Antiviral activities of hybrids of two major human leukocyte interferons

Regulatory T cells as central regulators of both autoimmunity and B cell malignancy in New Zealand Black mice

Regulatory T cells (Tregs) play an important role in protection against autoimmune disease and are also known to be potent inhibitors of anti-tumor immune responses. The New Zealand Black (NZB) mouse is a murine model for both autoimmune diseases, since high levels of autoantibodies are present, and human CLL, due to the expansion of malignant B-1 cells. In this study, we examined the functional role of CD4(+)CD25(+) Foxp3(+) Tregs in these different manifestations. Flow cytometric analysis showed increased levels of Tregs in NZB mice compared to healthy C57Bl/6 controls. Aged NZB mice that have developed a B-1 cell malignancy identified as IgM(+)CD5(+), have the most pronounced increase in Tregs. Ex vivo treatment of splenocytes from NZB mice with IFN-alpha resulted in a decrease in the frequency of Tregs and malignant B-1 cells. In vivo treatment of both NZB and C57Bl/6 mice with poly (I:C), a potent inducer of IFN-alpha, also led to a decrease in the levels of Tregs and malignant B-1 cells (NZB only) while amplifying autoimmune manifestations. These results indicate that while high levels of Tregs found in NZB mice might suppress a more severe autoimmune disease, they may also contribute to the development of the B cell malignancy.

Mutation of the IFNAR-1 receptor binding site of human IFN-alpha2 generates type I IFN competitive antagonists

Type I interferons (IFNs) are multifunctional cytokines that activate cellular responses by binding a common receptor consisting of two subunits, IFNAR-1 and IFNAR-2. Although the binding of IFNs to IFNAR-2 is well characterized, the binding to the lower affinity IFNAR-1 remains less well understood. Previous reports identified a region of human IFN-alpha2 on the B and C helices ("site 1A": N65, L80, Y85, Y89) that plays a key role in binding IFNAR-1 and contributes strongly to differential activation by various type I IFNs. The current studies demonstrate that residues on the D helix are also involved in IFNAR-1 binding. In particular, residue 120 (Arg in IFN-alpha2; Lys in IFN-alpha2/alpha1) appears to be a "hot-spot" residue: substitution by alanine significantly decreased biological activity, and the charge-reversal mutation of residue 120 to Glu caused drastic loss of antiviral and antiproliferative activity for both IFN-alpha2 and IFN-alpha2/alpha1. Mutations in residues of helix D maintained their affinity for IFNAR-2 but had decreased affinity for IFNAR-1. Single-site or multiple-site mutants in the IFNAR-1 binding site that had little or no detectable in vitro biological activity were capable of blocking in vitro antiviral and antiproliferative activity of native IFN-alpha2; i.e., they are type I IFN antagonists. These prototype IFN antagonists can be developed further for possible therapeutic use in systemic lupus erythematosus, and analogous molecules can be designed for use in animal models.

Interferon alfacon-1 protects hamsters from lethal pichinde virus infection

Hemorrhagic fever of arenaviral origin is a frequently fatal infectious disease of considerable priority to the biodefense mission. Historically, the treatment of arenaviral infections with alpha interferons has not yielded favorable results. Here we present evidence that interferon alfacon-1, a nonnaturally occurring bioengineered alpha interferon approved for the treatment of chronic hepatitis C, is active against Pichinde and Tacaribe arenaviruses in cell culture. In the hamster model of Pichinde virus (PCV) infection, interferon alfacon-1 treatment significantly protected animals from death, prolonged the survival of those that eventually died, reduced virus titers, and limited liver damage characteristic of PCV-induced disease. Moreover, interferon alfacon-1 also demonstrated therapeutic activity, to a lesser degree, when the initiation of treatment was delayed up to 2 days post-virus challenge. Despite the observed advantages of interferon alfacon-1 therapy, efforts to stimulate the immune system with the known interferon inducer poly(I:C12U) (Ampligen) offered only limited protection against lethal PCV challenge. Taken together, these data suggest that the increased potency of the bio-optimized interferon alfacon-1 molecule may be critical to the observed antiviral effects. These data are the first report demonstrating efficacious treatment of acute arenaviral disease with alpha interferon therapy, and further study is warranted.

The biological effects of five feline IFN-alpha subtypes

IFN-alpha has been shown to induce both antiviral and antiproliferative activities in animals. This report describes the biological activity of five recently identified feline IFN-alpha subtypes expressed in the Chinese hamster ovary (CHO) cell line (rfeIFN-alpha1[CHO], rfeIFN-alpha2[CHO], rfeIFN-alpha3[CHO], rfeIFN-alpha5[CHO] and rfeIFN-alpha6[CHO]) and the feIFN-alpha6 subtype expressed in and purified from Pichia pastoris (rfeIFN-alpha6[P. pastoris]). The rfeIFN-alpha[CHO] subtypes were tested for antiviral activity against either Vesicular stomatitis virus (VSV) or feline calicivirus (FCV) infected feline embryonic fibroblast cell line (AH927) or Crandell feline kidney cell line (CRFK). Antiviral activity was induced against both VSV and FCV infected AH927 cells and VSV infected CRFK cells by all five of the rfeIFN-alpha[CHO] subtypes and rfeIFN-alpha6[P. pastoris]. In addition, the IFN-alpha inducible Mx gene (associated with antiviral activity) was upregulated in vivo 24 h following treatment with rfeIFN-alpha6[P. pastoris], compared to baseline levels seen prior to treatment. All of the rfeIFN-alpha[CHO] subtypes and rfeIFN-alpha6[P. pastoris] exhibited antiproliferative activity in the FeT-J cell line (an IL-2 independent feline T-cell line). Both necrosis and apoptosis were observed in rfeIFN-alpha6[P. pastoris]-treated FeT-J cells. The rfeIFN-alpha3[CHO] subtype consistently exhibited lower antiviral and antiproliferative activity compared to that observed with the other four rfeIFN-alpha[CHO] subtypes. In summary, this paper demonstrates that five previously described feIFN-alpha subtypes induce both antiviral and antiproliferative activities in vitro and are capable of upregulating the feMx gene in vivo.

