Absolute timing of the photoelectric effect.

Photoemission spectroscopy is central to understanding the inner workings of condensed matter, from simple metals and semiconductors to complex materials such as Mott insulators and superconductors1. Most state-of-the-art knowledge about such solids stems from spectroscopic investigations, and use of subfemtosecond light pulses can provide a time-domain perspective. For example, attosecond (10-18 seconds) metrology allows electron wave packet creation, transport and scattering to be followed on atomic length scales and on attosecond timescales2-7. However, previous studies could not disclose the duration of these processes, because the arrival time of the photons was not known with attosecond precision. Here we show that this main source of ambiguity can be overcome by introducing the atomic chronoscope method, which references all measured timings to the moment of light-pulse arrival and therefore provides absolute timing of the processes under scrutiny. Our proof-of-principle experiment reveals that photoemission from the tungsten conduction band can proceed faster than previously anticipated. By contrast, the duration of electron emanation from core states is correctly described by semiclassical modelling. These findings highlight the necessity of treating the origin, initial excitation and transport of electrons in advanced modelling of the attosecond response of solids, and our absolute data provide a benchmark. Starting from a robustly characterized surface, we then extend attosecond spectroscopy towards isolating the emission properties of atomic adsorbates on surfaces and demonstrate that these act as photoemitters with instantaneous response. We also find that the tungsten core-electron timing remains unchanged by the adsorption of less than one monolayer of dielectric atoms, providing a starting point for the exploration of excitation and charge migration in technologically and biologically relevant adsorbate systems.

IFN-gamma and IL-12 but not IL-10 are required for local tumour surveillance in a syngeneic model of orthotopic bladder cancer.

In recent studies, a crucial role for IFN-gamma in immunosurveillance of tumours and in IL-12 immunotherapy has been suggested. Nevertheless, little is known about the relevance of IFN-gamma and IL-12 for tumour surveillance in noncytokine immunotherapy. Adjuvant immunotherapy with viable BCG (Bacillus Calmette--Guérin) is considered to be the most powerful clinical treatment regimen of bladder cancer and is known to induce a variety of proinflammatory cytokines. Consequently, we analysed the antitumour response of IFN-gamma knockout (KO), IL-12 KO and IL-10 KO mice in the absence and presence of BCG immunotherapy in a syngeneic orthotopic model of bladder cancer. IFN-gamma KO and IL-12 KO mice died much earlier and by far smaller tumour inocula compared to wildtype mice, while this intrinsic antitumour response was not altered in IL-10 KO mice. BCG immunotherapy was effective in wildtype mice, but totally ineffective in IFN-gamma KO and IL-12 KO mice. BCG induced a massive local immune response in the bladder of treated animals. This response was markedly increased in IL-10 KO mice, which coincides with increased therapeutic efficacy in this mouse strain compared with wildtype mice. Our data establish a crucial role for a Th1 type immune response in the intrinsic and immunotherapeutic control of local orthotopic bladder cancer.

NK cells are essential for effective BCG immunotherapy.

Adjuvant intravesical bacillus Calmette-Guérin (BCG) therapy is a well-established and successful adjuvant immunotherapy in the treatment of superficial bladder cancer. Although the function of natural killer (NK) cells in other immunotherapeutic regimens (e.g., lymphokine-activated killer [LAK] cell or interleukin-2 [IL-2] therapy) has been established, the contribution of NK cells to effective BCG immunotherapy is not clear. We used a human in vitro system to analyze the role of NK cells in BCG-induced cellular cytotoxicity. After stimulation of mononuclear cells with BCG for 7 days, these BCG-activated killer (BAK) cells displayed substantial cytotoxicity against bladder tumor cells. Magnetic depletion experiments and fluorescence activated cell sorting revealed that NK cells were the major effector cell population. To address NK cell function in vivo, we studied a syngeneic orthotopic murine bladder cancer model and compared BCG immunotherapy in C57BL/6 wild-type mice, NK-deficient beige mice and mice treated with anti-NK1.1 monoclonal antibody. Four weekly instillations of viable BCG significantly prolonged survival in wild-type mice compared with control mice treated with solvent alone. In contrast, BCG therapy was completely ineffective in NK-deficient beige mice and in mice treated with anti-NK1.1 monoclonal antibody. These findings suggest a key role for NK cells during BCG immunotherapy.

Perforin-mediated lysis of tumor cells by Mycobacterium bovis Bacillus Calmette-Guérin-activated killer cells.

Immunotherapy with Bacillus Calmette-Guérin (BCG) is clinically established in the treatment of superficial bladder cancer. In our attempt to clarify the underlying immunological mechanism, we could previously show that stimulation of PBMC with BCG leads to the generation of cytotoxic BCG-activated killer (BAK) cells. Among others, these BAK cells as well as lymphokine-activated killer (LAK) cells have been suggested as possible effector cells during BCG therapy. To understand BCG-induced activation of effector lymphocytes more precisely, we investigated the lytic pathways of human BAK cells and compared BAK cell cytotoxicity with LAK cell cytotoxicity. Perforin and Fas ligand (FasL) are the major cytolytic molecules of cytotoxic lymphocytes. Our results demonstrate that BAK and LAK cells showed an increased expression of perforin and FasL as compared with unstimulated controls. Killing of T-24 bladder tumor as well as Jurkat cells by BAK and LAK cells was predominantly mediated via perforin as demonstrated by a drastically reduced lysis in the presence of concanamycin A and EGTA/MgCl2, respectively. In contrast, lysis (radioactive release assay) and membrane disintegration (Annexin V binding) of both targets by BAK and LAK cells could not be blocked with an inhibitory anti-FasL monoclonal antibody (NOK-1). Nevertheless, T-24 and Jurkat were susceptible to killing by recombinant soluble FasL and by Chinese hamster ovary cells expressing membrane-bound FasL. We conclude that cellular mediators of BCG effector mechanisms, such as BAK and LAK cells, kill their targets via perforin and independent of the FasL pathway. Because we also found increased numbers of perforin-expressing lymphocytes in patients after BCG therapy, our findings have potential clinical relevance because BCG therapy would not be impaired by FasL resistance of target cells, which recently has been described for some tumors.