EFFECTS OF IONOPHORE A23187 ON OOCYTES OF COMANTHUS JAPONICA (ECHINODERMATA: CRINOIDEA)*

Micromolar amounts of divalent cation ionophore A23187 stimulate full grown (but unfertilizable) oocytes of Comanthus japonica to undergo a cortical reaction that is incomplete: first, cortical granule contents ejected at exocytosis do not coalesce but remain as individual blebs just outside the oocyte; and, second, about a fourth of the cortical granule population does not undergo exo-cytosis and remains in the cortical cytoplasm. Of the cortical granules remaining in the oocyte, some have unreacted contents and others have morphologically modified contents. Fine structures are compared among unreacted cortical granules, internally-reacted cortical granules, extracellular blebs of cortical granule material and normal fertilization membranes. The comparison strongly suggests that the outer dense layer and inner fibrous layer of the normal fertilization membrane are derived, respectively, from the dense patches and from the matrices of the cortical granules.     

The ultrastructure of guinea pig heterophil granulocytes and the heterogeneity of the granules

Summary The development of the heterophil granulocytes in the bone marrow of the guinea pig is described. During the maturation of these cells, three types of granule are formed, not only the azurophil and specific granules already described in other mammals but also a third type of granule referred to here as the nucleated granule. During the process of maturation of the cells, these three types of granule are formed successively. On this basis, two steps can be distinguished in the promyelocyte phase in which primary (nucleated and azurophil) granules are formed, i.e. an early and a late stage, nucleated granules being formed in early and azurophil granules in late promyelocytes. Secondary (specific) granules occur first in myelocytes. In mature heterophils of the guinea pig the granule population is composed of about 85% secondary granules, about 10% azurophil granules, and about 5% nucleated granules. The changes in the granule population during the maturation process were quantified. The observations and calculations point to the occurrence of three mitoses: one in the early and one in the late promyelocyte and the third in the myelocyte.     

ORIGIN AND DEVELOPMENT OF PROTEIN GRANULES IN MAIZE ENDOSPERM

Protein granule development in the starchy endosperm of normal maize (inbred line, W46A) was studied with optical and electron microscopy. The granules were first observed 12 days after pollination as spherical deposits, usually single, within an enclosing membrane. They developed from vesicles produced by the endoplasmic reticulum and were formed both as small localized cisternal dilations and as enlargements at the ends of endoplasmic reticulum. Dictyosomes also appear to proliferate protein granule vesicles. The protein accumulated in the granules appears to be synthesized outside the membranes. Once initiated, the granules rapidly increase in size and number as the kernel develops; their final diameter ranges up to 2 μ. Immature granules stain with a variety of biological dyes in aqueous solution as well as with metal stains; mature granules stain lightly or not at all. At kernel maturity, the protein granules are embedded in a protein matrix.     

Developmental changes in morphology and toxin content of the salivary gland of the australian paralysis tick Ixodes holocyclus

Binnington K.C. and Stone B.F. 1981. Developmental changes in morphology and toxin content of the salivary gland of the Australian paralysis tick Ixodes holocyclus.International Journal for Parasitology11: 343–351. Histological study of the salivary gland of female I. holocyclus has shown that 2 of the 4 cell types present are richest in granules in the unfed stage but have discharged these granules after an attachment period of 24 h. The presence of a toxin in homogenates of salivary glands from unfed females and its absence after 24 h of attachment may be associated with the loss of granules from these 2 cell types shortly after attachment. Another cell type shows a gradual increase in granule content throughout feeding and a fourth, a peak in granule content after an attachment period of 120 h. The latter cell type may produce the paralysing toxin since ticks do not paralyse the host until they have fed for about this time and homogenised glands are most toxic at 120–144 h.     

