猪皮肤成纤维细胞PERV体外和体内感染性的研究

为了解猪皮肤成纤维细胞PERV在体外和体内的感染性,通过建立猪皮肤成纤维细胞系,将所建细胞系与人胚胎肾293细胞体外共培养,并移植于严重联合免疫缺陷鼠(SCID鼠)皮下进行猪皮肤成纤维细胞PERV的体外和体内感染性实验。结果表明,猪皮肤成纤维细胞与人胚胎肾细胞共培养过程中,猪内源性逆转录病毒感染人胚胎肾细胞,进一步证实和拓宽了猪细胞PERV感染人细胞的范畴;猪皮肤成纤维细胞移植SCID鼠皮下后,导致SCID鼠发生猪细胞微嵌合(78．57％)和PERV在体内感染(85．71％)并且波及远离移植部位的多种组织或器官,但是并未检测出SCID鼠组织中表达PERV env RNA。这就证实了猪皮肤成纤维细胞PERV的体外感染性和在小鼠体内的感染性,但未能找到PERV在体内活跃复制的明显证据。因而,在猪异种移植过程中PERV传播的潜在危险仍然是必须高度重视的生物安全性问题。     

Comparison of replication-competent molecular clones of porcine endogenous retrovirus class A and class B derived from pig and human cells

Vertically transmitted endogenous retroviruses pose an infectious risk in the course of pig-to-human transplantation of cells, tissues, and organs. Two classes of polytropic type C porcine endogenous retroviruses (PERV) which are infectious for human cells in vitro are known. Recently, we described the cloning and characterization of replication-competent PERV-B sequences from productively infected human cells (F. Czauderna, N. Fischer, K. Boller, R. Kurth, and R. R. Tönjes, J. Virol. 74:4028–4038, 2000). Here, we report the isolation of infectious molecular PERV-A and PERV-B clones from pig cells and compare these proviruses with clones derived from infected human 293 cells. In addition to clone PERV-A(42) derived from 293 cells, four “native” full-length proviral PERV sequences derived from a genomic library of the porcine cell line PK15 were isolated. Three identical class A clones, designated PK15-PERV-A(42), PK15-PERV-A(45), and PK15-PERV-A(58), and one class B clone, PK15-PERV-B(213), were characterized. PK15-PERV-B(213) is highly homologous but distinct from the previously described clone PERV-B(43). PK15-PERV-A(58) demonstrates close homology to PERV-A(42) in env and to PERV-C in long terminal repeat, gag, and pro/pol sequences. All three PERV clones described here were replication competent upon infection of susceptible cell lines. The findings suggest that the pig genome harbors a limited number of infectious PERV-A and -B sequences.A better understanding of the cellular and molecular basis of transplant rejection and the generation of transgenic donor animals bearing genes that mediate protection towards rejection (3, 24, 25) have stimulated approaches to use xenotransplantation, i.e., the therapeutic use of animal cells, tissues, and organs, to overcome the shortage of allogeneic transplants (7). Pigs are preferred as donors for xenotransplants (10).Major concerns have been raised about the possibility of introducing new microbial agents from the animal into the recipient, leading to xenozoonosis (2, 11, 18, 27). Viruses that are germ line transmitted, i.e., porcine endogenous retroviruses (PERV) (21), and DNA viruses that can persist without symptoms in their natural host and are transmitted via intrauterine or transplacentar pathways, e.g., herpesviruses (8), are of particular interest.Approximately 50 integration sites of PERV exist in the genomes of different pig breeds (1, 14, 21), and at least three classes are known (14, 28). Those classes, named PERV-A, -B, and -C (PERV-C is also known as PERV-MSL), display high sequence homology in the genes for group-specific antigens (gag) and polymerase (pol) but differ in the envelope (env) genes which determine the host range. In addition, the existence of multiple other PERV sequences in domestic pigs and their phylogenetic relatives has been described. However, only classes A, B, and C appear to be infectious (22).PERV that are released from different pig cell lines are able to infect human cells in vitro (15, 32, 33). PERV-C (1) is ecotropic compared to PERV-A and PERV-B, which are polytropic as deduced from pseudotype experiments utilizing the corresponding env genes (28).A retrospective investigation of 160 patients who had been treated with porcine cells and tissues showed no evidence for transmission of PERV (20); however, no long-term transplantation of a whole vascularized organ has been attempted so far. In contrast, a recent study utilizing NOD/SCID mice revealed PERV infection in several tissue compartments after transplantation of pig pancreatic islets, indicating the xenozoonotic potential of those retroviruses (31).Recently, we have reported the isolation of replication-competent PERV-B molecular clones derived from human embryonic kidney cells infected with PERV (293 PERV-PK) (5). In this communication, we describe the cloning and characterization of PERV-A and PERV-B proviral sequences derived from the porcine kidney cell line PK15 as well as the characterization of the molecular clone PERV-A(42); isolated from 293 PERV-PK cells (5). [Hereafter, clones derived from cell line 293 PERV-PK will be designated 293-PERV-B(33), 293-PERV-B(43), and 293-PERV-A(42); clones derived from cell line PK15 will be designated PK15-PERV-A(58), and so on.] Three proviruses, one PERV-B and two PERV-A clones, produce infectious and replication-competent particles upon transfection of susceptible cells and subsequent infection of different human cell lines. Thus, this study provides the first functional PERV-A and PERV-B clones isolated directly from the pig genome and allows the comparison of proviral PERV sequences from different origins at the molecular and cellular level.     

