High-efficiency acousto-optic coupling in phoxonic resonator based on silicon fishbone nanobeam cavity.

We investigate the acousto-optic coupling rates between different acoustic resonance modes and a specified optical resonance mode in a one-dimensional phoxonic crystal fishbone nanobeam formed by periodically arranging semi-cylinders of air on both sides of a suspended silicon waveguide. The gradually tapered unit cells form optical and acoustic resonators. In acousto-optic coupling rate calculation, the acoustic fields and optical fields are obtained by steady state monochromatic analysis and eigen-mode computation, respectively. Results showed that the acoustic polarizations and symmetries of the acoustic resonance modes are dominant factors in the acousto-optic coupling efficiency, and appropriate selection of these parameters can prevent cancellation of acousto-optic interactions, thereby enhancing acousto-optic coupling rates. This study provides important insights that can be applied to acousto-optic device designs.

Brain isoform glycogen phosphorylase as a novel hepatic progenitor cell marker.

An appropriate liver-specific progenitor cell marker is a stepping stone in liver regenerative medicine. Here, we report brain isoform glycogen phosphorylase (GPBB) as a novel liver progenitor cell marker. GPBB was identified in a protein complex precipitated by a monoclonal antibody Ligab generated from a rat liver progenitor cell line Lig-8. Immunoblotting results show that GPBB was expressed in two liver progenitor cell lines Lig-8 and WB-F344. The levels of GPBB expression decreased in the WB-F344 cells under sodium butyrate (SB)-induced cell differentiation, consistent with roles of GPBB as a liver progenitor cell marker. Short hairpin RNA (shRNA)-mediated GPBB knockdown followed by glucose deprivation test shows that GPBB aids in liver progenitor cell survival under low glucose conditions. Furthermore, shRNA-mediated GPBB knockdown followed by SB-induced cell differentiation shows that reducing GPBB expression delayed liver progenitor cell differentiation. We conclude that GPBB is a novel liver progenitor cell marker, which facilitates liver progenitor cell survival under low glucose conditions and cell differentiation.

Investigating the suspension culture on aggregation and function of mouse pancreatic ß-cells.

The integrity and hierarchical structure of islet influence ß-cells physiology dramatically. A culture substrate which can maintain or improve ß-cells aggregation shall benefit cell therapy for diabetics. In this study, nontreated, type IV collagen, Lipidure, and ultralow attachment dishes were used to culture a murine ß-cell line, MIN-6. The formation and biological performances of pseudoislets were investigated. Results showed that ß-cells formed loose and irregular aggregates on nontreated dishes. Oppositely, pseudoislets formed on other three substrates. Most pseudoislets on Lipidure and type IV collagen dishes had a diameter between 100-150 µm with high survival rate, while large pseudoislets (>250 µm) with seriously central necrosis were found on ultralow attachment dishes. Western blot analysis revealed that pseudoislets had relatively higher connexin 36 protein productions relative to single cells. The glucose-stimulated insulin secretion test showed pseudoislets on type IV collagen have high stimulation index. Monolayers from TCPS dishes and pseudoislets from type IV collagen or Lipidure dishes were further transplanted into diabetic mice. Animals received both single cells and pseudoislets had decreasing blood glucose level and regained body weight. Histologic examination revealed that all implants successfully engrafted with positive insulin staining. Interestingly, the area under curve for the intraperitoneal glucose tolerance test showed pseudoislets had superior glucose disappearance rate. This study reveals that isolated islets or insulin-producing cells can be cultured on type IV collagen or Lipidure dishes to improve/maintain integrity prior to transplantation.

Generation of a monoclonal antibody specifically reacting with undifferentiated liver progenitor cells.

An adult rat liver progenitor cell line Lig-8 was established. In the induction by sodium butyrate, these cells were shown to be able to differentiate into both hepatocytes and bile duct cells expressing albumin and cytokeratin-19, the markers of respective cell types. In order to generate Lig-8 specific antibody for further studies, we produced a monoclonal antibody using the whole Lig-8 cells as immunogen. The yielded monoclonal antibody, named Ligab, belongs to IgG subclass G1 and kappa light chain. It specifically stained on Lig-8 cells in the cytoplasm but not on a rat hepatoma cell line H4IIE. Its immunoreaction against Lig-8 cell lysate on dot blots diminished as the concentration of sodium dodecyl sulfate (SDS) in the lysate increased to 2%, a level in the sample buffer of standard SDS-polyacrylamide gel electrophoresis (PAGE). Not surprisingly, Ligab failed to detect its reacting antigen in Lig-8 cell lysate by standard SDS-PAGE-based immunoblotting. It could detect this antigen only by native PAGE-based immunoblotting. These characteristics suggested that the antigenic epitope for Ligab is likely a molecular structure instead of a peptide sequence. More interestingly, expression of Ligab-reacting antigen in Lig-8 cells declined as the cells were induced to differentiate by sodium butyrate. This antigen is very likely a differentiation-related marker for these cells, and this monoclonal antibody may help study the molecular mechanisms of liver progenitor cell differentiation.

