Molecular mechanism of delta-selectivity of indole analogs of nonpeptide opioids

A combined experimental and computational approach was used to understand the mechanism of delta-receptor selectivity of a series of nonpeptide opioids. Six pairs of fused ring opioids/indole derivatives were studied. Receptor-binding assays using [3H][D-Ala2-MePhe4-Gly-ol]-enkephalin (mu), [3H][D-Pen2-D-Pen5]-enkephalin (delta), and [3H]U-69593 (kappa) were performed in guinea pig whole-brain membranes. Agonist activity was determined in norbinaltorphimine- or beta-funaltrexamine-treated guinea pig ileum (mu and kappa) and beta-funaltrexamine-treated mouse vas deferens (delta). Steric and electronic properties were calculated for each compound. Although the parent compounds were selective for the mu-receptor, the indole analogs displayed selectivity for the delta-site because of a decrease in mu-affinity accompanied by an increase in delta-affinity. The indole analogs displayed little or no activity at the delta-receptor. The role of the indole in enhanced delta-recognition is likely interaction with a lipophilic site in the receptor. The diminished mu-affinity of the indole analogs is a result of the loss of the carbonyl oxygen as the proton-accepting center, which we have previously determined to be important for recognition of the mu-receptor.

SERP1, a serine proteinase inhibitor encoded by myxoma virus, is a secreted glycoprotein that interferes with inflammation

Myxoma virus is a leporipoxvirus that causes a rapidly lethal, generalized infection known as myxomatosis in the European rabbit (Oryctolagus cuniculus). A characteristic feature of myxomatosis is the specific downregulation of key pathways important for numerous host defenses against the viral infection. The SERP1 gene has significant sequence similarity to the serpin superfamily of serine proteinase inhibitors and is one of many virulence factor genes located within the terminal regions of the myxoma virus genome. Transcriptional analysis of the SERP1 gene in myxoma virus (strain Lausanne) indicates that it is expressed as a late gene and studies using a polyclonal anti-SERP1 antiserum indicate that it encodes a secreted protein with an apparent molecular weight of 55 kDa. Using myxoma virus and recombinant vaccinia virus constructs for experiments with tunicamycin and peptide N-glycosidase F, it is shown that the secreted SERP1 protein is modified by N-linked glycosylation. Mutation of both copies of the SERP1 gene in myxoma virus results in a significant attenuation of the virus, such that more than 50% of infected animals are able to recover from the otherwise lethal infection. Histological analyses of lesions taken from infected animals suggest that in the absence of the SERP1 protein, a more effective inflammatory response occurs, allowing a more rapid resolution of the infection. This suggests that SERP1 contributes to viral pathogenesis by interacting with cellular component(s) involved in the regulation of inflammation.

Identification of a poxvirus gene encoding a uracil DNA glycosylase

An open reading frame, BamHI D6R, from the central highly conserved region of the Shope fibroma virus (SFV) genome was sequenced and found to have significant homology to that of uracil DNA glycosylases from a number of organisms. Uracil DNA glycosylase catalyzes the initial step in the repair pathway that removes potentially mutagenic uracil from duplex DNA. The D6R polypeptide was expressed in reticulocyte lysates programmed with RNA transcribed from an expression vector containing the T7 RNA polymerase promoter. A highly specific ethidium bromide fluorescence assay of the in vitro translation product determined that the encoded protein does indeed possess uracil DNA glycosylase activity. Open reading frames from other poxviruses, including vaccinia virus (HindIII D4R) and fowlpox (D4), are highly homologous to D6R of SFV and are predicted to encode uracil DNA glycosylases. Identification of the SFV uracil DNA glycosylase provides evidence that this poxviral protein is involved in the repair of the viral DNA genome. Since this enzyme performs only the initial step required for the removal of uracil from DNA, creating an apyrimidinic site, we suggest that other, possibly virus-encoded, repair activities must be present in the cytoplasm of infected cells to complete the uracil excision repair pathway.

