Transcriptional activity of avian retroviral long terminal repeats directly correlates with enhancer activity

The molecular basis for host responses to Marek's disease viruses integrated with different retro-viral long terminal repeat

Integration of retro-viral long terminal repeat (LTR) into the Marek's disease virus (MDV) genome can occur both in co-cultivation cell cultures and naturally in dual infected chickens. It is clear that the LTR insert is associated with the pathogenicity of MDV. The objective of this study was to compare the host responses to MDV with a different retro-viral LTR insert. Gene-chip containing chicken genome was employed to investigate the gene transcription profile of chicken embryo fibroblasts cells, and 795 genes were differentially expressed in chicken embryo fibroblasts infected with GX0101 with a reticuloendotheliosis virus LTR insert as compared to GX0101-ALV-LTR significantly. The differentially expressed genes were mostly associated with the regulation of transcription and the development of multiple organs. Based on the bio functions of the differential genes, infection of GX0101 was predicated with a greater development disorder of multiple systems, resulting in higher growth retardation, mortality, tumorigenicity, and immunosuppression in chickens than GX0101-ALV-LTR. Collectively, our results provided valuable insights into elucidation of the possible relationship between retro-viral LTR insert and the observed phenotypes caused by MDV recombinant viruses.

Influence of avian leukosis virus long terminal repeat on biological activities of Marek's disease virus

GX0101 was the first reported field strain of recombinant Marek's disease virus (MDV) that contained a long terminal repeat (LTR) from the reticuloendotheliosis virus (REV). It is a very virulent MDV strain, with relatively high horizontal transmission ability. The REV LTR in GX0101 genome was proved to decrease the pathogenicity but increase the potential for horizontal transmission of the virus. Here we constructed a recombinant MDV GX0101-ALV-LTR to study stability of avian leukosis virus (ALV) LTR at the REV LTR insertion site in GX0101 genome and its influence on biological activities of the recombinant virus. The results showed that GX0101-ALV-LTR was able to replicate stably both in vitro and in vivo. ALV LTR remained stable in chickens infected either by inoculation with the recombinant virus GX0101-ALV-LTR or by horizontal transmission, as well as in cell culture. The pathogenic properties of GX0101-ALV-LTR virus were evaluated in infected specific-pathogen-free chickens. The present study demonstrated that the GX0101-ALV-LTR virus had a weaker inhibitory effect on the growth rates of the infected chickens and induced weaker immunosuppressive effects. Horizontal transmission ability of the GX0101-ALV-LTR virus appeared to be similar with its parental virus GX0101. In short, ALV LTR was stable in GX0101 after replacing REV LTR, and the recombinant virus showed similar horizontal transmission ability but decreased pathogenicity.

Detection and molecular characterization of recombinant avian leukosis viruses in commercial egg-type chickens in China

Two natural recombinant avian leukosis viruses (ALVs) were isolated from Chinese commercial egg-type chickens in 2009, which suffered from haemangiomas and myelocytomas. Sequence analysis of the complete proviral genomes revealed several unique genetic characteristics of the present two isolates, demonstrating that the two viruses were derived from recombination between earlier Chinese ALV-J and endogenous virus sequences. The two recombinant viruses presented typical genetic organization of replication-competent genus Alpharetrovirus, and the gag and pol genes were well conserved with those of ALVs. The env genes of the two viruses were composed of the internal identical sequences (about 240 bp) of endogenous viruses, and the rest of the sequence belonged to subgroup J ALVs. The long terminal repeats of the two viruses were more closely related to HPRS-103 and earlier Chinese ALV-J than other subgroup ALVs, and multiple transcription regulatory elements of ALV-J were highly conserved. In addition, the two viruses shared an almost identical 3'-untranslated region (UTR) sequence with earlier Chinese ALV-J strains and the US strain 4817, containing a ~127 bp deletion in the E element region. However, further comparison with endogenous ALV indicated that the 3'-UTR sequences with ~127 bp deletion of ALV-J were most probably derived from endogenous viruses by recombination. These results suggested that the two isolates can be characterized as recombinant ALV-J with the internal env gene and 3'-UTR sequence of endogenous ALV.

Molecular epidemiology of avian leukosis virus subgroup J and evolutionary history of its 3' untranslated region

Avian leukosis subgroup J (ALV-J) causes a variety of tumors and mortality in meat-type chickens. Since its discovery in the late 1980s, ALV-J has spread to breeding stock produced by most primary breeding companies of North America, the European Union, and Asia. ALV-J seems to have been eradicated from elite breeding stock produced by most primary breeders, albeit ALV-J still circulates in some commercial poultry. This study was undertaken to examine the molecular epidemiology and evolution of ALV-J detected in breeding stock and broiler chickens representing eight primary breeding companies over a period of approximately 20 yr (1988-2007). The redundant transmembrane region of the envelope gene has been deleted in some isolates, suggesting that this region is dispensable for viral fitness. Within the 3' untranslated region (3' UTR), the direct repeat 1 was present in 100% of the ALV-J isolates studied. In contrast, the E element has undergone substantial deletions in >50% of the ALV-J proviruses studied. Overall, the unique region 3 was the least conserved within the 3' long terminal repeat (LTR), albeit the transcriptional regulatory elements typical of avian retroviruses (CAAT, CArG, PRE, TATA, and Y boxes) were highly conserved. The direct repeat region of the LTR was identical in all of the proviruses, and the 3' unique region 5 was relatively well conserved. Thus, the 3' UTR of ALV-J has evolved rapidly, reflecting significant instability of this region. Some of the mutations in the 3' UTR have resulted in the emergence of moderately distinct genetic lineages representing each primary breeding company from which ALV-J was isolated.

VBP and RelA regulate avian leukosis virus long terminal repeat-enhanced transcription in B cells

The avian leukosis virus (ALV) long terminal repeat (LTR) contains a compact transcription enhancer that is active in many cell types. A major feature of the enhancer is multiple CCAAT/enhancer element motifs that could be important for the strong transcriptional activity of this unit. The contributions of the three CCAAT/enhancer elements to LTR function were examined in B cells, as this cell type is targeted for ALV tumor induction following integration of LTR sequences next to the c-myc proto-oncogene. One CCAAT/enhancer element, termed a3, was found to be the most critical for LTR enhancement in transiently transfected B lymphoma cells, while in chicken embryo fibroblasts all three elements contributed equally to enhancement. Gel shift assays demonstrated that vitellogenin gene-binding protein (VBP), a member of the PAR subfamily of C/EBP factors, is a major component of the nuclear proteins binding to the a3 CCAAT/enhancer element. VBP activated transcription through the a3 CCAAT/enhancer element, supporting the idea that VBP is important for LTR enhancement in B cells. A member of the Rel family of proteins was also identified as a component of the a3 protein binding complex in B cells. Gel shift and immunoprecipitation assays indicated that this factor is RelA. Gel shift assays demonstrated that while RelA does not bind directly to the LTR CCAAT/enhancer elements, it does interact with VBP to potentiate VBP DNA binding activity. The synergistic interaction of VBP and RelA increased CCAAT/enhancer element-mediated transcription, indicating that both factors may be important for viral LTR regulation and also for expression of many cellular genes.

