A novel anti-inflammatory drug, SDZ ASM 981, for the treatment of skin diseases: in vitro pharmacology.

SDZ ASM 981, a novel ascomycin macrolactam derivative, has high anti-inflammatory activity in animal models of allergic contact dermatitis and shows clinical efficacy in atopic dermatitis, allergic contact dermatitis and psoriasis, after topical application. Here we report on the in vitro activities of this promising new drug. SDZ ASM 981 inhibits the proliferation of human T cells after antigen-specific or non-specific stimulation. It downregulates the production of Th1 [interleukin (IL)-2, interferon-gamma] and Th2 (IL-4, IL-10) type cytokines after antigen-specific stimulation of a human T-helper cell clone isolated from the skin of an atopic dermatitis patient. SDZ ASM 981 inhibits the phorbol myristate acetate/phytohaemagglutinin-stimulated transcription of a reporter gene coupled to the human IL-2 promoter in the human T-cell line Jurkat and the IgE/antigen-mediated transcription of a reporter gene coupled to the human tumour necrosis factor (TNF)-alpha promoter in the murine mast-cell line CPII. It does not, however, affect the human TNF-alpha promoter controlled transcription of a reporter gene in a murine dendritic cell line (DC18 RGA) after stimulation via the FcgammaRIII receptor. SDZ ASM 981 also prevents the release of preformed pro-inflammatory mediators from mast cells, as shown in the murine cell line CPII after stimulation with IgE/antigen. In summary, these results demonstrate that SDZ ASM 981 is a specific inhibitor of the production of pro-inflammatory cytokines from T cells and mast cells in vitro.

In vitro and in vivo activity of human recombinant granulocyte-macrophage colony-stimulating factor in dogs.

Although it is well documented that human granulocyte-macrophage colony-stimulating factor (GM-CSF) controls the production and functional activity of human and nonhuman primate granulocytes and macrophages, relatively little is known about its effects on cells obtained from other species. The molecular cloning of the complementary DNA for human GM-CSF has made it possible to determine the cross-reactivity of the purified recombinant human material (rhGM-CSF) on cells of other species. The results presented herein show that specific receptors for human GM-CSF exist on dog bone marrow cells and mature circulating dog granulocytes. The number of the receptors and the apparent binding affinity of the rhGM-CSF to its receptors on granulocytes were similar to those observed either on human or monkey cells. In cultures of dog bone marrow cells, rhGM-CSF was capable of promoting colony formation in a dose-dependent manner. Human GM-CSF also primed dog granulocytes for increased production of reactive oxygen metabolites in response to either phorbolmyristic acetate-or zymosan-activated dog serum. In vivo, s.c. administration to healthy dogs of rhGM-CSF in daily doses of 15, 50, or 150 micrograms/kg body weight over a period of 7-20 days induced a dose-dependent rise of up to a maximum of a fourfold increase in peripheral WBC counts. The rise in WBC counts was mainly due to elevated neutrophil levels, but an increase in the numbers of monocytes and eosinophils was also observed. However, the rhGM-CSF-induced leukocytosis in dogs was not as dramatic as that observed in nonhuman primates. In all rhGM-CSF-treated dogs, circulating platelet counts dropped to nadir levels of about 20%-30% of normal numbers. Dogs that were treated with 150 micrograms/kg rhGM-CSF developed specific antibodies after about 10-12 days of treatment. These antibodies were able to neutralize the effect of rhGM-CSF in in vitro assays. In vivo WBC counts began to decline when specific antibodies developed, but they never dropped below normal levels. Taken together, the results suggest that human GM-CSF does not appear to exhibit absolute species specificity.

Molecular cloning and sequence determination of the genomic regions encoding protease and genome-linked protein of three picornaviruses.

