Gregory W. Erdos

DQAsomes: A Novel Potential Drug and Gene Delivery System Made from Dequalinium™

AbstractPurpose. Dequalinium, a drug known for over 30 years, is a dicationic amphiphile compound resembling bolaform electrolytes. The purpose of our work was to determine the state of aggregation of dequalinium in aqueous medium and to investigate both, its ability to bind DNA and its potential to serve as a novel non-viral transfection vector. Methods. The form of aggregation was determined employing electron microscopic techniques. The DNA binding capacity of dequalinium was assayed using SYBR™ Green I stain. For in vitro cell transfection experiments plasmid DNA encoding for firefly luciferase was used. Results. Dequalinium forms in aqueous medium liposome-like aggregates, which we term DQAsomes. These dequalinium vesicles bind DNA and they are able to transfect cells in vitro with an efficiency comparable to Lipofectin™. Conclusions. Based on the intrinsic properties of dequalinium such as the in vivo selectivity for carcinoma cells and selective accumulation in mitochondria we propose DQAsomes as a novel and unique drug and gene delivery system.

Alterations in Ultrastructural Morphology of Two-Cell Bovine Embryos Produced In Vitro and In Vivo Following a Physiologically Relevant Heat Shock

Abstract Exposure of cultured preimplantation embryos to temperatures similar to those experienced by heat-stressed cows inhibits subsequent development. In this study, the effects of heat shock on the ultrastructure of two-cell bovine embryos were examined to determine mechanisms for inhibition of development. Two-cell embryos produced in vitro were harvested at ∼28 h postinsemination and cultured for 6 h at one of three temperatures: 38.5°C (cow body temperature), 41.0°C (characteristic temperature for heat-stressed cows), or 43.0°C (severe heat shock). Ultrastructural examinations revealed that both heat shocks resulted in the movement of organelles towards the center of the blastomere. In addition, heat shock increased the percentage of mitochondria exhibiting a swollen morphology. Distance between the membranes comprising the nuclear envelope was increased but only when embryos were treated at 43.0°C. To determine whether ultrastructural responses to heat shock in culture were similar for embryos produced in vitro and in vivo, two-cell embryos were collected from superovulated Angus cows 48 h postinsemination and treated ex vivo for 6 h at 38.5°C or 41.0°C. Again, heat shock caused an increase in number of swollen mitochondria and movement of organelles away from the periphery of the blastomere. Exposure of two-cell bovine embryos to physiologically relevant elevated temperatures causes disruption in ultrastructural morphology that is inimical to development. The observation that overall morphology and response to heat was similar for embryos produced in vitro and in vivo implies that the former can be a good model for understanding embryonic responses to heat shock.

Identification and characterization of a testis-specific isoform of a chaperonin in a moth, Heliothis virescens.

Two relatively abundant proteins having subunit molecular weights of 60,000 and 63,000 (p60 and p63, respectively) have been purified as a 16 to 18S complex from sperm mitochondria of a moth. Heliothis virescens. Although the function of these proteins had heretofore not been established, interest in the p63 polypeptide stemmed from its sperm-specific expression and its striking occurrence as a net charge variant among several insect species surveyed, using two-dimensional gel electrophoresis. Genomic and cDNA clones corresponding to the p63 protein have now been isolated and their sequencing has revealed extensive amino acid sequence identity with both the Escherichia coli GroEL protein and its eukaryotic homologues, the chaperonins. Immunoblot studies with a Tetrahymena chaperonin antiserum demonstrated that the p60 protein, which is expressed in all cell types, is structurally related to p63 and is itself a chaperonin subunit. While the chaperonin complex from Heliothis sperm shares certain properties with GroEL, including the ability to hydrolyze ATP and organization of its subunits into a seven-member ring, electron microscopic analysis revealed that its higher-order structure differed from GroEL (and other lower eukaryotic chaperonins) in that the native particle comprises one such ring rather than a doublet. It is not yet known whether the two chaperonin isoforms coexpressed in moth sperm assemble separately or give rise to hybrid particles. In either case, the existence of multiple chaperonin subunits in sperm leaves open the possibility that some aspect of mitochondrial biogenesis that is dependent upon the activity of these proteins is qualitatively or quantitatively different in this cell type.

