Recruitment of monocytes/macrophages by tissue factor-mediated coagulation is essential for metastatic cell survival and premetastatic niche establishment in mice.

Tissue factor (TF) expression by tumor cells correlates with metastasis clinically and supports metastasis in experimental settings. However, the precise pathways coupling TF to malignancy remain incompletely defined. Here, we show that clot formation by TF indirectly enhances tumor cell survival after arrest in the lung, during experimental lung metastasis, by recruiting macrophages characterized by CD11b, CD68, F4/80, and CX(3)CR1 (but not CD11c) expression. Genetic or pharmacologic inhibition of coagulation, by either induction of TF pathway inhibitor ex-pression or by treatment with hirudin, respectively, abrogated macrophage recruitment and tumor cell survival. Furthermore, impairment of macrophage function, in either Mac1-deficient mice or in CD11b-diphtheria toxin receptor mice in which CD11b-positive cells were ablated, decreased tumor cell survival without altering clot formation, demonstrating that the recruitment of functional macrophages was essential for tumor cell survival. This effect was independent of NK cells. Moreover, a similar population of macrophages was also recruited to the lung during the formation of a premetastatic niche. Anticoagulation inhibited their accumulation and prevented the enhanced metastasis associated with the formation of the niche. Our study, for the first time, links TF induced coagulation to macrophage recruitment in the metastatic process.

Spitzenkörper, vacuoles, ring-like structures, and mitochondria of Phanerochaete velutina hyphal tips visualized with carboxy-DFFDA, CMAC and DiOC6(3).

Growth and organelle morphology in the wood rotting basidiomycete fungus Phanerochaete velutina were examined in Petri dishes, on agar-coated slides, and in submerged cultures, using DIC, fluorescence and four-dimensional (4-D; x,y,z,t) confocal microscopy, with several fluorescent probes. Phanerochaete is ideal for this work because of its fast growth, robustness, and use in a wide range of other studies. The probe carboxy-DFFDA, widely used for labelling vacuoles, has no effect either on hyphal tip extension or colony growth at the concentrations usually applied in labelling experiments. Carboxy-DFFDA labels the vacuoles and these form a tubular reticulum in hyphal tip cells. The probe also labels extremely small vesicles (punctate fluorescence) in the apex of tip cells, the Spitzenkörper, and short tubules that undergo sequences of characteristic movements and transformations to produce various morphologies, including ring-like structures. Their location and behaviour suggest that they are a distinct group of structures, possibly a subset of vacuoles, but as yet to be fully identified. Regular incursions of tubules extending from these structures and from the vacuolar reticulum into the apical dome indicate the potential for delivery of material to the apex via tubules as well as vesicles. Such structures are potential candidates for delivering chitin synthases to the apex. Spitzenkörper behaviour has been followed as hyphal tips with linear growth encounter obstacle hyphae and, as the hydrolysis product of carboxy-DFFDA only accumulates in membrane-enclosed compartments, it can be inferred that the labelled structures represent the Spitzenkörper vesicle cloud. Mitochondria also form a reticular continuum of branched tubules in growing hyphal tips, and dual localisation with DiOC6(3) and CMAC allows this to be distinguished from the vacuolar reticulum. Like vacuolar tubules, mitochondrial tubules also span the septa, indicating that they may also be a conduit for intercellular transport.

Imaging of long-distance alpha-aminoisobutyric acid translocation dynamics during resource capture by Serpula lacrymans.

alpha-Aminoisobutyric acid (AIB) is a nonmetabolized amino acid analogue of alanine, which at low (muM) concentrations acts as a tracer for amino acid movements. At high concentrations (mM), it competitively inhibits membrane transport and metabolism of protein amino acids and acts as a systemic translocated inhibitor of mycelial extension in fungi. AIB can control mycelial spread of the basidiomycete Serpula lacrymans, the cause of brown rot of wood in buildings. However, it is not known how effectively the inhibitor is distributed throughout the mycelium. Realistically heterogeneous microcosms, in which the fungus grew across nutritionally inert sand to colonize discrete wood resources, were used to investigate patterns of inhibition and translocation following local application of AIB. At a 0.1 M concentration, locally applied AIB caused immediate arrest of extension throughout the whole mycelium, maintained for a 6-week experimental period. The dynamics of translocation of subtoxic amounts of [1-(14)C]AIB ([(14)C]AIB) were mapped by photon-counting scintillation imaging in conjunction with destructive harvest to establish the velocity, direction, and rate of translocation and the extent of [(14)C]AIB reallocation accompanying the invasion of fresh wood. Locally applied [(14)C]AIB was distributed throughout complex mycelial networks within 2 h of application, becoming localized in growing margins by 12 h. Encounter with a fresh wood resource triggered a widespread response, causing withdrawal of [(14)C]AIB from throughout the network, accompanied by accumulation in the newly colonized wood and associated mycelium. The results are discussed in the context of nutrient dynamics in wood decomposer fungi and the mechanism of the amino acid reallocation response.