Sodium-dependent neutral amino acid transporter type 1 is an auxiliary receptor for baboon endogenous retrovirus

The baboon endogenous retrovirus (BaEV) belongs to a large, widely dispersed interference group that includes the RD114 feline endogenous virus and primate type D retroviruses. Recently, we and another laboratory independently cloned a human receptor for these viruses and identified it as the human sodium-dependent neutral amino acid transporter type 2 (hASCT2). Interestingly, mouse and rat cells are efficiently infected by BaEV but only become susceptible to RD114 and type D retroviruses if the cells are pretreated with tunicamycin, an inhibitor of protein N-linked glycosylation. To investigate this host range difference, we cloned and analyzed NIH Swiss mouse ASCT2 (mASCT2). Surprisingly, mASCT2 did not mediate BaEV infection, which implied that mouse cells might have an alternative receptor for this virus. In addition, elimination of the two N-linked oligosaccharides from mASCT2 by mutagenesis, as substantiated by protein N-glycosidase F digestions and Western immunoblotting, did not enable it to function as a receptor for RD114 or type D retroviruses. Based on these results, we found that the related ASCT1 transporters of humans and mice are efficient receptors for BaEV but are relatively inactive for RD114 and type D retroviruses. Furthermore, elimination of the two N-linked oligosaccharides from extracellular loop 2 of mASCT1 by mutagenesis enabled it to function as an efficient receptor for RD114 and type D retroviruses. Thus, we infer that the tunicamycin-dependent infection of mouse cells by RD114 and type D retroviruses is caused by deglycosylation of mASCT1, which unmasks previously buried sites for viral interactions. In contrast, BaEV efficiently employs the glycosylated forms of mASCT1 that occur normally in untreated mouse cells.     

Localization of the receptor gene for type D simian retroviruses on human chromosome 19.

Simian retrovirus (SRV) serotypes 1 to 5 are exogenous type D viruses causing immune suppression in macaque monkeys. These viruses exhibit receptor interference with each other, with two endogenous type D viruses of the langur (PO-1-Lu) and squirrel monkey, and with two type C retroviruses, feline endogenous virus (RD114/CCC) and baboon endogenous virus (BaEV), indicating that each utilizes the same cell surface receptor (M. A. Sommerfelt and R. A. Weiss, Virology 176:58-69, 1990). Vesicular stomatitis virus pseudotype particles bearing envelope glycoproteins of RD114, BaEV, and the seven SRV strains were employed to detect receptors expressed in human-rodent somatic cell hybrids segregating human chromosomes. The only human chromosome common to all the susceptible hybrids was chromosome 19. By using hybrids retaining different fragments of chromosome 19, a provisional subchromosomal localization of the receptor gene was made to 19q13.1-13.2. Antibodies previously reported to be specific to a BaEV receptor (L. Thiry, J. Cogniaux-Leclerc, R. Olislager, S. Sprecher-Goldberger, and P. Burkens, J. Virol. 48:697-708, 1983) did not block BaEV, RD114, or SRV pseudotypes or syncytia. Antibodies to known surface markers determined by genes mapped to chromosome 19 did not block virus-receptor interaction. The identity of the receptor remains to be determined.     

N-linked glycosylation and sequence changes in a critical negative control region of the ASCT1 and ASCT2 neutral amino acid transporters determine their retroviral receptor functions

