Faculty Bibliography

The asymmetric unit membrane (AUM) forms the apical plaques of mammalian urothelium and is believed to play a role in strengthening the urothelial apical surface thus preventing the cells from rupturing during bladder distention. We have shown previously that purified bovine AUMs contain four major integral membrane proteins: the uroplakins Ia (27 kDa), Ib (28 kDa), II (15 kDa), and III (47 kDa). This contradicts some previous reports indicating that some of these proteins are absent in AUMs of several species. Using an improved procedure, we isolated AUMs from, in addition to cattle, eight mammalian species (human, monkey, sheep, pig, dog, rabbit, rat, and mouse). The AUMs of these species appear morphologically similar bearing crystalline patches of 12-nm protein particles with a center-to-center spacing of 16.5 nm. Using antibodies raised against synthetic oligopeptides or individual bovine uroplakins, we established by immunoblotting that the four uroplakins are present in AUMs of all these species. The DNA-deduced amino acid sequences of bovine and mouse uroplakin II revealed 83% identity. These results indicate that uroplakins Ia, Ib, II, and III are the major protein components of probably all mammalian urothelial plaques, and that the sequence and three-dimensional structure of uroplakin molecules are highly conserved during mammalian evolution

The mammalian bladder epithelium elaborates, as a terminal differentiation product, a specialized plasma membrane called asymmetric unit membrane (AUM) which is believed to play a role in strengthening and stabilizing the urothelial apical surface through its interactions with an underlying cytoskeleton. Previous studies indicate that the outer leaflet of AUM is composed of crystalline patches of 12-nm protein particles, and that bovine AUMs contain three major proteins: the 27- to 28-kD uroplakin I, the 15-kD uroplakin II and the 47-kD uroplakin III. As a step towards elucidating the AUM structure and function, we have cloned the cDNAs of bovine uroplakin I (UPI). Our results established the existence of two isoforms of bovine uroplakin I: a 27-kD uroplakin Ia and a 28-kD uroplakin Ib. These two glycoproteins are closely related with 39% identity in their amino acid sequences. Hydropathy plot revealed that both have four potential transmembrane domains (TMDs) with connecting loops of similar length. Proteolytic digestion of UPIa inserted in vitro into microsomal vesicles suggested that its two main hydrophilic loops are exposed to the luminal space, possibly involved in interacting with the luminal domains of other uroplakins to form the 12-nm protein particles. The larger loop connecting TMD3 and TMD4 of both UPIa and UPIb contains six highly conserved cysteine residues; at least one centrally located cysteine doublet in UPIa is involved in forming intramolecular disulfide bridges. The sequences of UPIa and UPIb (the latter is almost identical to a hypothetical, TGF beta-inducible, TI-1 protein of mink lung epithelial cells) are homologous to members of a recently described family all possessing four transmembrane domains (the '4TM family'); members of this family include many important leukocyte differentiation markers such as CD9, CD37, CD53, and CD63. The tissue-specific and differentiation-dependent expression as well as the naturally occurring crystalline state of uroplakin I molecules make them uniquely suitable, as prototype members of the 4TM family, for studying the structure and function of these integral membrane proteins

The asymmetric unit membrane (AUM) is a highly specialized biomembrane elaborated by terminally differentiated urothelial cells. It contains quasi-crystalline arrays of 12-nm protein particles each of which is composed of six dumbbell-shaped subdomains. In this paper we describe the precursor sequence, processing and in vitro membrane insertion properties of bovine uroplakin II (UPII), a 15-kDa major protein component of AUM. The cDNA-deduced amino acid sequence revealed that UPII is synthesized as a precursor protein containing a cleavable signal peptide of approximately 26 amino acids, a long pro-sequence of approximately 59 residues harboring three potential N-glycosylation sites, and the mature polypeptide of 100 residues. In vitro translation of UPII mRNA demonstrated that UPII is indeed first synthesized as a 19-kDa precursor, which loses its signal peptide upon insertion into added microsomes; this process is accompanied by the acquisition of high mannose-type oligosaccharides giving rise to a 28-kDa precursor which is completely protected from the digestion by exogenous proteases. These results, together with the presence of a stretch of 25 hydrophobic amino acids at the C terminus, suggest that UPII protein is anchored to the lipid bilayer via its C-terminal membrane-spanning domain with its major N-terminal domain exposed luminally. The formation of the 15-kDa mature UPII requires the removal of the pro-sequence by a furin-like endoprotease. Since only mature UPII devoid of this pro-sequence can interact with 27-kDa uroplakin I, the proteolytic processing of UPII precursor may play an important role in regulating the assembly of AUM. Finally, we showed that genomic sequences cross-hybridizing with bovine UPII cDNA are present in many mammals suggesting that UPII performs a highly conserved function in the terminally differentiated cells of mammalian urinary bladder epithelium

