MORPHOLOGICAL AND CYTOCHEMICAL IDENTIFICATION OF THE GOLGI APPARATUS

1. A modification of Elftman's direct silver method reveals both the lipochondria of Baker and the network of Golgi in the same cell. For purpose of distinction, it is proposed to call Baker's lipochondria the nucleopetal fraction, the Golgi network the nucleofugal fraction of the Golgi apparatus. 2. The nucleopetal fraction is located closer to the nucleus. It is spherical in shape and appears black in color. The nucleofugal fraction is located farther away from the nucleus. It is reticular in form and appears brown in color after silver impregnation by the modified Elftman's method. 3. These two fractions are separate entities. The network of Golgi is not due to deposition of silver on lipochondria. Lipochondria do not represent Golgi apparatus in living cells. 4. Aldehydes facilitate the demonstration of the nucleofugal fraction. Based on the circumstantial evidence presented, it appears that aldehyde dehydrogenase composed of a specific protein bound to a prosthetic group of flavin-adenine dinucleotide may be concentrated in this fraction. 5. Aldehyde dehydrogenase also functions as xanthine oxidase. It is suggested as a working hypothesis that under physiological condition, one of the functions of the nucleofugal fraction (Golgi network) is concerned with purine metabolism of nucleoproteins.     

EFFECTS OF PHOSPHOTUNGSTATE NEGATIVE STAINING ON THE MORPHOLOGY OF THE ISOLATED GOLGI APPARATUS

Isolated Golgi complexes can be recognized in phosphotungstate (PTA) negative stain as stacks of membranous plates surrounded by a complex anastomosing network of tubules and vesicles. The extent of this tubular network is, however, much greater than can be observed in thin sections of whole cells. To determine which of the steps leading to the final negatively stained image may produce the observed changes, we have monitored each of the steps by other electron microscope and biochemical methods. The first damage to the membranes seems to occur during the initial isolation procedure as judged by the appearance of smooth patches on the freeze-fractured membrane faces that are normally covered with particles. Subsequent suspension of the Golgi fraction in water, to dilute the sucrose for negative staining, leads to the disappearnce of the stacking, to some tubulation and some vesiculation of the membranes as judged by thin section and freeze-cleave microscopy. The latter technique also reveals an increase in smooth-cleaving membrane faces. Application of the negative stain to the water-washed Golgi fraction, finally, produces extensive tubular arrays and a simultaneous decrease in the remaining large membranous vesicles. The freeze-cleaved tubular membranes appear essentially smooth except for small patches of aggregated particles. Parallel gel electrophoresis studies of the membranes and of the water and negative stain wash extracts indicate that protein extraction is involved in these morphological changes. PTA seems to be a particularly effective solvent for certain membrane proteins that are not removed by the water wash. These observations suggest that removal of membrane proteins alters structural restraints on the membrane lipids so that they behave semiautonomously like myelinics and form new artificial structures. This does not eliminate the possibility, however, that some tubules also exist in the Golgi apparatus in vivo.     

ISOLATION OF THE GOLGI APPARATUS FROM PLANT CELLS

A method for the isolation of the Golgi apparatus from stem tissues of onion is described. Preparations that consisted mainly of morphologically identifiable Golgi apparatus have been obtained. The best preparations were obtained from tissue homogenized under conditions of minimum shear, and in the presence of sucrose and certain additives which aid in preservation of the integrity of the Golgi membranes. Those additives, which had a pronounced stabilizing effect on the isolated apparatus, included both monovalent and divalent ions (sodium and calcium) and dextran. A large portion of the Golgi apparatus did not appear to change microscopic appearance upon isolation, but were observed to fuse into large aggregate structures not unlike those occurring naturally in certain animal or insect cells (12). Fusion occurred both at the edges of the cisternae and in register, but the integrity of the individual cisternae was not destroyed. The major contaminants of the Golgi apparatus fraction were numerous small and large spherical vesicles. At least some of these vesicles appeared to have been derived from the Golgi apparatus; others may have been fragments of the cell membrane, the endoplasmic reticulum, or other cell debris. By utilizing this procedure, it has been possible to obtain fractions of Golgi apparatus from plant tissues other than onion stem. However, at the present time it is only with onion that the Golgi apparatus has been isolated in a form that would warrant further purification for biochemical analysis.     