A poxvirus-encoded uracil DNA glycosylase is essential for virus viability

Infection of cultured mammalian cells with the Leporipoxvirus Shope fibroma virus (SFV) causes the induction of a novel uracil DNA glycosylase activity in the cytoplasms of the infected cells. The induction of this activity, early in infection, correlates with the early expression of the SFV BamHI D6R open reading frame which possesses significant protein sequence similarity to eukaryotic and prokaryotic uracil DNA glycosylases. The SFV BamHI D6R open reading frame and the homologous HindIII D4R open reading frame from the Orthopoxvirus vaccinia virus were cloned under the regulation of a phage T7 promoter and expressed in Escherichia coli as insoluble high-molecular-weight aggregates. During electrophoresis on sodium dodecyl sulfate-polyacrylamide gels, the E. coli-expressed proteins migrate with an apparent molecular mass of 25 kDa. The insoluble protein aggregate generated by expression in E. coli was solubilized in urea and, following a subsequent refolding step, displayed the ability to excise uracil residues from double-stranded plasmid DNA substrates, with the subsequent formation of apyrimidinic sites. The viral enzyme, like all other characterized uracil DNA glycosylases, is active in the presence of high concentrations of EDTA, is substrate inhibited by uracil, and does not display any endonuclease activity. Attempts to inactivate the HindIII D4R gene of vaccinia virus by targeted insertion of a dominant xanthine-guanine phosphoribosyltransferase selection marker or direct insertion of a frame-shifted oligonucleotide were uniformly unsuccessful demonstrating that, unlike the uracil DNA glycosylase described for herpesviruses, the poxvirus enzyme is essential for virus viability.

Inhibition of plasmin, urokinase, tissue plasminogen activator, and C1S by a myxoma virus serine proteinase inhibitor

The myxoma and malignant rabbit fibroma poxviruses are lethal tumorigenic viruses of rabbits whose virulence is modulated by the production of a virus-encoded secreted serine proteinase inhibitor, SERP-1. This viral protein was detected in medium harvested from myxoma and malignant rabbit fibroma virus-infected cells, and its inhibitory profile has been characterized by gel and kinetic analysis. SERP-1 forms complexes with and inhibits the human fibrinolytic enzymes plasmin, urokinase, and two-chain tissue-type plasminogen activator (association rate constants 3.4 x 10(4), 4.3 x 10(4), and 3.6 x 10(4) M-1 s-1 respectively). It is also able to inhibit C1S, the first enzyme in the complement cascade with an association rate constant which was unaffected by the addition of heparin (1.3 x 10(3) M-1 s-1). SERP-1 acts as a substrate for and is cleaved by thrombin, porcine trypsin, human neutrophil elastase, porcine pancreatic elastase, thermolysin, subtilisin, bovine alpha-chymotrypsin, and factor Xa. Incubation with kallikrein and cathepsin G had no effect. The structure of SERP-1 has been modeled on other members of the serpin family which revealed the characteristic serpin architecture apart from the absence of the D-helix. Structural analysis and kinetic assays demonstrate that the absence of this region does not prevent inhibitory activity and furthermore allow the identification of cysteine residues involved in internal and intermolecular disulfide bonding.

Encoding of a homolog of the IFN-gamma receptor by myxoma virus

Many poxvirus-encoded virulence factors have been identified as proteins that are secreted from infected cells. The major secreted protein (37 kilodaltons) from cells infected with myxoma virus is encoded by the M-T7 open reading frame. This protein has significant sequence similarity to the human and mouse receptors for interferon-gamma (IFN-gamma). Furthermore, the myxoma M-T7 protein specifically binds rabbit IFN-gamma and inhibits the biological activity of extracellular IFN-gamma, one of the key regulatory cytokines in the host immune response against viral infections.