Maturation-related changes in mass and elemental contents of secretory granules as measured by electron-microprobe

Summary The relationship between granule density, protein content, and Ca and S contents were studied in two secretory granule fractions, from parotid glands of the rat, previously shown to constitute different stages in granule maturation. The density of the lighter fraction was between 1.133 and 1.142 g/ml, while that of the heavier fraction was greater than 1.142 g/ml. The mean protein content of the denser granules was 12% greater than that of the lighter granules (P<0.03), while the dry-mass elemental concentrations in the two granule fractions were unchanged. These results indicate that protein is added to granules during the maturation process (presumably by vesicular traffic), and that the resulting increase in granule density is not driven simply by decrease in water content and/or increased concentrations of inorganic Ca or S in the granules. The elemental concentration values also indicate that the diffusible elements permeate the granule membrane during the fractionation procedures.     

ANIMAL/VEGETAL DIFFERENCES IN CORTICAL GRANULE EXOCYTOSIS DURING ACTIVATION OF THE FROG EGG*

One of the more striking morphological events during egg activation is exocytosis of the cortical granules. In the frog egg, the wave of cortical granule exocytosis takes about 100 sec to traverse the animal half, and travels slower in the vegetal half. We examined cortical granule exoctyosis during activation with respect to this animal/vegetal difference. In eggs which were acquiring the ability to be activated (recovering from CO₂-intoxication or undergoing meiotic maturation), animal half cortical granules became capable of responding to activating stimuli prior to vegetal half ones. Since Ca²⁺ is involved in exocytosis, we examined the effect of Ca²⁺ on cortical granule breakdown in vitro. There was no difference in sensitivity to Ca²⁺ of cortical granules from immature vs. mature eggs, but animal half cortical granules were more sensistive to Ca²⁺ than vegetal half ones. Finally, we found that prick-activation of eggs at the vegetal pole was frequently unsuccessful but would occur when external Ca²⁺ was raised. These experiments show that there are regional differences in the frog egg with respect to cortical granule responsiveness, and they suggest that the differences are due to Ca²⁺ sensitivity.     

A Comparative Study of the Storage Carbohydrate Granules from Euglena (Euglenida) and Pavlova (Prymnesiida)1,2

ABSTRACT The storage carbohydrate granules from Euglena and Pavlova were compared by light and electron microscopy. Freezeetch studies demonstrated that while both types of granules are crystalline, they have different structures. The elemental microfibril of the euglenoid granule measures 4 nm, and the elemental striation of the granule from Pavlova is 22 nm. The granules each have a unique X-ray diffraction pattern. The storage carbohydrate granules from Pavlova are not the same as paramyton, and the term “paramylon” should be reserved for the euglenoid storage carbohydrate.     

STARCH GRANULE FORMATION IN DEVELOPING SEEDS OF PISUM SATIVUM L.: EFFECT OF GENOTYPE

Cell development and starch granule formation in seeds of three pea (Pisum sativum L.) genotypes, R/R Rb/Rb, r/r Rb/Rb, and R/R rb/rb, affecting cotyledon starch were compared. Cotyledon cells at 10 days after flowering were highly vacuolated and contained small protein bodies in the vacuoles and small oval starch granules in the cytoplasm in all three genotypes. Gradients of cell development from the center to the periphery of the cotyledon and toward the cotyledon-hypocotyl axis persisted through the cell enlargement, reserve synthesis, and into the maturation stages of cotyledon development. By 14 days after flowering, many small vacuoles lined with protein deposits had been formed. Vacuoles were only observed in peripheral and basal cells by 18 days after flowering. Starch granules were oval and birefringent in all three genotypes at 10 days. Starch granules in R/R Rb/Rb and R/R rb/rb cotyledons expanded regularly remaining nearly oval and birefringent throughout development. In contrast, starch granules from r/r Rb/Rb cotyledons began to fragment by 14 days after flowering. This process began as a single fissure, followed by a second fissure usually at or near right angles. Finally, because of the fragmentation, the granules appeared compound, and only a portion of the granule was birefringent. All genotypes contained nearly equal volumes of liquid endosperm and embryo at 10 days after flowering. In addition, a layer of parenchyma tissue (ovular and/or endospermic) inside the seed coat was observed. Although, thin walled and poorly defined cytologically, the parenchyma cells contained large numbers of starch granules. These granules were a mixture of simple and compound types in all genotypes. By 18 days after flowering, the parenchyma tissue was reduced to a small layer of cell walls and all starch granules had been mobilized.     