THE GOLGI APPARATUS IN CHICK CORNEAL EPITHELIUM: CHANGES IN INTRACELLULAR POSITION DURING DEVELOPMENT

The intracellular position of the Golgi apparatuses in the basal cell layer of the corneal epithelium in embryonic and hatched chicks has been studied in the light microscope by impregnating the Golgi apparatus with silver. During two distinct periods in development the Golgi apparatuses in the basal cells shift from an apical to basal position. Each of these periods correlates in time with the appearance of an acellular collagenous matrix beneath the epithelium. Examination of the basal epithelial cells in the electron microscope confirms the intracellular shifts in position of the Golgi apparatus. The results suggest that the Golgi apparatus shifts to the basal cell pole of the corneal epithelium in order to excrete connective tissue materials into the developing corneal stroma.     

THE GOLGI APPARATUS IN NEURONS AND EPITHELIAL CELLS OF THE COMMON LIMPET PATELLA VULGATA

1. In view of widely diverse views held about the identity and structure of the Golgi apparatus in neurons of Mollusca, particularly gastropods, a study has been made on neurons of the common limpet, Patella vulgata, both by light and electron microscopy. A report is given also of observations made on epithelial cells of Patella by electron microscopy. 2. As revealed by Kolatchev's method, the Golgi apparatus in neurons consists basically of black filaments lying to one side of the nucleus. The filaments generally anastomose to form networks of various complexity. Rarely some cells contain only discrete filaments. Associated with some of the filaments is a weakly osmiophilic substance identified as archoplasm. Kolatchev's method also revealed spheroidal bodies (neutral red bodies, "lipochondria," etc.). 3. It has not been possible to demonstrate the Golgi apparatus using either iron-haematoxylin or Sudan black. 4. Examination of Kolatchev's preparations by electron microscopy has revealed that some of the Golgi filaments consist of chromophilic and chromophobic components. The chromophilic component consists of dense lamellae. 5. After fixation in buffered osmium tetroxide solution and examination by electron microscopy, it has been concluded that (a) the chromophilic component of the Golgi apparatus corresponds to a system of paired membranes (which usually enclose an inner dense substance), (b) the chromophobic component corresponds to a substance lying within small dilations of the paired membrane, and (c) the archoplasm corresponds to numerous small vesicles. 6. The paired membranes branch, anastomose, and can often be traced back to a common source. They are interpreted as lamelliform folds, and occasionally tubular processes, of essentially a single Golgi membrane. In cells containing a Golgi network it is suggested that the membrane extends through the whole of the apparatus in such a way that the substance it encloses may be regarded as being in a continuous phase. 7. Epithelial cells of Patella contain a juxtanuclear Golgi apparatus with an ultrastructure similar to that described for neurons.     

DETECTION OF COMPLEX CARBOHYDRATES IN THE GOLGI APPARATUS OF RAT CELLS

Two methods used for the electron microscopic detection of glycoproteins were applied to a variety of cell types in the rat; one involved successive treatment of sections with periodic acid, chromic acid, and silver methenamine; and the other, a brief treatment with a chromic acid-phosphotungstic acid mixture. The results obtained with the two methods were identical and, whenever the comparison was possible, similar to those obtained with the periodic acid-Schiff technique of light microscopy. In secretory as well as in nonsecretory cells, parts of the Golgi apparatus are stained. The last saccule on one side of each Golgi stack is strongly reactive (mature face), and the last saccule on the other side shows little or no reactivity (immature face); a gradient of reactivity occurs in between these saccules. The more likely explanation of the increase in staining intensity is that carbohydrate is synthesized and accumulates in saccules as they migrate toward the mature face. In many secretory cells, the mature face is associated with strongly stained secretory granules. Other structures stained are: (1) small vesicles, dense and multivesicular bodies, at least some of which are presumed to be lysosomal in nature; (2) cell coat; and (3) basement membrane. The evidence suggests that the Golgi saccules provide glycoproteins not only for secretion, but also for the needs of the lysosomal system as well as for incorporation into the cell coat and perhaps basement membrane.