Localization of Carbohydrate-Containing Molecules

A variety of carbohydrate-containing molecules can be found at both extracellular and intracellular locations in microorganisms. These can be subdivided into several broad categories based on their general composition and would include the polysaccharides (both homo- and heteropolymers), glycoproteins, glycolipids, and proteoglycans. These macromolecules, especially those exposed at the cell surface, have taken on considerable importance in the study of self-nonself recognition, cell attachment, adhesion, and pathogenesis, and receptor-mediated uptake. Thus, in situ localization of these molecules has become an important adjunct to biochemical studies of their structure. Although histochemical methods provide precise localization of carbohydrates, they have, until recently, given us only very basic information about the specific structure of the molecule in question. Most investigations have been limited to the detection of anionic groups exposed at the cell surface or to the presence of hexose sugars. Both of these techniques are based on light microscopic histochemistry. With the discovery of more and more lectins, some of which have very specific binding characteristics, more precise information can be gained about the saccharide structure of a molecule in question. Increasingly sophisticated technology in the use of lectins can provide information about sugars at the cell surface as well as in the cell interior. in the cell interior. Most recent is the application of carbohydrate-specific polyclonal and monoclonal antibodies coupled to electron-dense markers for the ultrastructural localization of specific polysaccharides and glycoconjugates.

The spore coat of a fucosylation mutant in Dictyostelium discoideum

Strain HL250 of Dictyostelium discoideum cannot convert GDP-mannose to GDP-fucose, resulting in an inability to fucosylate protein. This affects a group of proteins which are normally fucosylated intracellularly and then secreted via prespore vesicles to become part of the outer lamina of the spore coat. We have found that strain HL250 nevertheless accumulates typical amounts of these proteins, stores them normally in prespore vesicles, and secretes them normally to become a part of the spore coat. However, affected proteins are proteolyzed after germination, the spore coat is more accessible to penetration by a macromolecular probe, and germination is inefficient in older spores. These findings can be explained by a dependence of the integrity of the outer layer of the spore coat on protein-linked fucose.

Reorganization of Microfilaments and Microtubules by Thermal Stress in Two-Cell Bovine Embryos

Abstract Two-cell bovine embryos become arrested in development when exposed to a physiologically relevant heat shock. One of the major ultrastructural modifications caused by heat shock is translocation of organelles toward the center of the blastomere. The objective of the present study was to determine if heat- shock-induced movement of organelles is a result of cytoskeletal rearrangement. Two-cell bovine embryos were cultured at 38.5°C (homeothermic temperature of the cow), 41.0°C (physiologically relevant heat shock), or 43.0°C (severe heat shock) for 6 h in the presence of either vehicle, latrunculin B (a microfilament depolymerizer), rhizoxin (a microtubule depolymerizer), or paclitaxel (a microtubule stabilizer). Heat shock caused a rearrangement of actin-containing filaments as detected by staining with phalloidin. Moreover, latrunculin B reduced the heat-shock-induced movement of organelles at 41.0°C but not at 43.0°C. In contrast, movement of organelles caused by heat shock was inhibited by rhizoxin at both temperatures. Furthermore, rhizoxin, but not latrunculin B, reduced the swelling of mitochondria caused by heat shock. Paclitaxel, while causing major changes in ultrastructure, did not prevent the movement of organelles or mitochondrial swelling. It is concluded that heat shock disrupts microtubule and microfilaments in the two-cell bovine embryo and that these changes are responsible for movement of organelles away from the periphery. In addition, intact microtubules are a requirement for heat-shock-induced swelling of mitochondria. Differences in response to rhizoxin and paclitaxel are interpreted to mean that deformation of microtubules can occur through a mechanism independent of microtubule depolymerization.

Formation and organization of the spore coat ofDictyostelium discoideum

Abstract Macromolecular components of the spore coat of Dictyostelium discoideum have been localized by gold-labeled affinity cytochemistry. The outer electron-dense layer is the residence of three prominent glycoproteins that express a fucose-dependent epitope, whereas the inner electron-dense layer includes SP85 and the galactose/ N -acetylgalactosamine-containing polysaccharide (GPS). The cellulosic layers are interposed between them. The outer-layer glycoproteins and the GPS also can be found in the interspore fluid, which is usually lost during collection of the spores. Assembly of the spore coat, examined over time, showed that all components, except for the cellulose, are found in an internal secretory vesicle population. All components are found in each vesicle but are not uniformly intermixed within them. Cellulose does not appear until after the outer electron-dense layer of the spore coat has been organized following secretion. The GPS is excluded from the outer dense layer and largely from the cellulosic layer, being more concentrated in the inner layer. SP85 remains localized in the inner dense layer near the cell surface with a circumferentially focal distribution. The distinct distributions of these macromolecular species in the mature spore coat are foreshadowed by their mosaic distribution in the prespore vesicles from which they originate.

