Arrangement of Integrated Avian Sarcoma Virus DNA Sequences Within the Cellular Genomes of Transformed and Revertant Mammalian Cells

We have examined the arrangement of integrated avian sarcoma virus (ASV) DNA sequences in several different avian sarcoma virus transformed mammalian cell lines, in independently isolated clones of avian sarcoma virus transformed rat liver cells, and in morphologically normal revertants of avian sarcoma virus transformed rat embryo cells. By using restriction endonuclease digestion, agarose gel electrophoresis, Southern blotting, and hybridization with labeled avian sarcoma virus complementary DNA probes, we have compared the restriction enzyme cleavage maps of integrated viral DNA and adjacent cellular DNA sequences in four different mouse and rat cell lines transformed with either Bratislava 77 or Schmidt-Ruppin strains of avian sarcoma virus. The results of these experiments indicated that the integrated viral DNA resided at a different site within the host cell genome in each transformed cell line. A similar analysis of several independently derived clones of Schmidt-Ruppin transformed rat liver cells also revealed that each clone contained a unique cellular site for the integration of proviral DNA. Examination of several morphologically normal revertants and spontaneous retransformants of Schmidt-Ruppin transformed rat embryo cells revealed that the internal arrangement and cellular integration site of viral DNA sequences was identical with that of the transformed parent cell line. The loss of the transformed phenotype in these revertant cell lines, therefore, does not appear to be the result of rearrangement or deletions either within the viral genome or in adjacent cellular DNA sequences. The data presented support a model for ASV proviral DNA integration in which recombination can occur at multiple sites within the mammalian cell genome. The integration and maintenance of at least one complete copy of the viral genome appear to be required for continuous expression of the transformed phenotype in mammalian cells.     

Structural organization and biological activity of molecular clones of the integrated genome of a BALB/c mouse sarcoma virus.

BALB/c mouse sarcoma virus (BALB-MSV) is a spontaneously occurring transforming retrovirus of mouse origin. The integrated form of the viral genome was cloned from the DNA of a BALB-MSV-transformed nonproducer NRK cell line in the Charon 9 strain of bacteriophage lambda. In transfection assays, the 19-kilobase-pair (kbp) recombinant DNA clone transformed NIH/3T3 mouse cells with an efficiency of 3 X 10(4) focus-forming units per pmol. Such transformants possessed typical BALB-MSV morphology and released BALB-MSV after helper virus superinfection. A 6.8-kbp DNA segment within the 19-kbp DNA possessed restriction enzyme sites identical to those of the linear BALB-MSV genome. Long terminal repeats of approximately 0.6 kbp were localized at either end of the viral genome by the presence of a repeated constellation of restriction sites and by hybridization of segments containing these sites with nick-translated Moloney murine leukemia virus long terminal repeat DNA. A continuous segment of at least 0.6 and no more than 0.9 kbp of helper virus-unrelated sequences was localized toward the 3' end of the viral genome in relation to viral RNA. A probe composed of these sequences detected six EcoRI-generated DNA bands in normal mouse cell DNA as well as a smaller number of bands in rat and human DNAs. These studies demonstrate that BALB-MSV, like previously characterized avian and mammalian transforming retroviruses, arose by recombination of a type C helper virus with a well-conserved cellular gene.     

Infectious and noninfectious recombinant clones of the provirus of SNV differ in cellular DNA and are apparently the same in viral DNA

Ten clones of Charon 4A containing proviruses of spleen necrosis virus, an avian retrovirus, and flanking chicken DNA sequences were isolated and characterized. Some clones gave rise to progeny with viral DNA sequences deleted or duplicated, probably as a result of crossing-over in the 600 bp terminal redundancy in viral DNA. The cellular sequences are different in each clone, indicating that all the proviruses are integrated in different sites in cellular DNA. Six clones are infectious and four are not. All the infectious molecules containing a provirus are of a similar size and are smaller than the noninfectious molecules containing a provirus. The viral DNA is not apparently different in eight clones, but two clones, one infectious and one noninfectious, lack two restriction sites each. Large changes in proviral DNA therefore do not seem responsible for the lack of infectivity of some clones. These results are consistent with the hypothesis that neighboring cellular DNA sequences control proviral expression (infectivity).     

Replication of endogenous avian retrovirus in permissive and nonpermissive chicken embryo fibroblasts.