Global gene expression profiling reveals a key role of CD44 in hepatic oval-cell reaction after 2-AAF/CCl4 injury in rodents.

Liver progenitors, so-called oval cells, proliferate remarkably from periportal areas after severe liver injury when hepatocyte regeneration is compromised. These cells invade far into the liver parenchyma. Molecular mechanisms underlying these behaviors of oval cells remain poorly understood. In this study, we treated rats with 2-acetylaminofluorene/carbon tetrachloride to induce hepatic oval cells. By expression microarray analysis, we investigated global gene expression profiles in liver tissue, with an emphasis on adhesion molecules, extracellular matrix proteins, matrix metalloproteinases (MMPs), growth factors/cytokines, and receptors that might contribute to the distinct behaviors of oval cells. Genes upregulated at least twofold were selected. We then performed immunostaining to verify the microarray results and identified expression of MMP-7 and CD44 in oval cells. Staining of cytokeratin (CK)-19, an oval-cell marker, was similar between oval cells located next to periportal areas and those located far within the parenchyma. In contrast, CD44 staining was more intense in the parenchyma than in periportal areas, suggesting a role of CD44 in oval-cell invasion. Moreover, newly differentiated CK-19+ hepatocytes within foci did not show CD44 staining, suggesting that CD44 is related to the undifferentiated oval-cell phenotype. We then investigated oval-cell reactivity in CD44-deficient mice fed an oval cell-inducing diet of 3,5-diethoxycarbonyl-1,4-dihydrocollidine. Results showed significantly reduced oval-cell reactivity in CD44-deficient mice. Thus, oval cells express MMP-7 and CD44, and CD44 appears to play critical roles in the proliferation, invasion, and differentiation of hepatic oval cells in rodents.

Characterization of cytokeratin 19-positive hepatocyte foci in the regenerating rat liver after 2-AAF/CCl4 injury.

Partial hepatectomy or carbon tetrachloride (CCl4) injury, following treatment of rats with 2-acetylaminofluorene (2-AAF) to inhibit proliferation of hepatocytes, induces proliferation of oval cells and possibly their differentiation into nodular foci of hepatocytes when higher doses of 2-AAF are used. Unfortunately, immunohistochemistry in previous studies failed to show oval cell markers in these foci, and thereby to demonstrate the precursor-product relationship between oval cells and hepatocytes. Immunohistochemistry on livers of rats treated with high dose 2-AAF/CCl4 was used. We found 7.6% of the hepatocyte foci were positive for an oval cell marker cytokeratin 19 (CK-19). These foci were positive for alpha-fetoprotein, less positive for carbamoylphosphate synthetase 1, and more positive for laminin in the basement membrane lining. Rarely present transitional foci had weaker expression of CK-19 and discontinuous laminin. Focal hepatocyte differentiation of oval cells was characterized by cell hypertrophy, membranous CK-19, and positive hepatocyte nuclear factor 4 (HNF-4). HNF-4+ small oval cells surrounding CK-19+ foci were frequently seen, suggesting that a paracrine mechanism(s) may be responsible for the enlargement of CK-19+ foci. In conclusions, oval cells appear to differentiate to CK-19+ foci and then to CK-19- foci in the high dose 2-AAF/CCl4 model.

EMP-1 is a junctional protein in a liver stem cell line and in the liver.

In an attempt to discover cell markers for liver stem cells, a cDNA microarray analysis was carried out to compare the gene expression profiles between an adult liver stem cell line, Lig-8, and mature hepatocytes. Several genes in the categories of extracellular matrix, cell membrane, cell adhesion, transcription factor, signal molecule, transporter, and metabolic enzyme were shown to be differentially expressed in Lig-8 cells. Among them, epithelial membrane protein (EMP)-1 has been previously implicated with stem cell phenotypes. Antiserum to EMP-1 was produced to localize its expression. On monolayers of Lig-8 cells, EMP-1 was expressed along the intercellular border. In the liver harboring proliferating oval cells, the liver progenitors, EMP-1 was localized as ribbon bands, a staining pattern for epithelial junctions, all the way through bile duct epithelia, oval cell ductules, and into peri-hepatocytic regions. These peri-hepatocytic regions were proved to be bile canaliculi by co-localization of EMP-1 and dipeptidyl peptidase IV, an enzyme located on bile canaliculi. This report is the first to indicate EMP-1 to be a junctional protein in the liver.