A widely dispersed interference group of retroviruses that includes the feline endogenous virus (RD114), baboon endogenous virus (BaEV), human endogenous virus type W (HERV-W), and type D primate retroviruses uses the human Na(+)-dependent neutral amino acid transporter type 2 (hASCT2; gene name, SLC1A5) as a common cell surface receptor. Although hamster cells are fully resistant to these viruses and murine cells are susceptible only to BaEV and HERV-W pseudotype viruses, these rodent cells both become highly susceptible to all of the viruses after treatment with tunicamycin, an inhibitor of protein N-linked glycosylation. A partial explanation for these results was recently provided by findings that the orthologous murine transporter mASCT2 is inactive as a viral receptor, that a related (ca. 55% identity) murine paralog (mASCT1; gene name, SLC1A4) mediates infections specifically of BaEV and HERV-W, and that N-deglycosylation of mASCT1 activates it as a receptor for all viruses of this interference group. Because the only two N-linked oligosaccharides in mASCT1 occur in the carboxyl-terminal region of extracellular loop 2 (ECL2), it was inferred that this region contributes in an inhibitory manner to infections by RD114 and type D primate viruses. To directly and more thoroughly investigate the receptor active sites, we constructed and analyzed a series of hASCT2/mASCT2 chimeras and site-directed mutants. Our results suggest that a hypervariable sequence of 21 amino acids in the carboxyl-terminal portion of ECL2 plays a critical role in determining the receptor properties of ASCT2 proteins for all viruses in this interference group. In addition, we analyzed the tunicamycin-dependent viral susceptibility of hamster cells. In contrast to mASCT1, which contains two N-linked oligosaccharides that partially restrict viral infections, hamster ASCT1 contains an additional N-linked oligosaccharide clustered close to the others in the carboxyl-terminal region of ECL2. Removal of this N-linked oligosaccharide by mutagenesis enabled hamster ASCT1 to function as a receptor for all viruses of this interference group. These results strongly suggest that combinations of amino acid sequence changes and N-linked oligosaccharides in a critical carboxyl-terminal region of ECL2 control retroviral utilization of both the ASCT1 and ASCT2 receptors.     

Nucleotide sequences of the retroviral long terminal repeats and their adjacent regions.

The nucleotide sequences of the LTRs and their adjacent regions from 19 type C and one type B retrovirus were compared. Salient features are: (a) The R regions in the genomes of most of the type C retroviruses begin with GC and end with CA. (b) The mammalian type C retroviruses have a polyadenylation signal "AATAAA" in the R region, and most have a "CAT" box and a "TATA" box in the U3 region. (c) The avian type C retroviruses have an AATAAA sequence, and some also have "CAT-like" and "TATA-like" boxes, in the U3 region. (d) As with many transposable elements, the IR regions of the proviruses begin with TG and end with CA, and the DR sequences in the host genomes flanking the proviruses are different from one another. Although SNV is an avian retrovirus, the nucleotide sequences in the R, U5, TBS, and PU region are more similar to the mammalian type C than to the avian type C retroviruses.     

Analysis of the virogenes related to the rhesus monkey endogenous type C retrovirus in monkeys and apes.

Molecular hybridization studies were carried out by using a [3H]complementary DNA (cDNA) probe to compare the endogenous type C retrovirus of rhesus monkeys (MMC-1) with other known retroviruses and related sequences in various primate DNAs. The genomic RNA of the endogenous type C retrovirus of stumptail monkeys (MAC-1) was found to be highly related to the MMC-1 cDNA probe, whereas the other retroviral RNAs tested showed no homology. Related sequences were found in Old World monkey DNAs and to a lesser extent in gorilla dn chimpanzee DNAs. No homology was detected between MMC-1 cDNA and DNA of gibbon, orangutan, or human origin. Restriction endonuclease analysis of genomic DNA indicated that many of the several hundred sequences related to MMC-1 in rhesus monkey DNA differed from that integrated into DNA of infected canine cells. Gorilla and chimpanzee DNAs contained a specific restriction endonuclease fragment of the MMC-1 genome.     

Complete amino acid sequence of Bombyx egg-specific protein deduced from cDNA clone

Complementary (c)DNA coding for an insect yolk protein, the egg-specific protein of the silkworm Bombyx mori was cloned and the nucleotide sequence determined. The sequence covers the entire coding region of 1,677 base pairs with 5′ and 3′ noncoding regions (21 and 115 base pairs, respectively). The deduced amino acid sequence of the egg-specific protein consists of 559 amino acid residues. The NH₂-terminal 18 amino acid sequence is enriched in hydrophobic amino acids and assumed to be a signal peptide. A sequence, Asn-X-Thr, a potential N-linked glycosylation site, is found at positions 191 to 193. A serine-rich domain is localized in the region from 63 to 90, in which phosphorylation takes place. Cys His motif in 405 to 415 is analogous to a proposed metal binding sequence. Lys¹³²-Asn¹³³ and Arg²²⁸-Asp²²⁹ are probably the sites cleaved by the egg-specific protein protease that appears during embryogenesis. The derived amino acid sequence has no appreciable homology to other sequenced proteins.     

