David Bermudes

Biodistribution and Genetic Stability of the Novel Antitumor Agent VNP20009, a Genetically Modified Strain of Salmonella typhimuvium

VNP20009 is a genetically modified strain of Salmonella typhimurium possessing an excellent safety profile, including genetically stable attenuated virulence (a deletion in the purI gene), reduction of septic shock potential (a deletion in the msbB gene), and antibiotic susceptibility. VNP20009 is genetically stable after multiple generations in vitro and in vivo. In mice, VNP20009 is rapidly cleared from the blood from a peak level of 1x104 cfu/mL to undetectable levels in 24 h. In tumor-bearing mice, VNP20009 accumulates preferentially in tumors over livers at a ratio of 1000&rcolon;1. In nonhuman primates, VNP20009 was also rapidly cleared from the blood, from a peak level of 1.0x106 cfu/mL to undetectable levels in 24 h. VNP20009 was detected in the liver, spleen, and bone marrow of monkeys; the amount decreased over time, and VNP20009 was cleared from all organs by day 41; no VNP20009 could be detected in the urine or feces of the monkeys. VNP20009 is genetically stable after many generations of growth (>140) both in vitro and in vivo.

Kinetics and pattern of organelle exocytosis during Toxoplasma gondii/host-cell interaction

The fate ofToxoplasma gondii dense-granule (GRA2, GRA3), rhoptry (ROP1), and surface (SAG1) proteins was followed by immunofluorescence assay (IFA) and immunoelectron microscopy at different stages after infection. Dense-granule exocytosis occurred in the apical area of the tachyzoite within minutes of invasion. Several exocytic events were found simultaneously in the same organism, both by serial sectioning and by freeze-fracture studies. Dense-granule contents were first found as a dense material trapped between parasite and vacuole membranes before either the vacuolar network or the vacuole membrane could be immunolabeled with specific antibodies. The vacuolar network was strongly labeled with dense-granule antibodies but not with the SAG1-specific probe, which suggests that the network is not enriched in membrane proteins. In addition to strongly labeling the vacuole membrane, GRA3 antibodies also labeled strands extending from the parasitophorous vacuoles into the host-cell cytoplasm.

Melanoma × macrophage hybrids with enhanced metastatic potential

Studies were conducted on the hypothesis that melanoma metastasis might be initiated through the gener-ation of hybrids comprised of cells of the primary tumor and tumor-infiltrating leukocytes. Fusion hybrids were generated in vitro between weakly metastatic Cloudman S91 mouse melanoma cells and normal mouse or human macrophages. Hybrids were implanted s.c. in the tail and mice were monitored for metastases. Controls included parental S91 cells, autologous S91 × S91 hybrids, and B16F10 melanoma cells. Of 35 hybrids tested, most were more aggressive than the parental melanoma cells, producing metastases sooner and in more mice. A striking characteristic was heterogeneity amongst hybrids, with some lines producing no metastases and others producing metastases in up to 80% of mice. With few exceptions, hybrids with the highest metastatic potential also had the highest basal melanin content whereas those with the lowest metastatic potential were basally amelanotic, as were t he parental melanoma cells. A spontaneous in vivo supermelanotic hybrid between an S91 tumor cell and DBA/2J host cell was one of the most metastatic lines. Hybrids with the highest metastatic potential also exhibited markedly higher chemotaxis to fibroblast-conditioned media. Histologically, the metastatic hybrids demonstrated vascular invasion and spread to distant organs similar to that of metastatic melanomas in mice and humans. Thus previous findings of enhanced metastasis in leukocyte × lymphoma hybrids can now be extended to include leukocyte × melanoma hybrids. Whether such hybridization is a natural cause of metastasis in vivo remains to be determined; however the fusion hybrids with genetically-matched parents described herein so closely resembled naturally- occurring metastatic melanoma cells that they could serve as useful new models for studies of this complex and deadly phenomenon.

Cloning of a cDNA encoding the dense granule protein GRA3 from Toxoplasma gondii.