Cloning, expression, purification, and biological activity of five feline type I interferons

Type I interferons (IFN) are important mediators of the host defense against viral infections in mammals. In humans multiple subtypes of IFN-alpha exist, most of which possess antiviral activity. Little is known about the type I IFN genes in cats and the role they may play in feline immunological responses to viruses. We have isolated cDNAs encoding five feline IFN-alpha (feIFN) subtypes that share from 95 to 99% amino acid sequence identity. FeIFN-alpha5 has five additional amino acids inserted at position 139, which are not present in the other four subtypes. Sequence identity of the feIFN proteins encoded by the five clones compared to human IFN-alpha2 is approximately 60%. Unlike most of the human subtypes, each of the five feline IFN sequences has an N-glycosylation recognition site. Expression of all five feIFN-alpha subtypes in Chinese hamster ovary (CHO) cells was confirmed by Western blot analysis, and all resulting proteins were glycosylated. The antiviral activity of each feIFN-alpha subtype produced in transiently transfected CHO cell cultures was tested in vitro. In addition, subtype feIFN-alpha6 was expressed in the yeast, Pichia pastoris. The resulting secreted mature recombinant protein was purified and demonstrated significant antiviral activity and induction of 2',5'-oligoadenylate synthetase activity in vitro.

The type I interferon receptor: structure, function, and evolution of a family business

Recent results indicate that coherent models of how multiple interferons (IFN) are recognized and signal selectively through a common receptor are now feasible. A proposal is made that the IFN receptor, with its subunits IFNAR-1 and IFNAR-2, presents two separate ligand binding sites, and this double structure is both necessary and sufficient to ensure that the different IFN are recognized and can act selectively. The key feature is the duplication of the extracellular domain of the IFNAR-1 subunit and the configurational geometry that this imposes on the intracellular domains of the receptor subunits and their associated tyrosine kinases.

The interferon-inducible 204 gene, a member of the Ifi 200 family, is not involved in the antiviral state induction by IFN-alpha, but is required by the mouse cytomegalovirus for its replication

To examine whether Ifi 200 genes are involved in antiviral state induction by IFNs we expressed mutant forms capable of inactivating the endogenous p204 and analyzed replication of both RNA and DNA viruses following IFN-alpha treatment. Inactivation of p204 does not impair replication of vesicular stomatitis virus, encephalomyocarditis virus, ectromelia virus, and herpes simplex virus 1 and does not alter an IFN-alpha induced antiviral state. By contrast, in cells lacking functional p204, mouse cytomegalovirus (MCMV) replication is strongly inhibited and is not further modulated by IFN-alpha. These results suggest that p204, a member of the Ifi 200 gene family, is not involved in the IFN-alpha-induced antiviral activity against some RNA or DNA viruses, but is required by MCMV for its replication.

The antiproliferative activity of the murine interferon-inducible Ifi 200 proteins depends on the presence of two 200 amino acid domains

Interferon-inducible proteins, p200, have a modular organization consisting of one (p203) or two (p202 and p204) 200 amino acid motifs, designated as type a or b domains. The relationship between this domain organization and the antiproliferative activity was investigated by generating a hybrid protein with the 204 a domain upstream from the 203 b domain. This 204a/203b protein inhibits the proliferation of transfected cells, delays G0/G1 progression into S phase following serum restimulation, and inhibits the E2F-mediated transcriptional activity. These results demonstrate for the first time that both a and b domains are needed for inhibition of proliferation by the Ifi 200 proteins.

In vitro and in vivo expression analysis of the interferon-inducible 203 gene

The interferon (IFN)-inducible protein family 200 is encoded by structurally related genes located on mouse chromosome 1. The encoded proteins so far characterized and designated p202, p204, and pD3 contain at least one copy of a conserved 200 amino acid domain in addition to other regions that are different or missing among the various family members. We have recently characterized a cDNA clone (203 cDNA) encoding a 408 amino acid protein bearing structural similarities to p202 and p204. Here, we report its pattern of expression in vitro and in vivo. In vitro, the mRNA and protein encoded by the 203 gene were increased by IFN-alpha in several cell lines of different histologic origin. By contrast, no significant induction was observed in vivo in mice from C57BL/6 and BALB/c strains even after treatment with the IFN-inducer poly rI:rC. In addition, the constitutive expression of 203 gene was restricted to some myeloid and lymphoid tissues, namely, thymus, bone marrow, and spleen. Comparison of the expression pattern of the 203 and 202 genes in three mouse strains revealed that they exhibit a differential inducibility by IFN and a reciprocal expression pattern. The 203 mRNA was constitutively expressed in C57BL/6 and BALB/c mice and undetectable in the spleen of DBA/2 mice. The 202 mRNA was strongly induced by poly rI:rC in the spleen of DBA/2 and BALB/c mice but absent in C57BL/6 mice. Southern analysis revealed a restriction fragment length polymorphism in the 203 locus. Taken as a whole, these results demonstrate a remarkable difference in the in vivo IFN responsiveness of two members belonging to the same gene family with a similar degree of IFN inducibility in vitro. Moreover, the reciprocal expression pattern in C57BL/6 and DBA/2 mice could mean that p203 and p202 play the same role in a mouse strain in which only one of them is expressed.

Interferons Alpha, Beta, and Omega

Interferon alpha (IFN-α) is a mixture of closely related proteins, termed “subtypes,” expressed from distinct chromosomal genes. Interferon β (IFN-β) is a single protein species and is molecularly related to IFN-α subtypes, although it is antigenically distinct from them. IFN omega (IFN-ω) is antigenically distinct from IFN-α and IFN-β but is molecularly related to both. The genes of three IFN subtypes are tandemly arranged on the short arm of chromosome 9. They are transiently expressed following induction by various exogenous stimuli, including viruses. They are synthesized from their respective mRNAs for relatively short periods following gene activation and are secreted to act, via specific cell surface receptors, on other cells. IFN-α subtypes are secreted proteins and as such are transcribed from mRNAs as precursor proteins, pre-IFN-α, containing N-terminal signal polypeptides of 23 hydrophobic amino acids (aa) mainly. Pre-IFN-β contains 187 aa, of which 21 comprise the N-terminal signal polypeptide and 166 comprise the mature IFN-β protein. IFN-ω contains 195 aa—the N-terminal 23 comprising the signal sequence and the remaining 172, the mature IFN-ω protein. At the C-terminus, the aa sequence of IFN-ω is six residues longer than that of IFN-α or IFN-β proteins. IFN-α, as a mixture of subtypes, and IFN-ω may be produced together following viral infection of null lymphocytes or monocytes/macrophages. The biological activities of IFNs are mostly dependent upon protein synthesis with selective subsets of proteins mediating individual activities. IFNs can also stimulate indirect antiviral and antitumor mechanisms, depending upon cellular differentiation and the induction of cytotoxic activity.