Chicken YB-2, a Y-box protein, is a potent activator of Rous sarcoma virus long terminal repeat-driven transcription in avian fibroblasts

We have previously reported on the cloning and characterization of chk-YB-2, a novel member of the Y-box family of proteins, that binds to the sequence 5'-GTACCACC-3' present on the noncoding strand of the Rous sarcoma virus (RSV) long terminal repeat (LTR) in a single-strand-specific manner. Here, we demonstrate that deletion or mutation of this motif not only eliminates chk-YB-2 binding in vitro but also down-regulates RSV LTR-driven transcription in avian cells. Selective abrogation of chk-YB-2 expression by using antisense oligonucleotides decreased RSV LTR-driven transcription in a promoter-specific manner. This inhibition was not observed when a reporter construct with a deletion in the chk-YB-2 binding site was used. Depletion of cellular chk-YB-2 by transfecting the cells with excess of its recognition sequence oligonucleotides also resulted in reduced transcription from the RSV LTR. Taken together, these results suggest that chk-YB-2 acts as an activator of LTR-promoted transcription in avian cells and that this activation is mediated primarily through the sequence 5'-GTACCACC-3'.

Unique long terminal repeat U3 sequences distinguish exogenous jaagsiekte sheep retroviruses associated with ovine pulmonary carcinoma from endogenous loci in the sheep genome

Ovine pulmonary carcinoma (OPC) is a contagious lung cancer of sheep that is presumed to be caused by an exogenous retrovirus of sheep, jaagsiekte sheep retrovirus (JSRV). The sheep genome carries 15 to 20 copies of endogenous sheep retrovirus (ESRV) loci that hybridize to JSRV DNA probes. In order to clarity the etiologic roles of ESRV and an exogenous JSRV-like retrovirus (exJSRV) in OPC, we assessed sequence differences between ESRV and JSRV. Molecular characterization of six ESRV loci revealed restriction sites specific for JSRV. Nucleotide sequences of ESRVs from sheep of different breeds were similar to those of JSRV in structural genes but divergent in U3. Therefore, primers specific for the U3 sequences of exJSRV were designed for use in the PCR. Of 13 tumor DNAs tested by PCR with these exogenous-virus U3 primers, 8 produced DNA fragments that hybridized with the JSRV gag probe, but neither lung DNAs from healthy sheep nor DNAs from nontumor tissues of diseased sheep produced similar DNA fragments. exJSRV PCR products from tumor DNAs of sheep with OPC from three continents had restriction profiles similar to each other but different from those of ESRVs upon digestion with EcoRI, HindIII, NdeI, KpnI, and ScaI. These exjSRVs could be classified into two genotypes according to U3 sequences and restriction profiles. U3 sequences of exJSRV proviruses in tumors strongly resembled those of JSRV but differed from those of ESRVs, suggesting that exJSRVs, rather than ESRVs, are primarily associated with oncogenesis in OPC.

Identification of EFIV, a stable factor present in many avian cell types that transactivates sequences in the 5' portion of the Rous sarcoma virus long terminal repeat enhancer

We define a protein complex present in avian nuclear extracts that interacts with the Schmidt-Ruppin strain of the Rous sarcoma virus (RSV) long terminal repeat (LTR) between positions -197 and -168 relative to the transcriptional start site. We call this complex EFIV and demonstrate that the EFIV protein(s) is present in several avian cell types examined, including B cells (S13 and DT40), T cells (MSB), and chicken embryo fibroblasts. We also report that the EFIV binding site activates transcription of reporter constructs after transfection into avian B cells and chicken embryo fibroblasts, demonstrating that the EFIV region constitutes a functional transactivator sequence. By chemical interference footprinting and mutational analyses we define the EFIV binding site as including the sequence GCAACATG, which is present in two copies between positions -197 and -168, as well as sequences that lie between the two repeats. Electrophoretic mobility shift competition experiments suggest that the EFIV protein(s) may be related to members of the CCAAT/enhancer-binding protein family of transcription factors that interact with different regions of the RSV and the avian leukosis virus (ALV) LTRs. However, as defined by differences in sensitivity to protein synthesis inhibitors and footprinting patterns, EFIV is clearly distinct from these previously defined LTR binding factors. In addition, the finding that EFIV binding activity is stable in B cells indicates either that the lability of all 5' LTR binding activities is not required for B-cell transformation by the ALV/RSV family of viruses or that nonacute transforming viruses that include an RSV LTR may use a mechanism to effect cellular transformation different from that proposed for ALV.

Alternating purine-pyrimidine tract activates transcription from the Rouse sarcoma virus LTR lacking promoter and enhancer elements

The transcriptional control region of the Rouse sarcoma virus long terminal repeats (LTR) was shown to contain enhancer and promoter elements located within 200 base pairs upstream from the transcription initiation site [Cullen et al. (1985) Mol. Cell. Biol. 5, 438-447]. Deletion of these elements results in significant loss of LTR transcriptional activity. In the present paper it is shown that a short alternating purine-pyrimidine sequence can restore the constitutive activity of the Rouse sarcoma virus LTR in the absence of upstream elements when inserted in close proximity to the transcription initiator site. The possible molecular bases of this phenomena are discussed.

Down-regulation of Rous sarcoma virus long terminal repeat promoter activity by a HeLa cell basic protein

We have previously isolated a HeLa cell cDNA encoding a 21-kDa polypeptide that is 48% similar to transcription factor IIS. To explore the possibility that p21 plays a role in transcriptional regulation in vivo, we tested the effect of p21 expression on the synthesis of reporter chloramphenicol acetyltransferase (CAT) in transfected COS-1 cells. CAT formation under control of the Rous sarcoma virus long terminal repeat (RSV LTR) promoter was decreased nearly 20-fold in cells coexpressing p21. In contrast, CAT production under control of other sequence elements was only slightly reduced (human immunodeficiency virus type 1 LTR, simian virus 40 early promoter), unaffected (human heat shock protein of 70-kDa promoter, adenovirus major late promoter TATA box), or increased (terminal deoxynucleotidyltransferase initiator element, c-fos promoter) by p21 coexpression as compared to cells cotransfected with the parental vector. The abundance of steady-state CAT transcripts from RSV LTR was also decreased by p21 expression in a dose-dependent manner, suggesting that transcription of RSV LTR/CAT is under negative control by p21. Consistent with an effect on transcription, p21 was localized in nuclei of transfected cells. Deletion analysis of p21 indicated that the sequences essential for inhibition of RSV LTR function include the previously identified ARg/Ser-rich region and zinc finger-like motif. Proliferation of chicken embryo fibroblasts transfected with an infectious molecular clone of RSV was diminished by p21 expression, which also resulted in fewer transformed foci.

The VBP and a1/EBP leucine zipper factors bind overlapping subsets of avian retroviral long terminal repeat CCAAT/enhancer elements

Two long terminal repeat (LTR) enhancer-binding proteins which may regulate high rates of avian leukosis virus (ALV) LTR-enhanced c-myc transcription during bursal lymphomagenesis have been identified (A. Ruddell, M. Linial, and M. Groudine, Mol. Cell. Biol. 9:5660-5668, 1989). The genes encoding the a1/EBP and a3/EBP binding factors were cloned by expression screening of a lambda gt11 cDNA library from chicken bursal lymphoma cells. The a1/EBP cDNA encodes a novel leucine zipper transcription factor (W. Bowers and A. Ruddell, J. Virol. 66:6578-6586, 1992). The partial a3/EBP cDNA clone encodes amino acids 84 to 313 of vitellogenin gene-binding protein (VBP), a leucine zipper factor that binds the avian vitellogenin II gene promoter (S. Iyer, D. Davis, and J. Burch, Mol. Cell. Biol. 11:4863-4875, 1991). Multiple VBP mRNAs are expressed in B cells in a pattern identical to that previously observed for VBP in other cell types. The LTR-binding activities of VBP, a1/EBP, and B-cell nuclear extract protein were compared and mapped by gel shift, DNase I footprinting, and methylation interference assays. The purified VBP and a1/EBP bacterial fusion proteins bind overlapping but distinct subsets of CCAAT/enhancer elements in the closely related ALV and Rous sarcoma virus (RSV) LTR enhancers. Protein binding to these CCAAT/enhancer elements accounts for most of the labile LTR enhancer-binding activity observed in B-cell nuclear extracts. VBP and a1/EBP could mediate the high rates of ALV and RSV LTR-enhanced transcription in bursal lymphoma cells and many other cell types.

