Germline mutations in BMPR1A/ALK3 cause a subset of cases of juvenile polyposis syndrome and of Cowden and Bannayan-Riley-Ruvalcaba syndromes

Juvenile polyposis syndrome (JPS) is an inherited hamartomatous-polyposis syndrome with a risk for colon cancer. JPS is a clinical diagnosis by exclusion, and, before susceptibility genes were identified, JPS could easily be confused with other inherited hamartoma syndromes, such as Bannayan-Riley-Ruvalcaba syndrome (BRRS) and Cowden syndrome (CS). Germline mutations of MADH4 (SMAD4) have been described in a variable number of probands with JPS. A series of familial and isolated European probands without MADH4 mutations were analyzed for germline mutations in BMPR1A, a member of the transforming growth-factor beta-receptor superfamily, upstream from the SMAD pathway. Overall, 10 (38%) probands were found to have germline BMPR1A mutations, 8 of which resulted in truncated receptors and 2 of which resulted in missense alterations (C124R and C376Y). Almost all available component tumors from mutation-positive cases showed loss of heterozygosity (LOH) in the BMPR1A region, whereas those from mutation-negative cases did not. One proband with CS/CS-like phenotype was also found to have a germline BMPR1A missense mutation (A338D). Thus, germline BMPR1A mutations cause a significant proportion of cases of JPS and might define a small subset of cases of CS/BRRS with specific colonic phenotype.     

Evolutionary conservation of the human nucleolar protein fibrillarin and its functional expression in yeast

NOP1 is an essential nucleolar protein in yeast that is associated with small nucleolar RNA and required for ribosome biogenesis. We have cloned the human nucleolar protein, fibrillarin, from a HeLa cDNA library. Human fibrillarin is 70% identical to yeast NOP1 and is also the functional homologue since either human or Xenopus fibrillarin can complement a yeast nop1- mutant. Human fibrillarin is localized in the yeast nucleolus and associates with yeast small nucleolar RNAs. This shows that the signals within eucaryotic fibrillarin required for nucleolar association and nucleolar function are conserved from yeast to man. However, human fibrillarin only partially complements in yeast resulting in a temperature-sensitive growth, concomitantly altered rRNA processing and aberrant nuclear morphology. A suppressor of the human fibrillarin ts-mutant was isolated and found to map intragenically at a single amino acid position of the human nucleolar protein. The growth rate of yeast nop1- strains expressing Xenopus or human fibrillarin or the human fibrillarin suppressor correlates closely with their ability to efficiently and correctly process pre-rRNA. These findings demonstrate for the first time that vertebrate fibrillarin functions in ribosomal RNA processing in vivo.     

The expression and localization of urokinase-type plasminogen activator and its type 1 inhibitor are regulated by retinoic acid and fibroblast growth factor in human teratocarcinoma cells.

Human Tera 2 embryonal carcinoma cells switch gradually from rapidly growing undifferentiated cells to almost nonproliferating cells during retinoic acid (RA)-induced neuronal differentiation. This process is associated with the increased expression of type 1 plasminogen activator inhibitor (PAI 1) mRNA, and the secreted inhibitor is immobilized to the pericellular area. Furthermore, the differentiation is accompanied by a decrease in the amount of both the secreted tissue-type PA (tPA) and the mainly cell-associated urokinase-type PA (uPA) activity. In RA-differentiated cells, uPA becomes localized at the vinculin-rich cell-substratum adhesion sites. Fibroblast growth factor activity has been associated with various events during embryonal growth and with the regulation of proteolytic enzymes. A short-term treatment of the undifferentiated Tera 2 cells with basic fibroblast growth factor (bFGF) increases uPA mRNA levels and the cell-associated uPA activity, whereas the secretory tPA activity decreases. bFGF induces PAI 1 mRNA expression in the undifferentiated cells, but unlike PAI 1 protein after RA-treatment, the inhibitor does not accumulate around the cells but is released in the medium. A similar exposure to bFGF has less effect on the RA-differentiated Tera 2 cells. Under these conditions bFGF treatment leads to an increase in the amounts of PAI 1 and uPA mRNAs, but no changes in the localization of these components can be seen. Differentiation of human embryonal carcinoma cells is thus connected with an altered response to bFGF.     

