Analysis of peptide-binding motifs for two disease associated HLA-DR13 alleles using an M13 phage display library.

Major histocompatibility complex (MHC) molecules bind peptides bearing an appropriate 'sequence motif' for MHC binding. The use of phage display libraries exploits the ability of MHC class II molecules to exchange peptides in solution and thus select out peptide sequences with high-affinity binding from a large array of random peptides. We have analysed the peptide binding motifs of HLA-DRB1*1301 and *1302 using affinity purified HLA-DR13 molecules to purify sequentially HLA-DR13-binding peptides from a large random library of M13 phage containing nonamer inserts in the pIII coat protein.

Peptide binding specificity of HLA-DR4 molecules: correlation with rheumatoid arthritis association.

We have investigated whether sequence 67 to 74 shared by beta chains of rheumatoid arthritis (RA)-associated HLA-DR molecules imparts a specific pattern of peptide binding. The peptide binding specificity of the RA-associated molecules, DRB1*0401, DRB1*0404, and the closely related, RA nonassociated DRB1*0402 was, therefore, determined using designer peptide libraries. The effect of single key residues was tested with site-directed mutants of DRB1*0401.

Promiscuous and allele-specific anchors in HLA-DR-binding peptides.

The major histocompatibility complex (MHC) class II molecules are highly polymorphic membrane glycoproteins that bind peptide fragments of proteins and display them for recognition by CD4+ T cells. To understand the effect of human MHC class II polymorphism on peptide-MHC interaction, we have isolated M13 phage from a large M13 peptide display library by selection with DRB1*0401 and DRB1*1101 molecules, as recently described for DRB1*0101. Sequence analysis of the peptide-encoding region of DR-bound phage led to the identification of position-specific anchor residues, defining motifs for peptide binding to DR molecules.

Mouse macrophage clones immortalized by retroviruses are functionally heterogeneous.

Murine macrophage clones were generated from thymus, spleen, brain, and bone marrow by in vitro immortalization with recombinant retroviruses carrying an avian v-myc oncogene. The cloned cell lines express F4/80 molecules, exert phagocytosis, have nonspecific esterase activity, and express class II molecules after interferon gamma activation. The macrophage clones are diploid and their karyotypes have remained stable for greater than 3 years in culture.

Activation of the M-CSF gene in mouse macrophages immortalized by retroviruses carrying a v-myc oncogene.

We have recently immortalized murine brain macrophages (microglial cells) with a complex of retroviruses (3RV) transducing separately the myc and mil oncogenes. Surprisingly, the immortalized cells harboured an exogenous v-myc oncogene, but no v-mil sequences. The transformed macrophage cell lines grew in vitro without the addition of exogenous growth factors and were also able to grow in vivo in nude mice.

Cellular sources and effects of tumor necrosis factor-alpha on pituitary cells and in the central nervous system.

Cytokine-mediated communication between the immune system and the nervous system has been shown in the past few years. The precise cellular sources of these molecules in the brain is still a controversial issue. We have thus immortalized primary cell cultures from mouse embryonic brains to analyze cloned cells involved in cytokine production.

The yeast DNA polymerase-primase complex: genes and proteins.

The yeast DNA polymerase-primase complex is composed of four polypeptides designated p180, p74, p58 and p48. All the genes coding for these polypeptides have now been cloned. By protein sequence comparison we found that yeast DNA polymerase I (alpha) shares three major regions of homology with several DNA polymerases.

DNA polymerase I gene of Saccharomyces cerevisiae: nucleotide sequence, mapping of a temperature-sensitive mutation, and protein homology with other DNA polymerases.

A 5600-base pair segment spanning the coding region of the Saccharomyces cerevisiae DNA polymerase I gene was sequenced and found to contain an open reading frame of 1468 codons, corresponding to a polypeptide of Mr 166,794. A pol1 temperature-sensitive mutation, encoding a DNA-polymerase-primase complex with altered stability, has a single base-pair substitution that changes the glycine at position 493 to a positively charged arginine. Protein sequence comparison with other prokaryotic and eukaryotic DNA polymerases reveals three major regions of homology.

Mechanism of initiation of in vitro DNA synthesis by the immunopurified complex between yeast DNA polymerase I and DNA primase.

The immunopurified yeast DNA-polymerase-I--DNA-primase complex synthesizes oligo(rA) and oligo(rG) molecules that are used as primer for replication of poly(dT) and poly(dC). Neither initiation nor DNA synthesis is observed with poly(dA) and poly(dI). Nitrocellulose-filter binding shows that the enzyme complex binds to deoxypyrimidine polymers, but not to deoxypurine polymers.

Polypeptide structure of DNA primase from a yeast DNA polymerase-primase complex.

An immunoaffinity chromatographic procedure was developed to purify DNA polymerase-DNA primase complex from crude soluble extracts of yeast cells. The immunoabsorbent column is made of mouse monoclonal antibody to yeast DNA polymerase I covalently linked to Protein A-Sepharose. Purification of the complex involves binding of the complex to the immunoabsorbent column and elution with concentrated MgCl2 solutions.

Initiation, elongation and pausing of in vitro DNA synthesis catalyzed by immunopurified yeast DNA primase: DNA polymerase complex.

Yeast DNA primase and DNA polymerase I can be purified by immunoaffinity chromatography as a multipeptide complex which can then be resolved into its functional components and further reassembled in vitro. Isolated DNA primase synthesizes oligonucleotides of a preferred length of 9-10 nucleotides and multiples thereof on a poly(dT) template. In vitro reconstitution of the DNA primase:DNA polymerase complex allows the synthesis of long DNA chains covalently linked to RNA initiators shorter than those synthesized by DNA primase alone.