STARCH GRANULE (AMYLOPLAST) DEVELOPMENT IN ENDOSPERM OF SEVERAL ZEA MAYS L. GENOTYPES AFFECTING KERNEL POLYSACCHARIDES

Endosperm cell and starch granule (amyloplast) development of six maize (Zea mays L.) genotypes, normal, amylose-extender (ae), sugary (su), waxy (wx), amylose-extender sugary (ae su), and amylose-extender waxy (ae wx), was compared. Endosperms of all genotypes were indistinguishable at 14 days after pollination. Cells were highly vacuolated and those in the central crown area of the kernel contained small starch granules in close association with the nucleus. Cellular and nuclear enlargement occurred during endosperm development in all genotypes, and major and minor gradients in physiological age of endosperm cells were observed in all kernels. Amyloplast development varied with genotype. Plastid development in normal and wx cells was characterized by an initial starch granule formation followed by granule enlargement to cell maturity. Endosperms homozygous for ae (ae, ae su, and ae wx) developed abnormal plastid-granules. Secondary granule formations preceded development of abnormality in ae and ae su, but not in ae wx endosperms. In contrast to ae and ae su starch granules, ae wx granules were highly birefringent indicating a high degree of crystallinity. In all three ae genotypes, abnormality increased as a function of kernel and physiological cell age. The su mutant had two distinct effects on amyloplast development. First, a mobilization of the initially formed starch, and second a synthesis and accumulation of phytoglycogen and the formation of large rounded plastids. In ae su plastid development, there was a mobilization of the starch initially formed (resulting in irregularly shaped, nonbirefringent granules) but only small amounts of phytoglycogen were produced.     

An energy-based population-balance approach to model granule growth and breakage in high-shear wet granulation processes

A mathematical model of high shear wet granulation is proposed, where granule breakage, and not growth, is the dominant process. The energy required for granule breakage is assumed to be provided by the impact of granules between themselves and the granulator parts, and the extent of granule breakage determined by the balance between the impactenergy and the work of adhesion between the agglomerating particles. A specific volume of dry powder per unit crack surface area was allowed to reattach to the surface of broken granules to account for granule growth. To verify proposed model conditions, lactose monohydrate was granulated with a relatively low amount (6%) of the binder phase, polyvinyl-pyrrolidone and water, and was added to the powder before granulation. The trend in granule size distribution during the experiment closely follwed the predicted model with an initial increase in the weight fraction of the larger granules. This increase was possibly due to extensive breakage of weaker granules and less extensive breakage, as if by attrition, of stronger granules, accompanied by the attachment of dry powder to the cracked surfaces. Eventually, larger granules experience increased impact energy and break. When excess binder is added and, higher volumes of powder reattach to the crack surface, more large granules form leading to granule overgrowth. This model highlights the importance of the probability of impact per unit time interval (ie, the rate of impact), the strength of the granules and the volume of powder that could attach to the cracked surface in high shear granulation processes where significant granule breakage is encountered. Published: August 10, 2007     

