Three times the length of the Mississippi River, or 20,000 km, is the extent of hepatocellular tight junctions (TJs) within a human liver if one extrapolates data obtained from rats (Weibel, 1979; Stammler et al., 1990; Hornstein et al., 1992; Rahner et al., 1996). This seal is formed by 200 billion hepatocytes and confines as little as 3.5 cmof biliary space organized in an anastomosing network of tiny, 1-µmcanaliculi. The secretory surface of the canalicular wall that is formed by the apical membrane domain of hepatocytes totals 115 m, approximately the size of a fiveroom apartment. It is obvious that stowing these dimensions in a 1500-g organ necessitates an elaborate organization (Figure 27.1A).
ABSTRACT The time courses of poliovirus plus- and minus-strand RNA synthesis in infected HEp-2 cells were monitored separately, using a quantitative RNase assay. In parallel, viral RNA and proteins were located in situ by confocal microscopy within cells fixed by a protocol determined to retain their native size and shape. Plus- and minus-strand RNAs were visualized by fluorescent in situ hybridization (FISH) with strand-specific riboprobes. The probes were labelled with different fluorochromes to allow for the simultaneous detection of plus- and minus-strand RNA. The FISH experiments showed minus-strand RNA to be present in distinct, regularly sized, round structures throughout the viral replication cycle. Plus-strand RNA was found in the same structures and also in smaller clusters of vesicles. Association of viral RNA with membranes was demonstrated by combining FISH with immunofluorescence (IF) detection of the viral 2B- and 2C-containing P2 proteins, which are known to be markers for virus-induced membranes. At early times postinfection, the virus-induced membranous structures were distributed through most of the cytoplasm, whereas around peak RNA synthesis, both RNA-associated membranous structures migrated to the center of the cell. During this process, the plus- and minus-strand-containing larger structures stayed as recognizable entities, whereas the plus-strand-containing granules coalesced into a juxtanuclear area of membranous vesicles. An involvement of Golgi-derived membranes in the formation of virus-induced vesicles and RNA synthesis early in infection was investigated by IF with 2C- and Golgi-specific antibodies.
In order to demonstrate the power of quantitative microscopy, the endocytic apparatus of rat hepatocytes was reexamined using in situ liver and short term cultured hepatocyte couplets that were allowed to internalize endocytic markers for various time intervals. Correlative confocal light and electron microscopy demonstrate a tubulovesicular reticulum representing the endocytic apparatus. Volume and membrane area account for 2% of cell volume and 30% plasma membrane surface. Colocalization analysis demonstrated that pathway-specific ligands and fluid-phase markers enter EEA1-positive vesicles, the early endosomal compartment, immediately after internalization. These vesicles are translocated rapidly from basolateral to perinuclear and apical locations. Ligands are sorted within 5 min to their respective pathways. Sequential colocalization of an asialoglycoprotein-pulse with rab7 and lamp3 demonstrates that early endosomes change into or fuse with late endosomes and lysosomes. Alternatively, markers are sequestered into the common endosome consisting of rab11-positive, long tubules that originate from early endosomes and show an affinity for the transcytotic marker pIgA and its receptor. This compartment mediates transcytosis by delivering the receptor-ligand complex to the subapical compartment, a set of apical, rab11-positive vesicles, which are connected to the tubular reticulum. We conclude that vesicular traffic between preexisting compartments, maturation or fusion of endocytic organelles, and transport in tubules act in concert and together mediate transport between compartments of a tubulovesicular endocytic apparatus. In addition, we show that quantitative microscopy using high resolution data sets can detect and characterize kinetics of various parameters thus adding a dynamic component to 3D information.
ABSTRACT Tactile sense organs in the skin of the head of 42 species belonging to several squamate families are described. These sense organs always consist of a dermal and an epidermal component. Six different types of these sense organs are distinguished. The sloughing cycle of the epidermal component of the sense organs occurs principally in the same manner as it does in the epidermis. The phenomenon of “persisting cells,” which occurs in some families, is discussed. Number and distribution of the organs are not considered.