Functional and biological properties of an avian variant long terminal repeat containing multiple A to G conversions in the U3 sequence

We previously reported that infection of chicken embryonic neuroretina cells with Rous-associated virus type 1 leads to the frequent occurrence of spliced readthrough transcripts containing viral and cellular sequences. Generation of such chimeric transcripts constitutes a very early step in oncogene transduction. We report, here, the isolation of a c-mil transducing retrovirus, designated IC4, which contains a highly mutated U3 sequence in which 48% of A is converted to G. Functional analysis of this variant U3 indicated that these mutations do not impair viral transcription and replication; however, they abolish functioning of its polyadenylation signal, thus allowing readthrough transcription of downstream cellular sequences. On the basis of these results, we designed a nonreplicative retroviral vector, pIC4Neo, expressing the neomycin resistance (Neo(r)) gene under the control of the IC4 long terminal repeat. Infection of nondividing neuroretina cells with virus produced by a packaging cell line transfected with pIC4Neo occasionally resulted in sustained cell proliferation. Two independent G418-resistant proliferating cultures were found to express hybrid RNAs containing viral and cellular sequences. These sequences were characterized by reverse transcription-PCR and were identified in both cultures, suggesting that proliferation was correlated with a common integration locus. These results indicate that IC4Neo virus functions as a useful insertional mutagen and may allow identification of genes potentially involved in regulation of cell division.

Mice expressing a bovine basic fibroblast growth factor transgene in the brain show increased resistance to hypoxemic-ischemic cerebral damage

BACKGROUND AND PURPOSE

Cerebral intraventricular infusion of acidic or basic fibroblast growth factor has been shown to attenuate ischemic damage to hippocampal CA1 neurons in the gerbil. The purpose of the present study was to determine if the basic fibroblast growth factor transgenic mouse has an enhanced ability to resist the effects of severe cerebral hypoxemia-oligemia.

METHODS

Mice that were transgenic for bovine basic fibroblast growth factor were exposed to right carotid artery ligation, hyperglycemia, and 20 minutes of 1% carbon monoxide. After 5 days' recovery, brains were examined for histological damage.

RESULTS

Counts of CA1 neurons in the right hippocampus showed a significantly higher number of neurons per millimeter CA1 in hypoxic-ischemic transgenic mice compared with nontransgenic controls (transgenic, 260 +/- 33; nontransgenic, 151 +/- 37 neurons per millimeter CA1; P < .05).

CONCLUSIONS

The results indicate that basic fibroblast growth factor transgenic mice, as judged by CA1 hippocampal neuronal survival, have an enhanced ability to resist the effects of a complex hypoxic-ischemic cerebral insult.

Functional and defective components of avian endogenous virus long terminal repeat enhancer sequences

Oncogenic avian retroviruses, such as Rous sarcoma virus (RSV) and the avian leukosis viruses, contain a strong enhancer in the U3 portion of the proviral long terminal repeat (LTR). The LTRs of a second class of avian retroviruses, the endogenous viruses (ev) lack detectable enhancer activity. By creating ev-RSV hybrid LTRs, we previously demonstrated that, despite the lack of independent enhancer activity in the ev U3 region, ev LTRs contain sequences that are able to functionally replace essential enhancer domains from the RSV enhancer. A hypothesis proposed to explain these data was that ev LTRs contain a partial enhancer that includes sequences necessary but not sufficient for enhancer activity and that these sequences were complemented by RSV enhancer domains present in the original hybrid constructs to generate a functional enhancer. Studies described in this report were designed to define sequences from both the ev and RSV LTRs required to generate this composite enhancer. This was approached by generating additional ev-RSV hybrid LTRs that exchanged defined regions between ev and RSV and by directly testing the requirement for specific motifs by site-directed mutagenesis. Results obtained demonstrate that ev enhancer sequences are present in the same relative location as upstream enhancer sequences from RSV, with which they share limited sequence similarity. In addition, a 67-bp region from the internal portion of the RSV LTR that is required to complement ev enhancer sequences was identified. Finally, data showing that CArG motifs are essential for high-level activity, a finding that has not been previously demonstrated for retroviral LTRs, are presented.

Characterization of nuclear proteins that bind the EFII enhancer sequence in the Rous sarcoma virus long terminal repeat

The EFII cis element is a 38-bp sequence at the 5' end of the Rous sarcoma virus long terminal repeat, extending from nucleotides -229 to -192 (with respect to the viral transcription start site), which is recognized by sequence-specific DNA-binding proteins in avian fibroblast nuclear extracts (L. Sealy and R. Chalkley, Mol. Cell. Biol. 7:787-798, 1987). We demonstrate that multiple copies of the EFII cis element strongly activate transcription of a reporter gene in vivo. We correlate the region of the EFII cis element which activates transcription in vivo with the in vitro binding site for three nuclear factors, EFIIa, EFIIb, and EFIIc. The sequence motif recognized by EFIIa, -b, and -c is also found in consensus binding sites for members of a rapidly growing family of transcription factors related to the CCAAT/enhancer-binding protein (C/EBP). EFIIa, -b, and -c are present in fibroblast and epithelial cell lines from various species but are much less abundant in differentiated rat liver and kidney cells. The EFIIa binding activity is particularly abundant in an avian B-cell lymphoma line. As judged from molecular weight analysis, cell type distribution, and sequence recognition properties, the EFII factors under study appear to differ from most of the previously described C/EBP-related factors and thus may expand the diversity of the C/EBP family.

Transformation of chicken myelomonocytic cells by a retrovirus expressing the v-myb oncogene from the long terminal repeats of avian myeloblastosis virus but not Rous sarcoma virus

To test the effect of long terminal repeat (LTR) regulatory sequences on the transforming capability of the v-myb oncogene from avian myeloblastosis virus (AMV), we have constructed replication-competent avian retroviral vectors with nearly identical structural genes that express v-myb from either AMV or Rous sarcoma virus (RSV) LTRs. After transfection into chicken embryo fibroblasts, virus-containing cell supernatants were used to infect chicken myelomonocytic target cells from preparations of 16-day-old embryonic spleen cells. Both wild-type AMV and the virus expressing v-myb from AMV LTRs (RCAMV-v-myb) were able to transform the splenocyte cultures into a population of immature myelomonocytic cells. The transformed cells expressed the p48v-Myb oncoprotein and formed compact foci when grown in soft agar. In contrast, the virus expressing v-myb from RSV LTRs (RCAS-v-myb) was repeatedly unable to transform the same splenocyte cells, despite being able to infect fibroblasts with high efficiency. This difference in the transforming activities of v-myb-expressing viruses with different LTRs most likely results from the presence of a factor (or factors) within the appropriate myelomonocytic target cell that promotes specific expression from the AMV but not from the RSV LTR.

