Cellular and molecular purification processes based on the use of magnetic micro-and nanobeads

Magnetic separation is a recent technology using magnetism properties. This technology is aimed to purify cells, cell organelles and biologically active compounds such as nucleic acids and proteins. Many magnetic separation procedures have been developed to isolate cells and molecules. The purpose of this review is to give an other view of various methods and strategies which can be employed for selection of targets cells and molecules. We describe techniques used to positive and negative cells selections, we show that magnetic selection is also aimed to perform multiparameter selection or functional selection. Then, we underline emerging technology used to select transfected cells and macromolecules such as proteins, DNA and RNA.     

Pathologic complete response to neoadjuvant chemotherapy of breast carcinoma is associated with the disappearance of tumor-infiltrating foxp3+ regulatory T cells.

PURPOSE: T-cell infiltration is associated with good tumor prognosis in many cancers. To assess the capacity of neoadjuvant chemotherapy to affect T-cell infiltration in breast cancer, we evaluated CD3 and CD8 infiltrates, and the Foxp3 immunosuppressive T cells. EXPERIMENTAL DESIGN: CD3+, CD8+, and Foxp3+ cell infiltrates were detected by immunohistochemistry in a series of 56 breast cancer patients before and after the end of neoadjuvant chemotherapy. RESULTS: Poor prognostic factors (negative hormonal receptors, high tumor grade, and nodal involvement) were associated with a significantly higher number of CD3, CD8, and Foxp3 infiltrates before the beginning of chemotherapy. Chemotherapy resulted in a decrease in Foxp3 infiltrates, whereas the level of CD8 and CD3 infiltrates remained unchanged. Pathologic complete responses (pCR) had a drastic decrease of Foxp3+ cells, whereas these cells remained elevated in nonresponders. A cutoff criterion that combined high CD8 infiltration and no Foxp3 cell infiltration on surgical specimens is associated with pCR with a sensitivity of 75% and a specificity of 93%. The infiltrate of cytotoxic TiA1 and granzyme B-positive cells was dramatically enhanced after chemotherapy only in patients with pCR. By multivariate analysis, association of a high CD8 infiltration and no Foxp3 infiltration on final histologic specimens were independently associated with pCR. CONCLUSION: These findings indicate that pCR to neoadjuvant chemotherapy is associated with an immunologic profile combining the absence of immunosuppressive Foxp3 cells and the presence of a high number of CD8 T cells and cytotoxic cells. These results argue for the induction of an antitumor immune response by chemotherapy.     

A DNA Vaccine Encoding the Enterohemorragic Escherichia coli Shiga-Like Toxin 2 A2 and B Subunits Confers Protective Immunity to Shiga Toxin Challenge in the Murine Model

Production of verocytotoxin or Shiga-like toxin (Stx), particularly Stx2, is the basis of hemolytic uremic syndrome, a frequently lethal outcome for subjects infected with Stx2-producing enterohemorrhagic Escherichia coli (EHEC) strains. The toxin is formed by a single A subunit, which promotes protein synthesis inhibition in eukaryotic cells, and five B subunits, which bind to globotriaosylceramide at the surface of host cells. Host enzymes cleave the A subunit into the A₁ peptide, endowed with N-glycosidase activity to the 28S rRNA, and the A₂ peptide, which confers stability to the B pentamer. We report the construction of a DNA vaccine (pStx2ΔAB) that expresses a nontoxic Stx2 mutated form consisting of the last 32 amino acids of the A₂ sequence and the complete B subunit as two nonfused polypeptides. Immunization trials carried out with the DNA vaccine in BALB/c mice, alone or in combination with another DNA vaccine encoding granulocyte-macrophage colony-stimulating factor, resulted in systemic Stx-specific antibody responses targeting both A and B subunits of the native Stx2. Moreover, anti-Stx2 antibodies raised in mice immunized with pStx2ΔAB showed toxin neutralization activity in vitro and, more importantly, conferred partial protection to Stx2 challenge in vivo. The present vector represents the second DNA vaccine so far reported to induce protective immunity to Stx2 and may contribute, either alone or in combination with other procedures, to the development of prophylactic or therapeutic interventions aiming to ameliorate EHEC infection-associated sequelae.Shiga toxin (Stx)-producing enterohemorrhagic Escherichia coli (EHEC) strains are important food-borne pathogens representing the major etiological agents of hemorrhagic colitis and hemolytic uremic syndrome (HUS), a life-threatening disease characterized by hemolytic anemia, thrombocytopenia, and renal failure (19). The infection correlates with ingestion of contaminated meat or vegetables but is also transmitted by water or even person-to-person contact (8, 14, 44). Sporadic or massive outbreaks have been reported in several developed countries but, in Argentina, HUS is endemic and represents a serious public health problem with high morbidity and mortality rates (29, 40). Production of verocytotoxin or Shiga-like toxin (Stx) is the basis of EHEC pathogenesis (18, 20). The toxin is formed by a single A subunit, which possesses N-glycosidase activity to the 28S rRNA and promotes protein synthesis inhibition in eukaryotic cells, and five B subunits, which bind to globotriaosylceramide at the surface of host cells (9, 28). Although two major types (Stx1 and Stx2) and several subtypes have been described, Stx2 and Stx2c are the most frequently found toxins in severe HUS cases among EHEC-infected subjects (12, 41). The degree of antigenic cross-reactivity between Stx2 and Stx1 is low, and several authors have reported that the two toxins do not provide heterologous protection, particularly concerning the B subunits (45, 47). On the other hand, Stx2c and Stx2d variants are readily neutralized by antibodies against Stx2 (27).Despite the magnitude of the social and economic impacts caused by EHEC infections, no licensed vaccine or effective therapy is presently available for human use. So far, attempts to develop vaccine formulations against EHEC-associated sequelae have relied mainly on induction of serum anti-Stx antibody responses. Several approaches have been pursed to generate immunogenic anti-Stx vaccine formulations and include the use of live attenuated bacterial strains (2, 32), protein-conjugated polysaccharides (21), purified B subunit (33, 48), B-subunit-derived synthetic peptides (15), and mutated Stx1 and Stx2 nontoxic derivatives (5, 6, 13, 16, 37, 39, 42, 45).In a previous report we described anti-Stx2 DNA vaccines encoding either the B subunit or a fusion protein between the B subunit and the first N-terminal amino acid of the A₁ subunit (8). The DNA vaccine encoding the hybrid protein elicited Stx-specific immune responses in mice and partial protection to Stx2 challenge (1, 33). Recent data have indicated that epitopes leading to generation of Stx-neutralizing antibodies are present on both the B as well as the A subunit (34, 45, 46). In addition, further evidence indicates that the A₂ subunit contains some of the most immunogenic epitopes of the Stx2 toxin (4). Thus, in line with such evidence, we attempted the construction of a new DNA vaccine encoding the last 32 amino acids from the A₂ subunit, in addition to the complete B subunit of Stx2, as separated polypeptides which could enhance the immunogenicity and protective effects of the vaccine formulation. In the present report, we describe the generation of a new DNA vaccine encoding both Stx2 A2 and B subunits as an approach to elicit protective antibody responses to Stx2. The results obtained demonstrate that immunization with this vaccine formulation results in systemic antibody responses to Stx2 A and B subunits and toxin neutralization activity both in vitro and in vivo.