Clones of chicken embryo fibroblasts exogenously infected with the endogenous avian retrovirus were analyzed to examine the replication of this virus in permissive (Gr+) and nonpermissive (Gr-) cells. The results demonstrate that the endogenous virus was capable of infecting both Gr+ and Gr- cells with equal efficiency. Infected clones of Gr+ and Gr- cells differed, however, in two significant ways. At the time of their initial characterization, the Gr+ clones produced 100- to 1,000-fold more virus than the Gr- clones. Further, the amount of virus produced by Gr+ clones did not change significantly during serial passage of the cells. In contrast, continued passage of the infected Gr- clones resulted in a gradual increase in the amount of virus produced. Individual clones of infected Gr- cells produced infectious virus at rates that, initially, differed by a factor of more than 10(4). The large differences in the production of virus by these clones could not be explained by equally large differences in the number of infected cells within the clonal populations. Greater than 80% of the clonal populations examined ultimately produced virus at rates that were not significantly different from the rates observed in infected Gr+ cells. Virus produced by these infected Gr- cells exhibited the same restricted replication upon establishing a new infection in nonpermissive cells. Analysis of the appearance of free and integrated viral DNA sequences during endogenous virus infection of Gr+ and Gr- cells demonstrated that, after an initial delay in the synthesis of free viral DNA in Gr- cells, the nonpermissive cells ultimately acquired as many integrated viral DNA sequences as were found in infected Gr+ cells. These results indicate that a majority of the infectious particles of the endogenous virus are capable of establishing infection in a Gr- cell and, ultimately, of producing virus at a rate that is not significantly different from that produced by infected Gr+ cells. The virus produced from the Gr- cells is not a stable genetic variant of the original endogenous virus that is capable of unrestricted replication in nonpermissive cells. The reduced efficiency with which the endogenous virus initially replicates in nonpermissive cells and the increased length of time required for infected Gr- cells to produce maximal virus titers suggest that the endogenous virus may utilize a different mechanism of replication in Gr+ and Gr- fibroblasts.     

Construction of a helper cell line for avian reticuloendotheliosis virus cloning vectors.

We wished to construct cell lines that supply the gene products of gag, pol, and env for the growth of replication-defective reticuloendotheliosis retrovirus vectors without production of the helper virus. To do this, first we located by S1 mapping the donor and acceptor splice sites of reticuloendotheliosis virus strain A. The donor splice site is ca. 850 base pairs from the 5' end of proviral DNA. It is close to or overlaps the encapsidation sequences for viral RNA. The splice acceptor site is ca. 5.6 kilobase pairs from the 5' end of proviral DNA. Therefore, the encapsidation sequences and the donor splice site were removed from viral DNA to give expression of the gag and pol genes without virus production. The promoter in the long terminal repeat was fused to a site near the first ATG codon of the env gene, thereby deleting the encapsidation sequences and the gag and pol genes to give expression of the env gene without virus production. The permissive canine cell line D17 was transfected with the two modified viral DNAs. Two cell clones that contain both modified viral DNAs support the production of replication-defective spleen necrosis virus-thymidine kinase recombinant retrovirus vectors without the production of helper virus. To prevent recombination, the vector contains deletions that overlap with deletions in the integrated helper virus DNAs. This helper cell-vector system will be useful to derive infectious recombinant virus stocks of high titer (over 10(5) thymidine kinase transforming units per ml) which are able to infect avian, rat, and dog cells without the aid of helper virus.     

Genome structure of mink cell focus-forming murine leukemia virus in epithelial mink lung cells transformed vitro by iododeoxyuridine-induced C3H/MuLV cells

