Formation of stress fibres in human endothelial cells infected with Bartonella bacilliformis is associated with altered morphology, impaired migration and defects in cell morphogenesis.

Bartonella bacilliformis, a Gram-negative, flagellated bacterium, infects human erythrocytes (haematic phase) and endothelial cells (tissue phase), resulting in a biphasic disease. In the tissue phase of disease (verruga peruana), infection leads to infection of endothelial cells and a pronounced proliferation of these cells, resulting in characteristic skin eruptions of papules and nodules. We have studied the properties of endothelial cells infected in vitro. Extensive cytoskeletal remodelling of endothelial cells occurred after infection in vitro with B. bacilliformis. The cells became spindle shaped and contained arrays of actin stress fibres orientated parallel to the long axis of the cell. Cell-cell contacts were disrupted, along with the distribution of the plasma membrane marker protein, PECAM-1, which participates in cell-cell junctions. The prominent stress fibres terminated in an increased number of focal contacts, which were studied using immunofluorescent staining for paxillin, a cytoplasmic protein that localizes in the focal adhesions. These morphological changes are consistent with activation of intracellular Rho by B. bacilliformis. Formation of stress fibres and the increased number of focal adhesions could be prevented by preincubation of the endothelial cells with C3 exoenzyme, which inactivates intracellular Rho by ADP ribosylation. Endothelial cell motility was greatly diminished in infected cells and the cells did not respond effectively to a stimulus that would evoke motility. In addition, infection of endothelial cells interfered with their ability to form networks of capillary tubes when suspended within three-dimensional collagen matrices. If the properties of infected endothelial cells in vivo are similar, the infected cells will probably not participate effectively in angiogenesis.

Deformin, a substance found in Bartonella bacilliformis culture supernatants, is a small, hydrophobic molecule with an affinity for albumin.

Culture supernatants of Bartonella bacilliformis were previously shown to contain a factor, called deforming factor or deformin, which causes deformation and invagination of red cell membranes and formation of intracellular vacuoles. This factor is here shown to be a small water-soluble molecule, approximately 1400 Da as estimated by gel-filtration chromatography. Deforming factor binds tightly to albumin, especially albumin dimers and multimers, present in the growth medium. It can be released from albumin with 50% ethanol and has been partially purified by filtration and HPLC.

Infection of human endothelial cells with Bartonella bacilliformis is dependent on Rho and results in activation of Rho.

Bartonella bacilliformis was continuously internalized into human endothelial cells beginning shortly after addition of the bacteria and continuing for at least 24 h after infection in vitro, with a major increase in uptake occurring between 16 and 24 h. Preincubation of endothelial cells with C3 exoenzyme, which inactivated intracellular Rho-GTPase, blocked internalization of the bacteria. Addition of C3 exoenzyme at any time after addition of the bacteria blocked further internalization of bacteria, including the major uptake of bacteria internalized at 16 to 24 h. Rho, a key signaling protein in pathways involving actin organization, was directly shown to be activated in endothelial cells undergoing infection with B. bacilliformis, with maximal activation and translocation to the plasma membrane at 12 to 16 h. At late times of infection, most of the bacteria were found in a perinuclear location. Staining of the Golgi complex with specific markers, anti-human Golgin-97, anti-KDEL receptor, and BODIPY-TR ceramide, showed colocalization of bacteria in the Golgi complex region. Disruption of the Golgi complex with brefeldin A scattered the bacteria from this perinuclear location and resulted in inhibition of internalization of the bacteria in endothelial cells.

Comparison of the abilities of proteins from Bartonella bacilliformis and Bartonella henselae to deform red cell membranes and to bind to red cell ghost proteins.

Infections in humans by Bartonella bacilliformis, but not Bartonella henselae, are characterized by invasion of red cells. Supernatants of culture medium from B. bacilliformis and B. henselae each contain a protein which causes invagination of membranes of human red cells and formation of intracellular vacuoles. These two proteins are very similar in molecular mass, heat stability and mechanism of action. B. henselae does not bind to human red cells, but human red cell ghost membrane proteins were recognized by both bacteria, five by B. bacilliformis and the same five, and one additional protein by B. henselae. Two of these proteins had molecular masses consistent with actin and spectrin. Actin binds to five electroblotted outer membrane proteins from B. henselae and four of these proteins are retained on an actin-Sepharose column.

Bartonella bacilliformis: dangerous pathogen slowly emerging from deep background.

Bartonella bacilliformis was perhaps the most lethal bacterial human pathogen in the pre-antibiotic era, but infections were and are limited to a specific geographical area, largely in Peru, corresponding to the range of its sand fly vector. B. bacilliformis targets both red cells and endothelial cells. Recent phylogenetic realignments have revealed a close genetic relationship to other bacteria which cause human diseases, including bacterial angiomatosis, to the former Grahamella species which infect red cells in other mammals, and to plant pathogens and symbionts including Agrobacterium tumefaciens and Rhizobium meliloti. Features of B. bacilliformis that contribute to its pathogenesis are slowly coming into view, and are here reviewed.