Small deletion in v-src SH3 domain of a transformation defective mutant of Rous sarcoma virus restores wild type transforming properties

RSV mutant virus PA101T was obtained while assaying the tumorigenicity of parental PA101 virus in chickens. PA101 is a transformation defective mutant of RSV which has a low src kinase activity. However, PA101 retained a temperature-sensitive ability to induce sustained proliferation of neuroretina cells. PA101T appeared as a wild-type phenotype revertant of PA101. Molecular cloning and sequencing of PA101T showed that this reversion is due to additional mutations in PA101 src gene. These mutations are a deletion eliminating three amino acids in the N-terminal region of SH3 domain and mutation of Ala 426 to Val. Analysis of the properties of chimeric src genes associating either half of PA101T with the complementary regions of PA101 or wild-type virus showed that the N-terminal moiety of PA101T src, which contains the deletion, confers wild-type transforming properties, whereas its C-terminal moiety, which contains single amino acid mutation, confers a partially temperature-sensitive phenotype. These results are consistent with other reports showing that mutations or deletions in this region of SH3 activate the transforming potential of c-src. They support the hypothesis that the N-terminal region of SH3 interacts with a cellular negative regulator of src activity.

CArG, CCAAT, and CCAAT-like protein binding sites in avian retrovirus long terminal repeat enhancers

A strong enhancer element is located within the long terminal repeats (LTRs) of exogenous, oncogenic avian retroviruses, such as Rous sarcoma virus (RSV) and the avian leukosis viruses. The LTRs of a second class of avian retroviruses, the endogenous viruses (evs), lack detectable enhancer function, a property that correlates with major sequence differences between the LTRs of these two virus groups. Despite this lack of independent enhancer activity, we previously identified sequences in ev LTRs that were able to functionally replace essential enhancer domains from the RSV enhancer with which they share limited sequence similarity. To identify candidate enhancer domains in ev LTRs that are functionally equivalent to those in RSV LTRs, we analyzed and compared ev and RSV LTR-specific DNA-protein interactions. Using this approach, we identified two candidate enhancer domains and one deficiency in ev LTRs. One of the proposed ev enhancer domains was identified as a CArG box, a motif also found upstream of several muscle-specific genes, and as the core sequence of the c-fos serum response element. The RSV LTR contains two CArG motifs, one at a previously identified site and one identified in this report at the same relative location as the ev CArG motif. A second factor binding site that interacts with a heat-stable protein was also identified in ev LTRs and, contrary to previous suggestions, appears to be different from previously described exogenous virus enhancer binding proteins. Finally, a deficiency in factor binding was found within the one inverted CCAAT box in ev LTRs, affirming the importance of sequences that flank CCAAT motifs in factor binding and providing a candidate defect in the ev enhancer.

Replication-competent retrovirus vectors for the transfer and expression of gene cassettes in avian cells

We have constructed a series of replication-competent retrovirus vectors to introduce and express gene cassettes in avian cells. To characterize these vectors, we inserted the coding sequences for the bacterial chloramphenicol acetyltransferase (CAT) gene linked to the chicken beta-actin gene promoter or the mouse metallothionein 1 gene promoter. In all cases, we found the structure of integrated proviruses to be stable during serial cell passage in vitro. Chloramphenicol acetyltransferase activity was detected biochemically and immunocytochemically in infected cells. Cassettes were inserted in the vectors in the same or in the opposite orientation with respect to viral transcription. Although both orientations were functional, the cassettes inserted in the forward orientation were usually expressed at higher levels than the corresponding backward constructions. The level of expression was strongly influenced by surrounding proviral sequences, particularly by the transcriptional enhancer elements within the retrovirus long terminal repeat sequences. Expression was higher with vectors that contained the polymerase (pol) region of the Bryan high-titer strain of Rous sarcoma virus. Inclusion of the Bryan pol region also improved vector replication in the chemically transformed quail fibroblast line QT6.

Improvement of avian leukosis virus (ALV)-based retrovirus vectors by using different cis-acting sequences from ALVs

Production and expression of double-expression vectors which transduce both Neo(r) and lacZ genes and are based on the structure of avian leukosis virus were enhanced by using cis-acting sequences (long terminal repeats and noncoding sequences) from Rous-associated virus-1 and Rous-associated virus-2 rather than those of avian erythroblastosis virus previously used in our constructs. Polyclonal producer cells obtained after transfection of these vectors into the Isolde packaging cell line gave rise to titers as high as 3 x 10(5) lacZ CFU/ml, whereas it was possible to isolate clones of producer cells giving rise to titers of more than 10(6) resistance focus-forming units per ml.

Activation of an endogenous retrovirus enhancer by insertion into a heterologous context

An enhancer element is located in the U3 portion of exogenous avian retrovirus long terminal repeats (LTRs). A similar element has not been detected in the LTRs of ev-1 and ev-2, two avian endogenous viruses (evs) that normally are not expressed in vivo. Experiments were initiated to determine whether minor nucleotide differences in the U3 region of a previously untested ev that is ubiquitously expressed in vivo (ev-3) might confer enhancer function on the LTR of this provirus. This question was addressed by inserting U3 regions from ev-3 and from ev-1 and/or ev-2 both upstream of the herpesvirus thymidine kinase gene promoter and in place of the major enhancer domains of the Rous sarcoma virus LTR and determining their relative effects on transcription. U3 regions from all evs tested were unable to enhance transcription from the thymidine kinase gene promoter, indicating that nucleotide differences in the ev U3 regions do not affect their relative enhancer function and therefore are unlikely to play a role in their differential expression in vivo. Unexpectedly, however, all ev U3 regions were able to augment transcription in an orientation-independent manner in the ev-Rous sarcoma virus hybrid LTRs. Further experiments conducted to determine why this enhancer activity is not detectable in intact ev LTRs demonstrated that it was not due to removal of repressor sequences in the ev fragments used that might normally be present in intact ev LTRs. The lack of detectable enhancer activity in intact ev LTRs also was not explained by a defect in ev promoters that makes them unresponsive to enhancers in cis. These experiments therefore identify sequences that, although unable to function detectably as enhancers in their natural context, can function efficiently in a heterologous context. Data are discussed in terms of the modularity of enhancer elements and possible interactions between enhancers and promoter-specific sequences.

