RNGB: a Dictyostelium RING finger protein that is specifically located in maturing spore cells.

The RING finger is a form of zinc finger motif found in proteins of widely varying biological function. The Dictyostelium RNGB protein contains a RING finger and also a K-box, a sequence motif found in several plant homeotic proteins. The rngB mRNA is present at low concentration in growing cells and gradually increases in abundance throughout development. However, the RNGB protein is not detected until culmination and we present evidence that suggests it is translationally regulated. The protein is specifically localised in maturing spore cells and is cytoplasmic, suggesting that the RING finger does not function as a DNA binding domain.

Network incorporation of intermediate filament molecules differs between preexisting and newly assembling filaments.

When studying the way in which intermediate filaments assemble in vivo, it is important to distinguish between the incorporation of intermediate filament proteins into an existing intermediate filament network and the ability to form a new network within cells. To distinguish between these alternatives, we have made a hybrid construct consisting of the rod and tail domains of murine glial fibrillary acidic protein (GFAP) coupled to the head domain of bovine keratin 19, called K19GFAP. The assembly characteristics of K19GFAP were analyzed in vitro and in vivo. Replacement of the head domain with the bovine K19 sequence did not prevent the incorporation of K19GFAP into the existing network of vimentin intermediate filaments in NIH 3T3 cells but it was incompatible with de novo formation of filament networks in the epithelial cell line MCF-7, which lacks an endogenous vimentin network. By in vitro assembly studies, it was confirmed that K19GFAP was unable to assemble into typical intermediate filaments. We also investigated the ability of an appropriate type II keratin partner to rescue K19GFAP from incorporation into a vimentin network and initiate de novo filament assembly, using the fibroblast cell line KF-K8(3), an NIH 3T3 fibroblast cell line expressing a single human keratin, K8. The results confirm the importance of the coiled coil interactions in determining the fate of intermediate filament proteins. The results also emphasize that filament networks can not only tolerate but also incorporate assembly-deficient intermediate filament protein subunits.

Antibody markers of basal cells in complex epithelia.

In the course of immunohistochemical studies it has become apparent that there is a distinct phenotype of keratin expression that is shared by basal epithelial cells in a variety of different tissues. A basal cell can be defined as a cell in contact with a basal lamina but with no free luminal surface; this distinguishes it from a simple epithelial cell, which has a free luminal surface as well as basal lamina contact, and from stratifying suprabasal keratinocytes, which have neither basal lamina contact nor free luminal surface. All basal cells, whether they are in glandular ductal or secretory epithelia, or in stratified squamous epithelia, express the keratin pair K5 and K14. In this paper we describe monoclonal and polyclonal antibodies that are monospecific for both keratins 14 and 5 or are specific for denaturation-sensitive epitopes unique to basal cells, including five new monoclonal antibodies: LL001 and LL002 (to keratin 14), 2.1.D7 (to keratins 5, 6 and 8), and LH6 and LH8 (conformation-specific basal cell markers). These antibodies have been used to monitor the distribution of the basal cell phenotype and to demonstrate the expression of keratins 5 and 14 in this cell type, in both stratified epithelia and mixed epithelial glands. The consistent association of this keratin pair with basal cells suggests a possible specific function for these keratin in reinforcing epithelia under physical stress, whilst expression of these keratins may conflict with the differentiated functions of most simple epithelial cells.

Embryonic simple epithelial keratins 8 and 18: chromosomal location emphasizes difference from other keratin pairs.

The keratins 8 and 18 of simple epithelia differ from stratified epithelial keratins in tissue expression and regulation. To examine the specific properties of human keratin 8, we cloned and sequenced the cDNA from a placental mRNA expression library and defined the optimum state of such clones for expression in bacterial plasmid vectors. Using the polymerase chain reaction we identified and sequenced three introns and located the single active gene for keratin 8, out of a background of 9 to 24 pseudogenes, on chromosome 12. This chromosome contains several genes for type II keratins and also the gene for keratin 18, the type I keratin that is coexpressed with keratin 8. This location of both members of a keratin pair on a single chromosome is thus far unique among the keratin genes; it is consistent with the hypothesis that keratins 8 and 18 may be closer to an ancestral keratin gene than the keratins of more highly differentiated epithelia.