Purification and postsynthetic modifications of Friend erythroleukemic cell high mobility group protein HMG-I

We have previously detected and purified a Friend erythroleukemic mouse cell nonhistone chromatin protein having extraction and acid-solubility properties like the low molecular weight "high mobility group" (HMG) nuclear proteins. We show here that the electrophoretic properties and the amino acid composition of this mouse cell "HMG-like" protein is comparable to those of the HMG-I proteins isolated from human HeLa S3 cells, African green monkey cells, Ehrlich ascites mouse cells, and rat fibroblast cells. Therefore, we have also designated the Friend erythroleukemic mouse cell protein as HMG-I. In common with the other HMG proteins the Friend cell HMG-I protein can undergo a variety of post-translational biochemical modifications including acetylation, ADP-ribosylation, glycosylation, and phosphorylation. Surprisingly, in the course of these studies we found that in vivo radiolabeling experiments revealed that only two minor HMG-14 subspecies (and/or possibly a minor HMG-I subspecies) are phosphorylated whereas HMG-1, -2, -17, and the major HMG-14 are not heavily phosphorylated.     

Hoechst 33258, distamycin A,and high mobility group protein I (HMG-I) compete for binding to mouse satellite DNA

The experiments described were designed to test the hypothesis that the (A+T)-specific DNA binding ligands Hoechst 33258 and distamycin A affect the condensation of mouse centromeric heterochromatin by competing for binding to satellite DNA with one or more chromosomal proteins. The studies focused on the nonhistone chromosomal protein HMG-I since its binding properties predict it would be a target for competition. Gel mobility shift assays show that HMG-I forms specific complexes with satellite DNA and that the formation of these complexes is competed for by both Hoechst and distamycin. In addition, methidium propyl EDTA Fe(II) [MPE Fe(II)] footprints of ligand-satellite DNA complexes showed essentially the same protection pattern for both drugs and a similar, but not identical, HMG-I footprint. If these in vitro results reflect the in vivo situation then the incomplete condensation of centromeric heterochromatin observed when mouse cells are grown in the presence of either chemical ligand could be a consequence of competition for binding of HMG-I (and possibly other proteins) to satellite DNA.by E.R. Schmidt     

A conformational study of the sequence specific binding of HMG-I (Y) with the bovine interleukin-2 cDNA

The DNA sequence specific interaction of the high mobility group non-histone protein HMG-I (Y) with the 3' untranslated region of the bovine interleukin-2 cDNA has been studied. Circular dichroism and thermal denaturation studies suggest that HMG-I (Y) alters the conformational state and increases the thermal stability of the DNA. Additionally, amino acid sequence analysis suggests that the previously identified non-histone protein HMG-Y is an isoform of HMG-I.     

Complete cDNA sequence,expression, alternative splicing,and genomic organization of the mouse Nfat5 gene

Members of the NFAT (nuclear factors of activated T cells) gene family have been investigated in numerous organisms, including man and mouse. All NFATs may be synthesized in several isoforms differing in amino or carboxy termini due to 5' and 3' alternative splicing of the corresponding mRNA. Recently, we mapped the murine Nfat5 gene to chromosome 8D. In the present paper we describe for the first time the complete sequence and primary structure of murine Nfat5, two new spliced isoforms, and the expression of murine Nfat5 in embryonic and adult mouse tissues.     

Netropsin, distamycin and berenil interact differentially with a high-affinity binding site for the high mobility group protein HMG-I

Netropsin, distamycin, berenil and the chromosomal protein HMG-I share the ability to bind preferentially to AT-rich regions of DNA. We studied the binding behaviour of the chemical agents towards a high-affinity binding site for HMG-I by DNase I and MPE footprinting and analyzed their ability to challenge HMG-I-DNA complexes by competition experiments. Significant differences in the binding affinities and in the efficiencies to abolish HMG-I-DNA complexes were observed for the three drugs. Netropsin proved to be the most avidly binding compound and the most efficient competitor raising the interesting possibility that netropsin affects cell growth by interfering with HMG-I-DNA interaction.     

