Susan K. Anderson

MARCKS regulates membrane ruffling and cell spreading.

The dynamic rearrangement of the actin cytoskeleton is fundamental to most biological processes including embryogenesis, morphogenesis, cell movement, wound healing and metastasis [1]. Membrane ruffling and reversible cell-substratum interactions underlie actin-driven cell movement. Protein kinase C (PKC) stimulates membrane ruffling and adhesion [2], but the mechanism by which this occurs is unknown. Myristoylated alaninerich C kinase substrate (MARCKS) is a PKC substrate that cycles on and off membranes by a mechanism termed the myristoyl-electrostatic switch [3-6]. While at the membrane, MARCKS binds to and sequesters acidic phospholipids including phosphatidyl-inositol-4,5-bisphosphate (PIP2) [7]. MARCKS also binds and cross-links filamentous actin, an activity which is regulated by PKC-dependent phosphorylation and calcium-calmodulin [3]. In this report, we demonstrate that expression, in fibroblasts, of MARCKS containing a mutation which abrogates the myristoyl-electrostatic switch prevents cell spreading. The MARCKS mutant arrests the cell during an early stage of spreading, characterized by profuse membrane blebbing, and prevents the formation of membrane ruffles and lamellae usually found at the leading edge of spreading cells. This defect in the regulation of the actin cytoskeleton is accompanied by a decrease in cell-substratum adhesion. Our results provide direct evidence that MARCKS and PKC regulate actin-dependent membrane ruffling and cell adhesion, perhaps via a PIP2-dependent mechanism.

Normal Human Kidney HLA-DR–Expressing Renal Microvascular Endothelial Cells: Characterization, Isolation, and Regulation of MHC Class II Expression

Human, but not murine, renal peritubular and glomerular capillaries constitutively express class II major histocompatibility (MHC) proteins at high levels in normal human kidney. Expression of class II proteins on renal microvascular endothelial cells (RMEC) makes it available to circulating lymphocytes and imparts a surveillance capacity to RMEC for controlling inflammatory responses. In this report, the co-expression of HLA-DR and the endothelial marker CD31 are used to identify RMEC as a distinct population of cells within a standard renal biopsy using flow cytometry. A three-laser, multicolor flow cytometry analysis using Alexa dyes, developed for characterizing the expression of cell surface antigens, identifies RMEC as a population separate from HLA-DR-expressing leukocytes. HLA-DR RMEC co-express HLA-DP and HLA-DQ. RMEC also express the T cell costimulatory factor CD58 but not CD80, CD86, or CD40. On the basis of high HLA-DR expression, RMEC are isolated for culture using fluorescence-activated cell sorting and magnetic beads. Cultured RMEC require normal basal physiologic concentrations of gamma interferon (gammaIFN) to maintain HLA protein expression. This expression is regulated by CIITA, the MHC class II-specific transcription factor. Four tissue-specific promoters have been described for CIITA. In freshly isolated RMEC, RT-PCR and hybridization using specific oligonucleotide probes to CIITA promoter sequences identify only the statin-sensitive gammaIFN-induced promoter IV of CIITA. Therefore, the constitutive expression of HLA-DR on RMEC in normal human kidney is located in a position for immune surveillance, depends on basal physiologic concentrations of gammaIFN, and may be amenable to regulation with statins.

Expression of antigen-specific, major histocompatibility complex-restricted receptors by cortical and medullary thymocytes in situ

We have examined the distribution of the antigen-specific, major histocompatibility complex-restricted receptor on mouse thymocytes in situ, using immunohistochemical techniques and the monoclonal antibody KJ16-133. This antibody reacts with the beta chain of the receptors on about 20% of peripheral murine T cells. Of the cortical thymocytes reacting with KJ16-133, cells with only cytoplasmic staining were most frequently observed. Such cytoplasmic staining was not observed in the medulla. Occasional cortical cells had low levels of surface expression, which was almost invariably patched in the region of contact with epithelial cell processes. KJ16-133+ medullary thymocytes had high levels of uniform surface labeling. These results suggest that thymic selection of MHC restriction and/or tolerance may occur in the cortex, where the receptors on maturing thymocytes interact with MHC proteins on epithelial cells.

