Functional and genetic plasticities of the poliovirus genome: quasi-infectious RNAs modified in the 5'-untranslated region yield a variety of pseudorevertants.

Poliovirus RNA species with nucleotides 564 to 571 deleted or with a secondary structure domain (positions 564 to 629) replaced by a shorter irregular oligonucleotide have been engineered previously; these RNAs have been considered quasi-infectious (yielding a single late revertant plaque) and dead, respectively (E. Pilipenko, A. Gmyl, Y. Svitkin, S. Maslova, A. Sinyakov, and V. Agol, Cell 68:119-131, 1992). By using large amounts of these RNAs for transfections, revertant clones with a great variety of genetic changes (point mutations, insertions of foreign sequences, short or extended deletions) were isolated. The pattern of these changes supported the notion that an appropriately spaced oligopyrimidine-AUG tandem is important for efficient poliovirus RNA translation. Structural features within and around this tandem modulated the initiation efficiency. The functional and genetic plasticities of the poliovirus genome are briefly discussed.     

Insulin stimulates GDP release from G proteins in the rat and human liver plasma membranes

Plasma membranes (1–2 mg protein) prepared from the livers of adult male rats and human organ donors were incubated with 0.6 μM [α-³²P] guanosine triphosphate (GTP) in an adenosine triphosphate (ATP)-regenerating buffer at 37°C for 1 h; during this incubation, the [³²P]GTP is hydrolyzed and the nucleotide that is predominantly bound to the membranes is [³²P] guanosine diphosphate (GDP). [³²P]GDP release from the liver membranes was proportional to the protein concentration and increased as a function of time. At 5 mM, Ca²⁺, Mg²⁺, Mn²⁺, and Zn²⁺ maximally inhibited GDP release by 80–90%, whereas, 5 mM Cu²⁺ maximally stimulated the reaction by 100%. Therefore, cations were not included in the buffer used in the GDP release step. One μM Gpp(NH)p (5′-guanylylimidodiphosphate), a nonhydrolyzable analog of GTP, maximally stimulated [³²P]GDP release in the liver membranes by up to 30%. Although 10 nM Gpp(NH)p had no effect on GDP release, it appeared to stabilize the hormonal effect by blocking further GDP/GTP exchange. In the rat membranes, 1–100 nM glucagon (used as a positive control) stimulated [³²P]GDP release by about 17% (P < .05); similarly, 0.1–100 nM insulin stimulated [³²P]GDP release by 10–13% (P < .05). In the human membranes, 10 pM to 100 nM insulin stimulated [³²P]GDP release by 7–10%. In the rat membranes, 10 nM insulin stimulated [³²P]GDP release by 17 and 24% at 2 and 4 min, respectively (P < .05); in the human membranes, 10 nM insulin stimulated [³²P]GDP release by about 9% at 2 and 4 min. Normal rabbit IgG (used as a control for insulin receptor antibody) by itself stimulated the GDP release by rat and human membranes. However, the stimulation of the GDP release by insulin receptor antibody was consistently higher than that observed with normal rabbit IgG. Four to 15 μg of insulin receptor antibody stimulated [³²P]GDP release by 12–22% (P < .05) and 7–14% in rat and human membranes, respectively. These results indicate that ligand binding to the insulin receptor results in a functional interaction of the receptor with a guanine nucleotide-binding transducer protein (G protein) and activation of GTP/GDP exchange.     

Model of mammalian cell reproductive death I. Basic assumptions and general equations

A systemic model describing the major radiobiological effects of various types of radiation is proposed. The model base lines were substantiated, and general mathematical equations for cell survival developed. The model takes into consideration such physical and biological factors as linear energy transfer, ion track structure, and structural and functional organization of interphase chromatin. This paper presents the basic assumptions made and general equations for the cell killing.     

Alterations in the hepatic enzymes following experimental lead poisoning

An investigation on the influence of lead toxicity on some of the hepatic enzymes was studied in rats both after a shorter interval of 15 d and after longer intervals of 60 and 90 d. Three different doses of lead as 5, 10, and 50 mg/kg body wt were administered orally on every alternate day. Whereas significant inhibition of succinic dehydrogenase was seen following lead poisoning, the activity acid and alkaline phosphatase increased with lead intoxication. The histoarchitecture of the liver was grossly intact. Liver accumulated less lead compared to kidney at 60 and 90 d.     