Myxoma virus M11L ORF encodes a protein for which cell surface localization is critical in manifestation of viral virulence

Myxoma virus (MYX) induces extensive immunosuppression in infected rabbits and is associated with high levels of mortality. The virus encodes multiple gene products designed to circumvent the cellular immune response to the viral infection. Deletion analysis has shown that the M11L open reading frame (ORF) is an important virulence factor which downregulates leukocyte infiltration of MYX-induced tumors. To investigate the role of the M11L protein in viral pathogenesis, we sequenced the MYX M11L ORF and showed that the sequence has motifs consistent with a 166-aa class III membrane-spanning molecule possessing a single transmembrane helix near the C-terminus and a 142-aa N-terminal extracellular domain that has six cysteine residues plus two consensus N-glycosylation sites. Transcription analysis indicates that M11L is expressed as an early gene, and surface immunofluorescence studies with anti-M11L antibodies reveal that M11L protein is transported to the infected cell surface. Immunoprecipitation analysis of an attenuated viral recombinant, vMYX-GF-delta M11L, indicates that an M11L variant protein with an altered C-terminus is synthesized at about 45% of wild type levels; however, it is not detectable on the cell surface, suggesting that proper M11L function requires localization at the infected cell membrane. We propose that M11L is a virulence factor whose function is to recognize an extracellular ligand essential for the cellular inflammatory response.

Pharmacological profiles of fentanyl analogs at mu, delta and kappa opiate receptors

Receptor binding assays using [3H]DAGO ([D-Ala2,MePhe4-Gly5-ol]enkephalin) (mu), [3H]DPDPE ([D-Pen2,D-Pen5]enkephalin) (delta) and [3H]U-69593 (kappa) were done in guinea pig whole brain membranes. Agonist activity was determined in norbinaltorphimine or beta-funaltrexamine (beta-FNA) treated guinea pig ileum (mu and kappa, respectively) and beta-FNA-treated mouse vas deferens (delta). The compounds with highest affinity were the most potent at the mu-receptor. The selectivity observed in the binding affinities was also found in in vitro activity. No correlation was found between mu-affinity and selectivity; the highest affinity analog, lofentanil, was found to be among the least selective, while another high affinity analog, R30490, was the most mu-selective. The results show that not all fentanyls are highly mu-selective, and could produce actions through delta- and kappa-opiate receptors.

Stereochemical studies of chiral h-1 antagonists of histamine: The resolution, chiral analysis, and biological evaluation of four antipodal pairs

The resolution of the H-1 antihistamines chloropheniramine, dimethindene, carbinoxamine, and mebrophenhydramine is described. The optical purity of antipodal products is investigated by chiral HPLC (use of alpha 1-acid glycoprotein and beta-cyclodextrin columns) and NMR (spectra of beta-cyclodextrin inclusion complexes). Configurational relationships among the group are reviewed and assignments are confirmed and extended by circular dichroism evidence. Affinity constants of antipodal pairs for guinea pig ileum and cerebellum sites, determined by gut bath and binding experiments respectively, are reported together with some in vivo tests in man for central effects. Results are discussed in terms of configurational requirements for activity and variations in antipodal potency ratios within the group.

Deletion of the growth factor gene related to EGF and TGF alpha reduces virulence of malignant rabbit fibroma virus

The role of the epidermal growth factor homologue in malignant rabbit fibroma virus (MRV) pathogenicity was investigated by constructing a viral growth factor deletion mutant (MRV-GF-). Since MRV is a recombinant virus with a myxoma virus background but possesses some terminal sequences derived from Shope fibroma virus, the growth factor gene in MRV is in fact identical to Shope fibroma growth factor (SFGF). Although no significant differences were detected in the in vitro characteristics of MRV and MRV-GF-, a pronounced attenuation was observed after inoculation of the test rabbits with MRV-GF-. Animals infected with wild-type MRV uniformly developed a fatal syndrome involving disseminated tumors accompanied by purulent conjunctivitis and rhinitis. In contrast, although MRV-GF- recipients developed similar initial signs of the MRV disease syndrome, 75% of these animals completely recovered from the viral and secondary bacterial infections and became immune to subsequent MRV challenge. Tumors in MRV-GF- recipients displayed earlier and more prominent inflammatory reactions than their wild-type MRV counterparts and contained fewer proliferating cells. Squamous metaplasia and hyperplasia of target epithelia were less pronounced in MRV-GF- than in MRV infection. We conclude that SFGF is a major virulence factor in MRV infection and is responsible for at least some of the cellular proliferation observed at tumor sites. In addition, the diminished ability of MRV-GF- to cause hyperplasia in nasal and conjunctival epithelia may decrease the extent of gram negative bacterial overgrowth as compared to the parental virus and hence contribute to the dramatic reduction in the lethality of MRV-GF- infection.

