Efficient elimination of chronic lymphocytic leukaemia B cells by autologous T cells with a bispecific anti-CD19/anti-CD3 single-chain antibody construct.

Recently, we have shown that a novel recombinant bispecific single-chain antibody construct (bscCD19 x CD3), induces highly efficacious lymphoma-directed cytotoxicity mediated by unstimulated peripheral T lymphocytes. Functional analysis of bscCD19 x CD3 has so far been exclusively performed with human B lymphoma cell lines and T cells from healthy donors. Here we analysed the properties of bscCD19 x CD3 using primary B cells and autologous T cells from healthy volunteers or patients with B-cell chronic lymphocytic leukaemia (B-CLL). We show that bscCD19 x CD3 induces T-cell-mediated depletion of nonmalignant B cells in all four cases and depletion of primary lymphoma cells in 22 out of 25 cases. This effect could be observed at low effector-to-target (E:T) ratios and in the majority of cases without additional activation of autologous T cells by IL-2. Even in samples derived from patients heavily pretreated with different chemotherapy regimens, strong cytotoxic effects of bscCD19 x CD3 could be observed. The addition of bscCD19 x CD3 to patients' cells resulted in an upregulation of activation-specific cell surface antigens on autologous T cells and elevated levels of CD95 on lymphoma B cells. Although anti-CD95 antibody CH-11 failed to induce apoptosis in lymphoma cells, we provide evidence that B-CLL cell depletion by bscCD3 x CD3 is mediated at least in part by apoptosis via the caspase pathway.

The pH-sensitive actin-binding protein hisactophilin of Dictyostelium exists in two isoforms which both are myristoylated and distributed between plasma membrane and cytoplasm.

The histidine-rich protein hisactophilin is known to be associated with the inner surface of the plasma membrane and to be present as a soluble protein in the cytoplasm of Dictyostelium discoideum cells. Mass spectrometry of hisactophilin from the cytosol or extracted from a membrane fraction showed that none of the hisactophilin purified from D. discoideum cells had the mass predicted from the known cDNA-derived amino acid sequence of the protein. Electrospray mass spectrometry and liquid secondary ion mass spectrometry of tryptic fragments separated by reversed-phase high performance liquid chromatography (HPLC) identified the most hydrophobic peptide as a myristoylated fragment from the N terminus of hisactophilin. Taken together the analytical data, it is concluded that all hisactophilin in D. discoideum cells is N terminally modified by myristoylation. By reversed-phase HPLC, two isoforms of hisactophilin, HsI and HsII, were recovered from the cytosolic as well as the membrane fraction of D. discoideum cells. Whereas the masses of HsI fragments produced by trypsin fit into the previously published sequence of hisactophilin (myristoylation considered), HsII is another protein distinguished from HsI by several amino acid exchanges. HsI and HsII can form homo- and heterodimers by disulfide bridges. Hisactophilin is phosphorylated in vivo. Both isoforms proved to be substrates of membrane-associated threonine/serine kinase from D. discoideum, which may regulate the interaction of hisactophilin with the plasma membrane.

Binding of hisactophilin I and II to lipid membranes is controlled by a pH-dependent myristoyl-histidine switch.

The interaction of the two N-terminally myristoylated isoforms of Dictyostelium hisactophilin with lipid model membranes was investigated by means of the monolayer expansion method and high-sensitivity titration calorimetry. The two isoforms, hisactophilin I and hisactophilin II, were found to insert with their N-terminal myristoyl residue into an electrically neutral POPC monolayer corresponding in its lateral packing density to that of a lipid bilayer. The partition coefficient for this insertion process was Kp = (1.1 +/- 0.2) x 10(4) M-1. The area requirement of the protein in the lipid membrane was estimated as 44 +/- 6 A2 which corresponds to the cross sectional area of the myristoyl moiety with an additional small contribution from amino acid side chains. The interaction of hisactophilin I (hisactophilin II) with negatively charged membrane surfaces is modulated in a pH-dependent manner by charged amino acid residues clustered around the myristoyl moiety. The electrostatic binding site consists of three lysine (one arginine and two lysine), seven (nine) histidine, and four (four) glutamic acid residues and has an isoelectric point of 6.9 (7.1). For small unilamellar POPC/POPG (75/25 mole/mole) vesicles, an apparent binding constant, K(app) = (8 +/- 1) x 10(5) M-1, was measured at pH 6.0 by means of high-sensitivity titration calorimetry. Electrostatic interactions hence increase the binding constant by about 2 orders of magnitude compared to hydrophobic binding alone. With increasing pH, the electrostatic attraction decreases and turns into an electrostatic repulsion at pH > 7.0 +/- 0.1. The area occupied by the cluster of charged residues constituting the membrane binding region was 280 +/- 20 A2 as derived from monolayer measurements in close agreement with molecular modeling data derived from the NMR structure of hisactophilin I [Habazettl et al. (1992) Nature 359, 855-858].

Myristoylated and non-myristoylated forms of the pH sensor protein hisactophilin II: intracellular shuttling to plasma membrane and nucleus monitored in real time by a fusion with green fluorescent protein.

Hisactophilins are myristoylated proteins that are rich in histidine residues and known to exist in Dictyostelium cells in a plasma membrane-bound and a soluble cytoplasmic state. Intracellular translocation of these proteins in response to pH changes was monitored using hisactophilin fusions with green fluorescent protein (GFP) and confocal laser scanning microscopy. Both the normal and a mutated non-myristoylated fusion protein shuffled within the cells in a pH-dependent manner. After lowering the pH, these proteins translocated within minutes between the cytoplasm, the plasma membrane and the nucleus. The role of histidine clusters on the surface of hisactophilin molecules in binding of the proteins to the plasma membrane and in their transfer to the nucleus is discussed on the basis of a pH switch mechanism.