Characterization and mapping to human chromosome 8q24.3 of Ly-6-related gene 9804 encoding an apparent homologue of mouse TSA-1.

The 9804 gene, which encodes a human Ly-6 protein most similar to mouse differentiation Ag TSA-1/Sca-2, has also been called RIG-E. Like mouse TSA-1, it has a broad tissue distribution with varied expression levels in normal human tissues and tumor cell lines. Like some members of the murine Ly-6 family, the 9804 gene is responsive to IFNs, particularly IFN-alpha. Overlapping genomic fragments spanning the 9804 gene (5543 bp) have been isolated and characterized. The gene organization is analogous to that of known mouse Ly-6 genes. The first exon, 2296 bp upstream from exon II, is entirely untranslated. The three coding exons (II, III, and IV) are separated by short introns of 321 and 131 bp, respectively. Primers were developed for specific amplification of 9804 gene fragments. Screening of human-hamster somatic cell hybrids and yeast artificial chromosomes (YACs) indicated that the gene is distal to c-Myc, located in the q arm of human chromosome 8. No positives were detected from the Centre d'Etude du Polymorphisme Humain mega-YAC A or B panels, nor from bacterial artificial chromosome libraries; two positive cosmids (c101F1 and c157F6) were isolated from a human chromosome 8 cosmid library (LA08NC01). Fluorescence in situ hybridization of metaphase spreads of chromosome 8, containing hybrid cell line 706-B6 clone 17 (CL-17) with cosmid c101F1, placed the 9804 gene close to the telomere at 8q24.3. This mapping is significant, since the region shares a homology with a portion of mouse chromosome 15, which extends into band E where Ly-6 genes reside. Moreover, the gene encoding E48, the homologue of mouse Ly-6 molecule ThB, has also been mapped to 8q24.

Increased growth promoting but not mast cell degranulation potential of a covalent dimer of c-Kit ligand.

The native form of soluble c-kit ligand (KL) is a noncovalent dimer. We have isolated a soluble, disulfide-linked dimer of murine KL (KL-CD) by expressing KL in Escherichia coli and refolding the denatured protein under conditions that promote the formation of both noncovalent dimers (KL-NC) and KL-CD. KL-CD exhibits a 10- to 15-fold increase in the ability to stimulate the growth of both the human megakaryocytic cell line MO7e and murine bone marrow-derived mast cells relative to KL-NC. Colony-forming assays of murine bone marrow progenitor cells also reflected this increased potency. However, KL-CD and KL-NC are equally able to prime mast cells for enhanced IgE-dependent degranulation in vitro and activate mast cells in vivo. Improving the growth-promoting activity of KL without changing its mast cell activation potential suggests that KL-CD or a related molecule could be administered in the clinic at doses that stimulate hematopoietic recovery while avoiding significant mast cell activation.

Recombinant interleukin-2 analogs. Dynamic probes for receptor structure.

Interleukin-2 (IL-2) and its receptor complex have become one of the most studied members of a growing family of protein hormones characterized by structural similarities in both ligands and their receptors. Structure-function studies of IL-2 have been complicated by the multimeric nature of its receptor. Two receptor subunits (55- and 75-kDa type I cell surface proteins) can participate to form the high affinity binding site. Although the IL-2 is apparently unique in some respects, similar subunit cooperativity has now been shown to be a common feature for other members of this receptor family. The availability of cell lines expressing the individual IL-2 receptor subunits has allowed detailed analysis of subunit binding characteristics. Results regarding the relationship of molecular recognition at each subunit to the mechanism of ligand binding at the high affinity site, however, have led to different interpretations. In this study we have employed previously prepared C-terminal IL-2 mutant proteins to examine receptor binding at all three classes using a variety of equilibrium and kinetic techniques. These results indicate that the high affinity IL-2 receptor complex includes the p55/p75 heterodimer prior to IL-2 binding and that both receptor subunits participate simultaneously in ligand capture.

Monitoring of protein conformation by high-performance size-exclusion liquid chromatography and scanning diode array second-derivative UV absorption spectroscopy.