Based on cell kinetic, morphological and several biological considerations, we have recently proposed that hair follicle stem cells reside in the bulge area of the upper follicle. We predicted that during early anagen the normally slow-cycling bulge stem cells may be activated by the abutting dermal papilla cells to undergo transient proliferation giving rise to keratinocytes of the lower follicle. In the present work, we performed tritiated thymidine-labeling of DNA-synthesizing cells and colcemid-arrest of mitotic figures on the skins of 20-23 and 75-80 day old SENCAR mice, when the follicles entered the anagen phase of the 2nd and 3rd hair cycles. The results clearly indicate that the normally slow-cycling bulge cells indeed undergo transient proliferation during early anagen. Similar results were obtained when the telogen follicles are experimentally induced to enter the 3rd hair cycle by plucking and by topical applications of phorbol ester or tretinoin. These results support the notion that bulge cells are follicular stem cells, and that transient proliferation of these cells is a critical feature of early anagen. However, the long duration of the 2nd telogen (> 30 days in mouse) suggests that a new anagen phase does not automatically result from the physical proximity of dermal papilla to the bulge cells, and that another 'factor' is required for the initiation of the 3rd anagen. The tremendous difference in the durations of the first and second telogen (lasting for 2-3 days and > 50 days, respectively) suggests that follicles can exist in a non-cycling state that may be conceptually equivalent to the G0 state of the cell cycle. Our results also underscore the fact that the first hair cycle is distinct from all the subsequent hair cycles in their cellular origin and morphological sequence, and thus should be regarded as a neogenic event

We and others have shown previously that corneal keratinocyte stem cells can proliferate in vitro better than their progeny cells. In this paper, we applied this approach to the identification of hair follicular stem cells. When human scalp hair follicles were placed in explant culture, the bulge area yielded best outgrowths. In another experiment, we isolated different subpopulations of human follicular keratinocytes by micro-dissection, dispersed them by trypsin/EDTA into single cells, and grew them in the presence of 3T3 feeder cells. The keratinocytes were then subcultured under identical conditions to compare their in vitro life span. Our results indicate that the life span of keratinocytes of the upper follicle (containing mainly the isthmus area) > sebaceous gland > lower follicle (between the bulge and bulb) > bulb (containing the matrix cells). The cultured upper follicular keratinocytes tend to be small and relatively uniform in size. The poor in vitro growth of matrix cells may reflect their non-stem cell nature and/or special growth requirement(s) satisfied in vivo by the neighboring dermal papilla cells. Unexpectedly, we found that the upper follicular keratinocytes grow even better than epidermal keratinocytes. The existence of a subpopulation of keratinocytes with an in vitro growth potential superior than other known keratinocytes of the skin supports the hypothesis that follicular stem cells reside in the upper follicle. Our data also raise the possibility that putative follicular stem cells are involved not only in forming the follicle, but also in the long-term maintenance of the epidermis. Finally, we discuss the possibility that keratinocyte stem cells, as defined by their in vivo slow-cycling nature, are absent in culture

The asymmetric unit membrane (AUM) of the apical surface of mammalian urinary bladder epithelium contains several major integral membrane proteins, including uroplakins IA and IB (both 27 kDa), II (15 kDa), and III (47 kDa). These proteins are synthesized only in terminally differentiated bladder epithelial cells. They are encoded by separate genes and, except for uroplakins IA and IB, appear to be unrelated in their amino acid sequences. The genes encoding these uroplakins were mapped to chromosomes of cattle through their segregation in a panel of bovine x rodent somatic cell hybrids. Genes for uroplakins IA, IB, and II were mapped to bovine (BTA) Chromosomes (Chrs) 18 (UPK1A), 1 (UPK1B), and 15 (UPK2), respectively. Two bovine genomic DNA sequences reactive with a uroplakin III cDNA probe were identified and mapped to BTA 6 (UPK3A) and 5 (UPK3B). We have also mapped genes for uroplakins IA and II in mice, to the proximal regions of mouse Chr 7 (Upk1a) and 9 (Upk2), respectively, by analyzing the inheritance of restriction fragment length variants in recombinant inbred mouse strains. These assignments are consistent with linkage relationships known to be conserved between cattle and mice. The mouse genes for uroplakins IB and III were not mapped because the mouse genomic DNA fragments reactive with each probe were invariant among the inbred strains tested. Although the stoichiometry of AUM proteins is nearly constant, the fact that the uroplakin genes are unlinked indicates that their expression must be independently regulated. Our results also suggest likely positions for two human uroplakin genes and should facilitate further analysis of their possible involvement in disease

The full-length cDNA of mouse K12 keratin was characterized by sequencing overlapping cDNA clones isolated from a mouse cornea cDNA library. Using Northern blot hybridization, the radio-labeled cDNA hybridized to a 1.9 kb mRNA from adult cornea, but not from other mouse tissues including snout, esophagus, tongue, and skin. During mouse development, corneas do not express K12 mRNA until 4 days postnatal when the epithelium begins to stratify as judged by Northern blot and in situ hybridization. In situ hybridization with 3H-labeled cDNA probe and immunohistochemical studies with antibodies against a synthetic oligo-peptide deduced from rabbit K12 cDNA demonstrate that this mouse K12 keratin is expressed in all cell layers of adult corneal epithelium, and the suprabasal layers, but not the basal layer of the limbal epithelium. Epidermal growth factor (EGF) has been shown to promote epithelium stratification of cultured chicken and human corneas in vitro. To examine whether EGF can promote K12 expression, EGF was administered to neonatal mice. The results indicate that EGF retards K12 expression by corneal epithelial cells, even though it promotes corneal epithelial stratification during mouse development. Taken together, our results demonstrate that the expression of K12 keratin is cornea-specific, differentiation-dependent, and developmentally regulated