猪内源性反转录病毒在中国实验小型猪中的存在与表达

目的对中国实验小型猪中内源性反转录病毒的存在与mRNA的表达进行检测,摸清中国实验小型猪中内源性反转录病毒的携带情况.方法根据已发表的PERV的序列设计并合成了三对引物,分别用于检测PERV核心蛋白基因(gag)、多聚酶基因(pol)及囊膜基因(env)的存在与表达;同时,根据目前通用的env基因分型方法合成了三对用于分型检测的引物env-A、env-B、env-C.应用PCR、RT-PCR扩增的方法,对来自于中国实验小型猪外周血淋巴细胞的DNA和RNA样品进行了检测.结果在6个被检DNA样品中均检出了PERV特异性DNA的存在;同样,在被检RNA样品中均有PERV特异性RNA的表达,且所表达的PERV均为A型和B型,在所有样品中均未检出C型PERV的表达.结论初步表明中国实验小型猪中存在内源性反转录病毒序列,且能以mRNA的形式表达,这一结果为我国特有小型猪的开发、利用及其病毒安全性评价奠定了基础.     

The significance of N-linked glycosylation in pig endogenous retrovirus infectivity

The significance of the envelope glycoprotein in the transmission of pig endogenous retrovirus (PERV) to human cells was investigated. Pig endothelial cells (PEC) were transduced with the LacZ gene by a pseudotype infection and then infected with PERV subtype B. Culture supernatants of the infected PEC previously incubated with several types of drugs were inoculated into HEK293 cells. The inoculated cells were then stained and the number of LacZ-positive foci was counted. PERV from tunicamycin treated PEC was not transmitted to human cells, indicating the importance of N-linked sugars in this process. Moreover, while inhibition of the terminal alpha-glucose residues from the precursor N-glycan by castanospermine and 1-deoxynojirimycin attenuated PERV infectivity, the mannosidase inhibitors, 1-deoxymannojirimycin and swainsonine, upregulated the infectivity. In addition, treatment with alpha-mannosidase and incubation with concanavalin A completely abrogated the transmission of PERV to HEK293. These data imply that the high-mannose type of N-glycan plays a key role in PERV infectivity.     

Characterization of chromosomally assigned replication-competent gamma porcine endogenous retroviruses derived from a large white pig and expression in human cells