Myxoma virus expresses a secreted protein with homology to the tumor necrosis factor receptor gene family that contributes to viral virulence

Poxviruses are known to contain a large number of open reading frames, particularly near the termini of the viral genome, that are not required for growth in tissue culture. However, many of these gene products are believed to play important roles in determining the virulence of the virus by modulating the host immune response to the infection. Recently it has been shown that Shope fibroma virus encodes, within the terminal inverted repeats, a protein (T2) related to the cellular tumor necrosis factor receptor (TNFR) and which specifically binds both TNF alpha and TNF beta. We have sequenced the terminal regions of two other Leporipoxviruses (myxoma virus and malignant rabbit fibroma virus) that are extremely invasive and capable of inducing extensive immunosuppression in rabbits and demonstrate that they also encode a closely related T2 homolog with all the structural motifs predicted for a secreted TNF binding protein. To investigate the biological role of the T2 protein, we have inactivated the myxoma virus T2 gene within each copy of the viral TIR by the insertion of a dominant selectable marker (Escherichia coli guanosine phosphoribosyltransferase) and selection of the recombinant virus in the presence of mycophenolic acid. The success of the inactivation of both copies of T2 was confirmed by the loss a broad protein band (52-56 kDa) of the predicted size for T2 from the profile of proteins secreted from mutant virus-infected BGMK cells at early times after infection. Although the T2-minus recombinant myxoma virus grew normally in tissue culture, upon infection of susceptible rabbits the viral disease was observed to be significantly attenuated. The majority of infected rabbits were able to mount an effective immune response to the infection and completely recovered. These survivor rabbits became immune to subsequent challenge with wild type myxoma virus. We conclude that the T2 viral protein is an important secreted virulence factor and that it in all likelihood functions by compromising the antiviral effects of TNF. We propose the term "viroceptor" to describe viral-encoded homologs of cellular lymphokine receptors whose function is to intercept the activity of the cognate lymphokine in order to short circuit the host immune response to the viral infection.

Identification and DNA sequence of the large subunit of the capping enzyme from Shope fibroma virus

A 3.6-kb region of the Shope fibroma virus (SFV) BamHI D fragment located in the central region of the viral genome was sequenced. Three open reading frames (ORFs) were identified, D3R, D4L, and D5R. Each of these ORFs have a counterpart organized identically within the HindIII fragment D of the vaccinia virus genome (D1R, D2L, and D3R). Homology scores and assays of viral cores indicate that SFV D3R encodes the large subunit of the SFV mRNA capping enzyme.

T2 open reading frame from the Shope fibroma virus encodes a soluble form of the TNF receptor

A transcriptionally active open reading frame (T2) from Shope Fibroma Virus was recently shown to have striking sequence homology with members of a new superfamily of cell surface proteins, including a receptor for human tumor necrosis factor. Here we report that recombinant T2 protein expressed in COS cells is a soluble, secreted glycoprotein which specifically binds human TNF alpha and beta, and inhibits binding of these cytokines to native TNF receptors on cells. T2 binding of TNF is not inhibited by nerve growth factor, although the nerve growth factor receptor is also a member of the same family, nor by nine other recombinant cytokines. Further, the repeating domain structure of T2 most closely resembles that of the type I TNF receptor (p75) and is significantly different from other family members, including the type II TNF receptor (p55). Since T2 possesses a leader sequence but lacks a transmembrane domain, these results confirm the original suggestion (1) that T2 represents a soluble form of the type I TNF receptor which is secreted from virally infected cells, and whose function is to immunosuppress the host by abrogating the potentially destructive effects of TNF. This is the first such virally-encoded soluble cytokine receptor to be identified, and may represent a more general mechanism by which viruses subvert the host immune system.