Molecular cloning and expression of an interferon-inducible protein encoded by gene 203 from the gene 200 cluster

We report here the complete coding sequence of a 203 cDNA, a member of the interferon-inducible Ifi 200 gene family. By combining reverse-transcriptase PCR and rapid amplification of cDNA ends (RACE) techniques we have obtained a 3.8-kb cDNA corresponding to a 203 mRNA. When used as a probe in northern analysis, its 3' segment hybridized to a 3.8-kb interferon-inducible mRNA, whereas the 5'-end additionally hybridized to a less abundant interferon-inducible 1.8-kb mRNA. Nucleotide sequence analysis revealed that the two mRNAs share the 5'-untranslated region and the same open reading frame, which encodes a hydrophilic protein composed of 408 amino acids. The difference between them is due to a 3'-untranslated region extended by alternative polyadenylation site selection. Furthermore, 203 mRNA was found to be inducible by interferon-alpha in various murine cell lines. Using polyclonal antibodies raised against a segment specific for the 203 protein, we established that p203 protein levels increase on treatment with interferon-alpha in murine fibroblasts and that p203 is located in the nucleus.

Isolation, properties and chromosomal localization of four closely linked hamster interferon-alpha-encoding genes

Three recombinant phages containing hamster interferon-alpha-encoding genes (Ha Ifa) were isolated from a Ha genomic library, using a murine (Mu) Ifa probe. The phage inserts contained overlapping genomic fragments which span a total length of approx. 30 kb, on which four Ha Ifa genes are localized. The Ifa gene cluster could be assigned to hamster chromosome 2q. The nt sequences of the four Ifa genes were determined. Two of the genes are functional (Ha Ifa-1 and Ifa-3) and two are pseudogenes (Ifa-ps2 and Ifa-ps4). Ha Ifa-1 and -3 were transiently expressed in COS cells and they gave rise to protein products (A1 and A3, respectively) with antiviral properties on hamster CHO cells. In addition, Ha A1 revealed high antiviral activity on murine L929 cells.

Interferon-alpha hybrids

The alpha-interferons (IFN-alpha) belong to a family of polypeptides comprising several subtypes. Using recombinant DNA technology, it has been possible to create IFN hybrids that provide novel combinations of the amino acid residues from the parental protein sequences. They have been used to study structure-activity relationships of IFN-alpha and interactions with the IFN-alpha receptor, and to create analogs of natural IFNs with novel properties for potential therapeutic application. The biological data obtained with these hybrids are now evaluated in terms of the published structural and homology models of IFN-beta and -alpha.

Neuroendocrine effects of interferon-alpha in the rat

We have previously found that recombinant human interferon-alpha 2A (rHu-IFN-alpha 2A) inhibits hypothalamo-pituitary-adrenocortical (HPA) axis activity following both peripheral and central administration. This effect is antagonized by mu-opioid receptor antagonists, suggesting transduction by this subtype of opioid receptors. We have now demonstrated that this effect is also observed with hybrid rHu-IFN-alpha A/D, rat kidney fibroblast-derived IFN-alpha, and recombinant rat IFN-alpha preparations. The inhibitory effects on HPA activity were observed after intraperitoneal (i.p.) injections of rHu-IFN-alpha2A(10(03)U), rHu-IFN-alpha A/D (10(4)U), and of Rat-IFN-alpha (1-10U). Similar effects were observed with intracerebroventricular (i.c.v.) administration of all four IFN-alpha preparations. No increases in plasma corticosterone concentrations were observed with doses of rHu-IFN-alpha A/D up to 10(6)U (i.p.) or 7x10(5)U (i.c.v.), but increases were found following i.c.v. administration of high doses of Rat-IFN-alpha (10(3) and 5x10(3)U). The inhibitory effects of all of the IFN-alpha preparations tested were antagonized by naloxone, but the stimulatory effects of 5x10(3)U Rat-IFN-alpha were not. Injections of rHu-IFN-alpha 2A(10(4)U, i.p.) to urethane-anesthetized rats decreased the electrical activity of the majority of hypothalamic paraventricular nucleus (PVN) neurons tested, including putative corticotropin-releasing factor-(CRF)-secreting neurons antidromically identified as projecting to the median eminence. Similarly, iontophoretic application of rHu-IFN-alpha 2A decreased the electrical activity of such cells. These electrophysiological data suggest that the decreases in HPA activity evoked by IFN-alpha are mediated, at least in part, by a rapid inhibitory effect at the level of the corticotropin-releasing factor-secreting neurons.

HPV replication in experimental models: effects of interferon

Preclinical evaluation of the effectiveness of interferon (IFN) therapy on human papillomaviruses (HPV) has been hampered by the inability to propagate these viruses in cell culture. Nonetheless, interferon is used extensively in the treatment of HPV infections. Alpha interferons in particular have found a place in the treatment of anogenital disease, plantar warts, and laryngeal papillomas. While their is significant clinical evidence to suggest that interferon is useful in therapy of disease, the cellular mechanism(s) (i.e., antiviral, antiproliferative, immunomodulatory) by which IFN is able to control HPV-induced pathology is not well understood. This review focuses on experimental animal and cell culture models which are currently being used to help identify the antiviral, antiproliferative and immunomodulatory effects of IFN on HPV infection.

Interferon induces sleep and other CNS responses in mice recovering from hexobarbital anesthesia

Immediately after recovery from hexobarbital anesthesia, mice were injected intraperitoneally with one of the following interferons: natural mouse alpha/beta, recombinant mouse (rmouse gamma IFN-A) or human alpha A, alpha D, alpha AD interferon (rHu alpha IFN-A, rHu alpha IFN-D, rHu alpha IFN-AD). All of these interferons, except rHu alpha IFN-A induced unconsciousness ("sleep"); all produced stimulatory effects that mimicked those produced by morphine in the mouse. Quantification of the duration of sleep, induced by rmouse gamma IFN, was investigated and found to be dose-related. Only 3 of the 5 interferons (mouse alpha/beta IFN; rmouse gamma IFN, rHu alpha IFN-AD) possesses antiviral activity and depresses the cytochrome P-450 system in the mouse, yet all 5 of the interferons produced CNS effects. This partition of effects, together with the very short latency of the interferon-induced CNS effects, shows that the CNS effects were mechanistically independent of the anti-viral and anti-cytochrome P-450 effects. This disparity of the actions of the interferons suggests the possibility that selected morphine antagonists could be used to counter some of the dose-limiting CNS effects of the large doses of interferons used in clinical situations.