Vertically transmitted endogenous retroviruses pose an infectious risk in the course of pig-to-human transplantation of cells, tissues, and organs. Two classes of polytropic type C porcine endogenous retroviruses (PERV) productively infect human cells in vitro. The cloning and characterization of replication-competent PERV-B sequences from infected human cells (F. Czauderna, N. Fischer, K. Boller, R. Kurth, and R. R. T?njes, J. Virol. 74:4028-4038, 2000) as well as the cloning of functional PERV-A and -B sequences from porcine cell line PK15 (U. Krach, N. Fischer, F. Czauderna, and R. R. T?njes, J. Virol. 75:5465-5472, 2001) have been previously described. Here we report the isolation of four full-length proviral sequences from a porcine bacterial artificial chromosome (BAC) library that comprises chromosomally assigned PERV. Clones Bac-PERV-A(130A12) and Bac-PERV-A(151B10) map to pig chromosome 1 and demonstrate close homology to PK15-PERV-A(58) in env and to PERV-MSL in long terminal repeat (LTR), gag, and pro/pol sequences. Clone Bac-PERV-A(463H12) is located on pig chromosome 3 and demonstrates close homology to PK15-PERV-A(58) in env and to 293-PERV-B(43) in LTR, gag, and pro/pol (Czauderna et al.; R. R. T?njes, F. Czauderna, N. Fischer, U. Krach, K. Boller, P. Chardon, C. Rogel-Gailard, M. Niebert, G. Scheef, A. Werner, and R. Kurth, Transplant Proc. 32:1158-1161, 2000). Clone Bac-PERV-B(192B9) is located on pig chromosome 7 in the swine leukocyte antigen region and is highly homologous with but distinct from the previously described functional clone 293-PERV-B(43) and bears the number of repeats initially observed in the LTRs of clone 293-PERV-A(42) (Czauderna et al.; Krach et al.). Clones Bac-PERV-A(130A12), Bac-PERV-A(151B10), and Bac-PERV-A(463H12) were replication competent upon transfection into susceptible 293 and HeLa cells. Bac-PERV-B(192B9), however, bears two stop codons in pro/pol preventing this clone from being replication competent in some individual pigs, but initial screenings indicate that this provirus might be intact in others. The data suggest that the porcine genome harbors a limited number of infectious PERV sequences, allowing for specific screening in different pig breeds.     

Isolation and characterization of an infectious replication-competent molecular clone of ecotropic porcine endogenous retrovirus class C

Xenotransplantation of pig organs is complicated by the existence of polytropic replication-competent porcine endogenous retroviruses (PERV) capable of infecting human cells. The potential for recombination between ecotropic PERV-C and human-tropic PERV-A and PERV-B adds another level of infectious risk. Proviral PERV-C were characterized in MAX-T cells derived from d/d haplotype miniature swine. Three proviruses were cloned from a genomic library. Clone PERV-C(1312) generated infectious particles after transfection into porcine ST-IOWA cells. Electron microscopy revealed the same morphologies of virions in MAX-T cells and in ST-IOWA cells infected with cell-free PERV-C(1312) particles, indicating that MAX-T cells harbor one functional PERV-C provirus.     

Mapping dispersed repetitive loci using semi-specific PCR cloning and somatic cell hybrid mapping

A simple and effective method based upon semi-specific PCR followed by cloning has been developed. Chromosomal mapping of the generated fragment on a somatic cell hybrid panel identifies the chromosomal position, and yields a unique sequence tag for the site. Using this method, the chromosomal location of one porcine endogenous retrovirus (PERV) was determined. The porcine genomic sequences were first amplified by PCR using a PERV-specific primer and a porcine short interspersed nuclear element (SINE)-specific primer. PCR products were cloned, and those sequences that contained PERV plus flanking regions were selected using a second round of PCR and cloning. Sequences flanking the PERV were determined and a PERV-B was physically mapped on porcine chromosome 17 using a somatic hybrid panel. The general utility of the method was subsequently demonstrated by locating PERVs in the genome of PERV infected human 293 cells. This method obviates the need for individual library construction or linker/adaptor ligation, and can be used to quickly locate individual sites of moderately repeated, dispersed DNA sequences in any genome.     

Comparison of PERV genomic locations between Asian and European pigs

Xenotransplantation from pigs provides a possible solution to the shortage of human organs for allotransplantation. Porcine endogenous retroviruses (PERVs) are a possible obstacle to using porcine organs in addition to the immunological barriers. Three main types of PERVs (A, B and C) have been previously investigated in diverse pig breeds. To examine the copy numbers of PERVs and their genomic locations in the Korean native pig genome, we screened a BAC (Bacterial Artificial Chromosome) library with PERV-specific protease primers for initial recognition of PERV-positive clones and three sets of envelope-specific primers for the identification of PERV types. A total of 45 PERV-positive clones, nine PERV-A and 36 PERV-B, have been identified from the library screening and the BAC contigs were constructed using the primers designed from BAC end sequences (BESs). These primers were also used for SCH (Somatic Cell Hybrid) and RH (Radiation Hybrid) mapping of the PERV-positive clones. The results indicate that 45 PERV-positive BAC clones belong to nine contigs and a singleton. SCH and IMpRH (INRA-Minnesota Porcine Radiation Hybrid) mapping results indicated that there are at least eight separate PERV genomic locations, consisting of three PERV-A and five PERV-B. One contig could not be mapped, and two contigs are closely located on SSC7. Southern blotting indicates there may be up to 15 additional sites. Further investigation of these clones will contribute to a general strategy to generate PERV-free lines of pigs suitable for xenotransplantation.     