Formation of vinculin plaques precedes other cytoskeletal changes during retinoic acid-induced teratocarcinoma cell differentiation

Immunofluorescence and immunoblotting techniques were used to study the presence and distribution of vimentin and keratin type intermediate filaments, actin, and vinculin (130 kD protein) during retinoic acid (RA)-induced differentiation of F9 embryonal carcinoma (EC) cells. The undifferentiated F9 cells regularly expressed vimentin, usually concentrated close to the nucleus, but not keratin. Actin appeared as short intracellular filaments and as spikes at the edges of the colonies, together with some diffuse cytoplasmic staining. F9 cells also showed a weak, diffuse cytoplasmic vinculin-specific fluorescence in addition to occasional small focal vinculin patches at the edges of the cell colonies. RA treatment led into a series of changes in the cytoskeletal organization of F9 cells. These changes were initiated by the appearance of distinct vinculin plaques and followed by formation of actin stress fibers and by profound changes in the organization of vimentin in the flattening cells. RA treatment finally led to the appearance and co-expression of keratin fibrils in many of the vimentin-containing F9 cells. This sequence of changes suggests that the vinculin-containing adhesion plaques may be important in the mechanism of RA-induced differentiation of EC cells.     

Differentiation and vascularization of the metanephric kidney grafted on the chorioallantoic membrane

The origin and development of mouse kidney vasculature were examined in chorioallantoic grafts of early kidney rudiments and of experimentally induced explants of separated metanephric mesenchymes. Whole kidney rudiments developed into advanced stages, expressed the segment-specific antigenic markers of tubules and the polyanionic coat of the glomeruli. In contrast to development in vitro, these grafts regularly showed glomeruli with an endothelial component and a basement membrane expressing type IV collagen and laminin. The glomerular endothelial cells in these grafts were shown to carry the nuclear structure of the host. This confirms the outside origin of these cells and the true hybrid nature of the glomeruli. When in vitro induced mesenchymes were grafted on chorioallantoic membranes, abundant vascular invasion was regularly found but properly vascularized glomeruli were exceptional. Uninduced, similarly grafted mesenchymal explants remained avascular as did the undifferentiated portions of partially induced mesenchymal blastemas. It is concluded that the stimulation of the host endothelial cells to invade into the differentiating mesenchyme requires the morphogenetic tissue interaction between the ureter bud and the mesenchyme. The induced metanephric cells presumably start to produce chemoattractants for endothelial cells at an early stage of differentiation. Kidney development thus seems to require an orderly, synchronized development of the three cell lineages: the branching ureter, the induced, tubule-forming mesenchyme, and the invading endothelial cells of outside origin.     

Exogenous fibronectin is not required for organogenesis in vitro

The biological effect of plasma fibronectin on the differentiation of embryonic mouse kidney and tooth was studied in organ cultures. Transferrin (50 micrograms/ml) was a strong mitogen for kidney cells, whereas the addition of soluble fibronectin (50 to 250 micrograms/ml) had no detectable effect on differentiation or proliferation. The same serum-free, transferrin-containing medium did not support tooth differentiation. However, fibronectin was not a necessary serum component because fibronectin-free serum supported tooth development. It was demonstrated with antibodies specific for human fibronectin that the exogenously added human fibronectin at 50 micrograms/ml did not become incorporated to the cultured organs. Only minimal incorporation to the kidney basement membrane area was observed when fibronectin concentration was 250 micrograms/ml. The mesenchymal stroma and the basement membranes of the kidney and tooth rudiments cultured in fibronectin-free media stained intensely with conventional fibronectin antibodies, indicating endogenous production of fibronectin. Outgrowing epithelial cells from isolated kidney tubules produced fibronectin as well as laminin. The results suggest that the fibronectin found in the stroma and basement membranes is an endogenous product of the developing tissues and that plasma fibronectin is not required for in vitro organogenesis. The results also indicate that it is difficult to study the effect of fibronectin on morphogenetic processes because it may not penetrate the organ explants in vitro.     