Ig/EBP-1: a ubiquitously expressed immunoglobulin enhancer binding protein that is similar to C/EBP and heterodimerizes with C/EBP

We report the isolation and characterization of cDNA clones that encode a protein with the same DNA binding specificity as the immunoglobulin heavy chain enhancer binding protein E (muEBP-E). We call the gene encoding this protein Ig/EBP-1. A fusion protein encoded by the cDNA binds specifically to muEBP-E-binding sites (E sites) in both the IgH enhancer and the VH1 promoter. Sequence analysis reveals that Ig/EBP-1 is a member of the "basic-zipper" family of DNA-binding proteins that are characterized by basic regions and heptad repeats of leucine residues. Among known family members, Ig/EBP-1 demonstrates highest homology to C/EBP throughout the DNA-binding domain and leucine repeat region. Ig/EBP-1 and C/EBP have highly overlapping binding specificities; both cloned proteins bind to the IgH enhancer and the VH1 promoter E sites, and Ig/EBP-1 binds to previously characterized C/EBP binding sites in the Rous sarcoma virus (RSV) LTR and the murine albumin promoter. Consistent with their homology in the leucine repeat region, Ig/EBP-1 and C/EBP form heterodimers; Ig/EBP-1 is the first member of this family that has been found to heterodimerize with the well-characterized C/EBP. Ig/EBP-1 mRNA is present in all tissues and cell lines examined, although its levels vary almost 20-fold from different sources, with highest levels in early B cells. In tissues where Ig/EBP-1 and C/EBP are both present, heterodimers may be functionally important. The presence of Ig/EBP-1 in fibroblasts and other tissues where C/EBP is not expressed suggests that Ig/EBP-1 may be functionally important for the activity of the RSV enhancer in these cell types. Finally, elevated expression of Ig/EBP-1 in early B cells may explain in part the enhancer-independent activity of VH promoters early in B-cell development.

Interaction of a liver-specific factor with an enhancer 4.8 kilobases upstream of the phosphoenolpyruvate carboxykinase gene

We have previously identified a series of five DNase-I hypersensitive (HS) sites within and around the rat phosphoenolpyruvate carboxykinase (PEPCK) gene. The far upstream region has now been sequenced, and the tissue-specific HS site has been mapped more precisely at 4,800 base pairs upstream of the transcription start site of the PEPCK gene. DNA fragments that include the HS site were cloned upstream of various promoters to test whether these regions modulate transcription of the chloramphenicol acetyltransferase reporter gene. Chloramphenicol acetyltransferase activity was enhanced when the DNA fragment encompassing the upstream HS site was linked to various lengths of the PEPCK promoter or to the heterologous simian virus 40 promoter. This upstream region in conjunction with the proximal promoter, which may contain a tissue-specific element, conferred maximum activation in H4IIE hepatoma cells, which express the endogenous PEPCK gene. When these experiments were performed in XC cells, in which the gene is not expressed, transcriptional activation by the upstream element was still significant. Evidence of a specific protein-DNA interaction, using DNA mobility shift and DNase I footprinting assays, was obtained only when using H4IIE cell nuclear extracts. Competition assay showed that the interacting factor may be similar or identical to the liver-specific factor HNF3. We suggest that this protein factor binds to DNA within the HS site and interacts with the proximal promoter region to control tissue-specific high-level expression of the PEPCK gene.

Transcriptional activity of the Rous sarcoma virus long terminal repeat correlates with binding of a factor to an upstream CCAAT box in vitro

The avian nuclear protein, enhancer factor 1 (EF1), binds specifically to the long terminal repeat (LTR) of Rous sarcoma virus (RSV) in a region that has been implicated in enhancer/promoter function. We have characterized the in vitro binding properties of this factor from chick embryo nuclear extracts by methylation interference/protection foot-printing of the wild-type LTR and also by gel electrophoretic mobility shift assays performed on a series of LTR mutants. We find that the inverted CCAAT pentanucleotide located at position -129 is essential for EF1 binding in vitro. Nucleotides flanking this element exert a smaller effect on binding. Linker-substitution and point mutations which reduce EF1 binding to this site in vitro also reduce promoter activity in transiently transfected cells. EF1 also binds with lower affinity to another inverted CCAAT box at position -65, an element which we show is also essential for transcriptional activity of the RSV LTR. We conclude, therefore, that EF1 is a CCAAT box-binding factor which is involved in the activation of RSV transcription in avian cells. Furthermore, we show that EF1 can recognize the CCAAT boxes of several other promoters in which the functional importance of this pentanucleotide has been established.

Interaction of a liver-specific factor with an enhancer 4.8 kilobases upstream of the phosphoenolpyruvate carboxykinase gene

We have previously identified a series of five DNase-I hypersensitive (HS) sites within and around the rat phosphoenolpyruvate carboxykinase (PEPCK) gene. The far upstream region has now been sequenced, and the tissue-specific HS site has been mapped more precisely at 4,800 base pairs upstream of the transcription start site of the PEPCK gene. DNA fragments that include the HS site were cloned upstream of various promoters to test whether these regions modulate transcription of the chloramphenicol acetyltransferase reporter gene. Chloramphenicol acetyltransferase activity was enhanced when the DNA fragment encompassing the upstream HS site was linked to various lengths of the PEPCK promoter or to the heterologous simian virus 40 promoter. This upstream region in conjunction with the proximal promoter, which may contain a tissue-specific element, conferred maximum activation in H4IIE hepatoma cells, which express the endogenous PEPCK gene. When these experiments were performed in XC cells, in which the gene is not expressed, transcriptional activation by the upstream element was still significant. Evidence of a specific protein-DNA interaction, using DNA mobility shift and DNase I footprinting assays, was obtained only when using H4IIE cell nuclear extracts. Competition assay showed that the interacting factor may be similar or identical to the liver-specific factor HNF3. We suggest that this protein factor binds to DNA within the HS site and interacts with the proximal promoter region to control tissue-specific high-level expression of the PEPCK gene.

Localization by mutational analysis of transcription factor binding sequences in the U3 region of Rous sarcoma virus LTR

The transcription factor binding sequences in the U3 region of Rous Sarcoma virus LTR have been determined by gel retardation assays using mutant synthetic oligonucleotides. The results indicate that the factor, E2BP, specifically binds to sequences TGCAATAC and TGCAACAT, which are localized between nucleotides -222 to -215 and -203 to -196, respectively. This factor is present at elevated levels in avian QT6 cells compared to mouse 3T3 and rat 2 tk- cells. E2BP binds to a sequence that is similar or identical to the sequence recognized by rat liver C/EBP. However, the two proteins are different as judged by three criteria: (i) the E2BP complex migrates slightly faster than the E2-C/EBP complex; (ii) antibodies against C/EBP neither inhibit binding of E2BP nor form a supercomplex which migrates slower than the complex formed with the factor alone; and (iii) E2BP is heat labile whereas C/EBP is heat stable. Another factor, E3BP, which binds to a sequence from -169 to -158, in the U3 region is also detected mainly in QT6 cells but not in mouse or rat cells. These results suggest that different cell-specific factors interact with different cis-acting regulatory sequences in the U3 region of RSV LTR.

Identification of a third protein factor which binds to the Rous sarcoma virus LTR enhancer: possible homology with the serum response factor

We have identified a new protein factor (EFIII) in nuclear extracts of quail fibroblasts and chick embryos which binds specifically in vitro to a 26-bp region of the Rous sarcoma virus (RSV) long terminal repeat (LTR) enhancer. The EFIII binding site in the RSV LTR exhibits a strong sequence homology to the serum response element (SRE). The SRE is a 22-bp cis-acting DNA sequence element, first identified upstream of the human c-fos gene, which can confer serum inducibility to heterologous promotors. The binding site for EFIII in the RSV LTR enhancer is also of interest because this region has been implicated in mediating trans-activation of the RSV LTR enhancer by the protein product of the v-fos gene. We show that avian EFIII binds with equal efficiency to both its binding sites in the RSV LTR and the human c-fos SRE. A dyad symmetry element in the c-fos SRE, previously shown to be critical for binding of the cognate human serum response factor (SRF), is also critical for EFIII binding to the LTR SRE-homologous sequences; similarly, EFIII and the human SRF exhibit identical protein-DNA contacts with their corresponding recognition sequences. We suggest that EFIII may be the avian homolog of the mammalian SRF and, in fact, have evidence to indicate that the RSV LTR is serum responsive.

