the cadherin family were present in the heterotypic contacts between EC and melanoma cells. EC surrounding the intercalated melanoma cell subsequently extended processes and spread over the melanoma cell to re-form the endothelial monolayer. Interestingly, the leading margins of these EC processes contained high levels of N-cadherin, but not VE-cadherin. VE-cadherin-rich cell-cell contacts, however, reformed between advancing endothelial processes when they met above the melanoma cell. As the melanoma cells came into contact with the underlying matrigel, they spread out and adopted a fibroblast-like morphology. Addition of anti-N-cadherin antibodies to the assay resulted in a delay in the transendothelial migration of melanoma cells. Together, these results suggest that EC actively participate in diapedesis by disassembling and reassembling VE-cadherin-rich adherens junctions, and that N-cadherin plays an important role in the transmigration of melanoma cells and the reclosure of the endothelium.

Astrocyte cell lineage. III: The morphology of differentiating mouse astrocytes in colony culture

SummaryDisaggregated cells of newborn DBA/1J mouse neopallium were grown in colony cultures, and colonies of cells at various stages of differentiation along the astrocyte cell lineage were examined after 3 days, 1, 2 and 4 weeks by electron microscopy and by NBD-phallacidin which demonstrates the distribution of microfilaments. The earliest astrocyte precursor cells or glioblasts are closely apposed epithelial cells that rarely have junctions. Their scanty cytoplasm contains many free ribosomes but few microfilaments. The cells in the next stages of astrocyte lineage or proastroblasts are flat and are separated from each other to a variable degree. They have intercellular junctions associated with microfilaments and contain singly dispersed intermediate filaments. The proastroblasts gradually differentiate into astroblasts which have a similar morphology except that in addition to the singly distributed intermediate filaments they also contain intermediate filaments arranged into bundles of various sizes. The mature fibrous astrocytes have well-defined processes and distinct perikarya. They form from astroblasts in culture and also contain numerous bundles of intermediate filaments. The dibutyryl-cyclic AMP (dBcAMP)-induced astrocytes in culture in contrast are large stellate cells similar to reactive astrocytes found around sites of injury in the brain. On the basis of these and previous immunocytochemical studies of the formation and distribution of intermediate filaments in the cytoplasm of differentiating astrocytes, criteria are proposed for identification of different cells along the astrocyte lineage.

The distribution of tau and HMW microtubule-associated proteins in different cell types

Abstract To investigate the distribution of the tau and HMW microtubule-associated proteins (MAPS) and their relationship to microtubules in vivo, we have examined a wide variety of avian and mammalian cell types by immunofluorescence with antisera to these two proteins. Anti-HMW serum stains cytoplasmic microtubules in all mammalian cell types so far examined. However, anti-tau serum did not stain cytoplasmic microtubules in rat glial cells or in pig kidney cells. In mammalian neurons, fibroblasts and neuroblastoma cells, the staining of microtubules with both sera was similar. Anti-HMW serum did not stain primary cilia or cilia on isolated tracheal epithelial cells, whereas anti-tau serum did stain these ciliary microtubules. We believe these results indicate that some types of microtubules may be associated with only the tau or the HMW protein, whereas others may be associated with both tau and HMW protein. With respect to avian cells, anti-HMW serum did not stain microtubules in any of the three cell types examined, whereas the anti-tau serum stained them in two cell types. Furthermore, double diffusion tests indicated that anti-pig tau serum will precipitate both pig brain tau and tau protein isolated from chick brain, whereas anti-HMW serum will precipitate only pig brain and not chick brain HMW protein. We believe tau protein is antigenically similar in both avian and mammalian cells, whereas the HMW protein from these two sources is antigenically distinct.

Microtubules, microfilaments and adhesion patterns in differentiating chick retinal pigment epithelial (RPE) cells in vitro