We characterized mink cell focus-forming murine leukemia viruses that were isolated from C3H/MCA-5 cells after induction with 5-iododeoxyuridine in culture. Mink lung epithelial cells malignantly transformed in vitro by induced virus were the source of four molecular clones of mink cell focus-forming virus. CI-1, CI-2, CI-3, and CI-4. Three clones, CI-1, CI-2, and CI-3, had full-length mink cell focus-forming viral genomes, one of which (CI-3) was infectious. In addition, we obtained a defective viral genome (CI-4) which had a deletion in the envelope gene. A comparison between the envelope genes of CI-4 and those of spleen focus-forming virus by heteroduplex mapping showed close homology in the substitution region and defined the deletion as being identical to the p15E deletion of spleen focus-forming virus. The recombinant mink cell focus-forming genomes are not endogenous in C3H/MCA-5 cells and therefore must have been formed in culture after induction by 5-iododeoxyuridine. CI-3, the infectious clone of mink cell focus-forming murine leukemia virus, was dualtropic, and mink cells infected with CI-3 were altered in their response to epidermal growth factor. In the presence of epidermal growth factor at 10 ng/ml, uninfected mink cells retained their epithelial morphology in monolayer culture and did not form colonies in soft agar. In contrast, CI-3 virus-infected mink cells grew with fibroblastic morphology in monolayer culture and showed an increased growth rate in soft agar in the presence of epidermal growth factor.     

Analysis of integrated proviral DNA sequences with an octadecanucleotide probe designed for specific identification of spleen focus-forming virus in the mouse genome.

The Friend spleen focus-forming virus (SFFV) is an envelope gene recombinant between the ecotropic Friend murine leukemia virus and the endogenous xenotropic mink cell focus-forming retroviral sequences. We synthesized an octadecanucleotide complementary to the 3' end of the SFFV env gene designed for discriminating the SFFV proviruses from the xenotropic mink cell focus-forming virus and ecotropic exogenous or endogenous viral sequences. Under appropriate hybridization conditions this probe allowed the identification, in addition to few endogenous DNA fragments, of multiple SFFV proviruses integrated in the genome of Friend malignant cells. Therefore this probe should be of interest in further characterizing the SFFV integration sites and possibly the SFFV ancestor gene.     

Transformation-defective mutants of feline sarcoma virus which express a product of the viral src gene.

Mink cell cultures infected with the Snyder-Theilen strain of feline sarcoma-leukemia virus were cloned from single cells under conditions favoring single virus-single cell interactions. The primary colonies included (i) typical feline sarcoma virus (FeSV)-transformed nonproducer clones, one of which segregated revertants, and (ii) FeSV-infected, phenotypically normal clones, three of which spontaneously converted to the transformed phenotype. The revertants and spontaneous transformants were compared with parental and sister clones expressing the opposite phenotype. Transformed subclones formed colonies in agar, were tumorigenic in nude mice, and failed to bind epidermal growth factor, whereas flat sister subclones were indistinguishable from uninfected mink cells in each of these assays. Sister subclones derived from the same infectious event contained FeSV proviruses integrated at the same molecular site, regardless of which phenotype was expressed. One revertant clone, however, lacked most FeSV proviral DNA sequences but retained terminal portions of the FeSV genome which persisted at the original site of proviral DNA insertion. Two flat subclones expressed viral RNA and the phosphorylated "gag-x" polyprotein (pp78gag-x) encoded by the gag and src sequences of the FeSV genome. Both of these clones were susceptible to retransformation by FeSV. Although unable to induce foci, the viruses rescued from these cells contained as much FeSV RNA as the focus-forming viruses rescued from transformed sister subclones and could be retransmitted to mink cells, again inducing FeSV gene products without signs of morphological transformation. We conclude that these FeSV genomes represent transformation-defective mutants.     

Genetic analysis of myeloproliferative leukemia virus, a novel acute leukemogenic replication-defective retrovirus.

The myeloproliferative leukemia virus (MPLV) is a new acute leukemogenic, nonsarcomatogenic retroviral complex that is generated during the in vivo passage of a molecularly cloned Friend ecotropic helper virus. Examination of viral RNA expression in MPLV-producing cells revealed the presence of two distinct molecular species that hybridized with a long terminal repeat or an ecotropic env-specific probe but not with a xenotropic mink cell focus-forming virus env-specific probe derived from a spleen focus-forming virus: an 8.2-kilobase species corresponding to a full-length Friend murine leukemia virus (F-MuLV) and a deleted species with a genomic size of 7.4 kilobases. This deleted virus was biologically cloned by limiting dilutions and single cell cloning in Mus dunni fibroblasts. Three nonproducer clones with normal morphologies and containing one single integrated copy of the deleted virus were superinfected with F-MuLV, Moloney murine leukemia virus, Gross murine leukemia virus, mink cell focus-forming virus (HIX), or the amphotropic 1504 murine leukemia virus. All pseudotypes caused macroscopic and microscopic abnormalities in mice that were similar to those seen in the parental stock. A comparison of the physical maps of F-MuLV and MPLV, which was deduced from the restriction enzyme digests of unintegrated proviral DNAs, indicated that the MPLV-defective genome (i) is probably derived from F-MuLV, (ii) has conserved the F-MuLV gag and pol regions, and (iii) is deleted and rearranged in the env region in a manner that is clearly distinct from that of Friend or Rauscher spleen focus-forming viruses.     

