Close linkage of genes encoding receptors for subgroups A and C of avian sarcoma/leucosis virus on chicken chromosome 28

Avian sarcoma and leucosis viruses (ASLV) are classified into six major subgroups (A to E and J) according to the properties of the viral envelope proteins and the usage of cellular receptors for virus entry. Subgroup A and B receptors are identified molecularly and their genomic positions TVA and TVB are mapped. The subgroup C receptor is unknown, its genomic locus TVC is reported to be genetically linked to TVA, which resides on chicken chromosome 28. In this study, we used two chicken inbred lines that carry different alleles coding for resistance (TVC(R) and sensitivity (TVC(S)) to infection by subgroup C viruses. A backross population of these lines was tested for susceptibility to subgroup C infection and genotyped for markers from chicken chromosome 28. We confirmed the close linkage between TVA and TVC loci. Further, we have described the position of TVC on chromosome 28 relative to markers from the consensus map of the chicken genome.

Intraembryonic avian leukosis virus subgroup C (ALV-C) inoculation producing wasting disease in ducks soon after hatching

We have studied the pathogenic changes in Khaki Campbell ducks injected in mid embryogenesis with ALV subgroup C virus td daPR-C derived from a molecular clone. The employed duck flock was shown to be highly genetically homogeneous and was controlled for the absence of current infections. Clear symptoms of wasting disease, which appeared since one week post hatching, represented the early consequence of the virus infection. They were manifested by decreased body weight, including clear involution of thymic tissue and pronounced anaemia. Microscopically, thymuses of infected animals displayed lymphatic depletion, clearly visible in the lobular cortex. Similarly, in the bursa Fabricii follicles, a marked reduction of the cortical layer and a decrease in folicullar centres was revealed. A decrease in the antibody response correlated with bursa Fabricii atrophy. The clear signs of anaemia were confirmed by haematological measurements, red blood cell count, haematocrit value and haemoglobin included. On the basis of these and additional observations we propose that inoculation of duck embryos provides a suitable model for analysis of the wasting disease produced by ALV-C.

The 3' untranslated region of the chicken c-src protooncogene modulates gene expression

Tight regulation of the Src tyrosine kinase activity is essential for a variety of cellular processes, namely transitions of the cell cycle. The peaks of Src activity are dependent on its posttranslational modifications as well as on the regulation of gene expression. The 3'UTRs of mRNAs are often crucial for rapid changes of the protein level. The chicken c-src 3'UTR effects on gene expression have been explored. The c-src 3'UTR decreased the in vivo tumorigenic potential of the src-activated mutants in chickens. This corresponds with the finding that the c-src 3'UTR reduced the Src protein and src mRNA levels and luciferase activity in vitro. Our results suggest that the chicken c-src 3'UTR plays a role in the negative control of gene expression, either transcriptionally or posttranscriptionally.

Chicken cells--oncogene transformation, immortalization and more

Domestic chicken as a laboratory animal as well as chicken cells in vitro have been highly evaluated in several fields of experimental biology. Retrovirology and experimental oncology traditionally use this model, whose comparative aspects are still inspirative. The first (retro)viral aetiology of a tumour was recognized in the chicken and the first quantitative in vitro measurement of oncogenic transformation was developed using the chicken cells. Chicken cells (like human and primate, but unlike rodent cells) have a long primary life-span, during which they remain genetically stable. While this property is advantageous for several types of experiments, it correlates with a low propensity of the chicken cells to immortalization. Recent establishment of several continuous chicken cell lines, however, has surmounted this drawback. Furthermore, the chicken B cell line DT40 was proved to be extremely useful for gene disruption studies because of a high frequency of gene targeting not found in any vertebrate cells. In the present communication, we have tried to review several traditional achievements accomplished using the chicken model and point to newly opened areas, where chicken cells appear to be an efficient tool, particularly in cell transformation and immortalization.