The mouse Kell blood group gene (Kel): cDNA sequence, genomic organization, expression, and enzymatic function

The human Kell blood group system is important in transfusion medicine, since Kell is a polymorphic protein and some of its antigens can cause severe reactions if mismatched blood is transfused, while maternal alloimmunization may lead to fetal and neonatal anemia. In humans, Kell is an Mr 93,000 type II membrane glycoprotein with endothelin-3-converting enzyme activity that is linked by a single disulfide bond to another protein, XK, that spans the membrane ten times. An absence of XK leads to clinical symptoms termed the McLeod syndrome. We determined the cDNA sequence of the mouse Kell homologue, the organization of the gene, expression of the protein and its enzymatic function on red cells. Comparison of human and mouse Kell cDNA showed 80% nucleotide and 74% amino acid sequence identity. Notable differences are that the mouse Kell protein has eight probable N-linked carbohydrate side chains, compared to five for human Kell, and that the mouse homologue has one more extracellular cysteine than human Kell protein. The mouse Kell gene (Kel), like its human counterpart, is similarly organized into 19 exons. Kel was located to proximal Chromosome 6. Northern blot analysis showed high expression in spleen and weaker levels in testis and heart. Western blot analysis of red cell membrane proteins demonstrated that mouse Kell glycoprotein has an apparent Mr of 110,000 and, on removal of N-linked sugars, 80,000. As in human red cells, Kell is disulfide-linked to XK and mouse red cells have endothelin-3-converting enzyme activity.     

Sequence of a cDNA encoding turtle high mobility group 1 protein

In order to understand sequence information about turtle HMG1 gene, a cDNA encoding HMG1 protein of the Chinese soft-shell turtle (Pelodiscus sinensis) was amplified by RT-PCR from kidney total RNA, and was cloned, sequenced and analyzed. The results revealed that the open reading frame (ORF) of turtle HMG1 cDNA is 606 bp long. The ORF codifies 202 amino acid residues, from which two DNA-binding domains and one polyacidic region are derived. The DNA-binding domains share higher amino acid identity with homologues sequences of chicken (96.5%) and mammalian (74%) than homologues sequence of rainbow trout (67%). The polyacidic region shows 84.6% amino acid homology with the equivalent region of chicken HMG1 cDNA. Turtle HMG1 protein contains 3 Cys residues located at completely conserved positions. Conservation in sequence and structure suggests that the functions of turtle HMG1 cDNA may be highly conserved during evolution. To our knowledge, this is the first report of HMG1 cDNA sequence in any reptilian.     

Complete sequence and genomic analysis of murine gammaherpesvirus 68.

Murine gammaherpesvirus 68 (gammaHV68) infects mice, thus providing a tractable small-animal model for analysis of the acute and chronic pathogenesis of gammaherpesviruses. To facilitate molecular analysis of gammaHV68 pathogenesis, we have sequenced the gammaHV68 genome. The genome contains 118,237 bp of unique sequence flanked by multiple copies of a 1,213-bp terminal repeat. The GC content of the unique portion of the genome is 46%, while the GC content of the terminal repeat is 78%. The unique portion of the genome is estimated to encode at least 80 genes and is largely colinear with the genomes of Kaposi's sarcoma herpesvirus (KSHV; also known as human herpesvirus 8), herpesvirus saimiri (HVS), and Epstein-Barr virus (EBV). We detected 63 open reading frames (ORFs) homologous to HVS and KSHV ORFs and used the HVS/KSHV numbering system to designate these ORFs. gammaHV68 shares with HVS and KSHV ORFs homologous to a complement regulatory protein (ORF 4), a D-type cyclin (ORF 72), and a G-protein-coupled receptor with close homology to the interleukin-8 receptor (ORF 74). One ORF (K3) was identified in gammaHV68 as homologous to both ORFs K3 and K5 of KSHV and contains a domain found in a bovine herpesvirus 4 major immediate-early protein. We also detected 16 methionine-initiated ORFs predicted to encode proteins at least 100 amino acids in length that are unique to gammaHV68 (ORFs M1 to 14). ORF M1 has striking homology to poxvirus serpins, while ORF M11 encodes a potential homolog of Bcl-2-like molecules encoded by other gammaherpesviruses (gene 16 of HVS and KSHV and the BHRF1 gene of EBV). In addition, clustered at the left end of the unique region are eight sequences with significant homology to bacterial tRNAs. The unique region of the genome contains two internal repeats: a 40-bp repeat located between bp 26778 and 28191 in the genome and a 100-bp repeat located between bp 98981 and 101170. Analysis of the gammaHV68, HVS, EBV, and KSHV genomes demonstrated that each of these viruses have large colinear gene blocks interspersed by regions containing virus-specific ORFs. Interestingly, genes associated with EBV cell tropism, latency, and transformation are all contained within these regions encoding virus-specific genes. This finding suggests that pathogenesis-associated genes of gammaherpesviruses, including gammaHV68, may be contained in similarly positioned genome regions. The availability of the gammaHV68 genomic sequence will facilitate analysis of critical issues in gammaherpesvirus biology via integration of molecular and pathogenetic studies in a small-animal model.     