Molecular deletion of 9p sequences in non-small cell lung cancer and malignant mesothelioma

Previously we have reported non-random cytogenetic abnormalities involving the short arm of chromosome 9 (9P) in the majority of primary non-small cell lung cancer (NSCLC) patient samples, which indicated loss of DNA sequences. In another lung tumor, pleural malignant mesothelioma (MM), cytogenetic changes also include apparent deletions of 9p. To define the location and extent of deletions of 9p in NSCLC and MM, Southern blot analyses on six NSCLC and five MM cell lines using molecular probes to 9p loci (IFNA, IFNB1, D9S3, and D9S19) were performed, and DNA dosage was determined by densitometry. Our data demonstrated reduced dosage of 9p sequences in three of six NSCLC and four of five MM lines. A homozygous deletion of D9S3 was found in one NSCLC and one MM cell line. The region of common loss overlapped the D9S3 locus and was flanked by the IFNB1 and D9S19 loci. IFNB as previously been localized to 9p22, and the D9S3 and D9S19 loci have been mapped in this study by in situ hybridization to 9p21 and 9p13, respectively. We hypothesize the existence of one or more tumor suppressor genes on 9p with a role in the development or progression of NSCLC and MM.

Structural, functional and evolutionary implications of the three-dimensional crystal structure of murine interferon-beta

The crystal structure of recombinant murine interferon-beta as elucidated by Senda et al. (Proc. Jap. Acad. 66B: 77-80 (1990); EMBO J. 11: 3193-3201 (1992)) appears to represent the basic structural framework of all Type I interferons including interferons-beta and all subtypes of interferons-alpha of various mammalian origin. Now the huge accumulated data on the structure-activity relationship of Type I interferons using various chemical and genetic techniques can be systematically evaluated in terms of the three-dimensional structure. Structural comparison with other cytokines, for which three-dimensional structures have been established, including interferon-gamma and considerations on the evolution of cytokines and cytokine receptors are also given.

Signal transduction mediated by growth hormone receptor and its chimeric molecules with the granulocyte colony-stimulating factor receptor

The granulocyte colony-stimulating factor receptor (G-CSF-R) and growth hormone receptor (GH-R) belong to the cytokine receptor family and have some similarity in the cytokine receptor-homologous (CRH) domain of the extracellular region. Among members of this family, the G-CSF-R and GH-R seem to function as homodimers. Previously, we showed that mouse myeloid precursor FDC-P1 cells expressing the G-CSF-R can respond to G-CSF for growth. Here we show that the GH-R can also transduce the growth signal in FDC-P1 cells in the range 10 pM-100 nM GH. At a higher concentration of GH, GH did not promote the growth of the transformant cells. A series of chimeric receptor cDNAs between the G-CSF-R and GH-R cDNAs was constructed by exon swapping and was expressed in FDC-P1 cells. A ligand-binding assay with transformants expressing chimeric receptors indicated that the entire CRH domain is necessary for specific binding of the ligand. Although the transmembrane and cytoplasmic regions of the G-CSF-R and GH-R have no apparent similarity, these regions were interchangeable, resulting in growth-signal transduction in FDC-P1 cells.

Structure/function studies of murine interferon-alpha 1 using site-directed mutagenesis followed by in vitro synthesis

Site-directed in vitro mutagenesis followed by in vitro transcription and translation has been used to study structure/function relationships for murine interferon-alpha 1 (MuIFN-alpha 1). The mature form of the MuIFN-alpha 1 protein was expressed as well as analogue forms with amino acid substitutions at positions 33, 71, 72, 123 and 133. These positions were chosen on the basis of known human interferon-alpha structure/function relationships. Biological assays for antiviral activity on murine cells and natural killer cell activation have been performed for each of the proteins produced. The data obtained have been interpreted in the light of previous human and murine interferon-alpha structure/function work and the recently published three-dimensional structure of murine type I interferon.

Interferon action: binding of viral RNA to the 40-kilodalton 2'-5'-oligoadenylate synthetase in interferon-treated HeLa cells infected with encephalomyocarditis virus

The 40-kDa 2'-5'-oligoadenylate [(2'-5') (A)n] synthetase isoenzyme was proven to be a mediator of the inhibition of encephalomyocarditis virus (EMCV) replication by interferon (IFN). When activated by double-stranded RNA, this enzyme converts ATP into 2'-5'-oligoadenylate [(2'-5') (A)n], and (2'-5') (A)n was found to accumulate in IFN-treated, EMCV-infected cells. The only known function of (2'-5') (A)n is the activation of RNase L, a latent RNase, and this was also implicated in the inhibition of EMCV replication. Intermediates or side products in EMCV RNA replication, presumed to be partially double stranded, were shown to activate (2'-5') (A)n synthetase in vitro. These findings served as the basis of the long-standing hypothesis that the activator of (2'-5') (A)n synthetase in IFN-treated, EMCV-infected cells is the viral RNA. To test this hypothesis, we have generated a polyclonal rabbit antiserum to the human 40-kDa (2'-5') (A)n synthetase. The antiserum immunoprecipitated, from IFN-treated HeLa cells that had been infected with EMCV, the 40-kDa (2'-5') (A)n synthetase protein in complex with both strands of EMCV RNA. The immunoprecipitate was active in (2'-5') (A)n synthesis even without addition of double-stranded RNA, whereas the immunoprecipitate from IFN-treated, uninfected cells was not. These and other results demonstrate that in IFN-treated, EMCV-infected cells, viral RNA is bound to the (2'-5') (A)n synthetase and suggest that the agent activating the (2'-5') (A)n synthetase is the bound viral RNA.

Structure-function studies of human interferons-alpha: enhanced activity on human and murine cells

To identify functionally important regions of the human interferon (IFN)-alpha molecule, mutagenesis in vitro of human IFN-a genes was used to create analogs with deletions or specific amino acid replacements. These analogs were expressed in vitro using SP6 RNA polymerase and a rabbit reticulocyte lysate protein synthesis system. Deletion of 7 highly conserved hydrophilic amino acids from the C-terminus of human IFN-alpha 4 reduced, but did not abolish, antiviral activity on human cells. However, analogs with deletions of 15 or 25 amino acids from the C-terminus, or 28 amino acids from the N-terminus, had no measurable antiviral activity. The antiviral activity of human IFN-alpha 4 was increased by substitution of cysteine for serine at position 86, and lysine for arginine at position 121. However, other amino acid substitutions at positions 121, 122 or 123 reduced antiviral activity. The size of the side chain of the amino acid residue at position 130 was shown to be important. Replacement of the absolutely conserved leucine residue at position 131 with glutamine had little effect on antiviral activity. However, the introduction of a proline residue at this position abolished antiviral activity, probably due to the formation of a beta turn in the polypeptide chain. The antiviral activity of human IFN-alpha 4 on murine cells was increased by substitutions at positions 86, 121 and 133. This study illustrates the utility of the in vitro mutagenesis and rabbit reticulocyte lysate systems for the investigation of structure-function relationships, and extends our knowledge of the biologically active regions and species specificity of the human IFN-alpha molecule.