SIMPLE interacts with NEDD4 and TSG101: evidence for a role in lysosomal sorting and implications for Charcot-Marie-Tooth disease.

Mutation of the SIMPLE gene (small integral membrane protein of the lysosome/late endosome) is the molecular basis of Charcot‐Marie‐Tooth disease type 1C (CMT1C), a demyelinating peripheral neuropathy. Although the precise function of SIMPLE is unknown, prior reports suggest it localizes to the lysosome/late endosome. Furthermore, murine Simple interacts with Nedd4 (neural precursor cell expressed, developmentally downregulated 4), an E3 ubiquitin ligase that is important for regulating lysosomal degradation of plasma membrane proteins. To bring insights into the biochemical function of human SIMPLE, we confirmed that human SIMPLE interacts with NEDD4 and also report a novel interaction with tumor susceptibility gene 101 (TSG101), a class E vacuolar sorting protein. TSG101 is known to function downstream of NEDD4, sorting ubiquitinated substrates into multivesicular bodies (MVBs), which then deliver their cargo into the lysosomal lumen for degradation. Given the interaction with NEDD4 and TSG101, and the localization of SIMPLE along the lysosomal degradation pathway, we hypothesize that SIMPLE plays a role in the lysosomal sorting of plasma membrane proteins. We examine three CMT1C‐associated SIMPLE mutations and show that they do not affect the interaction with NEDD4 or TSG101, nor do they lead to altered subcellular localization.

Intracellular catabolism of radiolabeled anti-CD3 antibodies by leukemic T cells☆

The endocytosis and intracellular metabolism of radiolabeled anti-CD3 MoAb 64.1 by the malignant human T cell line HPB-ALL were studied using biochemical, morphological, electrophoretic, and chromatographic techniques. Biosynthetically labeled [3H]64.1 and externally radioiodinated 125I-64.1 were similarly internalized and degraded by tumor cells, with approximately 70% of the initially bound radioactivity being released to the culture supernatant as trichloroacetic acid-soluble radioactivity in the first 24 hr of culture. Radiolabeled 64.1 was routed from the cell membrane to endosomes where initial proteolysis began and finally to lysosomes where terminal catabolism to single amino acids occurred. SDS-PAGE demonstrated four major intracellular metabolite species (46, 25, 15, and less than 10 kDa). Thin-layer chromatography demonstrated that greater than 95% of the trichloroacetic acid-soluble radioactivity in culture supernatants was 125I-monoiodotyrosine, indicating that proteases, not deiodinases, were of primary importance in catabolism of 125I-64.1. In the presence of inhibitors of lysosomal function (leupeptin, monensin, and ammonium chloride), 125I-64.1 degradation was impeded, causing prolonged retention of radioactivity in the lysosomal compartment of cells. However, although the pace of catabolism was markedly diminished by these agents, no major changes in the sizes of intermediate metabolites generated were observed. Our results suggest that judicious administration of lysosomal inhibitors (e.g. chloroquine, verapamil, monensin) may significantly enhance retention of radioimmunoconjugates by lymphoid malignancies, improving radioimmunoscintigraphic and radioimmunotherapeutic efforts.

Medullary epithelial cell lines from murine thymus constitutively secrete IL-1 and hematopoietic growth factors and express class II antigens in response to recombinant interferon-γ

In this report, we describe the generation of two cloned epithelial cell lines, TE-71 and TE-75, from murine thymus. These cell lines resemble medullary thymic epithelium by a number of criteria, including reactivity with the monoclonal antibodies A2B5 and ER-TR5, the fucose-specific lectin derived from Ulex europeus, and the expression of keratins normally expressed by medullary thymic epithelial cells in situ. Constitutive Class II antigen expression by these cells is not detectable at the light or electron microscopic level or with flow cytometry. Following exposure to recombinant interferon-gamma or supernatants from mitogen-stimulated spleen cells, expression of Class II antigens by these thymic epithelial cell lines is increased, although less than the levels expressed by spleen cells. Medium conditioned by TE-71 and TE-75 cells exhibited colony-stimulating activity for bone marrow cells. In addition, TE-71-conditioned medium exhibited IL-1-like activity which could be neutralized with anti-IL-1 antibodies.