Systemic release of high mobility group box 1 protein during severe murine influenza

Hypercytokinemia is gaining recognition as the mechanism of fatality from influenza. No work to date has addressed the role of high mobility group box 1 protein (HMGB1) in influenza, the parallel being that in other severe proinflammatory cytokine syndromes (e.g., sepsis and malaria) levels of circulating HMGB1 are elevated and may correlate with death. Using a commercially available ELISA for HMGB1, we found that HMGB1 was not increased in the plasma of influenza virus-infected mice (A/Japan/305/57) on day 7 post infection, about the time of peak mortality, and peak levels of HMGB1 in the plasma did not occur until relatively late in infection, on day 9 post infection. In keeping with the late peak of HMGB1 being unassociated with mortality, administration of ethyl pyruvate, which inhibits active secretion but not passive release of HMGB1, to influenza virus-infected mice, did not affect their survival. Further work is required to determine whether influenza virus infection induces passive release of HMGB1, and whether HMGB1 neutralization with a specific Ab would improve survival.     

Drosophila basement membrane procollagen alpha 1(IV). II. Complete cDNA sequence, genomic structure, and general implications for supramolecular assemblies

A Drosophila melanogaster gene for a basement membrane procollagen chain was recently identified from the sequence homology of the carboxyl (NC1) end of the polypeptide that it encodes with the corresponding domain of human and murine collagens IV (Blumberg, B., MacKrell, A. J., Olson, P. F., Kurkinen, M., Monson, J. M., Natzle, J. E., and Fessler, J. H. (1987) J. Biol. Chem. 262, 5947-5950). This gene is at chromosome location 25C. Here we report the complete 6-kilobase cDNA sequence coding for a chain of 1775 amino acids, as well as the genomic structure. The gene is composed of nine relatively large exons separated by eight relatively small introns. This organization is different from the multiple small exons separated by large introns reported for mouse and human type IV collagens (Kurkinen, M., Bernard, M. P., Barlow, D. P., and Chow, L. T. (1985) Nature 317, 177-179. Sakurai, Y., Sullivan, M., and Yamada, Y. (1986) J. Biol. Chem. 261, 6654-6657. Soininen, R., Tikka, L., Chow, L., Pihlajaniemi, T., Kurkinen, M., Prockop, D. J., Boyd, C. D., and Tryggvason, K. (1986) Proc. Natl. Acad. Sci. U.S.A. 83, 1568-1572). Drosophila and human alpha 1(IV) procollagen chains share not only polypeptide domains near their amino and carboxyl ends for making specialized, intermolecular junctional complexes, but also 11 of 21 sites of imperfections of the collagen triple helix. However, neither the number nor the nature of the amino acids in these imperfections appear to have been conserved. These imperfections of the helical sequence may be important for the supramolecular assembly of basement membrane collagen. The 9 cysteine residues of the Drosophila collagen thread domain are arranged as several variations of a motif found in vertebrate collagens IV only near their amino ends, in their "7 S" junctional domains. The relative positions of these cysteine residues provide numerous opportunities for disulfide bonding between molecules in both parallel and antiparallel arrays. There is a pseudorepeat of one-third of the thread length, and there are numerous possibilities for disulfide-linked microfibrils and networks. We propose that collagen microfibrils, stabilized by disulfide segment junctions, are a versatile ancestral form from which specialized collagen fibers and networks arose.