Generation of hybrid genes and proteins by vaccinia virus-mediated recombination: application to human immunodeficiency virus type 1 env

The ability of poxviruses to undergo intramolecular recombination within tandemly arranged homologous sequences can be used to generate chimeric genes and proteins. Genes containing regions of nucleotide homology will recombine to yield a single sequence composed of portions of both original genes. A recombinant virus containing two genes with a number of conserved regions will yield a population of recombinant viruses containing a spectrum of hybrid sequences derived by recombination between the original genes. This scheme has been used to generate hybrid human immunodeficiency virus type 1 env genes. Recombinant vaccinia viruses that contain two divergent env genes in tandem array have been constructed. In the absence of selective pressure to maintain both genes, recombination between conserved homologous regions in these genes generated a wide range of progeny, each of which expressed a novel variant polypeptide encoded by the newly created hybrid env gene. Poxvirus-mediated recombination may be applied to map type-specific epitopes, to create novel pharmaceuticals such as hybrid interferons, to study receptor-binding or enzyme substrate specificities, or to mimic the antigenic diversity found in numerous pathogens.

Characterization of the binding of radioiodinated hybrid recombinant IFN-alpha A/D to murine and human lymphoid cell lines

The hybrid recombinant human interferon (IFN) rIFN-alpha A/D was radioiodinated. Specific binding of [125I]rIFN-alpha A/D was observed with both human and murine cell lines. The binding of [125I]rIFN-alpha A/D to human Daudi cells had similar characteristics to the previously described binding of [125I]rIFN-alpha A or -alpha 2. The following lines of evidence demonstrated that [125I]rIFN-alpha A/D bound with high affinity to the same receptor on murine cells as murine IFN-alpha and -beta: (i) the binding of [125I]rIFN-alpha A/D to murine LBRM cells was inhibited to a similar extent by natural murine IFN-alpha, natural murine IFN-beta, and rIFN-A/D; (ii) the Kd (approximately 2 X 10(-10) M) obtained from both competition experiments and saturation binding experiments with [125I]rIFN-alpha A/D was comparable to the previously reported Kd for the binding of natural murine IFN-alpha and -beta to other murine cell lines; (iii) the size of the cross-linked [125I]rIFN-alpha A/D receptor complex formed on murine LBRM cells was similar to the previously reported cross-linked complex formed after binding radioiodinated natural murine IFN-beta to other murine cell lines. Due to the current lack of readily available recombinant murine IFN-alpha or -beta for radiolabeling and the previously demonstrated biological activity of rIFN-alpha A/D on murine cells, [125I]rIFN-alpha A/D should prove to be a useful reagent for further studies of murine IFN receptors.

From cloning to a commercial realization: human alpha interferon

Recent applications of recombinant DNA techniques have enabled the cloning of several interesting human genes, leading to the production of rare biologicals in abundant quantities. We review here the discovery, early characterization, cloning, and expression of Interferon Alfa-2B (IFN alpha-2b or Intron A) as a therapeutic at Schering-Plough Research. IFN alpha-2a is marketed by Hoffman LaRoche under the trade name Roferon. The studies on the expression, purification, biology, and clinical aspects of this interferon offer a plethora of information on one of the earliest recombinant DNA based drugs to reach the market place.

The biological activity of interferon alpha is influenced by two distinct regions in the protein

With the aim to assign differences in activity between murine interferon-alpha 1 and -alpha 4 to specific amino acids, we have constructed hybrid genes and analysed the antiviral properties of the corresponding hybrid proteins. The hybrid genes were constructed by means of homologous recombination between the alpha 1 and alpha 4 genes in Escherichia coli. Hybrids in which the N-terminal part is derived from alpha 1 show that two regions have a major effect on the activity: amino acid 10-20 and 55-67. When comparing hybrids with N-terminal alpha 4 sequences, transitions in activity are found in the same regions. Interestingly, the curves for the two sets of hybrids are exactly each others mirror image.

Functional significance of amino acid residues within conserved hydrophilic regions in human interferons-alpha

Site-directed in vitro mutagenesis was used to create analogs of human interferons (IFNs)-alpha 1 and -alpha 4. Analogs were expressed in vitro using SP6 RNA polymerase and a rabbit reticulocyte lysate cell-free protein synthesis system. Amino acid substitutions for the highly conserved residues at positions 33, 121, 122 and 123 greatly reduced the antiviral and antiproliferative activities on human cells of IFNs-alpha 1 and -alpha 4. In general, the amino acid substitutions had much less effect on the antiviral activities on bovine, compared with human, cells. Substitutions at positions 31, 41, 42, 124, 134, 135 and 136 had little or no effect on the biological activities of the IFN analogs. The abrogation of antiviral activity resulting from amino acid substitutions for the arginine residue at position 33 suggests that this arginine residue is required for binding to the IFN-alpha receptor on the cell surface.

The cellular receptor of the alpha-beta interferons

This is a selective review of recent trends in research on the cellular receptor for the alpha-beta interferons. It deals mainly with work published in the last three years (1985-88), and therefore mainly with receptors for the human interferons. The binding characteristics of several human alpha interferons are examined, and the importance of in vitro experimental models for establishing the relationship between receptor binding and the cellular response is emphasized.

Antiviral activity of a novel recombinant human interferon-alpha B/D hybrid

The antiviral potential of a novel cross-species active, recombinant human interferon-alpha B/D hybrid (rHuIFN-alpha B/D), was evaluated for its efficiacy in cultured human monocytes and in several murine models of viral disease. When examined in 14-day-old human monocyte cultures, rHuIFN-alpha B/D was highly effective in preventing viral replication and cell destruction caused by herpes simplex virus type 1 (HSV-1/VR3). The effect observed with 100 units of this hybrid IFN was as good or higher than that observed with equivalent amounts of rHuIFN-alpha A or IFN-gamma. In addition, a single dose (5 X 10(7) U/kg) of rHuIFN-alpha B/D administered several hours after intranasal infection with HSV-1/VR3 suppressed pulmonary virus replication and prevented death due to interstitial pneumonia. Similarly, mice infected with a more aggressive strain of HSV-1 (McIntyre) were protected when this IFN preparation was administered at the time of virus infection and 1 day later. The anti-retroviral activity of rHuIFN-alpha B/D was examined in two murine leukemia retroviral models, Rauscher (RMLV) and Friend (FMLV), and a murine model of acquired immunodeficiency (LP-BM5). Treatment of RMLV or FMLV infected mice significantly prolonged mean survival times and the number of long-term FMLV survivors. These therapeutic effects were demonstrated when IFN was administered on the day of virus infection or as late as 3 days following infection. Transient reversal of the immunosuppressive effects induced by LP-BM5 infection was observed when rHuIFN-alpha B/D treatment was initiated at the time of virus infection. Moreover, when rHuIFN-alpha B/D was used together with azidothymidine (AZT), the effect of the combination was better than either drug alone.