Physical map of the Bartonella bacilliformis genome.

The genome of Bartonella bacilliformis was shown to be a single circular DNA molecule of about 1,600 kbp having six NotI, four SfiI, and two CeuI sites. A physical map of the DNA was constructed by contour-clamped homogeneous electric field pulsed-field gel electrophoresis of DNA restriction fragments. rRNA operons, the invasion-associated locus, and a flagellin gene were located on the map by hybridization.

Purification of deformin, an extracellular protein synthesized by Bartonella bacilliformis which causes deformation of erythrocyte membranes.

A factor capable of deforming erythrocyte membranes, found in the culture supernatants of Bartonella bacilliformis, was purified 1840-fold using hydrophobic, ion exchange and gel exclusion chromatography. The final fractions contained a single detectable polypeptide species, referred to as deformin, having a molecular weight of 67000 by SDS-PAGE and a native molecular weight of 130,000 by gel exclusion chromatography or velocity sedimentation in a glycerol gradient. Erythrocytes treated with deformin acquire trenches, indentations, and invaginations which could be reversed by vanadate, dilauroylphosphatidylcholine (DLPC), or by raising the internal Ca2+ concentrations with the inophore A23187. Internal vacuoles also form. Erythrocytes treated with trypsin or neuraminidase are much more sensitive to deformin than untreated erythrocytes; erythrocytes treated with phospholipase D are less sensitive to deformin. This protein may play a role in causing the severe anemia which can result as a consequence of infection by B. bacilliformis.

Deformation factor: an extracellular protein synthesized by Bartonella bacilliformis that deforms erythrocyte membranes.

Bartonella bacilliformis, a hemotropic bacterium and the causative agent of the human disease bartonellosis, when incubated in a tryptone-based medium produces an extracellular factor, termed deformation factor (DF), which induces extensive indentations and trenches in trypsinized erythrocyte membranes. The factor is stable during storage at 4 degrees C. It can be inactivated by proteases or brief heating to 70 to 80 degrees C, can be precipitated by ammonium sulfate, is nondialyzable, and is retained by membranes with a 30,000-molecular-weight cutoff. These properties suggest that DF is probably a protein. Incubation of erythrocytes with phospholipase D renders them resistant to deformation by DF.

Cytochrome b5 and a recombinant protein containing the cytochrome b5 hydrophobic domain spontaneously associate with the plasma membranes of cells.

Both cytochrome b5, isolated from rabbit liver microsomes, and LacZ:HP, a recombinant protein consisting of enzymatically active Escherichia coli beta-galactosidase coupled to the C-terminal membrane-anchoring hydrophobic domain of cytochrome b5, were shown to spontaneously associate with the plasma membranes of erythrocytes and 3T3 cells. Association was promoted by low pH values, but proceeded satisfactorily over several hours at physiological pH and temperature. About 150,000 cytochrome b5 molecules or 100,000 LacZ:HP molecules could be associated per erythrocyte. These proteins were not removed from the membrane by extensive washing, even at high ionic strength. After incubation with fluorescently labeled cytochrome b5 or LacZ:HP, cells displayed fluorescent membranes. The lateral mobility of fluorescently labeled cytochrome b5 and LacZ:HP was measured by photo-bleaching techniques. In the plasma membrane of erythrocytes and 3T3 cells, the apparent lateral diffusion coefficient D ranged from 1.0.10(-9) to 8.10(-9) cm2 s-1 with a mobile fraction M between 0.4 and 0.6. The lateral mobility of these proteins closely resembled that reported for lipid-anchored proteins and was much higher than that reported for Band 3, an erythrocyte membrane-spanning protein with a large cytoplasmic domain. These results suggest that the hydrophobic domain of cytochrome b5 could be employed as a universal, laterally mobile membrane anchor to associate a variety of diagnostically and therapeutically useful recombinant proteins with cells.

Beta-galactosidase fused to the hydrophobic domain of cytochrome b5 spontaneously associates with liposomes.

Since liver microsomal cytochrome b5 spontaneously associates with liposomes and membranes by means of its C-terminal hydrophobic domain (HP), chimeric proteins containing HP prepared by genetic fusion might also spontaneously associate with liposomes or cellular membranes. Synthetic DNA corresponding to the hydrophobic domain of cytochrome b5 was enzymatically fused in-frame to cloned DNA corresponding to the C-terminus of the Escherichia coli enzyme, beta-galactosidase. This protein, LacZ:HP, synthesized in E. coli and purified from a crude E. coli membrane extract, was shown to spontaneously associated with liposomes, as does cytochrome b5. Association is rapid and stable in the presence of salt and high pH and the fusion protein behaves as an integral membrane protein. LacZ:HP can be readily and extensively purified from crude extracts by association with liposomes and this procedure may provide a convenient purification scheme for proteins not otherwise readily purified, for example polypeptides from cloned gene fragments to be used for antibody production. These hybrid proteins may represent a new potentially useful class of polypeptides capable of hydrophobic interactions with membranes.