CHARACTERIZATION AND TOPOGRAPHY OF THE GLYCOPROTEINS OF ADRENAL CHROMAFFIN GRANULES

The glycoproteins of the membranes of bovine chromaffin granules were characterized by two polyacrylamide gel electrophoresis systems. Five components (I-V) were demonstrated with apparent molecular weights ranging in the unreduced form from 45,000 to 150,000. Glycoprotein I was identified as the enzyme dopamine β-hydroxylase. Four of these glycoproteins (with the exception of component IV) were apparently also present in the membranes of pig and horse chromaffin granules. The soluble proteins of chromaffin granules contained at least three glycoproteins. Only glycoprotein I (dopamine β-hydroxylase) was present both in the soluble content and in the membranes of chromaffin granules. Affinity chromatography with lectins demonstrated that from the soluble proteins only dopamine β-hydroxylase was adsorbed by concanavalin A, whereas none of these proteins reacted with wheat germ lectin and Ricinus communis agglutinin. Three membrane proteins including dopamine β-hydroxylase and glycoprotein II as major components were adsorbed by concanavalin A, whereas wheat germ lectin bound only component II and a small amount of component III. By electron microscopy it was demonstrated that concanavalin A did not bind to intact chromaffin granules whereas ruthenium red and cationized ferritin did. Isotope labelling after galactose oxidase treatment revealed that at least the carbohydrate portion of the major glycoproteins is present on the inner side of the granule membranes facing the content.     

Morphological heterogeneity of secretory granules of rat Clara cells: an immunocytochemical study

Summary The secretory granules of rat bronchiolar Clara cells were classified into different types by their ultrastructural appearances followed by immunocytochemistry using anti-rat 10 kDa Clara cell-specific protein (10 kDa CCSP) antibody. One predominant type was the oval to round granule (type A granule), of which the matrix was composed of a map-like mixture of electron-dense and less electron-dense material. Another predominant type was the rod-shaped granule (type B granule). The content of type B granules varied from a finely fibrillar (type B1 granule) to an electron-dense, rod-like (type B3 granule) structure. Various intermediate types (type B2 granule) between type B1 and B3 granules were also found. Small cytoplasmic vesicles were found occasionally in close proximity to type B2 or B3 granule. Another type of granule (type C granule) was large, up to 8 m in diameter, and contained a moderately electron-dense amorphous matrix. Both type A and C granules stained at a similar density with the antibody. The nascent form of type A granules, which was found in the vicinity to the trans face of the Golgi apparatus, was also labeled. On the other hand, the labeling density of type B granules varied: type B1 granules were almost devoid of immunolabeling, whereas type B3 granules were intensely labeled. Type B2 granules stained with the antibody; however, the labeling density was less than that of type B3 granules. The small cytoplasmic vesicles of type B2 granules were labeled. From these findings, it is suggested that the granules of rat Clara cells consist of two types of granules of distinct origin; one appears to derive from condensing vacuoles of Golgi origin, whereas the other may be formed by membranefusions with small cytoplasmic vesicles of unknown source.     

ASSOCIATION OF THE ALKALINE PHOSPHATASE OF RABBIT POLYMORPHONUCLEAR LEUKOCYTES WITH THE MEMBRANE OF THE SPECIFIC GRANULES

The localization of alkaline phosphatase in the specific granules of rabbit polymorphonuclear leukocytes was investigated. The results obtained suggest very strongly that alkaline phosphatase is a component of the granule membrane. The enzyme remains attached to the membrane upon disruption of the granules by the use of detergents or by hypotonic shock and subsequent extraction with sodium sulfate, and can be isolated together with fragments of the granule membrane by isopycnic equilibration. Treatment of the granules with high amounts of Triton-X-100, sodium deoxycholate, or hexadecyltrimethylammonium bromide releases the enzyme in soluble form. In polymorphonuclear leukocyte homogenates, lysis of the granules is needed in order to render alkaline phosphatase fully accessible to substrates. This suggests that the catalytic site of the enzyme is exposed at the inner face of the granule membrane.     

Control of secretory granule interaction and exocytosis in pancreatic cells

Application of the laser-based technique of photon correlation spectroscopy to anin vitro study of the ionic stability and interaction kinetics of zymogen granules isolated from rat exocrine pancreas is described here. In addition the separation from pancreatic acinar cell cytosol of a factor which stabilizes isolated zymogen granules and inhibits cation-induced granule aggregation is outlined. The basis of this action and the significance of the cytosolic inhibitory factor in the regulation of granule mobility and exocytosisin vivo is discussed.     