Alloreactive lymphocytes from T cell receptor (beta-chain) transgenic mice do not mediate a graft-versus-host reaction.

The injection of mature T cells into a tolerant or immunocompromised allogeneic host animal produces a graft versus host response (GVHR) that can result in splenomegaly, immunosuppression and death of the host animal. We demonstrate here that lymphocytes from T cell receptor beta-chain (TCR-beta) transgenic mice, in which the expression of the transgene inhibits endogenous beta- and gamma-gene rearrangements and thus causes abnormal T cell development, are unable to mediate a GVHR. The GVHR was measured after the injection of lymphocytes from transgenic mice into normal F1 mice and also after transplantation of bone marrow and lymphocytes from transgenic mice into lethally irradiated F1 recipients. In both systems, cells from transgenic mice failed to produce a significant GVHR. Cells from the transgenic mice were able to recognize the foreign histocompatibility Ag of the host in vitro and in vivo although the transgenic mice rejected skin grafts more slowly than controls. Thus, lymphocytes from transgenic mice were unable to produce a GVHR despite the presence of alloreactive T cells. These results suggest that lymphocytes from TCR-beta transgenic mice fail to mediate a GVHR either because lymphocytes with a single transgenic TCR-beta chain have a limited ability to recognize allogeneic cells in vivo or because the transgenic mice lack lymphocyte subsets that are important for the mediation of a GVHR.     

Affinity requirements for induction of sequential phases of human B cell activation by membrane IgM-cross-linking ligands

The affinity of Ag interaction with a B cell's membrane IgM (mIgM) receptors has long been considered to play a critical role in the in vivo clonal selection of B lymphocytes. This study has examined a possible basis for this affinity selection at the level of Ag induction of sequential B cell activation phenomena, i.e., elevated membrane class II MHC expression (G0* excitation), G1 entry, and S phase entry. Functional experiments with model bivalent Ag, i.e., a group of murine mAb of diverse intrinsic binding affinities for human IgM, revealed that the minimal affinity requisites for inducing the above phenomena vary significantly. At a ligand concentration of 100 micrograms/ml, the induction of increased class II MHC expression, G1 entry, and S phase had minimal affinity thresholds of Ka approximately 0.2 to 2 x 10(6) M-1; approximately 7 x 10(6) M-1; and approximately 1 x 10(8) M-1, respectively. Pulsing studies revealed that whereas high affinity ligand was essential at later periods in the prolonged (greater than 24 h) signaling period that leads to S phase entry, mAb with significantly lower affinity were competent at signaling during the first 24 h. Because all but the lowest affinity ligand (Ka = 2 x 10(5) M-1) could effectively modulate mIgM, and furthermore, because B cells show a substantial increase in surface area during activation, it appears likely that one factor contributing to the higher affinity requirements for induction of late activation phenomena is a progressive decrease in the density of mIgM on the responsive B cells. These studies suggest that whereas only a small proportion of B cells, i.e., those with relatively high affinity for an antigenic epitope, will be triggered to clonally expand on encountering a paucivalent Ag in the absence of T cell help, a much wider spectrum of the B cell repertoire will be triggered to a state of partial activation. How the presence of ancillary T cells and cytokines may facilitate the full clonal expansion of these latter cells is discussed.     

Variations in thymocyte susceptibility to clonal deletion during ontogeny. Implications for neonatal tolerance.

Activation of immature thymocytes via the TCR results in programmed cell death and clonal deletion. We have examined thymocytes from mice of different ages and observed that, whereas TCR-mediated signaling caused deletion of thymocytes from newborn and 3-week-old mice, it failed to delete thymocytes from mice of 1 week of age. This could not be attributed to differences in cell surface TCR expression, TCR-mediated phosphoinositide hydrolysis or Ca2+ mobilization, or total cellular levels of TCR zeta- and eta-chains. Moreover, thymocytes of all ages were equally susceptible to corticosteroid- and Ca2+ ionophore-induced programmed cell death. These data are consistent with the notion that fetal and neonatal thymocytes represent a relatively synchronous wave of cells passing through phases in which they are susceptible and then resistant to TCR-induced programmed cell death. They also support the notion that the classical phenomenon of neonatal tolerance is due to clonal deletion and that the inability of allogeneic cells to tolerize mice at 1 week of age is because the thymocytes are refractory to TCR-alpha beta-mediated clonal deletion.