Receptor and antibody epitopes in human growth hormone identified by homolog-scanning mutagenesis

A strategy, termed homolog-scanning mutagenesis, was used to identify the epitopes on human growth hormone (hGH) for binding to its cloned liver receptor and eight different monoclonal antibodies (Mab's). Segments of sequences (7 to 30 residues long) that were derived from homologous hormones known not to bind to the hGH receptor or Mab's, were systematically substituted throughout the hGH gene to produce a set of 17 chimeric hormones. Each Mab or receptor was categorized by a particular subset of mutant hormones was categorized by a particular subset of mutant hormones that disrupted binding. Each subset of the disruptive mutations mapped within close proximity on a three-dimensional model of hGH, even though the residues changed within each subset were usually distant in the primary sequence. The mapping analysis correctly predicted those Mab's which could or could not block binding of the receptor to hGH and further suggested (along with other data) that the folding of these chimeric hormones is like that of HGH. By this analysis, three discontinuous polypeptide determinants in hGH--the loop between residues 54 and 74, the central portion of helix 4 to the carboxyl terminus, and to a lesser extent the amino-terminal region of helix 1--modulate binding to the liver receptor. Homolog-scanning mutagenesis should be of general use in identifying sequences that cause functional variation among homologous proteins.

Hybrid bacillus endo-(1-3,1-4)-beta-glucanases: construction of recombinant genes and molecular properties of the gene products

Hybrid beta-glucanase genes were constructed by the reciprocal exchange of the two halves of the isolated beta-glucanase genes from Bacillus amyloliquefaciens and B. macerans. The beta-glucanase hybrid enzyme 1 (H1) contains the 107 amino-terminal residues of mature B. amyloliquefaciens beta-glucanase and the 107 carboxyl-terminal amino acid residues of B. macerans beta-glucanase. The reciprocal beta-glucanase hybrid enzyme 2 (H2) consists of the 105 amino-terminal residues from the B. macerans enzyme and the carboxyl-terminal 107 amino acids from B. amyloliquefaciens. The biochemical properties of the two hybrid enzymes differ significantly from each other as well as from both parental beta-glucanases. Hybrid beta-glucanase H1 exhibits increased thermostability in comparison to other beta-glucanases, especially in an acidic environment. This hybrid enzyme has maximum activity between pH 5.6 and 6.6, whereas the pH-optimum for enzymatic activity of B. amyloliquefaciens beta-glucanase was found to be at pH 6 to 7 and for B. macerans at pH 6.0 to 7.5. Hybrid enzyme 1 being more heat stable than both parental enzymes represents a case of intragenic heterosis. Hybrid beta-glucanase 2 (H2) was found to be more thermolabile than the naturally occurring beta-glucanases it was derived from and the pH-optimum for enzymatic activity was determined to be between pH 7 and pH 8.

The role of three domains in the biological activity of human interferon-alpha

Earlier studies showed that minor differences in primary structure among the interferon-alpha (IFN-alpha) protein family are reflected in their potency in selected biological assays. These studies have been extended and results from assays of antiviral, growth inhibitory and 2',5'-oligoadenylate (2-5A) synthetase activities indicate that the various novel hybrid and analog species are differentially biologically active. Overall these observations suggest a correlation between predicted secondary structure characteristics, receptor binding affinity, and 2-5A synthetase, antiviral and growth inhibitory activities. Studies with a consensus IFN-alpha analog particularly implicated the region around residues 78 and 79 as influencing antiviral activity. Neutralization experiments with a monoclonal antibody directed against a conserved region from residues 113 to 149 indicated that although this region of the IFN-alpha molecule may be important for antiviral activity, altering residues at sites removed from this region may reduce the effectiveness of the neutralizing antibody. Receptor binding experiments suggested that no single site at either the amino or carboxyl terminus of IFN-alpha alone determines receptor affinity or biological activity: apparently three distinct domains along IFN-alpha are involved (10-35, 78-107, 123-166). Overall, the data indicate that the three sites contribute toward the active configuration of human IFN-alpha.

Effect of recombinant hybrid human interferon on replication and morphogenesis of HSV-1 in monkey cells

Human recombinant alpha interferon, A/D, significantly reduced the replication and cell fusion induced by herpes simplex virus type 1 in monkey cells. Thin-section electron microscopy of interferon-treated monkey cells showed distinct assembly of nucleocapsids within the nucleus. Analysis of virus-specific proteins by the immunoblot technique confirmed that A/D interferon had no significant effect on the expression of major nucleocapsid proteins, although the expression of glycoproteins B and D was reduced in interferon-treated cells. The possibility of an interferon-induced block at a late stage in virus morphogenesis is discussed.

Purification and properties of a novel recombinant human hybrid interferon, delta-4 alpha 2/alpha 1

The human interferon (huIFN) delta-4 alpha 2(5-62)/alpha 1(64-166) is a genetically engineered hybrid that consists of residues 5-62 of huIFN alpha 2 and residues 64-166 of huIFN alpha 1. This variant contains four cysteine residues at positions 29, 86, 99 and 139, but does not contain the cysteine at position 1 that is characteristic of naturally occurring huIFN alpha subtypes. This novel recombinant hybrid was purified from Escherichia coli to greater than 95% homogeneity. The purification was based on ethanol extraction of a trichloroacetic acid precipitate and Matrex Gel Blue A chromatography followed by either a selective precipitation or DEAE-Sepharose chromatography. The purified protein that was treated with 2-mercaptoethanol exhibited two closely migrating bands on sodium dodecyl sulfate-polyacrylamide gel electrophoresis with apparent molecular weight values of 17,800 and 17,100, both of which exhibited antiviral activity. Electrophoresis performed without prior reduction with 2-mercaptoethanol indicated only a minor extent of intermolecular disulfide bonding. The purified protein exhibited a high specific antiviral activity of 7 x 10(7) units/mg when assayed on human fibroblast cells and, in distinction to the parental huIFN alpha 2, it also demonstrated antiviral activity on human fibroblast cells and, in distinction to the parental huIFN alpha 2, it also demonstrated antiviral activity on murine L929 cells. The level of antiproliferative activity of huIFN delta-4 alpha 2(5-62)/alpha 1(64-166) on various cell lines of different histological origin appeared to be more comparable to that of huIFN alpha 1 than huIFN alpha 2. The data suggest that huIFN delta-4 alpha 2(5-62)/alpha 1(64-166) hybrid may be a useful tool for understanding huIFN structure-function relations.

