Sidney H. Golub

The 1311-base pair human tumor necrosis factor (TNF) alpha promoter region was fused to the luciferase (Luc) reporter gene and studied in a transient transfection system in three TNF producing cell lines, the U937 macrophage cell line, the MLA 144 T cell line, and the 729-6 B cell line. This full length promoter construct can be induced by phorbol 13-myristate acetate (PMA) in each of these cell types. Analysis of a series of 5'-truncations showed several peaks of basal and PMA induced activity suggesting the presence of several positive and negative regulatory elements. A PMA responsive element was localized to a region between -95 and -36 bp relative to the transcription start site. Within this region, single AP-2- and AP-1-like consensus sequences were noted. These AP-2 and AP-1 sites were each modified with a double point mutation. A modest (20-50%) reduction in TNF promoter activity was observed with the AP-2 site mutation. However, mutation of the AP-1 site markedly diminished both the basal and PMA-activated promoter activity. Also co-transfections of the wild-type promoter construct with an AP-1/c-jun expression vector resulted in augmented basal and PMA-induced promoter activity.

Natural killer (NK) and lymphokine-activated killer (LAK) cell cytotoxic functions can be strongly augmented by the iron-carrier protein lactoferrin (LF). LF significantly enhances NK and LAK activities when added at the beginning of NK or LAK cytotoxicity assays. LF is effective in augmenting cytotoxic activities at concentrations as low as 0.75 microgram/ml, and higher concentrations of LF induce greater augmentation of NK and LAK. Iron does not appear to be essential for LF to increase NK and LAK, as depleting iron from LF with the chelator deferoxamine does not affect the capacity of LF to increase cytotoxicity. LF is known to have RNase enzymatic activity, and LF enhancement of NK and LAK can be blocked by RNA. However, LFs from two different sources with over 100-fold difference in RNase activity are equally effective in enhancing NK and LAK. Furthermore, purified non-LF RNase does not modulate NK or LAK activity and DNA is as effective as RNA in blocking LF augmentation of NK or LAK cytotoxicity. Therefore, the RNase activity is unlikely to be responsible for LF enhancement of the cytotoxicities. Newborn infants are known to have low NK activity and NK and LAK cells have been implicated in host defense against microbial infections. Thus, maternal milk-derived LF may have a role in boosting antimicrobial immunity in the early stages of life. In adults, LF released from neutrophils may enhance NK and LAK functions in the inflammatory process induced by microbial infections.

Human mixed lymphocyte cultures (MLC) have been observed to generate cytotoxicity not only against allospecific targets but also against autochthonous control target cells. This work investigates the types of target cells susceptible to the MLC-activated effectors and also analyzes the time course of the generation of these activities. Normal human peripheral blood lymphocytes (PBL) were sensitized to normal allogeneic mitomycin C-treated PBL in MLC and subsequently were tested for cytotoxicity against various targets in a 51 Cr-release cell-mediated lympholysis (CML) assay. Two types of cytotoxic activities were clearly distinguishable by the types of target cells susceptible to the effectors: a) The allocytotoxicity was directed at the relevant allogeneic Con A blasts (alloblasts), but not to the autochthonous control Con A blast (autoblast) targets. b) In contrast, the “anomalous” cytotoxicity, which was originally defined as alloactivated cytotoxicity against the autochthonous lymphoblastoid cell line (auto-LCL) target, was shown to have a broad range of cytotoxic activity against all cultured cell line targets tested. The allocytotoxicity was further distinguished from the “anomalous” reactivity by studies on the time of development in culture of these activities. The peak anomalous activity always occurred 1 or 2 days earlier and declined more rapidly than the peak allocytotoxicity. Experiments to find common antigenic determinants between the sensitizing cells and targets susceptible to anomalous cytotoxicity revealed no obvious antigenic relationships.

In the past decade, a new family of highly conserved antioxidant enzymes, Peroxiredoxins (Prxs), have been discovered and defined. There are two major Prx subfamilies: one subfamily uses two conserved cysteines (2-Cys) and the other uses 1-Cys to scavenge reactive oxygen species (ROS). This review focuses on the four mammalian 2-Cys members (Prx I–IV) that utilize thioredoxin as the electron donor for antioxidation. The array of biological activities of these proteins suggests that they may be evolutionarily important for cell function. For example, Prxs are capable of protecting cells from ROS insult and regulating the signal transduction pathways that utilize c-Abl, caspases, nuclear factor-κB (NF-κB) and activator protein-1 (AP-1) to influence cell growth and apoptosis. Prxs are also essential for red blood cell (RBC) differentiation and are capable of inhibiting human immunodeficiency virus (HIV) infection and organ transplant rejection. Distribution patterns indicate that Prxs are highly expressed in the tissues and cells at risk for diseases related to ROS toxicity, such as Alzheimer's and Parkinson's diseases and atherosclerosis. This interesting correlation suggests that Prxs are protective against ROS toxicity, yet overwhelmed by oxidative stress in some cells. Prxs tend to form large aggregates at high concentrations, a feature that may interfere with their normal protective function or may even render them cytotoxic. Imbalance in the expression of subtypes can also potentially increase their susceptibility to oxidative stress. Understanding the function and biological role of Prxs may lead to important discoveries about the cellular dysfunction of ROS-related diseases ranging from atherosclerosis to cancer to neurodegenerative diseases.