Prevention of PERV infections in pig to human xenotransplantation by the RNA interference silences gene

The possibility of preventing the transmission of porcine endogenous retrovirus (PERV) to human cells using short interfering RNAs (siRNA) was investigated. The siRNA for the p30 of PERV gag region was cloned into pSUPER, the polymerase-III H1-RNA gene promoter. A green fluorescence protein (GFP) was also cloned into pSUPER to establish pSXGH. Pig endothelial cells (PEC) were transduced with the LacZ gene by pseudotype infection, and infected with PERV subtype B, resulting in the formation of PEC(LacZ)/PB. The PEC(LacZ)/PB was next transfected with pSXGH-siRNA. The expression of siRNA was provisionally checked by determining the level of expression of GFP. Culture supernatants of infected cells were then inoculated into HEK293 cells. The siRNA clearly destroyed the PERV infectivity of PEC(LacZ)/PB in both transient cell lines and stable clones. Moreover, the decreased levels of mRNA and gag protein were evidenced in the stable clones by real-time PCR and Western blotting, respectively. The final goal of our study was to establish a transgenic pig expressing the siRNA for PERV. The results suggest that siRNA represents a novel approach for controlling PERV infections in clinical xenotransplantation.     

Evolutionary spread and recombination of porcine endogenous retroviruses in the suiformes

Different Suiformes with increasing phylogenetic distance to the common pig (Sus scrofa) were assayed for the presence of porcine endogenous retroviruses (PERV) in general (pol gene), while the distribution of long terminal repeat (LTR) types (with or without repeats in U3) and env genes (classes A, B, and C) were determined in detail. PERV was not detectable in the most distantly related species, while classes PERV-A and PERV-B are present in Suiformes originating in the Pliocene epoch, and class PERV-C was detectable only in S. scrofa and in closely related species originating in the Holocene epoch. This distribution pattern of PERV classes is in line with our previous study on the age of PERV (45) and suggests an African origin of about 7.5 million years ago (MYA) and a gradual spread of PERV through the Suiformes. It seems likely that PERV-C originated more recently (1.5 to 3.5 MYA) by recombination with a homologue of unknown descent, while the origin of the repeatless LTR was a separate event approximately 3.5 MYA.     

Restriction of porcine endogenous retrovirus by porcine APOBEC3 cytidine deaminases

Xenotransplantation of porcine cells, tissues, and organs shows promise to surmount the shortage of human donor materials. Among the barriers to pig-to-human xenotransplantation are porcine endogenous retroviruses (PERV) since functional representatives of the two polytropic classes, PERV-A and PERV-B, are able to infect human embryonic kidney cells in vitro, suggesting that a xenozoonosis in vivo could occur. To assess the capacity of human and porcine cells to counteract PERV infections, we analyzed human and porcine APOBEC3 (A3) proteins. This multigene family of cytidine deaminases contributes to the cellular intrinsic immunity and act as potent inhibitors of retroviruses and retrotransposons. Our data show that the porcine A3 gene locus on chromosome 5 consists of the two single-domain genes A3Z2 and A3Z3. The evolutionary relationships of the A3Z3 genes reflect the evolutionary history of mammals. The two A3 genes encode at least four different mRNAs: A3Z2, A3Z3, A3Z2-Z3, and A3Z2-Z3 splice variant A (SVA). Porcine and human A3s have been tested toward their antiretroviral activity against PERV and murine leukemia virus (MuLV) using novel single-round reporter viruses. The porcine A3Z2, A3Z3 and A3Z2-Z3 were packaged into PERV particles and inhibited PERV replication in a dose-dependent manner. The antiretroviral effect correlated with editing by the porcine A3s with a trinucleotide preference for 5' TGC for A3Z2 and A3Z2-Z3 and 5' CAC for A3Z3. These results strongly imply that human and porcine A3s could inhibit PERV replication in vivo, thereby reducing the risk of infection of human cells by PERV in the context of pig-to-human xenotransplantation.     