High-performance size-exclusion chromatography of recombinant derived proteins and aggregated species

The chromatographic behavior of some recombinant derived proteins and aggregated species was studied using high-performance size-exclusion chromatography (HPSEC). At neutral pH values, monomeric proteins exhibited non-ideal behavior while aggregated species were not eluted. As the pH was lowered below 5, both aggregated and monomeric species were eluted, with the amount of aggregated species increasing with decrease in pH. Final elution conditions selected for the simultaneous chromatography of monomeric and aggregated proteins were 0.1 M orthophosphoric acid, pH 2.5. The utility of the system was evaluated by determining the rates of protein degradation at elevated temperatures and comparing the results with those obtained using standard bioassay procedures. The rate of formation of aggregated species was also determined by HPSEC and corresponded to the rate of degradation of monomeric protein. The use of HPSEC with low pH eluent provides a rapid means for estimating protein stability under accelerated temperature conditions as well as for determining the existence and formation of aggregated species.

Electrostatic interactions in the cellular dynamics of the interferon-receptor complex

Using membrane preparations of the interferon receptor, prepared from cells of the Burkitt line, Daudi, we have examined the binding of three human recombinant alpha-interferons. 1. We discovered a binding titration of the interferons IFN-alpha A and IFN-alpha D in the pH range 6-9. Receptor binding, negligible at pH 6, rises to a maximum close to pH 9. We have shown that binding of IFN-alpha A at basic pH is to the same receptors as at neutrality and that IFN-receptor complexes extracted with digitonin are more stable at basic pH than they are at neutrality. 2. The recombinant interferon, IFN-alpha B, shows little change of binding in the pH range 6-9. At its basic optimum the binding of IFN-alpha A approaches that of IFN-alpha B, while at neutral pH the binding of IFN-alpha A is 3-4 times less. This difference at neutral pH is seen on intact cells as well as on membrane preparations. The specific activity of IFN-alpha B is close to that of IFN-alpha A, both of which are 10-20 times more active than IFN-alpha D; and the binding titration is, therefore, independent of the initial binding affinities. 3. Using hybrid IFNs constructed from the DNA sequences of alpha D and alpha B, we have isolated the sequence responsible for the binding titration to the segment comprising amino acids 61-92. Examination of these sequences reveals that Lys-84 is present in all the IFN-alpha except IFN-alpha B where it is replaced by Glu; and Tyr-90, present in most of the common IFN-alpha including alpha A and alpha D, is replaced by Asp in IFN-alpha B. Lys and Tyr would normally titrate in the pH range 6-9. We conclude that the binding titration is due to an electrostatic interaction and we propose that the interaction is between IFN-receptor complexes. The role of the interaction in the binding losses that accompany the antiproliferative effects of IFN is discussed.

Recombinant interferons alpha and gamma: comparative antiviral activity and synergistic interaction in encephalomyocarditis virus infection of mice

The antiviral properties of 2 recombinant DNA-produced interferons, a human hybrid interferon alpha that is active in mice and a murine interferon gamma, were examined in the treatment of mice infected with encephalomyocarditis virus. A single dose of interferon alpha induced a protective state in mice more rapidly than did interferon gamma, but the activity of the latter was more long lasting. When interferon and virus were administered 6 h apart, either intraperitoneally or intravenously, interferons alpha and gamma were equally effective. However, this was not the case when the routes of treatment and infection were different. Interferon alpha showed somewhat reduced activity when the route of administration (intravenous) was different from the route of virus challenge (intraperitoneal) while interferon gamma showed very little activity when tested in this manner. When interferons alpha and gamma were administered in combination to mice, a marked synergistic antiviral effect was observed.

Two domains in alpha interferons influence the efficacy of the antiviral response

Murine interferon-alpha 1 and murine interferon-alpha 4 share 80% of their amino acids, yet the proteins differ considerably in their ability to protect mouse or hamster cells against viral infection. With the aim of localizing areas within these proteins which influence the biological response we have constructed hybrid alpha 1 alpha 4 genes by means of homologous recombination of the parent genes. When the antiviral activities of these proteins were compared, it appeared that there are at least two domains that affect the biological response to these proteins: area A (amino acids 10-20) and area B (amino acids 55-67). These areas are presumably involved in the interaction between ligand and receptor. Most interestingly, hybrids in which area A from IFN-alpha 1 is combined with area B from alpha 4, have antiviral activities on homologous cells that are one to two orders of magnitude higher than those of the parent proteins.

Cloned human interferons alpha: differential affinities for polyinosinic acid and relationship between molecular structure and species specificity

The HuIFN-alpha A and HuIFN-alpha D interferons, produced by two independent recombinant bacterial clones, have different affinities for polyinosinic acid (poly I). The monomeric form HuIFN-alpha A (FMM), but not the HuIFN-alpha D, binds to poly (I)-agarose and is protected by poly (I) from thermal inactivation. Other subtypes of HuIFN-alpha A including the monomer SMM and oligomers have no affinity for this polynucleotide. In addition, these interferons show different target cell preferences in agreement with our previous suggestion (23) that the polynucleotide binding domain may be responsible for species specificity. Two significant observations are 1) the fractions of HuIFN-alpha D and HuIFN-alpha A unbound on poly (I)-agarose show higher antiviral inducing activity on heterologous (MDBK) than on homologous (WISH) cells, whereas they induce about the same activity of 2'5' oligoadenylate synthetase in these two cell lines. These fractions are also active on L929 cells. 2) The bound fraction of HuIFN-alpha A induces almost the same antiviral and 2'5' oligoadenylate synthetase activities in MDBK and in WISH cells but neither activity in L929 cells.

Chemical mutagenesis of human interferon-beta: construction, expression in E. coli, and biological activity of sodium bisulfite-induced mutations

A series of modified human interferon-beta (IFN-beta) genes was produced by sodium bisulfite treatment of the IFN-beta gene cloned in M13. A library of mutated sequences was generated from which subgenomic fragments containing one or a small number of coding alterations were isolated and substituted into the IFN-beta gene in an E. coli expression vector. A number of modified genes and their expression products were evaluated. In several instances levels of expression and biological activity profiles are altered compared to the parental gene product. A number of key amino acids can be identified, whose substitutions have marked effects on biological activity of IFN-beta.