Myxoma virus and malignant rabbit fibroma virus encode a serpin-like protein important for virus virulence

The leporipoxviruses Shope fibroma virus (SFV), the myxoma virus (MYX), and the SFV/MYX recombinant malignant rabbit fibroma virus (MRV) are closely related yet induce profoundly different diseases in the European rabbit. SFV, which produces a benign tumor at the site of inoculation, is cleared by the immune system after approximately 2 weeks whereas MYX and MRV induce a rapidly lethal systemic infection characterized by generalized suppression of host immune functions. DNA sequencing studies reveal that MRV and MYX possess homologous gene members of the T6/T8/T9 family originally described in the terminal inverted repeat (TIR) of SFV. We also describe a gene present in both MYX and MRV genomes, but which has apparently evolved in the SFV genome into a fragmented pseudogene that appears to contribute to the aggressive nature of MYX and MRV infections. Translation of this open reading frame, designated MYXOMA SERPIN 1 (SERP1), reveals a protein sequence with highly significant homology to the super-family of serine protease inhibitors (serpins) which also includes a number of other poxviral proteins. In the MYX genome the SERP1 gene lies entirely within the TIR sequences and is thus present as two copies, while in the MRV genome SERP1 is present in the unique sequences adjacent to the TIR boundary and hence is a single copy. The amino acid homology between the putative active site of SERP1 and those of other serpins predicts that the target enzyme will be different from the known catalog of serine antiprotease substrates. Deletion of this gene from MRV significantly attenuates the disease spectrum induced by the normally lethal virus. Although the MRV-S1 deletion construct (MRV with SERP1 gene deleted) grows in all tissue culture cells tested in a fashion identical to the MRV parent, the majority of rabbits infected with MRV-S1 are able to mount an effective immune response and totally recover from the virus infection to become resistant to subsequent challenge by MRV or MYX.

Identification and DNA sequence of the Shope fibroma virus DNA topoisomerase gene

The Shope fibroma virus (SFV) DNA topoisomerase gene has been identified and mapped to the BamHI D fragment near the midpoint of the genome. The DNA sequence of the SFV BamHI S fragment together with the contiguous BamHI-ClaI subfragment of BamHI D which encompasses the topoisomerase gene and two flanking genes has been determined and analyzed. Both the SFV DNA topoisomerase and the two flanking genes are closely related in terms of sequence and spatial organization to the homologous sequences from the midpoint of the vaccinia virus genome, indicating that these proteins are conserved not only in their sequence but also by position within the poxvirus genome. To confirm the assignment of the SFV gene, the putative SFV DNA topoisomerase has been expressed as an active fusion protein in Escherichia coli and this system should be useful in the analysis of topoisomerase function following the introduction of targeted mutations into the topoisomerase gene. The results of this work shed further light on the evolutionary relationship of the different poxvirus genera and indicate that central unique regions of the poxvirus genomes contain many of the essential viral genes and are thus highly conserved.

Transcriptional regulation of two cytotoxic T lymphocyte-specific serine protease genes

The expression of two serine proteases is induced by antigenic stimulation in cytotoxic T lymphocytes. Using nuclear run-on analysis the increase in steady state mRNA level has been shown to correspond to transcriptional activation. However, the two genes appear to be sequentially rather than coordinately induced. Both genes were shown to be more sensitive to DNase I digestion than a beta-globin gene in cytotoxic T cells. In addition, for the cytotoxic cell protease 1 gene the 5' region of the gene was more sensitive than the 3' end. Two DNaseI hypersensitive sites were seen in the 5' flanking sequences of both genes. The DNA sequences of the upstream regions of both genes were determined and compared. Although the two flanking sequences are overall quite dissimilar, there are short regions which are shared between the two CTL-protease genes. A number of these have been implicated in regulating the expression of other T cell genes.