Conserved Region of Mammalian Retrovirus RNA

The viral RNAs of various mammalian retroviruses contain highly conserved sequences close to their 3' ends. This was demonstrated by interviral molecular hybridization between fractionated viral complementary DNA (cDNA) and RNA. cDNA near the 3' end (cDNA(3')) from a rat virus (RPL strain) was fractionated by size and mixed with mouse virus RNA (Rauscher leukemia virus). No hybridization occurred with total cDNA (cDNA(total)), in agreement with previous results, but a cross-reacting sequence was found with the fractionated cDNA(3'). The sequences between 50 to 400 nucleotides from the 3' terminus of heteropolymeric RNA were most hybridizable. The rat viral cDNA(3') hybridized with mouse virus RNA more extensively than with RNA of remotely related retroviruses. The related viral sequence of the rodent viruses (mouse and rat) showed as much divergence in heteroduplex thermal denaturation profiles as did the unique sequence DNA of these two rodents. This suggests that over a period of time, rodent viruses have preserved a sequence with changes correlated to phylogenetic distance of hosts. The cross-reacting sequence of replication-competent retroviruses was conserved even in the genome of the replication-defective sarcoma virus and was also located in these genomes near the 3' end of 30S RNA. A fraction of RD114 cDNA(3'), corresponding to the conserved region, cross-hybridized extensively with RNA of a baboon endogenous virus (M7). Fractions of similar size prepared from cDNA(3') of MPMV, a primate type D virus, hybridized with M7 RNA to a lesser extent. Hybridization was not observed between Mason-Pfizer monkey virus and M7 if total cDNA's were incubated with viral RNAs. The degree of cross-reaction of the shared sequence appeared to be influenced by viral ancestral relatedness and host cell phylogenetic relationships. Thus, the strikingly high extent of cross-reaction at the conserved region between rodent viruses and simian sarcoma virus and between baboon virus and RD114 virus may reflect ancestral relatedness of the viruses. Slight cross-reaction at the site between type B and C viruses of rodents (mouse mammary tumor virus and RPL virus, 58-2T) or type C and D viruses of primates (M7, RD114, and Mason-Pfizer monkey virus) may have arisen at the conserved region through a mechanism that depends more on the phylogenetic relatedness of the host cells than on the viral type or origin. Determining the sequence of the conserved region may help elucidate this mechanism. The conserved sequences in retroviruses described here may be an important functional unit for the life cycle of many retroviruses.     

Repetitive sequences in class-switch recombination regions of immunoglobulin heavy chain genes

Immunoglobulin class switch involves a unique recombination event that takes place at the region 5′ to each heavy chain constant region gene during B lymphocyte differentiation. Such regions that are responsible for the class-switch recombination are defined as S regions (Kataoka et al., Proc. Natl. Acad. Sci. USA 77, 919, 1980). We have cloned a rearranged γ2b gene from a mouse myeloma (MPC11) and compared its structure with the germ line counterparts. The rearranged γ2b gene contained the 5′ flanking region of the γ3 gene (S_γ3 region) which are linked to the 5′ flanking region of the γ2b gene (S_γ2b region). We have determined nucleotide sequences surrounding the recombination site of the rearranged and germ line γ2b genes, which include the S_γ2b and S_γ3 regions. Both _γ2b and S_γ3 regions comprise tandem repetition of conserved units of 49 bp. Similar 49 bp repeating units are also found in the previously determined sequence of the S_γ1 region in which class-switch recombination took place in MC101 myeloma. The nucleotide sequences of the S_γ1, S_γ2b and S_γ3 repeating units share significant homology with each other. The Sμ region, partial nucleotide sequence of which was previously determined, contains abundant short sequences such as AGCT, TGGG and AGCTGGGG which are shared in common by repeating sequences in S_γ regions. These results suggest that the recombination responsible for class switch from μ to γ or from a γ to another γ, may be facilitated directly or indirectly by homology of repeating sequences in S regions.     