To investigate the degree of similarity between picornavirus proteases, we cloned the genomic cDNAs of an enterovirus, echovirus 9 (strain Barty), and two rhinoviruses, serotypes 1A and 14LP, and determined the nucleotide sequence of the region which, by analogy to poliovirus, encodes the protease. The nucleotide sequence of the region encoding the genome-linked protein VPg, immediately adjacent to the protease, was also determined. Comparison of nucleotide and deduced amino acid sequences with other available picornavirus sequences showed remarkable homology in proteases and among VPgs. Three highly conserved peptide regions were identified in the protease; one of these is specific for human picornaviruses and has no obvious counterpart in encephalomyocarditis virus, foot-and-mouth disease virus, or cowpea mosaic virus proteases. Within the other two peptide regions two conserved amino acids, Cys 147 and His 161, could be the reactive residues of the active site. We used a statistical method to predict certain features of the secondary structures, such as alpha helices, beta sheets, and turns, and found many of these conformations to be conserved. The hydropathy profiles of the compared proteases were also strikingly similar. Thus, the proteases of human picornaviruses very probably have a similar three-dimensional structure.

Structure of nonintegrated, circular Herpesvirus saimiri and Herpesvirus ateles genomes in tumor cell lines and in vitro-transformed cells.

Nonintegrated, circular DNA molecules of Herpesvirus saimiri and Herpesvirus ateles were found in five lymphoid cell lines originating from tumor tissues or established by in vitro immortalization of T lymphocytes. The arrangement of unique (L) and repetitive (H) DNA sequences in circular viral genomes was analyzed by partial denaturation mapping followed by visualization with an electron microscope. Three types of circular viral DNA structures were found. (i) The virus-producing cell line RLC, which is derived from an H. ateles-induced rabbit lymphoma, contains circular viral genomes which consist of a single L-DNA and a single H-DNA region, both the same length as in virion DNA. (ii) The circular viral genomes of the nonproducer cell lines H1591 and A1601, in vitro transformed by H. saimiri and H. ateles, respectively, have deletions in the unique L-DNA region and larger H-DNA regions. Cell line A1601 lacks about 8% of virion L-DNA, and H1591 cells lack about 40% of viral L-DNA information. (iii) The nonproducing H. saimiri tumor cell lines 1670 and 70N2 harbor viral genomes with two L-DNA and two H-DNA regions, respectively. Both types of circular molecules have a long and a short L-segment. The sequence arrangements of circular DNA molecules from H. saimiri-transformed cell lines were compared with those of linear virion DNA by computer alignment of partial denaturation histograms. The L-DNA deletion in cell line H1591 was found to map in the right half of the virion DNA. Comparison of the denaturation patterns of both L regions of cell lines 1670 and 70N2 identified the short L regions as subsets of the long L regions. Thus, circular viral DNA molecules of all four nonproducer cell lines represent defective genomes.

Episomal viral DNA in herpesvirus saimiri-transformed lymphoid cell lines.

Structural analysis of episomal viral genomes from two herpesvirus saimiri (HVS)-transformed tumour cell lines (No. 1670 and 70N2) showed that both types of episomes have a higher molecular weight than linear virion DNA. The arrangement of unique (L) and repetitive (H) DNA in No. 1670 episomes was studied by partial denaturation mapping. Part of the L-sequences present in linear virion DNA was found to be missing, part was found to be duplicated in the episomes. The episomal L-DNA regions were correlated with the known physical gene maps of linear HVS DNA.

Herpesvirus ateles DNA and its homology with Herpesvirus saimiri nucleic acid.

