Synapse Plasticity in Motor, Sensory, and Limbo-Prefrontal Cortex Areas as Measured by Degrading Axon Terminals in an Environment Model of Gerbils (Meriones unguiculatus)

Still little is known about naturally occurring synaptogenesis in the adult neocortex and related impacts of epigenetic influences. We therefore investigated (pre)synaptic plasticity in various cortices of adult rodents, visualized by secondary lysosome accumulations (LA) in remodeling axon terminals. Twenty-two male gerbils from either enriched (ER) or impoverished rearing (IR) were used for quantification of silver-stained LA. ER-animals showed rather low LA densities in most primary fields, whereas barrel and secondary/associative cortices exhibited higher densities and layer-specific differences. In IR-animals, these differences were evened out or even inverted. Basic plastic capacities might be linked with remodeling of local intrinsic circuits in the context of cortical map adaptation in both IR- and ER-animals. Frequently described disturbances due to IR in multiple corticocortical and extracortical afferent systems, including the mesocortical dopamine projection, might have led to maladaptations in the plastic capacities of prefronto-limbic areas, as indicated by different LA densities in IR- compared with ER-animals.

Differential and sequential delivery of fluorescent lysosomal probes into phagosomes in mouse peritoneal macrophages.

It has previously been inferred that the fusion of a macrophage secondary lysosome with a phagosome delivers the entire lysosomal contents uniformly to the phagosome. We found, however, that different fluorescent lysosomal probes can enter phagosomes at remarkably different rates, even though they are initially sequestered together in the same organelles. Thus, sulforhodamine is almost exclusively delivered to yeast-containing phagosomes within 2 h of phagocytosis. But fluoresceinated, high molecular weight dextran accumulates in the same phagosomes only over a period of approximately 24 h. We postulate that the delivery of lysosomal contents may involve an intermittent and incremental process in which individual components can be selectively and sequentially transferred.

The role of intermediate vesicles in the adsorptive endocytosis and transport of ligand to lysosomes by human fibroblasts.

Recent work from several laboratories has suggested the participation of intermediate structures in the delivery of adsorbed ligands from the plasma membrane to lysosomes. This report presents subcellular fractionation studies bearing on the role of these structures in adsorptive pinocytosis of epidermal growth factor (EGF), beta-hexosaminidase, and low density lipoprotein (LDL) by human fibroblasts. Using a two-step Percoll density gradient fractionation, we identified newly internalized (5 min) EGF in two intermediate density structures that are essentially negative for plasma membrane marker, and more bouyant than secondary lysosomes. Continued incubation for 20 min resulted in transfer to (or conversion to) vesicles sedimenting with secondary lysosomes. Internalized beta-hexosaminidase and LDL behaved similarly, appearing first in structures of intermediate density, and later appearing in association with secondary lysosomes. Two drugs, NH4Cl and monensin, were found to inhibit ligand transfer to the secondary lysosome peak, although they did not inhibit entry of bound ligands into intermediate density structures. Upon removal of both inhibitors, internalized ligands were quickly transferred to the secondary lysosome peak. This "transfer process" was faster for EGF, than for the other two ligands studied. We interpret these data to indicate that the endocytosis of these three ligands, and their delivery to lysosomes in fibroblasts, proceeds through a common pathway, involving intermediate nonlysosomal structures.

Membrane flow during pinocytosis. A stereologic analysis.

HRP has been used as a cytochemical marker for a sterelogic analysis of pinocytic vesicles and secondary lysosomes in cultivated macrophages and L cells. Evidence is presented that the diaminobenzidine technique (a) detects all vaculoes containing encyme and (b) distinguishes between incoming pinocytic vesicles and those which have fused with pre-existing lysosomes to form secondary lososomes. The HRP reactive pinocytic vesicle spaces fills completely within 5 min after exposure to enzyme, while the secondary lysosome compartment is saturated in 45--60 min. The size distribution of sectioned (profile) vaculoe diameters was measured at equilibrium and converted to actual (spherical) dimensions using a technique modified from Dr. S. D. Wicksell. The most important findings in this study have to do with the rate at which pinocytosed fluid and surface membrane move into the cell and on their subsequent fate. Each minute macrophages form at least 125 pinocytic vesicles having a fractional vol of 0.43% of the cell's volume and a fractional area of 3.1% of the cell's surface area. The fractional volume and surface area flux rates for L cells were 0.05% and 0.8% per minute respectively. Macrophages and L cells thus interiorize the equivalent of their cell surface area every 33 and 125 min. During a 3-period, the size of the secondary lysosome compartment remains constant and represents 2.5% of the cell volume and 18% of the surface area. Each hour, therefore, the volume and surface area of incoming vesicles is 10 times greater than the dimensions of the secondary lysosomes in both macrophages and L cells. This implies a rapid reduction in vesicle size during the formation of the secondary lysosome and the egress of pinocytosed fluid from the vacuole and the cell. In addition, we postulate that membrane components of the vacuole are subsequently recycled back to the cell surface.