Inhibition of SV40 DNA replication by Rous sarcoma virus LTR enhancer

Simian virus 40 (SV40) late region recombinant constructs containing the Rous sarcoma virus (RSV) src gene along with RSV enhancer stimulated expression but completely abolished SV40 DNA replication. Constructs, in which the heterologous enhancer sequences were omitted, did replicate normally in African green monkey kidney cells and, in the presence of helper virus, gave rise to infectious progeny. Inhibition of SV40 DNA replication follows a cis-acting mechanism and is most likely due to a conformational change of the SV40 chromatin structure.

Purification and properties of the Rous sarcoma virus internal enhancer binding factor

The internal enhancer binding factor (IBF) that specifically binds sequences within the gag gene internal enhancer of Rous sarcoma virus Schmidt-Ruppin A was purified to near homogeneity from BHK cells. The polypeptides that constituted IBF DNA-binding activity were identified by sodium dodecyl sulfate-polyacrylamide gel analysis. As isolated from BHK cells, IBF consisted of two different but related polypeptides. One (IBF alpha) had a molecular weight of 40,000; the other (IBF beta) had a molecular weight of 20,000 and appeared to be a proteolytic product of IBF alpha. The site within the gag gene to which IBF bounds in vitro (internal enhancer site 2; nucleotides 856 to 878 of the Rous sarcoma virus genome) were demonstrated to function as a cis-acting transcriptional stimulatory element both in vivo and in vitro. By using HeLa cell nuclear transcription extracts, purified IBF was found to function as a trans-acting transcription factor that stimulated transcription in vitro. Purified IBF was also demonstrated to be very similar to EBP20 (K. Carlberg, T. A. Ryden, and K. Beemon, J. Virol. 62:1617-1624, 1988), and it may well belong to the same family of DNA-binding proteins.

Identification and characterization of nuclear retinoic acid-binding activity in human myeloblastic leukemia HL-60 cells

Specific [3H]retinoic acid (RA)-binding sites in nuclear and cytosolic extracts prepared from human myeloblastic leukemia HL-60 cells have been detected by sucrose density gradient sedimentation and size-exclusion high-performance liquid chromatography (HPLC) analyses. This RA-binding activity migrated as a single peak with an apparent molecular weight of 50,000 and greater than 95% of the total binding activity was associated with the nuclear extract. Nuclear extracts prepared from COS-1 cells transfected with an expression vector for the nuclear RA receptors RAR alpha or RAR beta were enriched (20- to 100-fold) with a RA-binding activity that coeluted by size-exclusion HPLC with the putative RAR from HL-60 cells. The HL-60 nuclear receptor exhibited high-affinity binding of RA and its benzoic acid analogs Ch55, Ch30, Ro 13-7410, and SRI 6409-40 and low-affinity binding of retinol, Ro 8-8717, and SRI 5442-60, correlating well with the biological activity of these compounds in HL-60 cells. Saturation binding and Scatchard plot analyses of the binding of RA to the nuclear HL-60 receptor yielded an apparent dissociation constant of approximately 0.46 nM and 1400 +/- 100 receptor sites per cell. Northern blot analyses of poly(A)+ RNA with cDNA probes specific for RAR alpha and RAR beta indicated that HL-60 cells contain predominantly transcripts encoded by the RAR alpha gene. Our results suggest that the observed nuclear RA-binding activity in HL-60 cells might mediate the action of RA in these cells.

Avian retroviral long terminal repeats bind CCAAT/enhancer-binding protein

DNA-protein interactions involving enhancer and promoter sequences within the U3 regions of several avian retroviral long terminal repeats (LTRs) were studied by DNase I footprinting. The rat CCAAT/enhancer-binding protein, C/EBP, bound to all four viral LTRs examined. The Rous sarcoma virus binding site corresponded closely to the 5' limit of the LTR enhancer; nucleotides -225 to -188 were protected as a pair of adjacent binding domains. The Fujinami sarcoma virus LTR bound C/EBP at a single site at nucleotides -213 to -195. C/EBP also bound to the promoter region of the enhancerless Rous-associated virus-0 LTR at nucleotides -77 to -57. The avian myeloblastosis virus LTR bound C/EBP at three sites: nucleotides -262 to -246, -154 to -134, and -55 to -39. We have previously observed binding of C/EBP to an enhancer in the gag gene of avian retroviruses. A heat-treated nuclear extract from chicken liver bound to all of the same retroviral sequences as did C/EBP. Alignment of the avian retroviral binding sequences with the published binding sites for C/EBP in two CCAAT boxes and in the simian virus 40, polyoma, and murine sarcoma virus enhancers suggested TTGNNGCTAATG as a consensus sequence for binding of C/EBP. When two bases of this consensus sequence were altered by site-specific mutagenesis of the Rous sarcoma virus LTR, binding of the heat-stable chicken protein was eliminated.

Purification and properties of the Rous sarcoma virus internal enhancer binding factor

The internal enhancer binding factor (IBF) that specifically binds sequences within the gag gene internal enhancer of Rous sarcoma virus Schmidt-Ruppin A was purified to near homogeneity from BHK cells. The polypeptides that constituted IBF DNA-binding activity were identified by sodium dodecyl sulfate-polyacrylamide gel analysis. As isolated from BHK cells, IBF consisted of two different but related polypeptides. One (IBF alpha) had a molecular weight of 40,000; the other (IBF beta) had a molecular weight of 20,000 and appeared to be a proteolytic product of IBF alpha. The site within the gag gene to which IBF bounds in vitro (internal enhancer site 2; nucleotides 856 to 878 of the Rous sarcoma virus genome) were demonstrated to function as a cis-acting transcriptional stimulatory element both in vivo and in vitro. By using HeLa cell nuclear transcription extracts, purified IBF was found to function as a trans-acting transcription factor that stimulated transcription in vitro. Purified IBF was also demonstrated to be very similar to EBP20 (K. Carlberg, T. A. Ryden, and K. Beemon, J. Virol. 62:1617-1624, 1988), and it may well belong to the same family of DNA-binding proteins.

Influence of avian leukosis viral sequences on transmission to the egg and embryo

Rous associated virus type-0 (RAV-0), a subgroup E replication-competent endogenous virus of chickens, is associated with a low efficiency of virus shedding into the egg albumen and failure to establish congenital transmission. In contrast, RAV-1, a subgroup A virus of exogenous origin, is efficiently shed into the albumen and readily infects the embryo. Among a series of in vitro constructed recombinants between RAV-0 and RAV-1, we have identified subgroup E recombinants that efficiently shed virus into the egg albumen but do not undergo efficient congenital transmission. The LTR region, subgroup-determining sequences in env, and sequences within a 375 bp Sacl-Xhol fragment at the 5' end of the genome each influenced the efficiency of virus shedding into the albumen. Egg inoculations with viruses differing only in env were used to confirm the low rate of congenital transmission of subgroup E viruses. These studies revealed that subgroup A envelope antigens are at least 100-fold more effective for the establishment of embryonic infection than subgroup E.