CpG island protects Rous sarcoma virus-derived vectors integrated into nonpermissive cells from DNA methylation and transcriptional suppression

CpG islands are important in the protection of adjacent housekeeping genes from de novo DNA methylation and for keeping them in a transcriptionally active state. However, little is known about their capacity to protect heterologous genes and assure position-independent transcription of adjacent transgenes or retroviral vectors. To tackle this question, we have used the mouse aprt CpG island to flank a Rous sarcoma virus (RSV)-derived reporter vector and followed the transcriptional activity of integrated vectors. RSV is an avian retrovirus which does not replicate in mammalian cells because of several blocks at all levels of the replication cycle. Here we show that our RSV-derived reporter proviruses linked to the mouse aprt gene CpG island remain undermethylated and keep their transcriptional activity after stable transfection into both avian and nonpermissive mammalian cells. This effect is most likely caused by the protection from de novo methylation provided by the CpG island and not by enhancement of the promoter strength. Our results are consistent with previous finding of CpG islands in proximity to active but not inactive proviruses and support further investigation of the protection of the gene transfer vectors from DNA methylation.

Retroviruses in foreign species and the problem of provirus silencing

Retroviruses are known to integrate in the host cell genome as proviruses, and therefore they are prone to cell-mediated control at the transcriptional and posttranscriptional levels. This plays an important role especially after retrovirus heterotransmission to foreign species, but also to differentiated cells. In addition to host cell-mediated blocks in provirus expression, also so far undefined host specificities, deciding upon the pathogenic manifestation of retrovirus heterotransmission, are in play. In this respect, we discuss especially the occurrence of wasting disease and immunodeficiency syndrome, which we established also in avian species using avian leukosis virus subgroup C (ALV-C) inoculated in mid-embryogenesis in duck or chicken embryos. The problem of provirus downregulation in foreign species or in differentiated cells has been in the recent years approached experimentally. From a series of observations it became apparent that provirus downregulation is mediated by its methylation, especially in the region of proviral enhancer-promoter located in long terminal repeats (LTR). Several strategies have been devised in order to protect the provirus from methylation using LTR modification and/or introducing in the LTR sequence motifs acting as antimethylation tags. In such a way the expression of retroviruses and vectors in foreign species, as well as in differentiated cells, has been significantly improved. The complexity of the mechanisms involved in provirus downregulation and further possibilities to modulate it are discussed.

Proviral load and expression of avian leukosis viruses of subgroup C in long-term persistently infected heterologous hosts (ducks)

Proviral DNA load and expression of avian leukosis viruses of subgroup C (ALV-C) in ducks infected in mid embryogenesis were studied using quantitative PCR, RT-PCR, in situ hybridization employing ALV-specific riboprobe, and immunohistochemistry. A group of long-term surviving, non-reviremic ducks was selected for the study and compared to control reviremic animals in order to obtain information about persisting retroviruses in different duck tissues. A widespread distribution of proviruses in the tested tissues was found, but the proviral load was significantly lower in non-reviremic in comparison to reviremic animals. The only exception were brain and blood cells, in which no significant difference in the quantity of integrated proviruses was found between both categories of ducks, thus indicating an exceptional position of the brain and blood cells among all tested tissues. Contrary to reviremic, the proviruses were not transcribed in non-reviremic ducks, with the exception of brain and thymus. In the majority of non-reviremic ducks viral RNA was revealed in the brain, but no infectious virus could be recovered from this tissue. The opposite situation was observed in the thymus, where infectious virus was recovered but viral RNA remained below the detection limit of the assay. As revealed by in situ analysis, infected cells were either disseminated or focally distributed in tissues. From the long-term follow up of ALV-C in intraembryonally infected ducks we conclude that this model is suitable for the study of retrovirus persistence accompained both by the presence and absence of reviremias. The possible consequences of transmission and long-term persistence of retroviruses in the heterologous host for retroviral evolution are discussed.