GRA3 is a 30-kDa protein located inside the dense granules of Toxoplasma gondii. Following invasion and exocytosis of dense granules within the parasitophorous vacuole, GRA3 becomes associated with the parasitophorous vacuolar membrane (PVM) and extensions of the PVM which protrude into the cytoplasm. A partial cDNA encoding GRA3 was isolated from a Toxoplasma gondii expression library using polyclonal and monoclonal antibodies to the mature GRA3 protein of tachyzoites. Antibodies affinity purified using the cloned fusion protein reacted with a 30-kDa band on immunoblots and recognized dense granules, the PVM, and PVM extensions by immunofluorescence staining of infected cells. Northern blot analysis indicated the major transcript was of a slightly larger size, and the complete cDNA encoding GRA3 was subsequently obtained. Southern blot analysis suggests that GRA3 is present as a single copy. The cDNA encodes two methionines at the N-terminus followed by an open reading frame with a hydrophobic region of 22 amino acids flanked by charged residues consistent with a signal sequence. Four shorter hydrophobic regions occur but are insufficient to span the membrane. No significant homology was detected to other proteins, including other dense granule proteins. In vitro translation of RNA generated from the cDNA containing either one or two of the N-terminal methionines yielded peptides with apparent M(r) of 35,000 and 37,000 respectively. Translation of RNA from the cDNA containing only the second initiation site in the presence of dog pancreas microsomes resulted in reduction of 4 kDa, sufficient to account for removal of the putative signal sequence.

Upstream elements required for expression of nucleoside triphosphate hydrolase genes of Toxoplasma gondii

Nucleoside triphosphate hydrolase is an abundant protein secreted by the obligate protozoan parasite Toxoplasma gondii. The protein has apyrase activity, degrading ATP to the di- and mono-phosphate forms. Because T. gondii is incapable of de novo synthesis of purines, it is postulated that NTPase may be used by the parasite to salvage purines from the host cell for survival and replication. To elucidate the molecular mechanisms of NTP gene expression, we isolated from the virulent RH strain of T. gondii the putative promoter region of three tandemly repeated NTP genes (NTP1, 2, 3). Using deletion constructs linked to the chloramphenicol acetyl transferase (CAT) reporter gene, we defined an active promoter within the first 220 bp. Sequence analysis of this region reveals the lack of a TATA box, but the promoter region is associated with a sequence which resembles an initiator element (Inr) in the NTP1 and NTP3 genes. This sequence which is similar to other Inrs known to regulate the expression of a wide variety of RNA polymerase II genes, is required for NTP expression. The NTP3 promoter contains sufficient information for developmentally regulated expression of CAT activity when the actively replicating stage tachyzoite differentiates into the dormant bradyzoite form.

Structure and Function of the Parasitophorous Vacuole Membrane Surrounding Toxoplasma gondii

Toxoplusma gondii is growing in popularity as a model for studying intracellular parasitism. The parasite has also gained more attention recently as the most common cause of focal central nervous system infections in patients with the acquired immunodeficiency syndrome,* and it continues to cause more than 3,000 cases per year of congenital birth defects in the United States alone. T. gondii infects nearly all animals and most birds and is one of the most widely distributed of all intracellular parasites. In vitro, tachyzoites of T. gondii can invade and replicate within essentially all nucleated cells, an unusual feat for any intracellular organism. The intracellular tachyzoites reside within a vacuole that is incapable of acidifying or fusing with any membrane-bound organelle within the host cell endocytic system= and as such is effectively hidden from the host, yet the parasite replicates rapidly. The fusion incompetence of the vacuole is established at the time of cell entry and does not depend on secretion by the parasite of a soluble inhibitor of the fusion or acidification events. On the basis of these findings and in conjunction with the known morphology of the newly formed parasitophorous vacuole membrane (PVM), we hypothesized that fusion incompetence results from the absence of protein signals for vesicular fusion events. Nonetheless, the PVM surrounding T. gondii serves a critical additional function which is likely to depend on proteins, by allowing access of necessary nutrients from and exchange of metabolites with the host cell. A second potential function for the PVM, binding of host cell mitochondria and endoplasmic reticulum,7 is also likely to be protein dependent. We believe that proteins that provide or contribute to these additional functions for the PVM are likely to be derived from parasite secretory organelles, but little direct data exist to support this hypothesis.