Avian retroviral long terminal repeats bind CCAAT/enhancer-binding protein

DNA-protein interactions involving enhancer and promoter sequences within the U3 regions of several avian retroviral long terminal repeats (LTRs) were studied by DNase I footprinting. The rat CCAAT/enhancer-binding protein, C/EBP, bound to all four viral LTRs examined. The Rous sarcoma virus binding site corresponded closely to the 5' limit of the LTR enhancer; nucleotides -225 to -188 were protected as a pair of adjacent binding domains. The Fujinami sarcoma virus LTR bound C/EBP at a single site at nucleotides -213 to -195. C/EBP also bound to the promoter region of the enhancerless Rous-associated virus-0 LTR at nucleotides -77 to -57. The avian myeloblastosis virus LTR bound C/EBP at three sites: nucleotides -262 to -246, -154 to -134, and -55 to -39. We have previously observed binding of C/EBP to an enhancer in the gag gene of avian retroviruses. A heat-treated nuclear extract from chicken liver bound to all of the same retroviral sequences as did C/EBP. Alignment of the avian retroviral binding sequences with the published binding sites for C/EBP in two CCAAT boxes and in the simian virus 40, polyoma, and murine sarcoma virus enhancers suggested TTGNNGCTAATG as a consensus sequence for binding of C/EBP. When two bases of this consensus sequence were altered by site-specific mutagenesis of the Rous sarcoma virus LTR, binding of the heat-stable chicken protein was eliminated.

Transduction of the cellular src gene and 3' adjacent sequences in avian sarcoma virus PR2257

When injected into chickens, a transformation-defective mutant of the Prague C strain of Rous sarcoma virus induced tumors at low incidence and after a long latency. One such tumor released a replication-defective virus designated PR2257. We molecularly cloned and sequenced the proviral DNA from quail fibroblasts transformed by PR2257. Comparison of PR2257 sequence with that of Prague C, cellular src, and 3' adjacent cellular DNA showed that the spliced version of the c-src gene and about 950 base pairs (bp) of 3'-flanking cellular DNA were transduced into PR2257. This transduction eliminated nearly all replicative genes, since the gag gene splice donor site was linked to the splice acceptor site of the src gene and, on the 3' side, recombination occurred in the end of env gene. Insertion of two extra cytosines 23 bp before and 19 bp after the c-src stop codon resulted in an extension of the coding portion up to 587 amino acids, divergence of sequences after Pro-525 and replacement of Tyr-527 by a valine residue. In addition, it appears that the 5' and 3' untranslated regions of PR2257 result from multiple recombinations between exogenous and endogenous virus genomes. Limited digestion of p66src encoded by PR2257 with Staphylococcus aureus V8 protease yielded a V2 peptide (C-terminal moiety) with an apparent molecular mass of 31 kilodaltons, consistent with the 5.7-kilodalton increase expected from the DNA sequence. The structure of PR2257 suggests that the first step in the capture of c-src gene by avian lymphomatosis viruses is the trans splicing of the viral leader mRNA to exon 1 of c-src.

Helper-independent retrovirus vectors with Rous-associated virus type O long terminal repeats

We have constructed nonpermuted replication-competent avian retrovirus vectors that derive from Rous sarcoma virus (S. H. Hughes, J. J. Greenhouse, C. J. Petropoulos, and P. Sutrave, J. Virol. 61:3004-3012, 1987). We describe here the construction and properties of corresponding vectors in which the long terminal repeats (LTRs) of the parental virus have been replaced by the LTRs of the endogenous chicken virus Rous-associated virus type O. The Rous-associated virus type O LTR vectors replicated approximately 1/10 as well as the parental vectors and expressed a test gene, chloramphenicol acetyltransferase, approximately 1/30 to 1/50 as well.

Functional analysis of the long terminal repeats of intracisternal A-particle genes: sequences within the U3 region determine both the efficiency and direction of promoter activity

The transcriptional activity of five intracisternal A-particle (IAP) long terminal repeats (LTRs) in mouse embryonal carcinoma PCC3-A/1 cells and in Ltk- cells was determined. We tested the promoter activity of the LTRs by coupling them to the reporter gene chloramphenicol acetyltransferase (CAT) or guanosine-xanthine phosphoribosyltransferase (gpt). Each LTR was tested for promoter function in both the sense (5' to 3') and antisense (3' to 5') orientation preceding the reporter gene. The transcriptional activity of individual IAP gene LTRs varied considerably, and the LTR from IAP81 possessed promoter activity in both directions. The bidirectional activity of the IAP81 LTR confirmed by monitoring Ecogpt expression in stably transfected Ltk- cells, with the initiation sites for sense and antisense transcription being localized to within the IAP81 LTR by S1 nuclease mapping. Deletions of LTR81 show that for normal 5'-to-3' gene transcription (sense direction), the 3'U3/R region determines the basal level of transcription, whereas sequences within the 5'U3 region enhance transcription four- to fivefold. Deletion mapping for antisense transcription indicates that a 64-base-pair region (nucleotides 47 to 110) within the U3 region is essential for activity. These data indicate that the U3 region contains all the regulatory elements for bidirectional transcription in IAP LTRs.

Three Epstein-Barr virus (EBV)-determined nuclear antigens induced by the BamHI E region of EBV DNA

In our previous study (Takada et al., 1986a), we showed that the BamHI E fragment of Epstein-Barr virus (EBV) DNA induces a nuclear antigen that is detected by human antisera against EBV-determined nuclear antigen (EBNA), when transfected into baby hamster kidney (BHK) cells. The present study shows that the sub-fragment containing the central open reading frame BERF2b of the BamHI E fragment (Baer et al., 1984) is responsible for nuclear antigen induction. In addition, 2 fragments corresponding to 2 other open reading frames of the BamHI E, BERFI and BERF4 also induce nuclear antigens upon transfection into BHK cells. These 3 antigens, designated RF2b, RFI and RF4 antigens, were serologically classified as EBNA and antigenically distinct. In immunoblotting analysis of latently EBV-infected BJ-B95-8 cells, 3 high-molecular-weight polypeptides (136, 142 and 147 kDa) were identified by anti-EBNA sera. Immunoblotting analysis of transfected BHK cells indicated that the RF2b antigen is 145 kDa in its native form and antigenically related to the 147-kDa protein of BJ-B95-8 cells. Although RFI and RF4 antigens were not detected by immunoblotting, reactivities of sera with RFI and RF4 antigens in the immunofluorescence test were correlated with those of sera with the 136- and 142-kDa polypeptides of BJ-B95-8 cells, respectively. The results suggest that 3 high-molecular-weight proteins of latently EBV-infected cells are encoded by 3 open reading frames of the BamHI E DNA fragment.

Localization and footprinting of an enhancer within the avian sarcoma virus gag gene

A cis-acting regulatory element within the gag gene of avian retroviruses has been localized by deletion analysis, and sites of protein interaction have been studied by DNase I footprinting. Unidirectional deletions were made from both the 5' and 3' ends of a 656-base-pair fragment of the gag gene of Fujinami sarcoma virus. These deletion mutants were tested for enhancer activity in a chloramphenicol acetyltransferase transient expression assay. A sharp 5' boundary for enhancer activity was observed between 776 and 786 nucleotides downstream from the transcription initiation site. In contrast, deletion from the 3' side resulted in a gradual loss of enhancer activity, reaching a near basal level of activity by nucleotide 868. Internal deletion of 76 nucleotides just downstream of the 5' boundary abolished enhancement. Mutagenesis of a consensus enhancer core sequence (GTGGTTTG) showed that this sequence was not necessary for enhancer activity in our transient assays. DNase I footprinting with both a highly purified enhancer-binding protein from rat liver (EBP20) and a partially purified chicken liver nuclear extract showed specific protection of nucleotides 813 to 872 within the localized enhancer region. Footprinting of unidirectional deletion mutants that had lost activity indicated that this binding was not sufficient to confer enhancement.

