Activation of autoreactive cytolytic T lymphocyte clone against human melanoma by anti-T3 monoclonal antibody and autologous accessory cells

A cytotoxic T-lymphocyte (CTL) clone Tc1.8 was derived in a limiting dilution culture from a single cell that was derived from melanoma-involved lymph node lymphocytes activated in in vitro coculture against the autologous melanoma cells (VIP). The clone Tc1.8 (T3+, T8+, T4-, and Leu7-) expressed restricted cytolytic activity against only the autologous target VIP. As it aged in continuous culture containing interleukin 2, Tc1.8 lost cytolytic activity. The cytolytic function could be restored, however, with monoclonal antibody (MoAb) against T3 (OKT3) or with F(ab')2 fractions of OKT3, and upon restimulation with irradiated accessory cells. OKT3-mediated reinduction of cytotoxicity by the aged Tc1.8 could not be achieved if the T3 molecules were modulated from the effector cell surface following overnight incubation of Tc1.8 with saturating concentrations of OKT3 MoAb. Following reactivation with OKT3 Tc1.8 gained cytolytic function against NK targets in addition to VIP. Reactivation with F(ab')2 fractions of OKT3 and with autologous accessory cells, however, maintained its restricted antigen fidelity. The NK-like activity of Tc1.8 upon reactivation with OKT3 resulted from conjugate formation between the activated Tc1.8 and NK targets via the activating ligand itself. Thus, upon stimulation with anti-T3 MoAb and with autologous accessory cells, independently, the autoreactivity could be restored in an aged and inactive CTL clone.     

Regulation of cellular immune response against autologous human melanoma. II. Mechanism of induction and specificity of suppression

The cytotoxic immune response in the peripheral blood lymphocytes (PBL) against an autologous malignant melanoma cell line, PJ-M, was found to be down-regulated in in vitro co-culture (IVC) selectively by unfractionated resident lymph node lymphocytes (derived from a lymph node infiltrated with the PJ-M melanoma cells) and T4+ as well as T8+ fractions of the resident lymph node-derived lymphocytes. In this study, the mechanism involved in, and the specificities of, cytotoxic immune response in this autologous system were examined at population and clonal levels. Resident lymph node lymphocytes were isolated from both involved and uninvolved lymph nodes from the same patient. Resident lymphocytes from both sources regulated the generation of cytotoxic immune response when both types of resident lymph node lymphocytes were further sensitized against the PJ-M cells in IVC and were expanded in interleukin 2 (IL 2). An IL 2-dependent homogeneous lymphocyte line (I-10:1) bearing the phenotype of a helper T cell (T4+) and a T4+ clone (I-10.3) of the I-10:1 line, established by limiting dilution culture, also down-regulated the generation of cytotoxic immune effector cells in the PBL in IVC against the PJ-M targets. The IL 2-dependent T4+ inducer line I-10:1 generated a functionally differentiated T8+ suppressor population(s) that, in turn, could abrogate cytotoxic response in fresh PBL in IVC against PJ-M cells. The inducer line I-10:1 and its subclone I-10.3 suppressed the generation of cytotoxic effector cells in the PBL in IVC selectively against the autologous PJ-M cells. Generation of cytotoxic allo-response in IVC was unaffected by the inducer lines. These results provide further evidence for the involvement of the regulatory network in cytotoxic immune response in an autologous human tumor system, and suggest a potential explanation for cytotoxic unresponsiveness against autologous melanoma cells.     

The enzymic synthesis of ribose-1,5-bisphosphate: studies of its role in metabolism

Ribose-1,5-bisphosphate is synthesized in a reaction that uses ribose-1(or 5)-P as the phosphoryl acceptor and the acyl-P of 3-phosphoglyceryl phosphate as the donor. Glucose-1,6-bisphosphate is synthesized in a similar reaction. The relative activity with the two substrates remains unchanged over almost 300-fold purification of the enzyme, indicating that glucose-1,6-bisphosphate synthase catalyzes both reactions. The relative V/Km values for alternative phosphoryl acceptors are ribose-1-P (1); glucose-1-P (0.30); mannose-1-P and ribose-5-P (0.11); glucose-6-P (0.10); 2-deoxyglucose-6-P (0.03); and 2-deoxyribose-5-P (0.02). Fructose-1- and 6-phosphates are not substrates. The synthesis of both ribose-1,5-bisphosphate and glucose-1,6-bisphosphate is inhibited by physiologically significant levels of fructose-1,6-bisphosphate, glycerate-2,3-bisphosphate, glycerate-3-phosphate, citrate, and inorganic phosphate. Ribose-1,5-bisphosphate is a strong activator of brain phosphofructokinase.     

Alteration in the Geotropic Response of Allium Seedlings by Growth Regulators

Indoleacetic acid (1AA) brings about a striking alteration in the normal geotropic response in the seedlings of onion and several other species of Allium. The seedlings which are normally positively geotropic, become ageotropic. Besides IAA several other auxins like IBA, NAA and 2,4-D also showed a similar response. An anti-auxin like triiodobenzoic acid (TIBA) enhanced the auxin-effect instead of reversing it. A marked enhancement of the auxin-effect was also brought about when sucrose (in the culture medium) was replaced by L-arabinose which appeared to act synergistically with the auxin.     

Role of inosine 5'-phosphate in activating glucose-bisphosphatase

Glucose-bisphosphate (G1c-1,6-P2) phosphatase has been purified greater than 200-fold from the cytosol of mouse brain. As reported earlier, the enzyme requires inosine monophosphate (IMP) and Mg2+ for activity [Guha, S.K., & Rose, Z. B. (1982) J. Biol. Chem. 257, 6634-6637]. Kinetic parameters and the role of IMP have been further investigated. When Glc-1,6-P2 and IMP are both varied, double-reciprocal plots of the data form a parallel line pattern. With 2 mM Mg2+, the Km obtained for G1c-1,6-P2 is 20 microM and the Ka for IMP is 9 microM. Co2+, Mn2+, and Ni2+ activate less effectively than Mg2+. The apparent Ka for Mg2+ decreases with increasing G1c-1,6-P2, and the observed Km of G1c-1,6-P2 decreases with increasing Mg2+. The extrapolated value of the Ka of Mg2+ at infinite substrate is 86 microM. Mg2+ does not affect the Ka of IMP. The phosphatase activity is optimal at pH 7. The phosphatase is not completely specific since mannose 1,6-bisphosphate is hydrolyzed and guanosine monophosphate activates. However, fructose 1,6-bisphosphate is no more than a poor inhibitor, and adenine nucleotides are neither activators nor inhibitors. The products of the reaction are glucose-1-P and glucose-6-P, in a ratio of 2:3, and Pi. Both glucose-P's are competitive inhibitors with respect to IMP [Ki(glucose-1-P) = 5 microM; Ki(glucose-6-P) = 18 microM]. Neither glucose-P competes with G1c-1,6-P2. The demonstration of an exchange reaction between G1c-1,6-P2 and glucose-6-P is evidence for the phosphorylation of the enzyme by the substrate. The exchange reaction requires Mg2+ and is inhibited by IMP. The observation of the exchange reaction and its elimination by IMP indicates that the low level of phosphoglucomutase activity that remains with the phosphatase throughout purification is an inherent property of the phosphatase. The requirement of glucose-bisphosphatase for the nucleotide IMP is consistent with possible roles for both G1c-1,6-P2 and IMP in the control of the ATP level in the brain.