Cytoskeleton in preimplantation mouse development

This paper reviews the constituents of the cytoskeleton in the cells of the preimplantation mouse embryo and how they change as the development proceeds. The cytoskeleton can be divided into two distinct groups, that in the cytosplasm and that associated with the membrane. The first and better-known group contains microfilaments, microtubules and intermediate filaments, the second such components of the cell and nuclear membrane as spectrin-like protein and nuclear lamin. The filamentous components of the cytoplasmic cytoskeleton adhere to the nuclear and cell membrane at attachment points where specific proteins such as vinculin may mediate the interaction. Each cell of the early embryo has all of these components, but their morphological organization and molecular constitution alter as the embryo develops. These modifications are especially pronounced when the cleavage-stage embryo compacts and when the blastocysts forms and differentiates. These events represent the most critical stages of morphogenesis and cytodifferentiation in the preimplantation embryo. The cytoskeleton may thus have an important role in the control of the early mammalian development.     

Reorganization of intermediate filament cytoskeleton in induced metanephric mesenchyme cells is independent of tubule morphogenesis

The metanephric mesenchyme becomes converted into epithelial tubules if cultured in transfilter contact with an inductor tissue. The expression of intermediate filaments (IFs), used as cell-type-specific markers has been studied in this model system for differentiation and organogenesis. In immunofluorescence microscopy of frozen sections, the undifferentiated cells of isolated metanephric mesenchymes uniformly showed IFs of vimentin type only. Also, when cultured as a monolayer, cells from the uninduced mesenchymes showed only vimentin filaments. In frozen sections of transfilter explants, epithelial tubules apparently negative for vimentin could be seen after 3 days in culture, but expression of cytokeratin could not be demonstrated in the developing tubules until the fourth day of culture. Sections of explants cultured further showed tubule cells with distinct fibrillar cytokeratin positivity. The appearance of cytokeratin in the explants was also demonstrated with immunoblotting experiments, using two different cytokeratin antibodies. Expression of IFs was further examined in monolayer cultures of metanephric mesenchymes which had been initially exposed to a short transfilter induction pulse. In these experiments, cytokeratin-positive cells could be demonstrated after a total of 4 days in culture. Double immunofluorescence experiments showed varying amounts of vimentin in the cytokeratin-positive cells: after 4 days in culture, most cytokeratin-positive cells still showed vimentin-positivity although often in a nonfibrillar form. During further culture, gradual disappearance of vimentin-specific fluorescence was observed in cytokeratin-positive cells. The results suggest that the vimentin-positive metanephric mesenchyme cells lose their fibrillar vimentin organization upon induction that leads to kidney tubule formation. This change may be essential for the transformation from an undifferentiated mesenchymal cell into a specialized epithelial cell. Cytokeratin filaments, regarded as a marker for epithelial cells, seem to appear simultaneously with or soon after the change in vimentin organization. These changes in IF expression also occur in monolayer cultures of mesenchyme cells initially exposed to a short transfilter induction pulse. This suggests that epithelial differentiation, as revealed by the emergence of cytokeratin positivity, may occur even in the absence of a clear morphological differentiation and three-dimensional organization of the cells.     

Endophytic fungus decreases plant virus infections in meadow ryegrass (Lolium pratense)

We studied the effects of fungal endophyte infection of meadow ryegrass (Lolium pratense=Festuca pratensis) on the frequency of the barley yellow dwarf virus (BYDV). The virus is transferred by aphids, which may be deterred by endophyte-origin alkaloids within the plant. In our experiment, we released viruliferous aphid vectors on endophyte-infected and endophyte-free plants in a common garden. The number of aphids and the percentage of BYDV infections were lower in endophyte-infected plants compared to endophyte-free plants, indicating that endophyte infection may protect meadow ryegrass from BYDV infections.