Comparison between the viral transforming gene (src) of recovered avian sarcoma virus and its cellular homolog.

Recovered avian sarcoma viruses are recombinants between transformation-defective mutants of Rous sarcoma virus and the chicken cellular gene homologous to the src gene of Rous sarcoma virus. We have constructed and analyzed molecular clones of viral deoxyribonucleic acid from recovered avian sarcoma virus and its transformation-competent progenitor, the Schmidt-Ruppin A strain of Rous sarcoma virus. A 2.0-megadalton EcoRI fragment containing the entire src gene from each of these clones was subcloned and characterized. These fragments were also used as probes to isolate recombinant phage clones containing the cellular counterpart of the viral src gene, termed cellular src, from a lambda library of chicken deoxyribonucleic acid. The structure of cellular src was analyzed by restriction endonuclease mapping and electron microscopy. Restriction endonuclease mapping revealed extensive similarity between the src regions of Rous sarcoma virus and recovered avian sarcoma virus, but striking differences between the viral src's and cellular src. Electron microscopic analysis of heteroduplexes between recovered virus src and cellular src revealed a 1.8-kilobase region of homology. In the cellular gene, the homologous region was interrupted by seven nonhomologous regions which we interpret to be intervening sequences. We estimate the minimum length of cellular src to be about 7.2 kilobases. These findings have implications concerning the mechanism of formation of recovered virus src and possibly other cell-derived retrovirus transforming genes.     

Production of avian oncoviral subgroups after multiple infection.

The number of different oncoviral env genes that can be expressed by a single chicken embryo fibroblast was investigated. Fibroblasts were infected with one to three subgroups of Rous-associated virus, which is a nontransforming avian oncovirus, then superinfected with a transforming virus, Rous sarcoma virus, of a different subgroup. The subgroups of viruses released by the resulting clones were analyzed. When two viral subgroups were used for preinfection, all the resulting clones produced transforming virus particles having the subgroup of the superinfecting virus, and most clones produced transforming virus particles of all the infecting viral subgroups. However, when cells were preinfected with three viral subgroups, many of the resulting clones did not produce transforming virus particles having the subgroup of the superinfecting virus, and only 1 of 23 clones produced transforming particles of all the infecting viral subgroups. DNA annealing experiments showed that cells infected with three or four viral subgroups had an additional 8 to 20 copies of proviral DNA per cell. Finally, most clones resulting from cells simultaneously infected with three or four viral subgroups were able to produce virus of all infecting subgroups. It appears that the number of exogenous oncoviral env genes that can be expressed by a single cell is limited, and in the range of 4 to 8-20 per cell.     

Amphotropic proviral envelope sequences are absent from the Mus germ line.

We derived an amphotropic murine leukemia virus (MuLV) type-specific probe for use in Southern blot hybridizations with cloned and genomic DNAs. A 133-base-pair RsaI-RsaI fragment from the 5' env region of the amphotropic viral isolate 4070A was subcloned into M13mp18 and radiolabeled in vitro. The probe detected the proviral DNAs in mink cells infected with seven different amphotropic MuLV isolates. The probe did not cross hybridize with the DNAs of molecular clones of ecotropic, mink cell focus-forming, or xenotropic MuLVs; nor did it anneal to the proviral DNAs of four xenotropic or six mink cell focus-forming viral isolates grown in mink cells. DNAs of 12 inbred laboratory mouse strains and more than 15 different wild mouse species and subspecies were examined for the presence of endogenous amphotropic env-related fragments. Amphotropic env-related sequences were found only in the DNAs of wild mice trapped in southern California in an area previously shown to harbor mice producing infectious amphotropic virus. Restriction enzyme analyses of DNAs from these mice showed that amphotropic sequences were not present as germ line copies but were the result of congenital or horizontal infection or both in this population. The DNAs of 11 various mammalian and avian species, including both natural predators of mice and squabs from the farms with virus-positive mice, lacked amphotropic envelope-related sequences.     