Glycoantigen expression is regulated both temporally and spatially during development in the cellular slime molds Dictyostelium discoideum and D. mucoroides

Six monoclonal antibodies were isolated which react with common antigens shared by multiple glycoconjugate species in the cellular slime mold Dictyostelium discoideum. Based on competition of antibody binding by glycopeptides and simple sugars, and inhibition of antibody binding by antigen pretreatment with Na periodate, it is argued that at least five of the six antibodies recognize epitopes which contain carbohydrate. These epitopes are consequently referred to as glycoantigens (GAs).Three of the GAs are expressed during growth and throughout the developmental cycle, but are eventually enriched in prestalk and stalk cells. The remaining three are expressed only during and/or after aggregation and are exclusively expressed or highly enriched in prespore cells and spores. These conclusions are derived from Western blot immunoanalysis of purified cell types, immunofluorescence, and EM immunocytochemistry.The two GAs found only in prespore cells appear to be exclusively enclosed within prespore vesicles. The third GA of this type, which is only enriched in prespore cells compared to prestalk cells, is also found in other vesicle types as well as on the cell surface.Two of the GAs enriched in prestalk cells are initially found in all cells of the slug. They are undetectable in spores and prominent in stalk cells. The third GA, though found in the interiors of both prestalk and prespore cells, is enriched on the cell surface of prestalk cells.The chief characteristics of expression of four of these GAs are conserved in the related species D. mucoroides. This species is characterized by continuous trans differentiation of prespore cells into prestalk cells. This shows that the prespore cells maintain specific mechanisms for turning over their cell type specific GAs and that prestalk cells express a specific mechanism for inducing at least one of their cell-type specific GAs.These observations identify specific carbohydrate structures (as GAs) whose synthesis, subsequent localization and turnover are developmentally regulated. The exclusive association of two GAs with prespore vesicles identifies these GAs as markers for this organelle and raises questions regarding the functional significance of this association. The restricted cell surface localization of the other four GAs, together with data from cell adhesion studies, suggest the possibility of a potential role for these GAs in intercellular recognition leading to cell sorting.

The expression of glycoproteins in the extracellular matrix of the cellular slime mold Dictyostelium discoideum

In this report we examine the accumulation of glycoconjugates in the extracellular medium and insoluble matrices surrounding developing cells of the cellular slime mold Dictyostelium discoideum. Conditions were employed which permitted advanced development (slug stage and beyond) in suspension culture. Under these conditions, up to one-third of the total culture protein appeared as non-sedimentable, extracellular material over the course of 48 h of incubation. Most of the secreted molecules expressed carbohydrate antigens (glycoantigens) as detected by Western blotting, using a panel of six monoclonal antibodies. Since the glycoantigens are secreted, immunoelectron microscopy was used to localize the glycoantigens in the extracellular matrices surrounding normally developing cells, including the slime sheath, stalk tube, inner spore coat, outer spore coat, and intercellular fluid between spores. Each glycoantigen had a characteristic distribution, and each extracellular matrix space contained a unique combination of glycoantigens. Thus, although each of these matrices (except inter-spore fluid) contains cellulose as a primary component, they could be distinguished on the basis of their glycoantigen and, by inference, glycoprotein compositions. Furthermore, there were differences between anterior and posterior regions of both slime sheaths and stalk tubes. These observations show that secretion as detected in suspension culture occurs under normal conditions as a part of the process of depositing extracellular matrices around the cells. The distributions show that the cell aggregate positionally regulates the expression and deposition of secretory glycoproteins; the resultant patterns of expression of unique protein-linked carbohydrate structures imply a functional role in matrix organization and possibly cell activity which can now be explored.

SP75 is encoded by the DP87 gene and belongs to a family of modular Dictyostelium discoideum outer layer spore coat proteins

Highly purified spore coats of Dictyostelium discoideum each contained about 5 x 10(6) protein molecules as determined by amino acid composition analysis. By two-dimensional gel electrophoresis the coats were found to contain nine major-abundance and numerous minor protein species, most of which were highly enriched relative to the adjacent interspore matrix. Protein was nearly quantitatively eluted by denaturants and 2-mercaptoethanol, showing that it was not irreversibly cross-linked. Because a reducing agent is required together with denaturants to elute most proteins if their free thiol groups have been prealkylated, it was concluded that the D. discoideum spore coat proteins are disulfide cross-linked into the matrix. One major coat protein, SP75, was partially sequenced and found to be encoded by the previously identified DP87 gene; this finding was supported by additional physical, genetic, biochemical and microscopic evidence. The five major proteins for which genes have been cloned were associated with the outer layer of the coat. In coats missing one or more of four of these proteins as a result of gene disruption, there were physical changes but, with one exception, the other major coat proteins appeared to be incorporated normally. Sequence analysis showed that these five outer layer coat proteins are homologous and consist of alternating sequence motifs related to epithelial mucin repeats, basic proline repeats found in salivary acidic proline-rich proteins, the NH2-terminal subdomain of epidermal growth factor modules and other cysteine repeats. Based on these and other observations, outer layer coat proteins are predicted to organize indeterminately to form a cell surface microenvironment supportive of cellulose morphogenesis during spore coat formation.