Functional analysis of the long terminal repeats of intracisternal A-particle genes: sequences within the U3 region determine both the efficiency and direction of promoter activity

The transcriptional activity of five intracisternal A-particle (IAP) long terminal repeats (LTRs) in mouse embryonal carcinoma PCC3-A/1 cells and in Ltk- cells was determined. We tested the promoter activity of the LTRs by coupling them to the reporter gene chloramphenicol acetyltransferase (CAT) or guanosine-xanthine phosphoribosyltransferase (gpt). Each LTR was tested for promoter function in both the sense (5' to 3') and antisense (3' to 5') orientation preceding the reporter gene. The transcriptional activity of individual IAP gene LTRs varied considerably, and the LTR from IAP81 possessed promoter activity in both directions. The bidirectional activity of the IAP81 LTR confirmed by monitoring Ecogpt expression in stably transfected Ltk- cells, with the initiation sites for sense and antisense transcription being localized to within the IAP81 LTR by S1 nuclease mapping. Deletions of LTR81 show that for normal 5'-to-3' gene transcription (sense direction), the 3'U3/R region determines the basal level of transcription, whereas sequences within the 5'U3 region enhance transcription four- to fivefold. Deletion mapping for antisense transcription indicates that a 64-base-pair region (nucleotides 47 to 110) within the U3 region is essential for activity. These data indicate that the U3 region contains all the regulatory elements for bidirectional transcription in IAP LTRs.

Specific nuclear proteins interact with the Rous sarcoma virus internal enhancer and share a common element with the enhancer located in the long terminal repeat of the virus

We have documented that the Rous sarcoma virus (RSV) internal enhancer functions in the nontransformed Baby Hamster Kidney (BHK) cell line. The sequences within this region were assayed for their ability to bind to specific factors present in BHK nuclear extracts using the gel retardation assay and DNAse I footprinting. At least two sequences within the internal enhancer which can specifically bind nuclear factors in vitro have been identified. These regions are located between nucleotides 813-850 and 856-877. These sites map within the overall region of the internal enhancer which has been shown to be essential for enhancer activity and within the specific region which can function as an orientation independent enhancer. Using the DNase I footprinting and binding data to design an oligonucleotide, we have demonstrated that an oligonucleotide extending from nucleotides 804-877 will substitute efficiently as an enhancer. We also demonstrate that the SV40 enhancer does not compete for the factors which bind to the RSV internal enhancer, whereas an oligonucleotide to the binding site for EFII in the LTR can compete for factor binding to the internal enhancer.

Both the rightward and the leftward open reading frames within the BamHI M DNA fragment of Epstein-Barr virus act as trans-activators of gene expression

The BamHI M DNA fragment of Epstein-Barr virus was shown to activate transcription of the cotransfected chloramphenicol acetyltransferase gene under the control of the simian virus 40 early promoter. Both the BamHI-BglII and the HindIII-BamHI subfragments of the BamHI M fragment, corresponding to the rightward reading frame BMRF1 and the leftward reading frame BMLF1, respectively, had the ability to activate transcription from the simian virus 40 promoter. The trans-activating function was well correlated with the expression of nuclear early antigens, which suggests that early antigens encoded by BMRF1 and BMLF1 are responsible for trans-activation and possibly play a role in regulated expression of virus genomes.

cis-acting regulatory elements within gag genes of avian retroviruses

A cis-acting enhancer element has been detected within the gag gene of several avian retroviruses, including Rous sarcoma virus, Fujinami sarcoma virus, and the endogenous Rous-associated virus-0. A consensus enhancer core sequence, GTGGTTTG, is present in all of these viral genomes, approximately 900 bases downstream from the site of initiation of transcription. When an internal fragment derived from the gag gene of any of these viruses (spanning nucleotides 533 to approximately 1149) was inserted into a plasmid containing the chloramphenicol acetyltransferase (cat) gene under control of the simian virus 40 promoter, 9- or 21-fold enhancement of CAT expression was observed after transfection into mouse L cells and chicken embryo fibroblasts, respectively. This enhancement was not dependent on the position of insertion of the gag fragment into the plasmid. However, there was a strong dependence on orientation, with higher levels of CAT expression in constructs in which the 5' end of the gag fragment was nearest to the promoter, suggesting a possible negative regulatory element at the 3' end of this fragment. Deletion of the 3' end of the insert resulted in a gag fragment, containing nucleotides 533 to 1017, which enhanced expression equally in either orientation. When the gag fragment was inserted into a plasmid containing the cat gene under the control of an intact Rous sarcoma virus long terminal repeat, it induced a two- to threefold increase in CAT activity and CAT mRNA levels. Translation of the gag fragment did not appear to be necessary for the observed enhancement, since two insertional mutations resulting in frameshifts in the gag insert did not affect CAT expression. However, deletion of a 330-base internal fragment from the gag insert restored a basal level of CAT activity. These results suggest that retroviruses have regulatory elements within their genes distinct from those in the long terminal repeats that flank the genes.

At least two nuclear proteins bind specifically to the Rous sarcoma virus long terminal repeat enhancer

We used the sensitive gel electrophoresis DNA-binding assay and DNase I footprinting to detect at least two protein factors (EFI and EFII) that bound specifically to the Rous sarcoma virus (RSV) enhancer in vitro. These factors were differentially extracted from quail cell nuclei, recognized different nucleotide sequences in the U3 region of the RSV long terminal repeat, and appeared to bind preferentially to opposite DNA strands as monitored by the DNase I protection assay. The EFI- and EFII-protected regions within U3 corresponded closely to sequences previously demonstrated by deletion mutagenesis to be required for enhancer activity, strongly suggesting a functional significance for these proteins. Only weak homologies between other enhancer consensus sequence motifs and the EFI and EFII recognition sites were observed, and other viral enhancers from simian virus 40 and Moloney murine sarcoma virus did not compete effectively with the RSV enhancer for binding either factor.

Characterization of Rous sarcoma virus sequences essential for viral gene expression

Using the Escherichia coli lacZ gene product beta-galactosidase as an indicator of gene expression, we analyzed sequences that are required for expression of the Rous sarcoma virus (RSV) genome in avian cells. The RSV long terminal repeat (LTR) and leader region were sufficient to direct the synthesis of high levels of enzymatically active gag-lacZ fusion proteins. A portion of U3 greater than 140 nucleotides upstream from the cap site was essential for gene expression. This element functioned in either orientation, but its activity was attenuated when it was relocated further away from the cap site. The insertion of exogenous LTRs 3' of lacZ augmented the expression of that gene by increasing the level of stable gag-lacZ transcripts. Furthermore, 3' LTRs could partially compensate for certain defects within the 5' LTR. Insertion of various fragmentary LTRs allowed the identification of at least three synergistically acting domains within the 3' LTR that influence gene expression. Interestingly, the gag-lacZ expression was only stimulated by a 3' LTR when the exogenous 3'-untranslated region was adjacent. Our results imply that the two LTRs of a provirus interact in a complex manner to promote high levels of stable transcripts. It was also found that gag-lacZ expression was independent of viral gene products, suggesting that trans-activation is not a key mechanism regulating RSV expression in avian cells.