Genetic methods now allow the rapid production of mutant proteins for structure-function analysis. To properly interpret any change in biologic activity resulting from modification in primary sequence, it is essential to monitor conformational changes resulting from mutations. Several methods allow low-resolution protein conformational analysis. One method, second-derivative UV absorption spectroscopy, is particularly useful for proteins containing tyrosine and/or tryptophan residues. Using high-performance size-exclusion liquid chromatography and scanning diode array detection we have demonstrated that it is possible to monitor the degree of aggregation as well as conformational perturbation for a series of interleukin-2 structural mutants. Furthermore, the combination of high-performance liquid chromatography and second-derivative UV absorption spectroscopy avoids a potential artifactual contribution in non-chromatographic analysis due to protein aggregation.

Early toxicity of recombinant interleukin-2 in cats.

Studies were conducted in cats to determine whether this species could serve as an animal model for the therapeutic toxicity of recombinant interleukin-2 in humans, and to establish the role of the area postrema in the causation of recombinant interleukin-2-induced vomiting. Injections of recombinant interleukin-2 (3.6 x 10(6) IU/kg, i.m.), given once every 24 hr for one to three days, evoked repeated vomiting in 4 out of 6 area postrema intact cats and in 3 out of 3 area postrema-ablated cats. These results suggest that the area postrema is not essential for the emetic action of recombinant interleukin-2. In anesthetized intact cats, no remarkable changes in ventilation, blood pressure, heart rate or blood pH were observed over 4.5 to 54 hr of continuous physiological recording after i.v. injections of recombinant interleukin-2 to a total dose as high as 27 x 10(6) IU/kg. Cat lymphocytes responded appropriately to the cytokinetic action of human recombinant interleukin-2.

Conformational perturbation of interleukin-2: a strategy for the design of cytokine analogs.

Interleukin-2 (IL-2) is a representative of a growing family of small proteins termed lymphokines which are responsible for mediating cell differentiation, growth and function in the immune system. Many of these proteins are being evaluated for their clinical potential. From the perspective of drug development, structure-function analysis of these molecules and their receptors require the use methodologies different than those traditionally employed for small peptides and other natural products. However, similar pharmacologic principles apply and an understanding of ligand-receptor interactions and the associated responses is required in order to efficiently pursue agonist and antagonist design. Although IL-2 is a protein of only 133 amino acid residues for which a low resolution X-ray structure does exist, the complexity of its receptor system has provided an added challenge to structure-function studies. Consequently, little is known concerning the receptor contact residues for this protein. We have attempted to utilize established principles of protein and peptide structure to manipulate the conformation of IL-2 in a manner which has provided analogs helpful for receptor interaction studies. These proteins have not only providing useful information on the nature of the IL-2 receptor but have also revealed potential strategies for the design of IL-2 agonists and antagonists.

Correlation between the induction of heat shock protein 70 and enhanced viral reactivation in mammalian cells treated with ultraviolet light and heat shock.

Enhanced viral reactivation (EVR) is considered to be one manifestation of an inducible response to DNA damage in mammalian cells analogous to the SOS response in Escherichia coli. EVR is characterized by the increased survival of ultraviolet (UV)-irradiated virus in cells which have been pretreated with DNA-damaging agents or by another type of cellular stress, heat shock (HS). In this study, we have analyzed the induction of nuclear proteins from Vero cells treated with either UV or HS, with the goal of identifying the protein(s) which mediate the EVR response. Results of 2-dimensional protein gel electrophoresis and fluorographic analysis of [35S]methionine-labeled nuclear proteins showed that UV-irradiation caused the increased synthesis of five proteins at 4-9 h after treatment. At 19-24 h, one of these proteins was still being synthesized at a higher level in UV-irradiated cells, and there were nine additional proteins whose syntheses were enhanced over control levels. In contrast, HS induced only one Mr 72,000 nuclear protein whose synthesis was maximal during the 4-9-h labeling period and corresponded to one of the proteins induced by UV at 19-24 h. Subsequent Western and Northern blot analyses have confirmed that this protein is a member of the heat shock protein (hsp) 70 family. Elevated nuclear levels of this protein correlated temporally with the maximum EVR response induced by each treatment (4 h after HS and 24 h after UV). Since the kinetics of EVR is different following UV and HS and parallels the difference in the induction of nuclear levels of hsp70 following each treatment, the results suggest that hsp70 may be involved in mediating the EVR response. In addition, this protein may also play a role in the recovery of DNA synthesis in UV-irradiated cells.