Analysis of the structural organization of Herpesvirus ateles DNA shows that two types of viral DNA molecules are encapsidated in virions: (i) M-genomes, which contain 74% light sequences (L-DNA, 38% guanine plus cytosine) and 26% highly repetitive heavy sequences (H-DNA, 75% guanine plus cytosine), and (ii) defective H-genomes, which consist exclusively of repetitive H-DNA. The structure of M-genomes from H. ateles consists of an L-DNA region of about 70 x 10(6) daltons inserted between H-DNA termini of variable length. M-genomes with a shorter H-DNA region at one end of the molecule have a long stretch of H-DNA at the other end, resulting in a total molecular weight of 89.8 +/- 8.5 x 10(6). Thus it resembles the structure of M-genomes of H. saimiri. H-DNA of the two independent H. ateles isolates, strains 810 and 73, reveals different patterns after cleavage with restriction endonuclease Sma I. H-DNA of H. ateles 810 appears to consist of identical tandem repeat units with a molecular weight of 1,035,000; the H-DNA repeat unit of strain 73 is shorter (930,000 molecular weight). Corresponding DNA sequences of the two H. ateles strains (810 and 73) are completely homologous in cross-hybridizations. However, a discrete nucleotide sequence divergence between these virus strains is detected by measuring melting temperatures (T(m)) of DNA hybrid molecules. Some homology exists between H. ateles and H. saimiri DNA. Hybridization of L-DNA from H. ateles with L-DNA from H. saimiri shows about a 35% homology between the respective L-DNA sequences; the resulting heteroduplex molecules show a decrease of T(m) by 13.5 degrees C, corresponding to about a 9% mismatching in cross-hybridizing parts of L-regions. Very little homology is found between H-DNA of H. ateles and H. saimiri.

Episomal viral DNA in a Herpesvirus saimiri-transformed lymphoid cell line.

The lymphoid cell line #1670 has been derived from the infiltrated spleen of a tumor-bearing marmoset monkey infected with Herpesvirus saimiri. The cells contain both types of H. saimiri DNA, unique light (L-) DNA (36% cytosine plus guanine) and repetitive heavy (H-) DNA (71% cytosine plus guanine), without producing infectious virus. Viral DNA was found to persist in these cells as nonintegrated circular DNA molecules. Closed circular superhelical viral DNA molecules were isolated by three subsequent centrifugation steps: (i) isopycnic centrifugation in CsCl, (ii) sedimentation through glycerol gradients, and (iii) equilibrium centrifugation in CsCl-ethidium bromide. The isolated circles had a molecular weight of 131.5 +/- 3.6 x 10(6). This is significantly higher than the molecular weight of linear DNA molecules isolated from purified H. saimiri virions (about 100 x 10(6)). Partial denaturation mapping of circular molecules from #1670 lymphoid cells showed uniform arrangement of H- and L-DNA sequences in all circles. All denatured molecules contained two L-DNA regions (molecular weights of 54.0 +/- 1.8 x 10(6) and 31.5 +/- 1.3 x 10(6)) and two H-DNA regions (molecular weight of 25.6 +/- 1.9 x 10(6) and 20.0 +/- 0.8 x 10(6)) of constant length. Maps of both L-regions suggested that the sequences of the shorter L-DNA region were a subset of those of the longer region. The sequences of both L-regions had the same orientation. Circular molecules from H. saimiri-transformed lymphoid cell line #1670 appeared to represent defective genomes, containing only 75% of the genetic information present in L-DNA of H. saimiri virions.

Structure of Herpesvirus saimiri genomes: arrangement of heavy and light sequences in the M genome.

Herpesvirus saimiri contains two species of DNA molecules. (i) The M genome is composed of 70% light (L) DNA (36% cytosine plus guanine; density in CsCl, 1.695 g/ml), which consists of unique sequences, and 30% heavy (H) DNA (71% cytosine plus guanine; density, 1.729 g/ml). (ii) The H genome contains heavy sequences exclusively. H sequences in M and H genomes cross-hybridize completely and are cleaved identically by restriction endonuclease R-Sma I into four classes of fragments with molecular weights of about 360,000, 300,000, 130,000 and 40,000, respectively. H sequences are chains of identical repeat units in tandem arrangement. The molecular weight of each repeat unit is about 830,000. L sequences have no cleavage site for endo R-Sma I H sequences are terminally arranged at both ends of the M genome, as seen by electron microscopy after partial denaturation. The length of the individual heavy ends varies between 21 mum and less than 1 mum, whereas the light region is uniform in size (35.3+/-0.35 mum). As a rule, molecules with a long heavy end at one side have a short heavy end at the other side, thus giving rise to a limited size heterogeneity. Orientation of M DNA molecules by the denaturation map of the light region shows that the longer heavy end may be located at the left or at the right side of the M genome.