Organization of two genes encoding cytotoxic T lymphocyte-specific serine proteases CCPI and CCPII

The genes encoding two recently described cytotoxic T cell proteases, CCPI and CCPII, have been isolated and sequenced. The organizations of the coding and noncoding portions of the two genes are very similar to each other and also to the gene encoding rat mast cell protease type II. Similarly to other serine protease genes, each of the active-site residues is contained on a separate exon; however, two introns were found in particularly interesting positions. One occurs within the postulated activation dipeptide and the other in a position close to the active-site Asp residue. This latter intron interrupts the amino acid sequence in the invariant core region of the protein. We believe that these genes represent a new subfamily of serine protease genes.

Tumorigenic poxviruses: fine analysis of the recombination junctions in malignant rabbit fibroma virus, a recombinant between Shope fibroma virus and myxoma virus

Malignant rabbit fibroma virus (MRV) has been shown to be a lethal tumorigenic poxvirus of rabbits derived from a recombination event between Shope fibroma virus (SFV), which induces benign fibromas in rabbits, and myxoma virus, the agent of myxomatosis. We have cloned and sequenced all of the MRV recombination junctions, which are located near the left and right terminal inverted repeat (TIR) regions, and present a composite map of the MRV genome with respect to the relevant gene products. The two junctions closet to the MRV termini, at identical positions at the left and right ends, are at nucleotide 5272 and result in an in-frame fusion protein (ORF T-5) in which the N-terminal 232 aa are derived from an SFV sequence linked to a C-terminus derived from myxoma. At the left MRV TIR the recombination junction distal from the terminus maps to nucleotide 9946 but leaves the adjacent gene virtually unchanged from its SFV homolog. At the right terminus, the relevant junction sequences from MRV and myxoma could not be cloned in wild-type Escherichia coli but were maintained stably in a recA recBC sbcB host. The SFV/myxoma junction at this location maps 5' to a growth factor gene (SFGF) which is related to those encoding epidermal growth factor and transforming growth factor-alpha. As a result, the myxoma growth factor gene has been deleted in MRV and replaced in toto by the SFV gene. The recombination junction upstream from the SFGF gene creates an in-frame fusion in ORF T11-R in which the N-terminal amino acids are derived from myxoma and the remainder from SFV. In summary, MRV has received the following ORFs from SFV: at the left terminus T5 (fusion), T6, T7, and T8; at the right terminus, T5 (fusion), T6, T7, T8, T9-R, SFGF, and T11-R (fusion).

Cloning and sequencing of the cytoplasmic precursor to the alpha subunit of rat liver mitochondrial succinyl-CoA synthetase

Succinyl-CoA synthetase [succinate-CoA ligase (GDP-forming); EC 6.2.1.4] of rat liver, an alpha beta dimer, is a component of the enzymology of the tricarboxylic acid cycle and functions within the mitochondrial matrix. We have isolated and determined the sequence of a cDNA clone containing the coding sequence of the cytoplasmic precursor to the alpha subunit of this enzyme together with stretches of nontranslated sequence at the 5' and 3' ends. The translated amino acid sequence indicates the presence of a 27-residue N-terminal signal sequence for mitochondrial targeting. The amino acid sequence of the mature alpha subunit shows an extraordinary degree of homology to the alpha subunit of Escherichia coli succinyl-CoA synthetase, with greater than 70% of the residues identical. This suggests that the fundamental differences in the quaternary structures and catalytic functions of the mammalian and bacterial enzymes must be attributable to differences in the beta subunits. mRNA that hybridizes to the cloned DNA is approximately equal to 1800 nucleotide residues in length, confirming that each of the two subunits is encoded separately and does not arise by proteolysis of a primary gene product containing both subunits of the mature protein.

The structure of phenindamine base and salts in the solute state

High-field NMR (13C and 1H) studies of phenindamine are reported which establish structures of the free base and some of its salts in the solute condition. The base exists as a mixture of two isomers which differ in double bond position (9-9a or 4a-9a) while most salts are 9-9a isomers. The clinically employed tartrate (Thephorin) is exceptional in being a 4a-9a ene. Salts of both double bond type exist in solution as mixtures of protonated epimers of variable epimeric ratio, that of the tartrate in D2O being approximately 1:1.