Single amino acid changes that render human IFN-alpha 2 biologically active on mouse cells

Human IFN-alpha 1 and IFN-alpha 2 differ in 28 of 166 amino acids and show very different specific antiviral activities on human and murine cells. We have identified, by hybrid scanning and site-directed mutagenesis, three residues in IFN-alpha 2, in positions 121, 125 and 132 which, when replaced individually or jointly by their IFN-alpha 1 counterparts, modify its activity on mouse cells by up to 400-fold. We argue that these residues are involved in direct contacts with the mouse interferon receptor.

Effect of antiviral agents on replication of herpes simplex virus type 1 in brain cultures

An in vitro tissue culture system consisting of reaggregated embryonic brain cells was used to evaluate the inhibition of herpes simplex type 1 (HSV-1) by several antiviral compounds. The efficacy of acyclovir, vidarabine, bromovinyldeoxyuridine, and 9-(1,3-dihydroxy-2-propoxymethyl) guanine in HSV-1-infected Vero cell monolayer cultures was compared with that seen with brain cell aggregates. At a mean 50% inhibitory dose with Vero cells, acyclovir showed a 99% reduction of virus titer in brain cell aggregates. Vidarabine and 9-(1,3-dihydroxy-2-propoxymethyl) guanine gave a dose-dependent reduction in virus titer with Vero cells; however, in aggregate cultures treated with the same drugs a dose-dependent decrease at 24 h was followed by an increase to a point of no inhibition at 72 h postinfection. Pretreatment of brain cell aggregates with a hybrid human leukocyte interferon (Le IF-AD) reduced virus titers at 48 h postinfection but did not maintain this reduction at 72 h. In contrast, infected Vero cell monolayer cultures demonstrated a dose-dependent reduction in virus titers with Le IF-AD. Postinfection treatment with Le IF-AD did not reduce plaque formation in Vero cells but was effective in reducing virus titer in HSV-1-infected brain cell aggregates at 48 h postinfection. Antiviral concentrations of up to 200 micrograms or 200,000 IU/ml for interferon did not appear morphologically toxic to brain cells. Antiviral therapy of HSV-1-infected brain cell aggregates may more closely mimic in vivo responses than monolayer cultures.

Interferons and tumor necrosis factors have similar catabolic effects on 3T3 L1 cells

The effect of a variety of cytokines on lipid metabolism in 3T3 L1 mouse fibroblasts and adipocytes was studied. Uptake of [3H]acetate by adipocytes and heparin-releasable lipoprotein lipase activity was inhibited after treatments of the cells with picomolar concentrations of recombinant human tumor necrosis factor alpha (rHuTNF-alpha), human tumor necrosis factor beta (rHuTNF-beta, also called lymphotoxin), murine interferon-gamma (rMuIFN-gamma), and a human hybrid interferon-alpha [rHuIFN-alpha 2/alpha 1 (Bgl II)]. Recombinant human interferon-gamma (rHuIFN-gamma), natural human colony-stimulating factor (HuCSF), and human interleukin 2 (HuIL-2) had no effect. Similar though less-marked suppression of [3H]acetate uptake by cytokines was seen in 3T3 L1 fibroblasts. Cytokines inhibited the incorporation of [3H]acetate into both membrane and storage lipids in the adipocytes. In addition to blocking lipid uptake and synthesis, rHuTNF-alpha and -beta, and rMuIFN-gamma stimulated the release of free fatty acid into the medium from adipocytes. Binding studies suggest that rHuTNF-alpha and rHuTNF-beta compete for the same cell-surface receptor on 3T3 L1 adipocytes, while rMuIFN-gamma binds to a separate receptor. The binding of rTNF-alpha to both adipocytes and fibroblasts can be significantly enhanced by preexposure of the cells to rMuIFN-gamma. There appear to be both high- and low-affinity receptors for rHuTNF-alpha on adipocytes, whereas fibroblasts exhibit a single class of high-affinity receptors. These results suggest that a variety of structurally distinct cytokines possess lipid mobilization activity, which may be of critical importance to the host in defense against infection or malignancy.

Regulatory effects on macrophages of human recombinant interferons-alpha

The regulatory effects of human recombinant and hybrid interferons-alpha (IFN-alpha) on macrophage-mediated tumoricidal activity were examined. Recombinant hybrid IFN-alpha-A/D suppressed the capacity of murine interferon-gamma (IFN-gamma) to activate mouse peritoneal macrophages to a tumorilytic state, and blocked the killing of syngeneic syngeneic melanoma target cells by macrophages previously committed to the cytotoxic phenotype with a 4-h pretreatment with IFN-gamma. This suppressive activity was limited to IFN-alpha-A/D, as IFN-alpha-A and IFN-alpha-D were not effective. In contrast, IFN-alpha-A, -D, and -A/D were all capable of activating human peripheral blood monocytes to lyse human tumor cells. When encapsulated in liposomes, only IFN-alpha-A/D maintained its monocyte activating efficacy. These findings suggest that the immunomodulatory effects of IFN-alpha subtypes and hybrid molecules are dependent on species of monocytes/macrophages, subtype, and nature of presentation to effector cells.

Human interferons active on murine cells induce pulmonary cysts in A2G mice

Suckling A2G mice were injected daily from birth for 8 days with highly purified human lymphoblastoid interferon (IFN) or recombinant interferons-alpha 1 or -alpha 2 rIFN-alpha 1, rIFN-alpha 2), or mouse interferon-alpha/beta (IFN-alpha/beta), or control preparations. Only mouse IFN inhibited the growth of suckling A2G mice and induced liver cell necrosis. At 56 days the mice were killed and the lungs examined for the presence of pulmonary cysts. Human lymphoblastoid IFN and rIFN-alpha 1 (and mouse IFN-alpha/beta), which exhibited significant biological activity on mouse cells in culture, induced pulmonary cysts in A2G mice. rIFN-alpha 2, which showed little or no activity on mouse cells, did not induce pulmonary cysts.

Simultaneous synthesis of human-, mouse- and chimeric epidermal growth factor genes via 'hybrid gene synthesis' approach

Simultaneous synthesis of two DNA duplexes encoding human and mouse epidermal growth factors (EGF) was accomplished in a single step. A 174 b.p. DNA heteroduplex, with 16 single and double base pair mismatches, was designed. One strand encoded the human EGF, and the opposite strand indirectly encoded the mouse EGF. The heteroduplex DNA was synthesized by ligation of seven overlapping oligodeoxyribonucleotides with a linearized plasmid. After transformation in E. coli HB101 (recA 13), the resulting heteroduplex plasmid served as the template in plasmid replication. Two different plasmid progenies bearing either the human or mouse EGF-coding sequence were identified by colony hybridization using the appropriate probes. However, in E. coli JM103, the same process yielded plasmid progenies encoding different chimeric EGF molecules, presumably due to crossover of human and mouse EGF gene sequences.