Inhibition of the rous sarcoma virus long terminal repeat-driven transcription by in vitro methylation: different sensitivity in permissive chicken cells versus mammalian cells

Rous sarcoma virus (RSV) enhancer sequences in the long terminal repeat (LTR) have previously been shown to be sensitive to CpG methylation. We report further that the high density methylation of the RSV LTR-driven chloramphenicol acetyltransferase reporter is needed for full transcriptional inhibition in chicken embryo fibroblasts and for suppression of tumorigenicity of the RSV proviral DNA in chickens. In nonpermissive mammalian cells, however, the low density methylation is sufficient for full inhibition. The time course of inhibition differs strikingly in avian and mammalian cells: although immediately inhibited in mammalian cells, the methylated RSV LTR-driven reporter is fully inhibited with a significant delay after transfection in avian cells. Moreover, transcriptional inhibition can be overridden by transfection with a high dose of the methylated reporter plasmid in chicken cells but not in hamster cells. The LTR, v-src, LTR proviral DNA is easily capable of inducing sarcomas in chickens but not in hamsters. In contrast, Moloney murine leukemia virus LTR-driven v-src induces sarcomas in hamsters with high incidence. Therefore, the repression of integrated RSV proviruses in rodent cells is directed against the LTR.

Sp1 binding sites inserted into the rous sarcoma virus long terminal repeat enhance LTR-driven gene expression

Although the Rous sarcoma virus (RSV) long terminal repeat (LTR) is an efficient promoter of transcription, most RSV proviruses are down-regulated upon retroviral integration in non-permissive mammalian cells. Among other mechanisms, DNA methylation has been shown to be involved in proviral silencing. The presence of Sp1 binding sites has been demonstrated to be essential for protection of a CpG island and also non-island DNA regions from de novo methylation. Also, the presence of these sites in the LTRs correlates with the transcriptional activity of certain proviral structures. Using transient and stable transfection assays, we demonstrate that insertion of Sp1 binding sites into the RSV LTR remarkably increases expression of the LTR-driven genes in permissive and non-permissive cells, despite the reported negative effect of insertion of the non-specific DNA into the LTR promoter/enhancer sequences. Particular arrangement of inserted Sp1 sites was effective even in stably transfected reporter gene constructs into non-permissive mammalian cells, where additional factors exert negative effects on expression.

The LTR, v-src, LTR provirus in H-19 hamster tumor cell line is integrated adjacent to the negative regulatory region

The tumor hamster cell line H-19 harbors a single copy LTR, v-src, LTR provirus that becomes permanently transcriptionally suppressed in morphological revertants segregating at high rate from this cell line. Our previous data document that the provirus suppression is mediated by epigenetic cell-regulatory mechanisms. In this report, we concentrate on cellular sequences neighboring the integration site. The locus is unique for Syrian hamster and is not detectable in DNA of several animal species. No restriction sites that usually hint at the presence of CpG islands were found in the significantly close vicinity of the provirus. Nevertheless, the chromosomal DNA flanking the provirus is rich in GC content (57.8%). We localized a 0.5-kb region downstream from the provirus that remarkably inhibits transcription in the transient expression assay and is effective both on the homologous RSV LTR promoter/enhancer and heterologous SV40 promoter. We propose that a cellular trans-acting factor is involved in the silencing of the reporter gene. Since this activity is comparable both in transformed and revertant cells, we speculate that this down-regulatory region makes the permissive integration locus prone to provirus silencing initiated by other fluctuating stimuli.

src-specific immunity in inbred chickens bearing v-src DNA- and RSV-induced tumors