Identification of exogenous forms of human-tropic porcine endogenous retrovirus in miniature Swine

The replication of porcine endogenous retrovirus subgroup A (PERV-A) and PERV-B in certain human cell lines indicates that PERV may pose an infectious risk in clinical xenotransplantation. We have previously reported that human-tropic PERVs isolated from infected human cells following cocultivation with miniature swine peripheral blood mononuclear cells (PBMC) are recombinants of PERV-A with PERV-C. Here, we report that these recombinants are exogenous viruses in miniature swine; i.e., they are not present in the germ line DNA. These viruses were invariably present in miniature swine that transmitted PERV to human cells and were also identified in some miniature swine that lacked this ability. These data, together with the demonstration of the absence of both replication-competent PERV-A and recombinant PERV-A/C loci in the genome of miniature swine (L. Scobie, S. Taylor, J. C. Wood, K. M. Suling, G. Quinn, C. Patience, H.-J. Schuurman, and D. E. Onions, J. Virol. 78:2502-2509, 2004), indicate that exogenous PERV is the principal source of human-tropic virus in these animals. Interestingly, strong expression of PERV-C in PBMC correlated with an ability of the PBMC to transmit PERV-A/C recombinants in vitro, indicating that PERV-C may be an important factor affecting the production of human-tropic PERV. In light of these observations, the safety of clinical xenotransplantation from miniature swine will be most enhanced by the utilization of source animals that do not transmit PERV to either human or porcine cells. Such animals were identified within the miniature swine herd and may further enhance the safety of clinical xenotransplantation.     

Evidence and consequence of porcine endogenous retrovirus recombination

The genetic nature and biological effects of recombination between porcine endogenous retroviruses (PERV) were studied. An infectious molecular clone was generated from a high-titer, human-tropic PERV isolate, PERV-A 14/220 (B. A. Oldmixon, et al. J. Virol. 76:3045-3048, 2002; T. A. Ericsson et al. Proc. Natl. Acad. Sci. USA 100:6759-6764, 2003). To analyze this sequence and 15 available full-length PERV nucleotide sequences, we developed a sequence comparison program, LOHA(TM) to calculate local sequence homology between two sequences. This analysis determined that PERV-A 14/220 arose by homologous recombination of a PERV-C genome replacing an 850-bp region around the pol-env junction with that of a PERV-A sequence. This 850-bp PERV-A sequence encompasses the env receptor binding domain, thereby conferring a wide host range including human cells. In addition, we determined that multiple regions derived from PERV-C are responsible for the increased infectious titer of PERV-A 14/220. Thus, a single recombination event may be a fast and effective way to generate high-titer, potentially harmful PERV. Further, local homology and phylogenetic analyses between 16 full-length sequences revealed evidence for other recombination events in the past that give rise to other PERV genomes that possess the PERV-A, but not the PERV-B, env gene. These results indicate that PERV-A env is more prone to recombination with heterogeneous backbone genomes than PERV-B env. Such recombination events that generate more active PERV-A appear to occur in pigs rather frequently, which increases the potential risk of zoonotic PERV transmission. In this context, pigs lacking non-human-tropic PERV-C would be more suitable as donor animals for clinical xenotransplantation.     

Characterization of two porcine endogenous retrovirus integration loci and variability in pigs

The pig (Sus scrofa) is a potential organ donor for man but porcine endogenous retroviruses (PERVs) represent an important concern for patients, and identification or engineering of PERV-free pigs suitable for xenotransplantation is a major undertaking. Consequently, studies of variability in pigs for the presence of PERVs at specific loci are a prerequisite. We identified genomic flanking sequences of two PERVs cloned in bacterial artificial chromosomes, a replication-competent PERV-A at locus 1q2.4 and a defective PERV-B at locus 7p1.1–2. PERV-A is embedded in the second repeat of a tandem of eight 190 bp repeats. A short duplicated 4 bp cellular motif, AGAC, was found at each flank of PERV-A and a degenerate 4 bp motif was found for PERV-B. At each locus, the PERV flanks matched expressed sequence tags available in public databases. Primer pairs were designed to amplify either genomic flanks or PERV-genomic junctions. Polymerase chain reaction screening was performed on pigs from 11 distinct Chinese breeds and from the European Large White breed. PERV-B at locus 7p1.1–2 was detected in all animals whereas the presence of PERV-A at locus 1q2.4 was variable. Our results suggest that a genetic selection can be designed to identify animals lacking a potentially active PERV at a specific locus and that Chinese and European pig breeds represent large biodiversity reservoirs to explore. Our results point also to the existence of PERVs that might be fixed in the pig genome, and that might not be eliminated by classical genetic selection.Accession numbers: Nucleotide sequence data reported are available in the DDBJ/EMBL/GenBank databases under Accession numbers AY160111–AY160114