The distribution of microtubules (MT), microfilaments (MF), and patterns of cell-to-substratum adhesion were studied by tubulin antibody labeling, NBD-phallacidin staining and by reflection interference contrast (RIC) microscopy respectively in colonies of differentiating RPE cells obtained from explants after 10 days in culture. In each colony three zones could be identified: a central zone of packed well-differentiated cuboidal cells (zone 1), an intermediate zone of more flattened, pleomorphic cells (zone 2) and a peripheral zone of very spread cells at the edge of the colony (zone 3). As visualized with antibodies to tubulin, the MT distribution in cells of each zone was distinctly different and correlated well with differences in cell shape. Changes in the distribution of MF were more striking. In the cuboidal well-differentiated cells of zone 1, prominent cortical bands but no stress fibers were observed after staining with NBD-phallacidin and RIC microscopy showed that the cells lacked strong adhesion to the substratum. Stress fibers, in addition to cortical bands of MF, were seen in the more spread, less differentiated cells of zone 2 and focal contacts were observed when these cells were examined by RIC microscopy. The flattened least differentiated cells in zone 3 lacked cortical bands but had prominent stress fibers. These cells displayed a variety of adhesion forms ranging from a mosaic of far and close contacts to numerous focal contacts and broad focal adhesions. Our results show that as the RPE cells display less differentiated morphologies, i.e. are more flattened and less densely packed towards the edge of the colony, there is a gradual decrease in the cortical bands of MF and an increase in the number and prominence of stress fibers. This increase in numbers of stress fibers is correlated with an increase in the cell adhesiveness to the substratum, as estimated by RIC microscopy. These results strongly support the general observation that normal epithelial cells in colonies tend to adhere to the substratum more strongly by marginal cells than by the more differentiated centrally located cuboidal cells which have well developed intercellular contacts.

Cell shape changes and cytoskeleton reorganization during transendothelial migration of human melanoma cells

Abstract An in vitro system has been established to study the migration of human melanoma cells through a monolayer of endothelial cells. Endothelial cells were cultured to confluence on Matrigel before the seeding of melanoma cells. Laser scanning confocal microscopy showed that, prior to migration, melanoma cells appeared round and showed cortical F-actin staining. The initial stage of transmigration was characterized by numerous membrane blebs protruding from basolateral surfaces of the melanoma cells, and contact regions showed an abundance of filaments arising in the underlying endothelial cells. Later, pseudopods from the melanoma cells inserted into contact regions between endothelial cells. Eventually, the melanoma cells intercalated with the endothelial cells. At this stage, many endothelial filament bundles terminated at contacts between the endothelial cells and the transmigrating melanoma cell, suggesting active interactions between the two cell types. Upon contact with the Matrigel, melanoma cells began to spread beneath the endothelium, displaying a fibroblastic morphology with prominent stress fibers. To reestablish the monolayer, adjacent endothelial cells extended processes over the melanoma cell. Tumor necrosis factor α did not affect the transmigration of melanoma cells from cell lines isolated from several stages of metastasis. However, tumor necrosis factor did promote the transmigration of melanoma cells derived from a non-metastatic lesion. These results thus define cell attachment and cell penetration of the monolayer as two distinct steps in transmigration and suggest that tumor necrosis factor may enhance the metastatic potential of tumor cells.

Adhesiveness and distribution of vinculin and spectrin in retinal pigmented epithelial cells during growth and differentiation in vitro

Colonies of chick retinal pigmented epithelial (RPE) cells offer an excellent model system for studying the organization of cytoskeleton in sheets of differentiating epithelial cells. The cells occupying the center of the colony resemble RPE cells in vivo and are cuboidal, pigmented, and relatively nonadherent while those toward the periphery gradually become flatter, nonpigmented, motile, and strongly adherent to the substratum. Immunofluorescence microscopy with antiserum against chicken erythrocyte alpha-spectrin reveals that this protein is present in the cortex of RPE cells in all parts of the colony. It is neither concentrated in, nor excluded from the regions occupied by the major microfilament bundles, and its distribution is not related to the adhesion patterns visualized by surface reflection interference microscopy. In contrast, the distribution of vinculin is closely correlated with the adhesiveness of RPE cells in different parts of the colony. Immunofluorescence microscopy reveals that in the RPE cells vinculin may be diffusely distributed in the cytoplasm; present in a cortical band outlining the cell borders; and present in focal contacts and adhesions. The distribution of vinculin is affected by the length of time the colonies grow in culture, by the degree of cell packing and by the adhesiveness of cells to the substratum. In RPE cells grown in vitro for short periods (less than or equal to 3 days) vinculin is found in focal contacts and adhesions in both the undifferentiated, well spread peripheral cells as well as in the differentiated, polygonally packed central cells of the colony. In RPE cells cultured for longer periods (greater than or equal to 14 days) vinculin is present in focal contacts and adhesions only in strongly adherent, undifferentiated cells at the edge of the colony. In packed central cells of both short- and long-term cultures vinculin is found in the cortical band which circumscribes the apical ends of cells at the level of the adherens type intercellular junctions. Its appearance in the cortical bands does not depend on the length of time the colonies are grown in vitro but on the presence of cell-cell contacts resulting from an increased degree of cell packing within the central part of the colony. These results are discussed in relation to the development and the role of extracellular matrix in determining the adhesiveness of RPE cells in vitro.