The influence of substrate transport limitation on porosity and methanogenic activity of anaerobic sludge granules

The relationship between porosity, diameter and methanogenic activity of anaerobic granules has been investigated. Experiments with different granular sludges revealed that substrate transport limitations increase with the diameter of the granules. As a consequence, autolysis can occur in the core of the granule, producing hallow granules. The porosity measurements revealed that the hollow centre is not available for substrate transport. Possibly as an effect of bacterial lysis, the porosity decreases in the more interior layers of the granules. This results in a inactive inner part of the large granules, which is not involved in the treatment process; the specific methanogenic activity decreases with granule size. No marked difference in substrate affinity is observed between granules of different sizes, which probably indicates that for large granules only the exterior is biological active. Correspondence to: G. Lettinga     

Subcellular fractionation of pig platelets

Subcellular components were obtained from pig platelets, disrupted by means of a French press and separated into 4 primary fractions. The granule fraction (10 000 g) was subjected to a sucrose gradient fractionation. Primary fractions and the granule subfractions were studied electron microscopically and biochemically by following the distribution of markers of membranes, lysosomes of α-granules, mitochondria and dense granules. With this technique of platelet homogenization, 80% of the serotonin and 93% of the β-N-acetylglucosaminidase were found to be particulate. In the gradient, mitochondria were sharply banded in a fraction (density 1.16–1.17) having a specific activity 10–100 times higher than the other fractions of the gradient. Serotonin-containing granules were found in a pellet of density greater than 1.27 and contained 60% of the serotonin and adenine nucleotides of the granule fraction. The lysosome markers that were monitored, acid phosphatase and β-N-acetylglucosaminidase, exhibited different distribution patterns. Acid phosphatase showed the highest specific activity in the microsomal fraction with only 2.8% in the granule fraction, and this latter amount also appeared to be associated with membranes upon further fractionation. β-N-Acetylglucosaminidase was present in both the granule fraction and in the microsomal fraction with nearly the same specific activity. However, that present in the granule fraction was clearly associated with granules that distributed over a wide range of densities on a sucrose gradient. The calcium distribution was followed to attempt to determine its subcellular location; 19% was found in the same subfraction as the serotonin-containing granules, but at least 50% of the particulate calcium was associated with granules distinctly separate from the storage granules.     

Evidence that the ability to respond to a calcium stimulus in exocytosis is determined by the secretory granule membrane: Comparison of exocytosis of injected bovine chromaffin granule membranes and endogenous cortical granules inXenopus laevis oocytes

Summary 1. To understand better the mechanisms which govern the sensitivity of secretory vesicles to a calcium stimulus, we compared the abilities of injected chromaffin granule membranes and of endogenous cortical granules to undergo exocytosis inXenopus laevis oocytes and eggs in response to cytosolic Ca²⁺. Exocytosis of chromaffin granule membranes was detected by the appearance of dopamine--hydroxylase of the chromaffin granule membrane in the oocyte or egg plasma membrane. Cortical granule exocytosis was detected by release of cortical granule lectin, a soluble constituent of cortical granules, from individual cells.2. Injected chromaffin granule membranes undergo exocytosis equally well in frog oocytes and eggs in response to a rise in cytosolic Ca²⁺ induced by incubation with ionomycin.3. Elevated Ca²⁺ triggered cortical granule exocytosis in eggs but not in oocytes.4. Injected chromaffin granule membranes do not contribute factors to the oocyte that allow calcium-dependent exocytosis of the endogenous cortical granules.5. Protein kinase C activation by phorbol esters stimulates cortical granule exocytosis in bothXenopus laevis oocytes andX. laevis eggs (Bement, W. M., and Capco, D. G.,J. Cell Biol. 108, 885–892, 1989). Activation of protein kinase C by phorbol ester also stimulated chromaffin granule membrane exocytosis in oocytes, indicating that although cortical granules and chromaffin granule membranes differ in calcium responsiveness, PKC activation is an effective secretory stimulus for both.6. These results suggest that structural or biochemical characteristics of the chromaffin granule membrane result in its ability to respond to a Ca²⁺ stimulus. In the oocytes, cortical granule components necessary for Ca²⁺-dependent exocytosis may be missing, nonfunctional, or unable to couple to the Ca²⁺ stimulus and downstream events.     

