Approach to a retrovirus vaccine: immunization of mice against Friend virus disease with a replication-defective Friend murine leukemia virus.

In an initial attempt to test the ability of replication-defective retroviruses to immunize against immunologically related pathogenic viruses, we have worked with the erythroleukemogenic Friend retrovirus complex (FV), which consists of a replication-competent helper component, Friend murine leukemia virus (FMuLV), and a related defective pathogenic component, spleen focus-forming virus (SFFV). An 81-base-pair deletion was introduced into the p15E-encoding region of the env gene of an otherwise replication-competent molecular clone of the FMuLV provirus. After transfection of this clone into cells that package the viral RNA in MuLV coats, infectious virus was released into the culture medium. Mouse fibroblasts infected with this virus, here called delta FMuLV, expressed the truncated viral env gene products in their cytoplasm but not on cell surfaces, and culture fluids from these cells did not transmit the infection to fresh mouse fibroblasts. In preliminary experiments, immunization of mice of H-2-congenic BALB/c strains with delta FMuLV conferred levels of immunity to FV disease ranging from weak to relatively strong. Immunized mice developed anti-FV IgM and IgG antibodies and cytotoxic T cells. Mice observed for 15 weeks after the first of two immunizations showed no detectable pathology, but delta FMuLV DNA was detectable in livers of some immunized mice for at least 3-6 weeks. These results suggest that our approach to development of retrovirus vaccines may be a useful one.

Identification of an epitope encoded in the env gene of Friend murine leukemia virus recognized by anti-Friend virus cytotoxic T lymphocytes.

We have previously shown that strong epitopes recognized by anti-Friend virus (FV) cytotoxic T lymphocytes (CTL) in H-2b mice are encoded in both the env and gag/pol regions of the helper friend leukemia virus genome. Two approaches have been used to identify these epitopes. At the nucleic acid level, we have constructed env genes with either of two in-frame deletions: pKR2, an env gene with a 681-bp deletion in the gp70 region and inserted into the pSV2-gpt-1 expression vector; and pKR1, an env gene with an 81-bp deletion in the p15E region and inserted into pSV2-gpt-1. Cell clones were established by transfecting Fisher rat embryo cells with pDb (the H-2Db restriction element), pNEO (for G418 selection) and either pKR1 or pKR2. Db and env gene expression was monitored by immunoprecipitation with polyclonal antibodies or by detection of viral RNA on Northern blots. Expressor cell clones were tested for susceptibility to lysis by polyclonal anti-FV/Db CTL in 51Cr-release assays. Whereas cells expressing pKR1 were lysed to the same extent as cells expressing the intact env gene, cells expressing pKR2 were resistant to lysis, suggesting that all detectable env epitopes are encoded within the 681-bp deletion. Polypeptides representing the two most likely candidate epitopes encoded in this segment were synthesized and tested for their abilities to sensitize FRE cells expressing Db alone for lysis by the CTL. One 17-mer polypeptide, AGTGDRLLNLVQGAYQA [corrected], functioned as a strong CTL epitope in this assay, but the other 18-mer polypeptide was inactive. Studies of the role of this epitope in the immune response to candidate viral vaccines are in progress.

Precise and imprecise somatic excision of the transposon Tc1 in the nematode C. elegans.

Eleven chromosomal products of somatic excision of Tc1 transposable elements have been cloned and sequenced. The cloning method did not involve genetic reversion; therefore the products analyzed should be representative. Six empty religated target sites were from excision of one Tc1 element inserted near actin genes on linkage group V; five were from a second Tc1 element inserted elsewhere on the same linkage group. All six products from the first element were identical in sequence to an empty target site from a second strain, indicating excision had been precise. Two of the products from the second element were also precise, whereas the other three contained four extra nucleotides at the point of excision, indicating an imprecise excision. The four nucleotides are the same in all cases and could represent two terminal nucleotides of the transposon plus a two-nucleotide target site duplication. The difference in the ratio of precise to imprecise excision at the two insertion sites suggests a possible chromosomal position effect on the pathway of Tc1 somatic excision.

Evidence in a nematode for regulation of transposon excision by tissue-specific factors.

The transposable element Tc1 in Caenorhabditis elegans undergoes an excision reaction, which can be detected in a Southern hybridization as the appearance of empty chromosomal insertion sites. This excision reaction is under tissue-specific regulation in that it occurs at much higher frequency in somatic cells than in the germ line. We show here that this regulation is likely to be due to the action of tissue-specific factors that either promote excision in somatic tissues or repress it in the germ line. The rate of excision of elements at five distinct chromosomal sites has been measured by a method that avoids ambiguities due to cell division. All these elements are found to undergo excision at closely similar rates during the L1 larval stage. No distinct difference exists among the elements at different sites that would suggest regulation by flanking sequences.

Regulation of Tcl transposable elements in Caenorhabditis elegans.

C. elegans strains contain variable numbers of a 1.6-kb transposable genetic element. Activity of this element, which is denoted Tcl, shows regulation at at least two levels. At one level, excision of Tcl elements occurs in somatic cells at a frequency several orders of magnitude higher than in germ cells. Evidence is presented suggesting that this results from regulation at the level of trans-acting functions that are required for excision or that repress excision. At the second level, germ line transposition of Tcl occurs at greater frequency in some strains than in others. The hypothesis is proposed that this is because Tcl is one component of a two-element system, the second element of which differs between strains. Evidence for a second putative transposable element family in C. elegans is presented. This family has properties that suggest a relationship to Tcl. This possibility is currently under investigation.

Evidence for a transposon in Caenorhabditis elegans.

The C. elegans genome contains a 1.7 kb repeated DNA sequence (Tc1) that is present in different numbers in various strains. In strain Bristol and 10 other strains analyzed, there are 20 +/- 5 copies of Tc1, and these are located at a nearly constant set of sites in the DNA. In Bergerac, however, there are 200 +/- 50 interspersed copies of Tc1 that have arisen by insertion of Tc1 elements into new genomic sites. The interspersed copies of Tc1 have a conserved, nonpermuted structure. The structure of genomic Tc1 elements was analyzed by the cloning of a single Tc1 element from Bergerac and the comparison of its structure with homologous genomic sequences in Bristol and Bergerac. Tc1 elements at three sites analyzed in Bergerac undergo apparently precise excision from their points of insertion at high frequency.