M. Watanabe

Proximal tubular epithelial cells from mice which develop autoimmune interstitial nephritis were found to express the nephritogenic target antigen, 3M-1. Anti-3M-1 mAbs (alpha 3M-1-Ab) were used to positively select for 3M-1-secreting tubular epithelium and, after stabilization in culture, this new cell line (MCT) was examined for the production of several moieties important to either immune interactions or to the development of extracellular matrix. Alkaline phosphatase-staining MCT cells also express epithelial growth factor receptors with a Kd of 0.87 nM and an epithelial growth factor receptor constant (Ro) of 2.1 X 10(4) receptors/cell. MCT culture supernatants contain greater amounts of laminin, and types IV and V procollagens compared to types I and III procollagens, and growing MCT cells on type I collagen matrix causes them to preferentially secrete even more type IV and V procollagen. The 30,000-Mr 3M-1 antigen could be immunoprecipitated from biosynthetically labeled MCT cell supernatants with alpha 3M-1-Ab. An identical-sized moiety was isolated by immunoaffinity chromatography from collagenase-solubilized mouse kidney tubular basement membranes. The 3M-1 antigen can be found on the MCT cell surface by radioimmunoassay, or deposited in a linear array in the extracellular matrix surrounding the MCT cells in culture by immunofluorescence. Mature messenger RNA species for both class I and class II major histocompatibility complex (MHC) molecules were detected by Northern hybridization, and their corresponding cell surface gene products were detected by cytofluorography of MCT cells stained with haplotype-specific antibodies. Both the cell surface 3M-1 and the small amounts of detected class II MHC molecules appear to be biologically functional, as MCT cells can support the proliferation of 3M-1-specific, class II MHC-restricted helper T cells in culture. These findings suggest that MCT cells provide all the necessary biological parameters for interfacing both as the target of a nephritogenic immune response, and as a potential source for new extracellular matrix which develops as a fibrogenic response to interstitial nephritis.

Tubulointerstitial changes in the diabetic kidney correlate closely with the decline in glomerular filtration. In this study, we used a cell culture system of mouse proximal tubule epithelial cells to test the effects of glucose on cell growth, size, and matrix biosynthesis. [3H]thymidine incorporation was significantly inhibited in cells grown in 450 mg/dl glucose, compared with cells grown in 100 mg/dl glucose. The cells grown in the higher glucose concentration were slightly larger, their protein content and the total protein synthetic rate were significantly increased, and they secreted approximately twice as much procollagens type IV and type I. Concordantly, steady-state procollagen mRNA levels were also increased: 2.6-fold for the alpha 1(IV) and 2.2-fold for the alpha 2(I) procollagens. Additionally, nuclear run-off studies demonstrated that procollagen gene transcription rate was stimulated approximately 50%; beta-actin transcription rate was not altered. We used chloramphenicol acetyltransferase (CAT) reporter gene constructs to determine whether the increased transcription rate of alpha 2(I) gene was associated with activation of its enhancer sequence. Cells transfected with the enhancer demonstrated more than fivefold increase in CAT activity when cultured in the high-glucose medium. These studies demonstrate a multitude of effects of high ambient glucose concentrations on proximal tubule cell growth and collagen biosynthesis; cell proliferation is decreased although cell hypertrophy occurs. Procollagen gene transcription rate is stimulated and this response contributes to the observed increase in procollagen mRNA content. Activation of an enhancer sequence may be one possible mode through which high glucose levels increase the transcription of procollagen type I, presumably involving trans-acting factor(s).

