Catherine P. Chia

Phagosomal Proteins of Dictyostelium discoideum

ABSTRACT. In recognizing food particles, Dictyostelium cell‐surface molecules initiate cytoskeletal rearrangements that result in phagosome formation. After feeding D. discoideum cells latex beads, early phagosomes were isolated on sucrose step gradietns. Protein analyses of these vesicles showed that they contained glycoproteins and surface‐labeled species corresponding to integral plasma membrane proteins. Cytoskeletal proteins also were associated with phagosomes, including myosin II, actin and a 30 kDa‐actin bundling protein. As seen by the acridine orange fluorescence of vesicles containing bacteria, phagosomes were acidified rapidly by a vacuolar H+‐ATPase that was detected by immunoblotting. Except for the loss of cytoskeletal proteins, few other changes over time were noted in the protein profiles of phagosomes, suggesting that phagosome maturation was incomplete. The indigestibility of the beads possibly inhibited further endocytic processing, which has been observed by others. Since nascent phagosomes contained molecules of both the cytoskeleton and plasma membrane, they will be useful in studies aimed at identifying specific protein associations occurring between membrane proteins and the cytoskeleton during phagocytosis.

Co-loss of profilin I, II and cofilin with actin from maturing phagosomes inDictyostelium discoideum

SummaryAlthough it is known that actin polymerizes rapidly at the plasma membrane during the ingestion phase of phagocytosis, not yet fully understood are the mechanisms by which actin is recruited to form a phagoeytic cup and subsequently is dissociated from the phagosome. The aim of this study was to identify actin-binding proteins that mediated actin filament dynamics during phagosome formation and processing. We report that profilins I and II, which promote filament assembly, and cofilin, which stimulates filament disassembly, were constituents of phagosomes isolated fromDictyostelium discoideum fed latex beads, and associated with actin. Biochemical analyses detected one isoform only of cofilin, which bound actin in unstimulated cells as well as in cells engaged in phagocytosis, subjected to various stress treatments, and through development. At membranes of young phagosomes, profilins I and II colocalized with monomeric actin labeled with fluorescent DNase I, and cofilin colocalized with filamentous actin labeled with rhodamine phalloidin. Both immunocytochemical and quantitative immunoblotting data indicated that the kinetic loss of profilins I, II, and cofilin of maturing phagosomes closely followed the falling levels of actin associated with the vesicles. As evidence of vesicle processing,D. discoideum crystal protein (an esterase) was recruited rapidly to phagosomes and its levels increased while those of actin, profilins I, II, and cofilin jointly decreased. The localization data and concurrent losses of profilins and cofilin with actin from phagosomes are consistent with the roles of these actin-binding proteins in filament dynamics and indicated that they were involved in regulating the assembly and disassembly of the actin coat of phagosomes.

Nonspecific interactions alter lipopolysaccharide patterns and protein mobility on sodium dodecyl sulfate polyacrylamide gels

In testing whether bacterial lipopolysaccharide (LPS) was a natural substrate for an esterase from the soil amebae Dictyostelium discoideum, we observed altered banding patterns of the LPS and changed protein mobility on sodium dodecyl sulfate (SDS) polyacrylamide gels after incubation of LPS with the enzyme. The initial interpretation of these results was that the enzyme had removed ester‐linked acyl chains from the LPS, leading to a change in its migration on gels. However, esterase inactivated by treatment with either dithiothreitol (DTT), heat, or SDS generated the same mobility shifts. Bovine serum albumin (BSA) also induced the same change in the electrophoretic pattern. We conclude that the altered LPS patterns and protein mobility on SDS gels were caused by nonspecific interactions between LPS and protein.

Giant Vacuoles Observed in Dictyostelium discoideum

Large intracellular vacuoles, >4μm in diameter and either round or oval‐shaped, were observed infrequently in Dictyostelium discoideum amoebae of axenically‐grown strain AX2 (only 1 in 106–108cells). These previously unreported single or multiple ‘giant’ vacuoles were more common, however, in newly germinated KAX3 cells (0.55% of the population) and AT‐Kneg, a strain that lacks an esterase (0.47% of the population). A vacuolar H+‐ATPase was enriched in their membranes of intracellular giant vacuoles, indicating that the vacuoles were related possibly to both endosomes and the contractile vacuole compartment. When monitored over time, giant vacuoles protruded from, and retracted back into cells under hyperosmotic conditions, suggesting an osmoregulatory role for these vacuoles. Some of the intracellular and protruded giant vacuoles harbored a fluid‐phase marker, fluorescein‐labeled dextran, implying a pinocytotic origin for the vacuoles.

