Reprogramming of myeloid angiogenic cells by Bartonella henselae leads to microenvironmental regulation of pathological angiogenesis.

The contribution of myeloid cells to tumour microenvironments is a decisive factor in cancer progression. Tumour-associated macrophages (TAMs) mediate tumour invasion and angiogenesis through matrix remodelling, immune modulation and release of pro-angiogenic cytokines. Nothing is known about how pathogenic bacteria affect myeloid cells in these processes. Here we show that Bartonella henselae, a bacterial pathogen causing vasculoproliferative diseases (bacillary angiomatosis), reprogrammes human myeloid angiogenic cells (MACs), a pro-angiogenic subset of circulating progenitor cells, towards a TAM-like phenotype with increased pro-angiogenic capacity. B. henselae infection resulted in inhibition of cell death, activation of angiogenic cellular programmes and induction of M2 macrophage polarization. MACs infected with B. henselae incorporated into endothelial sprouts and increased angiogenic growth. Infected MACs developed a vascular mimicry phenotype in vitro, and expression of B. henselae adhesin A was essential in inducing these angiogenic effects. Secretome analysis revealed that increased pro-angiogenic activities were associated with the creation of a tumour-like microenvironment dominated by angiogenic inflammatory cytokines and matrix remodelling compounds. Our results demonstrate that manipulation of myeloid cells by pathogenic bacteria can contribute to microenvironmental regulation of pathological tissue growth and suggest parallels underlying both bacterial infections and cancer.

Rapid detection and identification of pathogens in blood cultures by fluorescence in situ hybridization and flow cytometry.

Septicemia is one of the leading causes of death in hospitalized patients. The timely detection and identification of microorganisms from the patient's blood has great diagnostic, prognostic and economic significance. Fluorescence in situ hybridization (FISH) with rRNA-targeted oligonucleotide probes has been proven to be a fast method for the identification of human pathogenic bacteria and yeasts. Data presented herein reveal that the combination of FISH and flow cytometry (FC-FISH) is a rapid and reliable technique for identification of pathogens (Gram-negative rods, Candida spp.) directly from blood cultures without further cultivation and biotyping. Moreover, detection of growing pathogens (e.g., Stenotrophomonas maltophilia) in blood cultures is achieved more rapidly by FC-FISH compared to standard detection methods. Therefore, FC-FISH allows rapid detection and identification of pathogens in blood cultures.

Infection of human CD34+ progenitor cells with Bartonella henselae results in intraerythrocytic presence of B. henselae.

Although there is evidence that endothelial cells are important targets for human pathogenic Bartonella species, the primary niche of infection is unknown. Here we elucidated whether human CD34+ hematopoietic progenitor cells (HPCs) internalize B. henselae and may serve as a potential niche of the pathogen. We showed that B. henselae does not adhere to or invade human erythrocytes. In contrast, B. henselae invades and persists in HPCs as shown by gentamicin protection assays, confocal laser scanning microscopy (CLSM), and electron microscopy (EM). Fluorescence-activated cell sorting (FACS) analysis of glycophorin A expression revealed that erythroid differentiation of HPCs was unaffected following infection with B. henselae. The number of intracellular B. henselae continuously increased over a 13-day period. When HPCs were infected with B. henselae immediately after isolation, intracellular bacteria were subsequently detectable in differentiated erythroid cells on day 9 and day 13 after infection, as shown by CLSM, EM, and FACS analysis. Our data provide, for the first time, evidence that a bacterial pathogen is able to infect and persist in differentiating HPCs, and suggest that HPCs might serve as a potential primary niche in Bartonella infections.