Construction and isolation of a transforming murine retrovirus containing the src gene of Rous sarcoma virus.

Recombinant murine retroviruses containing the src gene of the avian retrovirus Rous sarcoma virus were isolated. Such viruses were isolated from cells after transfection with DNAs in which the src gene was inserted into the genome of the amphotropic murine retrovirus 4070A. The isolated viruses had functional gag and pol genes, but they were all env defective since the src gene was inserted in the middle of the env gene coding region. Infectious transforming virus could be isolated only from cells transfected with DNA constructions in which the src gene was in the same polarity as that of a long terminal repeat of the amphotropic viral genome. These recombinant viruses encoded a pp60src protein with a molecular weight similar to that of the Schmidt-Ruppin strain of Rous sarcoma virus. In addition, the src protein(s) of these recombinant viruses was as active as protein kinases in the immune complex protein kinase assay. Intravenous injection of helper-independent Moloney and Friend murine leukemia virus pseudotypes of the src recombinant viruses into 6-week-old NIH Swiss mice resulted in the appearance of splenic foci within 2 weeks, splenomegaly and, later after infection (8 to 10 weeks), anemia. Infectious transforming virus could be recovered from the spleens of diseased animals. Such viruses encoded pp60src but not p21ras or mink cell focus-forming virus-related glycoproteins.     

Suppression of multiplication of avian sarcoma virus by rapid spread of transformation-defective virus of the same subgroup.

We have tested the hypothesis that some transformation-defective (td) viruses grow faster than the avian sarcoma viruses (ASV) from which they are derived, resulting in establishment of interference by the td virus and suppression of the ASV multiplication. Using an ASV of subgroup A (ASV-A) that does not contain td virus and an independently isolated tdASV-A, we performed separate and mixed infections to test this hypothesis. At multiplicities of 1 or less, tdASV alone grew to higher titers and more rapidly than ASV alone. In mixed infections at low multiplicities that allowed spread of progeny virus, when as little as 10% of the virus inoculum was td virus, there was an excess of td virus by 2 days after infection and a decrease in the titer of ASV relative to a control infection with no td virus. In mixed infections at high multiplicities which minimized spread of progeny virus, there was no excess of td virus and the titer of ASV was not decreased relative to the control infection with no td virus. These data support the hypothesis that we proposed and indicate that deletions in the ASV src gene may not be a high-frequency event. We also present data concerning the amounts of unintegrated viral DNA found after the separare and mixed infections. There was no simple correlation between the amounts of unintegrated viral DNA early after infection and the titers of virus produced, indicating perhaps that virus production was determined by integrated viral DNA.     

Helper-independent transformation by unintegrated Harvey sarcoma virus DNA.

We have studied the unintegrated infectious DNA of Harvey sarcoma virus (Ha-SV) and Moloney leukemia virus (Mo-MuLV). The source of infectious viral DNA was the Hirt supernatant fraction from cells acutely infected with Ha-SV and Mo-MuLV. To obtain a direct quantitative assay for infectious viral DNA, recipient mouse cells were first exposed to calcium phosphate-precipitated viral DNA and then treated with dimethyl sulfoxide. Infectivity was monitored by focus formation for Ha-SV and XC plaque formation for Mo-MuLV. The viral DNA titration pattern followed single-hit kinetics for both foci and plaques, indicating that a single molecule carried information for each function. Focus-forming and plaque-forming activity were present in different molecules, since these two biological activities could be separated from each other by agarose gel electrophoresis. The focus-forming molecule was linear DNA with a molecular weight of about 4 x 10(6) daltons. The focus-forming activity of the viral DNA was sensitive to EcoRI and resistant to XhoI restriction endonucleases, whereas the plaque-forming activity was resistant to EcoRI and sensitive to XhoI. The generation of helper-independent foci indicates that Ha-SV DNA can transform mouse cells in the absence of helper virus or its proteins.     

BK virus-transformed inbred hamster brain cells: status of viral DNA in subclones.