The growth pattern (progression/regression) of v-src DNA- and Rous sarcoma virus (RSV)-induced tumors was analogous on a panel of inbred chicken lines. The decisive role of the major histocompatibility complex [Mhc(B)] alleles in resistance to the progression of these tumors was formally proved in segregating backcross populations. The immune mechanism of tumor regression was demonstrated by both in vivo and in vitro assays. A protective effect of v-src-specific immunity against RSV challenge was shown in Rous sarcoma regressor, line CB (B12/B12). Immune cells from regressors of v-src DNA-induced tumors can protect syngeneic hosts from the development of tumor after challenge with both v-src DNA and RSV. Suppression of RSV-induced tumor cell growth in vitro was also achieved by the use of cocultivation with spleen cells from chickens in which v-src DNA-induced tumors had regressed. This in vitro sarcoma-specific response was Mhc(B)-restricted. Chickens of the congenic Rous sarcoma progressor line CC (B4/B4) are sometimes able to regress v-src DNA-induced tumors, but immune cells can only slow the growth of v-src DNA-induced tumors in syngeneic hosts. This suggests that the primary reason for the susceptibility of CC chickens is a weak v-src-specific immune response. Furthermore, some of the v-src DNA-induced tumors were transplantable across the Mhc(B) barrier. The growth of tumor allografts was able to be facilitated when immunological tolerance to the B-F/L region antigens (class I and class II) had been established. This demonstrated that a high tumorigenicity of the transplantable tumor was not due to the lack of Mhc(B) antigens on tumor cells.

High rate of morphological reversion in tumor cell line H-19 associated with permanent transcriptional suppression of the LTR, v-src, LTR provirus

The highly malignant line of morphologically transformed H-19 hamster tumor cells that harbor a single LTR, v-src, LTR provirus segregates morphologically flat revertants at the rate of 1.4 to 2.4 x 10(-3)/cell/cycle. Revertants behave like almost nonmalignant cells; they keep the provirus within an unaltered junction DNA fragment. However, the provirus is methylated, permanently transcriptionally silent, and not rescuable. Using the polymerase chain reaction, we have synthesized the whole proviral structure from two revertants and established that the left-hand long terminal repeats assuring transcription remained structurally intact. Moreover, the cloned proviral DNAs from three revertants were shown to produce tumors in chickens. The unusually high reversion rate together with the finding of structural integrity of proviral transcriptional signals in revertants indicate strongly that the reversion has been mediated by cell-regulatory mechanisms.

Tumor induction by the LTR, v-src, LTR DNA in four B (MHC) congenic lines of chickens

We report that the cloned DNA harboring the long terminal repeat (LTR), v-src, LTR proviral structure is tumorigenic in chickens of the Prague congenic lines. The growth rate of these tumors is by far the highest in the recombinant CC.R1 line, the B haplotype of which is composed of the B-F/L4 and B-G12 subregions originating from different naturally occurring haplotypes. Some of the tumors induced by the LTR, v-src, LTR DNA are repeatedly transplantable in syngeneic chickens, maintain unaltered provirus, and express v-src mRNA. Differences in the response to challenge with Rous sarcoma virus (RSV) and LTR, v-src, LTR DNA on a given experimental model are compared and possible involvement of an interaction between B-F/L and B-G region genes is considered. Regression of the LTR, v-src, LTR DNA-induced tumors did not prevent the formation and growth of tumors induced subsequently by RSV.

Ducks: a new experimental host system for studying persistent infection with avian leukaemia retroviruses

Long-term persistence of the avian leukosis virus (ALV), the transformation-defective mutant of Prague strain Rous sarcoma virus subgroup C (td PR-C) was established in heterologous duck hosts after infection in mid-embryogenesis. Transient viraemia was observed for about 4 weeks after hatching and was lost in most of the infected ducks by about 6 months. Loss of viraemia was accompanied by the increasing synthesis of virus-neutralizing antibodies. In spite of strong virus-neutralizing antibodies, virus was detected by the cocultivation assay in duck tissues throughout the observation period up to 5 years. In the viraemic phase of infection, we found integrated proviruses in various tissues, preferentially in stomach muscle tissue and in the thymus. The long-term persistence of virus was frequently accompanied by liver necrosis and neoplastic diseases. Injection of td PR-C virus into early embryos resulted in more pronounced infection accompanied by an increased copy number of viral DNA per cell, high mortality and remarkable atrophy of thymus tissue in infected ducklings.