How many diseases is triple negative breast cancer: the protagonism of the immune microenvironment.

Triple negative breast cancer (TNBC) is a type of breast cancer (BC) that does not express the oestrogen and the progesterone receptors and the human epidermal growth factor receptor type 2 (HER2). Since there are no positive markers to reliably classify TNBC, these tumours are not yet treated with targeted therapies. Perhaps for this reason they are the most aggressive form of breast carcinomas. However, the clinical observation that these patients do not carry a uniformly dismal prognosis, coupled with data coming from pathology and epidemiology, suggests that this negative definition is not capturing a single clinical entity, but several. We critically evaluate this evidence in this paper, reviewing clinical and epidemiological data and new studies that aim to subclassify TNBC. Moreover, evidence on the role of tumour infiltrating lymphocytes (TILs) on TNBC progression, response to chemotherapy and patient outcome have been published. The heterogeneity, observed even at TILs level, highlights the idea that TNBC is much more than a single disease with a unique treatment. The exploration of the immune environment present at the tumour site could indeed help in answering the question 'How many diseases is TNBC' and will help to define prognosis and eventually develop new therapies, by stimulating the immune effector cells or by inhibiting immunological repressor molecules. In this review, we focus on the prospect of the patient's diverse immune signatures within the tumour as potential biomarkers and how they could be modulated to fight the disease.

Using dendritic cells to evaluate how Burkholderia cenocepacia clonal isolates from a chronically infected cystic fibrosis patient subvert immune functions.

Infection with Burkholderia cepacia complex (Bcc) bacteria is a threat to cystic fibrosis (CF) patients, commonly leading to a fatal pneumonia, the cepacia syndrome. It causes a massive production of pro-inflammatory cytokines and leucocyte recruitment to airway epithelium without resolving infection and contributing to tissue lesion. To dissect how Bcc bacteria subvert the immune response, we developed a co-culture model with human dendritic cells (DCs) and B. cenocepacia clonal variants isolated from a chronically infected CF patient, who died with cepacia syndrome. We demonstrated that the two late variants were sevenfold and 17-fold (respectively) more internalized by DCs than the variant that initiated infection. The late variants showed improved survival within DCs (60.29 and 52.82 CFU/DC) compared to the initial variant (0.38 CFU/DC). All clonal isolates induced high expression of inflammatory cytokines IL-8, IL-6, IL-1ß, IL-12, IL-23, TNF-α and IL-1ß. This pro-inflammatory trait was significantly more pronounced in DCs infected with the late variants than in DCs infected with the variant that initiated patient's infection. All infected DCs failed to upregulate maturation markers, HLA-DR, CD80, CD86 and CD83. Nevertheless, these infected DCs activated approximately twice more T cells than non-infected DCs. Similar T cell activation was observable with respective conditioned media, suggesting a non-antigen-specific activation. Our data indicate that during prolonged infection, B. cenocepacia acquires ability to survive intracellularly, inducing inflammation, while refraining DC's maturation and stimulating non-antigen-specific T cell responses. The co-culture model here developed may be broadly applied to study B. cenocepacia-induced immunomodulation.

Sialyl Tn-expressing bladder cancer cells induce a tolerogenic phenotype in innate and adaptive immune cells.

Despite the wide acceptance that glycans are centrally implicated in immunity, exactly how they contribute to the tilt immune response remains poorly defined. In this study, we sought to evaluate the impact of the malignant phenotype-associated glycan, sialyl-Tn (STn) in the function of the key orchestrators of the immune response, the dendritic cells (DCs). In high grade bladder cancer tissue, the STn antigen is significantly overexpressed and correlated with the increased expression of ST6GALNAC1 sialyltransferase. Bladder cancer tissue presenting elevated expression of ST6GALNAC1 showed a correlation with increased expression of CD1a, a marker for bladder immature DCs and showed concomitant low levels of Th1-inducing cytokines IL-12 and TNF-α. In vitro, human DCs co-incubated with STn(+) bladder cancer cells, had an immature phenotype (MHC-II(low), CD80(low) and CD86(low)) and were unresponsive to further maturation stimuli. When contacting with STn(+) cancer cells, DCs expressed significantly less IL-12 and TNF-α. Consistent with a tolerogenic DC profile, T cells that were primed by DCs pulsed with antigens derived from STn(+) cancer cells were not activated and showed a FoxP3(high) IFN-γ(low) phenotype. Blockade of STn antigens and of STn(+) glycoprotein, CD44 and MUC1, in STn(+) cancer cells was able to lower the induction of tolerance and DCs become more mature. Overall, our data suggest that STn-expressing cancer cells impair DC maturation and endow DCs with a tolerogenic function, limiting their capacity to trigger protective anti-tumour T cell responses. STn antigens and, in particular, STn(+) glycoproteins are potential targets for circumventing tumour-induced tolerogenic mechanisms.

Adaptative responses in yeast to the herbicide 2-methyl-4-chlorophenoxyacetic acid at the level of intracellular pH homeostasis.

AIMS: The objective of this work was to examine adaptative responses occurring in Saccharomyces cerevisiae following exposure to the herbicide 2-methyl-4-chlorophenoxyacetic acid (MCPA). METHODS AND RESULTS: The exposure of a yeast cell population to MCPA concentrations of moderate toxicity led to a period of latency before eventual resumption of inhibited growth. During this period of adaptation, the plasma membrane (PM) H+-ATPase was activated, in coordination with the decrease of intracellular pH (pHi), cell viability and average cell volume. The in vivo activation of this ATPase was demonstrated either by assaying PM-ATPase activity in membrane suspensions extracted from cells grown in the presence or absence of MCPA or by measuring the in vivo H+-pumping activity in the same cells. The PM-H+-ATPase activation could not be attributed to transcriptional activation of the encoding genes PMA1 and PMA2. CONCLUSIONS: The activity of PM-H+-ATPase was stimulated and the internal cell volume decreased during yeast adaptation to growth under MCPA stress. Based on the values estimated for the pHi, we hypothesize that these cell responses may contribute to the restoration of pHi homeostasis during recovery from MCPA stress. SIGNIFICANCE AND IMPACT OF THE STUDY: This work is a contribution to the understanding of the toxic effects of the herbicide MCPA and of physiological mechanisms underlying adaptation to MCPA, in the eukaryotic model S. cerevisiae. Results may be useful to elucidate the adaptation mechanisms to this xenobiotic compound in more complex and experimentally less-accessible eukaryotes. They also provide indications to assist the use of yeast cells as a bioassay system to assess the toxicity of phenoxyacetic acid herbicides and of other lipophilic xenobiotics, aiming at reducing the use of animals in toxicity testing.