We have recently reported that viral DNA sequences in inbred LSH hamster brain cells transformed by the GS variant of BK virus (LSH-BR-BK) are present predominantly in a free form (Beth et al., J. Virol. 40:276-284, 1981). In this report, we confirm that the presence of viral DNA sequences in these cells is not due to virus production, since viral capsid proteins were not detected by immunoprecipitation. Furthermore, we examined the status of viral DNA in 15 subclones of this cell line and detected free and integrated viral DNA sequences in only 5 of the subclones. The other 10 subclones contained exclusively integrated viral DNA sequences, as shown by the blot hybridization of high-molecular-weight cell DNA which was uncleaved or digested with HincII, for which there are no sites in viral DNA. The arrangement of viral DNA in these clones was further analyzed by cleavage of cellular DNA with HpaII and HindIII. Mitomycin (0.03 microgram/ml) treatment of subclones containing only integrated sequences resulted in the appearance of free viral DNA sequences in some of these cells. This result supports the postulation that free viral DNA in LSH-BR-BK cells is made up of excision products of observed tandemly repeated integrated sequences. In addition to the large T- and small t-antigens, LSH-BR-BK and all of its 15 subclones contained two antigen species which were larger than large T and one species which was smaller than small t. The number of tumor antigens in the LSH- BR-BK cell line and its subclones with a large copy number in a free form was not more than in the subclones with low copy number and integrated DNA. This suggests that free viral DNA is not a template for tumor antigen production in transformed cells.     

Genetic evidence that the avian retrovirus DNA endonuclease domain of pol is necessary for viral integration.

We used in vitro mutagenesis in the 3' region of the avian retrovirus polymerase (pol) gene to genetically define the role of the DNA endonuclease domain. In-frame insertional mutations, which were dispersed throughout the 5' region of pp32, produced a series of five replication-deficient mutants. In contrast, a single point mutant (Ala----Pro) located 48 amino acids from the NH2 terminus of pp32 exhibited a delayed replication phenotype. Molecular analysis of this mutant demonstrated that upon infection it was capable of synthesizing both linear and circular species of unintegrated viral DNA. The levels of unintegrated viral DNA present in cells infected with the mutant virus were several times greater than wild-type levels. Quantitation of the amount of integrated viral genomes demonstrated that the mutant virus integrated viral DNA one-fifth as efficiently as wild-type virus. This single point mutation in the NH2 terminus of pp32 prevented efficient integration of viral DNA, with no apparent effect on viral DNA synthesis per se. Thus, the DNA endonuclease domain has been genetically defined as necessary for avian retrovirus integration.     

Identification of the avian myeloblastosis virus genome. II. Restriction endonuclease analysis of DNA from lambda proviral recombinants and leukemic myeoblast clones.

Two lambda proviral DNA recombinants were characterized with a number of restriction endonucleases. One recombinant contained a complete presumptive avian myeloblastosis virus (AMV) provirus flanked by cellular sequences on either side, and the second recombinant contained 85% of a myeloblastosis-associated virus type 1 (MAV-1)-like provirus with cellular sequences adjacent to the 5' end of the provirus. Comparing the restriction maps for the proviral DNAs contained in each lambda hybrid showed that the putative AMV and MAV-1-like genomes shared identical enzyme sites for 3.6 megadaltons beginning at the 5' termini of the proviruses with respect to viral RNA. Two enzyme sites near the 3'-end of the MAV-1-like provirus were not present in the putative AMV genome. We also examined a number of leukemic myeloblast clones for proviral content and cell-provirus integration sites. The presumptive AMV provirus was present in all the leukemic myeloblast clones regardless of the endogenous proviral content of the target cells or the AMV pseudotype used for conversion. Multiple cellular sites were suitable for integration of the putative AMV genome and the helper genomes. The proviral genomes were all integrated colinearly with respect to linear viral DNA.     

AIV血凝素亚型同步检测基因芯片技术研究

对流感病毒14个血凝素亚型的基因芯片检测技术进行了初步研究。通过RT-PCR克隆禽流感病毒血凝素基因片段,获得重组质粒。从重组质粒扩增大约500bp的DNA片段,浓缩后点到氨基化玻璃载体上,制成芯片。待检病毒样品用TRIzolLS提取RNA,反转录过程中用Cy5标记样品cDNAs。将标记样品与芯片杂交,扫描芯片上待检样品与芯片上捕捉探针的结合位点,杂交信号与预期设想一致。结果显示,DNA芯片技术可以提供一种有效的AIV血凝素亚型鉴别诊断方法。