A Novel Three–Dimensional Human Peritubular Microvascular System

Human kidney peritubular capillaries are particularly susceptible to injury, resulting in dysregulated angiogenesis, capillary rarefaction and regression, and progressive loss of kidney function. However, little is known about the structure and function of human kidney microvasculature. Here, we isolated, purified, and characterized human kidney peritubular microvascular endothelial cells (HKMECs) and reconstituted a three-dimensional human kidney microvasculature in a flow-directed microphysiologic system. By combining epithelial cell depletion and cell culture in media with high concentrations of vascular endothelial growth factor, we obtained HKMECs of high purity in large quantity. Unlike other endothelial cells, isolated HKMECs depended on high vascular endothelial growth factor concentration for survival and growth and exhibited high tubulogenic but low angiogenic potential. Furthermore, HKMECs had a different transcriptional profile. Under flow, HKMECs formed a thin fenestrated endothelium with a functional permeability barrier. In conclusion, this three-dimensional HKMEC-specific microphysiologic system recapitulates human kidney microvascular structure and function and shows phenotypic characteristics different from those of other microvascular endothelial cells.

Biochemical and morphological differences between fibroblasts and myoblasts from embryonic chicken skeletal muscle

SummaryNon-myogenic cells were isolated from the breast muscle of 10-day-old chicken embryos employing Percoll density centrifugation. In culture, these cells exhibited the spread out, stellate morphology of fibroblast-like cells. They also exhibited receptor-mediated binding of plateletderived growth factor (PDGF). Such binding was not detected in cultures of predominantly myogenic cells isolated by the Percoll density centrifugation from the same muscle. Percoll-isolated myogenic and fibrogenic cell populations were also analyzed by two-dimensional polyacrylamide gel electrophoresis immediately after removal from the muscle. This analysis revealed at least six polypeptides specific to the fibroblasts but not detected in the myogenic cell population. In addition, at least eight polypeptides found in the myogenic population were barely detectable, or lacking altogether from the fibroblast-like cells. Ultrastructural analysis of the freshly isolated cells demonstrated that the fibroblasts were larger than the myoblasts and that their cytoplasm contained many vesicles. We conclude that the fibrogenic and myogenic cells isolated by Percoll from embryonic muscle express cell type-specific characteristics. Moreover, based on the PDGF binding studies, the fibrogenic cells can be categorized as “true” fibroblasts.

Noninvasive Measurement of Protein Aggregation by Mutant Huntingtin Fragments or α-Synuclein in the Lens

Many diverse human diseases are associated with protein aggregation in ordered fibrillar structures called amyloid. Amyloid formation may mediate aberrant protein interactions that culminate in neurodegeneration in Alzheimer, Huntington, and Parkinson diseases and in prion encephalopathies. Studies of protein aggregation in the brain are hampered by limitations in imaging techniques and often require invasive methods that can only be performed postmortem. Here we describe transgenic mice in which aggregation-prone proteins that cause Huntington and Parkinson disease are expressed in the ocular lens. Expression of a mutant huntingtin fragment or α-synuclein in the lens leads to protein aggregation and cataract formation, which can be monitored in real time by noninvasive, highly sensitive optical techniques. Expression of a mutant huntingtin fragment in mice lacking the major lens chaperone, αB-crystallin, markedly accelerated the onset and severity of aggregation, demonstrating that the endogenous chaperone activity of αB-crystallin suppresses aggregation in vivo. These novel mouse models will facilitate the characterization of protein aggregation in vivo and are being used in efficient and economical screens for chemical and genetic modifiers of disease-relevant protein aggregation.

In situ ultrastructural demonstration of cells bearing Ia antigens in the murine pancreas.

Although an important role has been postulated for class II major histocompatibility gene products in the rejection of transplanted islets, the identity of the cells bearing these molecules within pancreatic tissue has been the topic of some controversy. To clearly define the cell population(s) within the murine pancreas that express la antigens, perfused murine pancreata were processed for the ultrastructural in situ demonstration of la antigens. It was found that la antigen expression was restricted to mononuclear cells adjacent to capillaries throughout the exocrine and endocrine portions of the pancreas. Vascular endothelium and ductular epithelium did not express detectable amounts of la antigens.