1. Electrical events and intracellular calcium concentration ([Ca2+]) imaged using fluo-3 and laser scanning confocal microscopy were simultaneously monitored in single smooth muscle cells freshly isolated from guinea-pig vas deferens or urinary bladder. 2. Images obtained every 8 ms, during stepping from -60 to 0 or +10 mV for 50 ms under voltage clamp, showed that a rise in [Ca2+] could be detected within 20 ms of depolarization in five to twenty small (< 2 micrometer diameter) 'hot spots', over 95 % of which were located within 1.5 micrometer of the cell membrane. Depolarization at 30 s intervals activated hot spots at the same places. 3. Cd2+ or verapamil abolished both hot spots and Ca2+-activated K+ current (IK,Ca). Caffeine almost abolished hot spots and markedly reduced IK,Ca. Cyclopiazonic acid, which raised basal global [Ca2+], decreased the rise in hot spot [Ca2+] and IK,Ca amplitude during depolarization. These results suggest that Ca2+ entry caused Ca2+-induced Ca2+ release (CICR). 4. Under voltage clamp, hot spot [Ca2+] closely paralleled the rise in IK,Ca and reached a peak within 20 ms of the start of depolarization, but the rise in global [Ca2+] over the whole cell area was much slower. Step depolarization to potentials positive to -20 mV caused hot spots to grow in size and coalesce, leading to a rise in global [Ca2+] and contraction. Ca2+ hot spots also occurred during the up-stroke of an evoked action potential under current clamp. 5. It is concluded that the entry of Ca2+ in the early stages of an action potential evokes CICR from discrete subplasmalemma Ca2+ storage sites and generates hot spots that spread to initiate a contraction. The activation of Ca2+-dependent K+ channels in the plasmalemma over hot spots initiates IK,Ca and action potential repolarization.

12 distinct neural cell adhesion molecule (N-CAM) epitopes, each recognized by a different monoclonal antibody (mAb), have been characterized in terms of the major structural and functional features of the molecule. Seven antibodies, each recognizing the amino-terminal region of the molecule, altered the rate of N-CAM-mediated adhesion. Four of these were inhibitors, two of which also recognized a heparin-binding N-CAM fragment. The other three antibodies specifically enhanced the rate of N-CAM-mediated adhesion. Three epitopes, one polypeptide- and two carbohydrate-dependent, were associated with the sialic acid-rich central portion of the molecule. The remaining two antibodies were found to react with intracellular determinants, and are specific for the largest of the three major N-CAM polypeptide forms. Studies on the ability of one antibody to hinder recognition of native N-CAM by another antibody suggested that the epitopes associated with N-CAM binding functions are in close proximity compared with the other determinants. The classification of these mAb epitopes has allowed the topographical placement of key N-CAM features, as described in the following paper, and provides valuable probes for analysis of both the structure and function of N-CAM.

Two distinct cDNAs corresponding to two zebrafish protein O-mannosyltransferase genes, zPOMT1 and zPOMT2, were cloned from early developmental embryos. Gene expression analysis revealed that zPOMT1 and zPOMT2 were expressed in similar patterns during early embryonic development and in all adult tissues. To study the regulation of zPOMT1 and zPOMT2 mRNA distribution during zebrafish embryogenesis, we injected enhanced green fluorescent protein (EGFP) mRNA fused to the 3'untranslated regions of each zPOMT gene. The distribution of EGFP resulting from the two constructs was similar. Injection of antisense morpholino oligonucleotides of zPOMT1 and zPOMT2 resulted in several severe phenotypes-including bended body, edematous pericaridium and abnormal eye pigmentation. Immunohistochemistry using anti-glycosylated alpha-dystroglycan antibody (IIH6) and morphological analysis revealed that the phenotypes of zPOMT2 knockdown were more severe than those of zPOMT1 knockdown, even though the IIH6 reactivity was lost in both zPOMT1 and zPOMT2 morphants. Finally, only when both zPOMT1 and zPOMT2 were expressed in human embryonic kidney 293T cells were high levels of protein O-mannosyltransferase activity detected, indicating that both zPOMT1 and zPOMT2 were required for full enzymatic activity. Moreover, either heterologous combination, zPOMT1 and human POMT2 (hPOMT2) or hPOMT1 and zPOMT2, resulted in enzymatic activity in cultured cells. These results indicate that the protein O-mannosyltransferase machinery in zebrafish and humans is conserved and suggest that zebrafish may be useful for functional studies of protein O-mannosylation.