Superior Suppression of ErbB2-positive Tumor Cells by a Novel Human Triparatopic Tribody.

Downregulation of the epidermal growth factor receptor family of receptors is improved by combining different antibodies to noncompetitive epitopes. For ErbB2/HER2 this has already been translated into clinical practice by using a combination of trastuzumab and pertuzumab. Moreover, cocktails of 2 or 3 anti-epidermal growth factor receptor antibodies show an enhanced downregulation of the receptor due to the induction of matrix formation. A more efficient method for inducing matrix formation and receptor downregulation might include the use of trispecific reagents. A triparatopic Tribody consisting of 3 noncompeting ErbB2 binders was compared with equivalent trivalent monoparatopic counterparts, as well as to a cocktail of 3 monoclonal antibodies for its effects on downregulation of the ErbB2 receptor's kinase activity and survival of several ErbB2-expressing cancer cell lines. The triparatopic Tribody was significantly more efficient in downregulating ErbB2 and inhibiting tumor cell growth than either the control monoparatope tribodies or the combinatorial treatment with the 3 different parental antibodies on all the tested tumor cells, including trastuzumab-resistant cell lines. The enhancement of effectivity was dependent on all 3 binding moieties. Because the novel Tribody allows reduction of the costs of production (as only 1 construct provides the antitumor effects of 3 antibodies) and has an intermediate molecular size (∼100 kDa) well suited for both tumor penetration and acceptable half-life, it has the potential to become a precious tool for therapeutic use particularly in trastuzumab-resistant cancer patients.

Kinetics of nitrate and perchlorate removal and biofilm stratification in an ion exchange membrane bioreactor.

The biological degradation of nitrate and perchlorate was investigated in an ion exchange membrane bioreactor (IEMB) using a mixed anoxic microbial culture and ethanol as the carbon source. In this process, a membrane-supported biofilm reduces nitrate and perchlorate delivered through an anion exchange membrane from a polluted water stream, containing 60 mg/L of NO3⁻ and 100 µg/L of ClO4⁻. Under ammonia limiting conditions, the perchlorate reduction rate decreased by 10%, whereas the nitrate reduction rate was unaffected. Though nitrate and perchlorate accumulated in the bioreactor, their concentrations in the treated water (2.8 ± 0.5 mg/L of NO3⁻ and 7.0 ± 0.8 µg/L of ClO4⁻, respectively) were always below the drinking water regulatory levels, due to Donnan dialysis control of the ionic transport in the system. Kinetic parameters determined for the mixed microbial culture in suspension showed that the nitrate reduction rate was 35 times higher than the maximum perchlorate reduction rate. It was found that perchlorate reduction was inhibited by nitrate, since after nitrate depletion perchlorate reduction rate increased by 77%. The biofilm developed in the IEMB was cryosectioned and the microbial population was analyzed by fluorescence in situ hybridization (FISH). The results obtained seem to indicate that the kinetic advantage of nitrate reduction favored accumulation of denitrifiers near the membrane, whereas per(chlorate) reducing bacteria were mainly positioned at the biofilm outer surface, contacting the biomedium. As a consequence of the biofilm stratification, the reduction of perchlorate and nitrate occur sequentially in space allowing for the removal of both ions in the IEMB.

Optimisation of glycogen quantification in mixed microbial cultures.

This study addressed the key factors affecting the extraction and quantification of glycogen from floccular and granular mixed microbial cultures collected from activated sludge, nutrient removal systems and photosynthetic consortiums: acid concentration, hydrolysis time and concentration of biomass in the hydrolysis. Response surface modelling indicated that 0.9 M HCl and a biomass concentration of 1 mg mL(-1) were optimal conditions for performing acid hydrolysis. Floccular samples only needed a 2-h hydrolysis time whereas granular samples required as much as 5 h. An intermediate 3 h yielded an error of 10% compared to the results obtained with the hydrolysis times specifically tailored to the type of biomass and can thus be recommended as a practical compromise.