The untranslated regions of β-globin mRNA evolve at a functional rate in higher primates

We have sequenced the 3′ and 5′ untranslated regions of β-globin mRNAs from cebus monkey, rhesus monkey and chimpanzee. A comparison with the corresponding human sequences reveals that the rate of sequence divergence among the higher primates is the same in the 3′ and 5′ noncoding regions and that this rate is several times lower than the rate for silent substitutions in the coding regions. In addition, the rate of sequence divergence in the 3′ untranslated region of the primate β-globin mRNA is several times lower than the rate calculated for this region from other comparisons. The low rate of sequence divergence in the noncoding 3′ end of the primate β-globin mRNAs may indicate a specialized and significant function for this region in the higher primates.     

Similarity between 5'- and 3'-terminal nucleotide sequences and double-stranded RNA-derived sequences of eukaryotic mRNA

It has been reported recently that parts of the nucleotide sequences present in the 5′- and 3′-terminal regions of cytoplasmic mRNA are derived from double-stranded hairpin structures of heterogeneous nuclear RNA—a putative mRNA precursor (Naora, 1979). In order to explore the nature of double-stranded hairpin structures, using the sequencing data of human and rabbit globin mRNA and hen ovalbumin mRNA, we examined the following possibility: that certain regions of both the 5′- and 3′-terminal nucleotide sequences of mature mRNA were present in double-stranded hairpin structures covalently linked to both sides of the message sequence in the precursor mRNA molecule and that these double-stranded hairpin structures are similar to each other. The results support the above possibility by showing substantial similarity of nucleotide sequences between the 5′- and 3′-terminal regions of these mRNAs in terms of the formation of similar double-stranded hairpin structures.     

MuERVC: a new family of murine retrovirus-related repetitive sequences and its relationship to previously known families

Characterization of a new murine endogenous retrovirus-related sequence named MuERVC-C105 is reported. This sequence was found to be most similar to the murine leukemia C-type retroviruses and to murine defective endogenous retrovirus-like families MuRRS and MuRVY, although MuERVC-C105 has a novel LTR. MuERVC-C105, like MuRRS and MuRVY, represents a family of retrovirus-like sequences characterized by many defects in its reading frames. Phylogenetic analyses, in particular analysis of nonsynonymous and synonymous nucleotide substitutions in the descent of these sequences, revealed that the MuERVC-C105, MuRRS, and MuRVY families were each derived from a different nondefective retroviral ancestor, thus justifying the new family name MuERVC. These nondefective ancestors cluster together with Gibbon Ape Leukemia Virus, but were nearly as distinct from each other as are other subgroups of murine leukemia virus (MoMLV, BaEV, GALV). The analysis further indicated that, in spite of the high density of defects in these three families, most of their divergence from their common ancestor was as nondefective retroviruses. Received: 4 August 1998 / Accepted: 30 December 1998     

Nucleotide sequence of Fujinami sarcoma virus: evolutionary relationship of its transforming gene with transforming genes of other sarcoma viruses

We determined the entire nucleotide sequence of the molecularly cloned DNA of Fujinami sarcoma virus (FSV). The sequence of 1182 amino acids was deduced for the FSV transforming protein P130, the product of the FSV gag-fps fused gene. The P130 sequence was highly homologous to the amino acid sequence obtained for the gag-fes protein of feline sarcoma virus, supporting the view that fps and fes were derived from a cognate cellular gene in avian and mammalian species. In addition, FSV P130 and p60^src of Rous sarcoma virus were 40% homologous in the region of the carboxyterminal 280 amino acids, which includes the phosphoacceptor tyrosine residue. These results strongly suggest that the 3′ region of fps/fes and src originated from a common progenitor sequence. A portion (the U3 region) of the long terminal repeat of FSV DNA appears to be unusual among avian retroviruses in its close similarity in sequence and overall organization to the same region of the endogenous viral ev1 DNA.     

