Mitotic Bypass Via An Occult Cell Cycle Phase Following DNA Topoisomerase II Inhibition In p53 Functional Human Tumor Cells

Cells cycle checkpoints guard against the inapproriate commitment to critical cell events such as mitosis. The bisdioxxopiperazzine ICRF-193, a catalytic inhibitor of DNA topoisomerase II causes a reversible stalling of the exit of cells from G(2) at the decatenation checkpoint (DC) and can generate tetraploidy via the compromising of chromosome segregation and mitotic failure. We have addressed an alternative origin-endocycle entry-for the tetraploidisation step in ICRF-193 exposed cells. Here we show that DC-proficient p53-functional tumor cells can undergo a transition to tetraploidy and subbsequent aneuploidy via an initial bypass of mitosis and the mitotic spindle checkpoint. DC-deficient SV4-tranformed cells move exclusively through mitosis to tetraploidy. In p53-functional tumor cells, escape through mitosis is enhanced by dominant negative p53 co-expression. The mitotic bypass transition phase (termed G(2)(endo)) disconnects cyclin B1 degradation from nuclear envelope breakdown and allows cells to evade the action of Taxol. G(2)(endo) constitutes a novel and alternative cell cycle phase-lasting some 8 h-with distinct molecular motifs at its boundaries for G(2) exit and subsequent entry into a delayed G(1) tetraploid state. The result challenge the paradigm that checkpoint breaching leads directly to abnormal ploidy states via mitosis alone. We further propose that the induction of bypass could: facilitate the covert development of tetraploidy in p53 functional cancers, lead to a misinterpretation of phase allocation during cell cycle arrest and contribbute to tumor cell drug resistance.

Optical antenna arrays in the visible range

We report on experimental observations of highly collimated beams of radiation generated when a periodic sub-wavelength grating interacts with surface bound plasmon-polariton modes of a thin gold film. We find that the radiation process can be fully described in terms of interference of emission from a dipole antenna array and modeling the structure in this way enables the far-field radiation pattern to be predicted. The directionality, multiplicity and divergence of the beams can be completely described within this framework. Essential to the process are the surface plasmon excitations: these are the driving mechanism behind the beam formation, phase-coupling radiation from the periodic surface structure and thus imposing a spatial coherence. Detailed fitting of the experimental and modeled data indicates the presence of scattering events involving the interaction of two surface plasmon polariton modes.

Technique for measurement of fluorescence lifetime by use of stroboscopic excitation and continuous-wave detection

A study of the practicality a simple technique for obtaining time-domain information that uses continuous wave detection of fluorescence is presented. We show that this technique has potential for use in assays for which a change in the lifetime of an indicator occurs in reaction to an analyte, in fluorescence resonance energy transfer, for example, and could be particularly important when one is carrying out such measurements in the scaled-down environment of a lab on a chip (biochip). A rate-equation model is presented that allows an objective analysis to be made of the relative importance of the key measurement parameters: optical saturation of the fluorophore and period of the excitation pulse. An experimental demonstration of the technique that uses a cuvette-based analysis of a carbocyanine dye and for which the excitation source is a 650 nm wavelength, self-pulsing AlGaInP laser diode is compared with the model.