Influenza D Virus M2 Protein Exhibits Ion Channel Activity in Xenopus laevis Oocytes

Background A new type of influenza virus, known as type D, has recently been identified in cattle and pigs. Influenza D virus infection in cattle is typically asymptomatic; however, its infection in swine can result in clinical disease. Swine can also be infected with all other types of influenza viruses, namely A, B, and C. Consequently, swine can serve as a “mixing vessel” for highly pathogenic influenza viruses, including those with zoonotic potential. Currently, the only antiviral drug available targets influenza M2 protein ion channel is not completely effective. Thus, it is necessary to develop an M2 ion channel blocker capable of suppressing the induction of resistance to the genetic shift. To provide a basis for developing novel ion channel-blocking compounds, we investigated the properties of influenza D virus M2 protein (DM2) as a drug target. Results To test the ion channel activity of DM2, the DNA corresponding to DM2 with cMyc-tag conjugated to its carboxyl end was cloned into the shuttle vector pNCB1. The mRNA of the DM2–cMyc gene was synthesized and injected into Xenopus oocytes. The translation products of DM2–cMyc mRNA were confirmed by immunofluorescence and mass spectrometry analyses. The DM2–cMyc mRNA-injected oocytes were subjected to the two-electrode voltage-clamp (TEVC) method, and the induced inward current was observed. The midpoint (Vmid) values in Boltzmann modeling for oocytes injected with DM2–cMyc RNA or a buffer were −152 and −200 mV, respectively. Assuming the same expression level in the Xenopus oocytes, DM2 without tag and influenza C virus M2 protein (CM2) were subjected to the TEVC method. DM2 exhibited ion channel activity under the condition that CM2 ion channel activity was reproduced. The gating voltages represented by Vmid for CM2 and DM2 were –141 and –146 mV, respectively. The reversal potentials observed in ND96 for CM2 and DM2 were −21 and −22 mV, respectively. Compared with intact DM2, DM2 variants with mutation in the YxxxK motif, namely Y72A and K76A DM2, showed lower Vmid values while showing no change in reversal potential. Conclusion The M2 protein from newly isolated influenza D virus showed ion channel activity similar to that of CM2. The gating voltage was shown to be affected by the YxxxK motif and by the hydrophobicity and bulkiness of the carboxyl end of the molecule.

Structural insights into the mechanism defining substrate affinity in Arabidopsis thaliana dUTPase: the role of tryptophan 93 in ligand orientation

BackgroundDeoxyuridine triphosphate nucleotidohydrolase (dUTPase) hydrolyzes dUTP to dUMP and pyrophosphate to maintain the cellular thymine-uracil ratio. dUTPase is also a target for cancer chemotherapy. However, the mechanism defining its substrate affinity remains unclear. Sequence comparisons of various dUTPases revealed that Arabidopsis thaliana dUTPase has a unique tryptophan at position 93, which potentially contributes to its degree of substrate affinity. To better understand the roles of tryptophan 93, A. thaliana dUTPase was studied.ResultsEnzyme assays showed that A. thaliana dUTPase belongs to a high-affinity group of isozymes, which also includes the enzymes from Escherichia coli and Mycobacterium tuberculosis. Enzymes from Homo sapiens and Saccharomyces cerevisiae are grouped as low-affinity dUTPases. The structure of the homo-trimeric A. thaliana dUTPase showed three active sites, each with a different set of ligand interactions between the amino acids and water molecules. On an α-helix, tryptophan 93 appears to keep serine 89 in place via a water molecule and to specifically direct the ligand. Upon being oriented in the active site, the C-terminal residues close the active site to promote the reaction.ConclusionsIn the high-affinity group, the prefixed direction of the serine residues was oriented by a positively charged residue located four amino acids away, while low-affinity enzymes possess small hydrophobic residues at the corresponding sites.