Sequences of cDNAs for human salivary and pancreatic α-amylases

The nucleotide sequences of the cloned human salivary and pancreatic α-amylase cDNAs correspond to the continuous mRNA sequences of 1768 and 1566 nucleotides, respectively. These include all of the amino acid coding regions. Salivary cDNA contains 200 bp in the 5′-noncoding region and 32 in the 3′-noncoding region. Pancreatic cDNA contains 3 and 27 bp of 5′- and 3′-noncoding regions, respectively. The nucleotide sequence humology of the two cDNAs is 96% in the coding region, and the predicted amino acid sequences are 94% homologous.Comparison of the sequences of human α-amylase cDNAs with those previously obtained for mouse α-amylase genes (Hagenbuchle et al., 1980; Schibler et al., 1982) showed the possibility of gene conversion between the two genes of human α-amylase.     

Discovery of a New Endogenous Type C Retrovirus (FcEV) in Cats: Evidence for RD-114 Being an FcEVGag-Pol/Baboon Endogenous Virus BaEVEnv Recombinant

Analysis of a cat genomic DNA library showed that cats harbor a previously unrecognized endogenous type C retrovirus, whose env gene has homology to the murine Fv-4 resistance gene. This unique retrovirus, designated FcEV (Felis catus endogenous retrovirus), has a type C pol gene, closely related to the primate Papio cynocephalus endogenous virus (PcEV) pol, not overlapping the env gene, unlike in other type C retroviruses, and is presumably present in a higher copy number than RD-114. Phylogenetic analysis of FcEV and RD-114 fragments amplified from cat species and comparison with baboon endogenous virus (BaEV) fragments from monkeys suggested that RD-114 does not represent the cat strain of BaEV but is actually a new recombinant between FcEV type C genes and the env gene of BaEV. Although BaEV did appear to have infected an ancestor of the domestic cat lineage, it was a de novo recombinant that made its way into the cat germ line.     

A unique,thermostable dimer linkage structure of RD114 retroviral RNA

Retroviruses package their genome as RNA dimers linked together primarily by base-pairing between palindromic stem–loop (psl) sequences at the 5′ end of genomic RNA. Retroviral RNA dimers usually melt in the range of 55°C–70°C. However, RNA dimers from virions of the feline endogenous gammaretrovirus RD114 were reported to melt only at 87°C. We here report that the high thermal stability of RD114 RNA dimers generated from in vitro synthesized RNA is an effect of multiple dimerization sites located in the 5′ region from the R region to sequences downstream from the splice donor (SD) site. By antisense oligonucleotide probing we were able to map at least five dimerization sites. Computational prediction revealed a possibility to form stems with autocomplementary loops for all of the mapped dimerization sites. Three of them were located upstream of the SD site. Mutant analysis supported a role of all five loop sequences in the formation and thermal stability of RNA dimers. Four of the five psls were also predicted in the RNA of two baboon endogenous retroviruses proposed to be ancestors of RD114. RNA fragments of the 5′ R region or prolonged further downstream could be efficiently dimerized in vitro. However, this was not the case for the 3′ R region linked to upstream U3 sequences, suggesting a specific mechanism of negative regulation of dimerization at the 3′ end of the genome, possibly explained by a long double-stranded RNA region at the U3-R border. Altogether, these data point to determinants of the high thermostability of the dimer linkage structure of the RD114 genome and reveal differences from other retroviruses.     

Nucleotide sequences of influenza virus segments 1 and 3 reveal mosaic structure of a small viral RNA segment

Defective interfering RNAs of influenza virus are small segments derived from viral segments 1, 2 and 3. We present here the complete nucleotide sequences of segments 1 and 3 from the human influenza strain A/PR/8/34 and deduce that the sequence of a small RNA segment from A/NT/60/68, apparently a defective interfering RNA, is derived from five separate regions in segment 3 and from one region in segment 1. These regions, which are located near the termini of the two parental segments, are arranged in the small RNA segment in an alternating fashion: thus a region derived from near a 5′ terminus is adjacent to a region derived from near a 3′ terminus. We propose that the small segment is generated during positive strand synthesis as a result of the viral polymerase pausing at uridine-rich sequences in the template and reinitiating synthesis at another site.