The hydrophobic domain of cytochrome b5 is capable of anchoring beta-galactosidase in Escherichia coli membranes.

Cytochrome b5 is inserted posttranslationally into membranes in vivo and spontaneously into liposomes in vitro by a short carboxyl-terminal hydrophobic membrane-anchoring sequence. DNA corresponding to this hydrophobic sequence has been synthesized, and two gene fusions with the Escherichia coli enzyme beta-galactosidase have been constructed by locating the hydrophobic domain in one case at the EcoRI site near the C terminus and in the other at the normal C terminus of the enzyme. The latter fusion protein was enzymatically active, having approximately 50% of the specific activity of beta-galactosidase, and cells expressing this protein grew normally with lactose as the sole carbon source. Both fusion proteins were localized to the E. coli inner membrane, converting beta-galactosidase from a cytoplasmic enzyme to a membrane-associated enzyme. The hydrophobic domain of cytochrome b5 therefore contains the information required to target polypeptides containing this domain to the membrane. Use of the cytochrome b5 hydrophobic peptide, either alone or in conjunction with other localizing sequences such as signal sequences, provides a general procedure for associating proteins with membranes. Polypeptides bearing this hydrophobic peptide may have considerable use as pharmaceuticals when associated with liposomes or cellular membranes.

Genetic analysis of extracellular proteins of Serratia marcescens.

Serratia marcescens, a gram-negative enteric bacterium, is capable of secreting a number of proteins extracellularly. The types of activity found in the growth media include proteases, chitinases, a nuclease, and a lipase. Genetic studies have been undertaken to investigate the mechanisms used for the extracellular secretion of these exoproteins by S. marcescens. Many independent mutations affecting the extracellular enzymes were isolated after chemical and transposon mutagenesis. Using indicator media, we have identified loci involved in the production or excretion of extracellular protease, nuclease, or chitinase by S. marcescens. None of the mutations represented general extracellular-excretion mutants; in no case was the production or excretion of multiple exoproteins affected. A variety of loci were identified, including regulatory mutations affecting nuclease and chitinase expression. A number of phenotypically different protease mutants arose. Some of them may represent different gene products required for the production and excretion of the major metalloprotease, a process more complex than that for the other S. marcescens exoproteins characterized to date.

Reduced parasitemia observed with erythrocytes containing inositol hexaphosphate.

Chemicals entrapped in erythrocytes by hypotonic hemolysis can be assessed for possible antiparasitic activity both in vivo and in vitro, regardless of whether they are able to diffuse into erythrocytes readily. Inositol hexaphosphate, a highly charged compound, produced a dramatic lowering of the percentage of cells infected by Babesia microti in vivo and both B. microti and Plasmodium falciparum in vitro. Several possible mechanisms for this observation are discussed.

Sequence of amino acids in lamB responsible for spontaneous ejection of bacteriophage lambda DNA.

The DNA sequence of the promoter-distal half of lamB from Shigella sonnei 3070 has been determined and compared with the known sequence for the Escherichia coli K12 gene. The only predicted amino acid changes in this region of LamB, the receptor protein for bacteriophage lambda, lie between positions 381 and 390, where seven of the ten amino acids are altered. Evidence is presented that indicates that this region is responsible for the ability of the S. sonnei receptor, but not the E. coli receptor, to trigger spontaneous ejection of DNA from the bacteriophage in vitro. DNA injection in vivo must be more complex and involve also the host Pel protein and the lambda tail proteins gpJ, gpH, and gpV.

Entry of Bartonella bacilliformis into erythrocytes.

Bartonella bacilliformis, which causes the human diseases Oroya fever and verruga peruana, binds to human erythrocytes in vitro and produces substantial and long-lasting deformations in erythrocyte membranes, including cone-shaped depressions, trenches, and deep invaginations. The deforming force is probably provided by the polar flagella of these highly motile bacteria. Deep invaginations containing bacteria are commonly seen, and membrane fusion at the necks of the invaginations leads to the formation of intracellular vacuoles containing bacteria. Fluorescent compounds present externally render the vacuoles fluorescent and, occasionally, lightly fluorescent cells are seen, suggesting that the vacuoles sometimes rupture to admit the bacteria to the cytoplasm. Vacuoles present in fluorescent erythrocytes prepared by preloading the erythrocytes with fluorescent compounds are seen as dark areas from which the fluorescent marker is excluded. Entry of the bacteria appears to be the result of a process of forced endocytosis.

Plasmid expression vector using the lambda late promoter.

A plasmid expression vector called pQTE1 based on the late promoter, pR', and positive control gene Q of bacteriophage lambda has been constructed. This vector has unique cloning sites for placing exogenous DNA under control of pR'. Induction of expression of genes cloned into the pQTE1 plasmid leads to massive overproduction of the gene products. Also, transcription from the pR' promoter on pQTE1 appears to be insensitive to polarity effects.