Tumorigenic poxviruses: genomic organization and DNA sequence of the telomeric region of the Shope fibroma virus genome

Shope fibroma virus (SFV), a tumorigenic poxvirus, has a 160-kb linear double-stranded DNA genome and possesses terminal inverted repeats (TIRs) of 12.4 kb. The DNA sequence of the terminal 5.5 kb of the viral genome is presented and together with previously published sequences completes the entire sequence of the SFV TIR. The terminal 400-bp region contains no major open reading frames (ORFs) but does possess five related imperfect palindromes. The remaining 5.1 kb of the sequence contains seven tightly clustered and tandemly oriented ORFs, four larger than 100 amino acids in length (T1, T2, T4, and T5) and three smaller ORFs (T3A, T3B, and T3C). All are transcribed toward the viral hairpin and almost all possess the consensus sequence TTTTTNT near their 3' ends which has been implicated for the transcription termination of vaccinia virus early genes. Searches of the published DNA database revealed no sequences with significant homology with this region of the SFV genome but when the protein database was searched with the translation products of ORFs T1-T5 it was found that the N-terminus of the putative T4 polypeptide is closely related to the signal sequence of the hemagglutinin precursor from influenza A virus, suggesting that the T4 polypeptide may be secreted from SFV-infected cells. Examination of other SFV ORFs shows that T1 and T2 also possess signal-like hydrophobic amino acid stretches close to their N-termini. The protein database search also revealed that the putative T2 protein has significant homology to the insulin family of polypeptides. In terms of sequence repetitions, seven tandemly repeated copies of the hexanucleotide ATTGTT and three flanking regions of dyad symmetry were detected, all in ORF T3C. A search for palindromic sequences also revealed two clusters, one in ORF T3A/B and a second in ORF T2. ORF T2 harbors five short sequence domains, each of which consists of a 6-bp short palindrome and a 10- to 18-bp larger palindrome. The significance of these palindromic domains in this ORF is unclear but the coincidence of the end of one larger palindrome with the end of the translated protein sequence that has homology with the B chain of insulin suggests that the palindromes may divide the T2 protein into several functional units. The salient organizational features of the complete SFV TIR are also discussed in light of what is known about other poxviral TIRs.

Tumorigenic poxviruses: transcriptional mapping of the terminal inverted repeats of Shope fibroma virus

A composite transcriptional map for the entire 12.4-kb terminal inverted repeat (TIR) region of the Shope fibroma virus (SFV) genome has been determined. Northern blotting and S1-nuclease mapping were used to determine the regions which are transcribed, their temporal relationships, as well as the transcriptional initiation sites. Sequences representing the entire TIR are transcribed into poly(A)+ mRNA at both early and late times in the infection. Fifteen transcriptional initiation sites were mapped, 12 within the TIRs and 3 within the unique sequences close to the junction between the right TIR and the unique internal sequences. Ten of the 12 transcriptional initiation sites within the TIR and 2 of the 3 sites outside the right TIR correspond to the 5'-ends of the major open reading frames (ORFs) T1 to T9 plus the SFV growth factor gene. The 3 other initiation sites map within ORFs but near potential start codons for shorter polypeptides. All the expressed ORFs are tandemly arranged and transcribed toward the hairpin terminus. At early times during SFV infection of cultured rabbit cells, transcription of each ORF gives rise to a transcript of distinct size, while at late times termination of transcription is imprecise and substantial read-through into downstream sequences occurs. These results are discussed in light of recent observations on the related recombinant leporipoxvirus, malignant rabbit fibroma virus, which suggest that one or more gene products from this region of the SFV genome are implicated in viral tumorigenicity.

Mapping and sequencing of a gene from myxoma virus that is related to those encoding epidermal growth factor and transforming growth factor alpha

Myxoma virus, a Leporipoxvirus and agent of myxomatosis, was shown to possess a gene with the potential to encode an epidermal growth factorlike factor. Its relationship to other members of this family, including the poxvirus growth factors from Shope fibroma virus and vaccinia virus, was analyzed. Alignment of DNA sequences and related open reading frames of myxoma virus and Shope fibroma virus indicated colinearity of genes between these poxviruses.