CYTOPLASMIC FINE STRUCTURE OF SCIARA SALIVARY GLANDS : I. Secretion

Cells from the anterior segment of the salivary glands of Sciara coprophila were found to synthesize and secrete into the gland lumen three morphologically distinct types of granule: 1) A large, electron-lucid granule, up to 1 µ in diameter, staining only faintly with pH 2 fast green and the PAS reaction; 2) an ellipsoid granule of moderate density, strongly fast green and PAS positive; and 3) a small spherical granule of high electron density. The cells contained numerous Golgi areas, up to an estimated 8,000 per cell. Evidence is presented for the transfer of material from the endoplasmic reticulum to the Golgi areas via small vesicles. Three types of Golgi areas were distinguishable, each containing intercisternal material resembling one of the three types of secretion granule. Patterns of secretion granule synthesis varied with the developmental stage of the larva as determined by counts of eye spots in the eye anlage. Lucid granules were most abundant in the youngest larvae, and decreased in abundance as larvae grew older, becoming virtually absent in prepupae. The small, dense granules were present in all gland cells, but became more prevalent in older larvae and prepupae. Ellipsoid granules were only occasionally present, and were independent of larval stage. It is suggested that lucid granules are digestive in function, since their abundance correlates with feeding patterns. Other granules may produce the external slime coating of the larvae, and also the mucoprotein component of the pupal cocoon.     

The quorum-sensing effect of aerobic granules on bacterial adhesion, biofilm formation, and sludge granulation

Quorum sensing (QS) through signal chemical molecules is known to be essential to bacterial adhesion and biofilm formation. In this study, the QS ability of aerobic granules—a special form of biofilms used for biological wastewater treatment—was investigated and compared with that of conventional activated sludge flocs. A novel sectional membrane bioreactor was used together with a flow-cell to evaluate the possible influence of signal chemicals produced by the source sludge on the growth mode of bacterial cells. The results demonstrate the apparent production of QS chemicals from granules and its impact on initial cell attachment and granule formation. When granules were used as the signal-producing biomass, the attached-growth mode was dominant for the free cells, and the biofilm formation rate in the flow-cell was about ten times faster than in cases which used activated sludge as the signal source biomass. In addition, the intracellular extract from mature granules significantly accelerated the sludge granulation process. It is argued that the production and expression of QS signal chemicals from granules and granule precursors might have induced the gene expression of bacteria in suspension for attached growth rather than suspended growth, leading to granule formation and its stable structure.     

MATURATION OF RAT MAST CELLS : An Electron Microscope Study

Electron microscope study of rat mast cell maturation corroborates certain interpretations of features of mast cell differentiation based on light microscope studies. In addition, the ultrastructural variation observed in the granules of differentiating mast cells suggests that granule formation begins with the elaboration of dense granules about 70 mµ in diameter inside Golgi vacuoles. These progranules appear to aggregate inside a membrane and fuse to form dense cords 70 to 100 mµ in diameter. These dense cords are embedded in a finely granular material possibly added to the developing granule by direct continuity between perigranular membranes and cisternae of rough endoplasmic reticulum. The dense cords and finely granular material then appear to be replaced by a mass of strands about 30 mµ in diameter, thought to be a reorganization product of the two formerly separate components. A process interpreted as compaction of the strands completes the formation of the dense, homogeneous granules observed in mature rat mast cells. The similarity between mast cell granule formation and the elaboration of other granules is considered, with special reference to rabbit polymorphonuclear leukocyte azurophil granules. The relationships between the ultrastructural, histochemical, and radioautographic characteristics of mast cell granule formation are considered, and the significance of the perigranular membrane is discussed.