Detection of Measles Virus mRNA from Autopsied Human Tissues

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Journal of Clinical Microbiology, January 1998, p. 299-301, Vol. 36, No. 1
0095-1137/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.

Detection of Measles Virus mRNA from Autopsied Human Tissues

Yuko Katayama,¹ Kiyoyasu Kohso,¹ Akiyoshi Nishimura,² Yoshitsugu Tatsuno,³ Morio Homma,⁴ and Hak Hotta¹^,^*

Department of Microbiology,¹ and Department of Legal Medicine,³ Kobe University School of Medicine, Chuo-ku, Kobe, Hyogo 650, Department of Legal Medicine, Shiga University of Medical Science, Ohtsu, Shiga 520-21,² and Faculty of Home Economics, Kobe Women's University, Suma-ku, Kobe, Hyogo 654,⁴ Japan

Received 25 August 1997/Returned for modification 7 October 1997/Accepted 28 October 1997

	ABSTRACT

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By reverse transcription-PCR, measles virus (MV) mRNA was detected in the brain, kidney, spleen, liver, and lung tissues obtainedfrom 23 (45.1%) of 51 autopsy subjects, with the detection ratesof each tissue ranging from 8 to 20%. Sequence analysis revealedfrequent mutations in the corresponding viral protein. These resultssuggest that MV mutants commonly persist in apparently healthyindividuals.

	TEXT

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Measles virus (MV) is the causative agent of acute measles in young children worldwide. Although homotypic serologically,MV exhibits a considerable degree of genetic diversity and canbe classified into a number of phylogenetic groups (10, 19).Besides this genetic diversity, another kind of MV mutation hasbeen identified. Persistent infection of particular MV mutantsin the brain is known to result in a rare but incurable diseasecalled subacute sclerosing panencephalitis (SSPE) (5, 7,20). It is generally believed that, except for the rare casesof SSPE, MV is eliminated from infected individuals by potentanti-MV immunity after recovery from acute measles. However, ourprevious study showed that, by using a reverse transcription (RT)-PCRmethod, MV mRNA was detected in 11 (18%) of 61 brain tissue samplesobtained from autopsy subjects who had not exhibited SSPE-likesymptoms (9). This result suggests the possibility that MVpersists in apparently healthy individuals. The question of whetherMV mRNA was present in human tissues other than the brain wasthen raised. To address this question, we obtained various tissuesfrom autopsy subjects and tried to detect MV mRNA by RT-PCR. Wereport here that MV mRNA was detected not only in the brain butalso in other human tissues, such as kidney, spleen, liver, andlung.

Human tissues were obtained from 51 autopsy subjects (within 24 h postmortem) during the period between April and December1995. The autopsy subjects consisted of 33 males and 18 females,with a mean age of 54.3 years (range, 4 months to 88 years). Thetissue samples were stored at $-$ 130°C until RT-PCR analysis wasperformed. Extraction of RNA and detection of MV nucleoproteinmRNA were performed as described previously (9). Briefly, 10µg of total RNA extracted from the tissue samples was reversetranscribed into cDNA by using MV-specific primer NP4. The resultantcDNA was amplified by using a set of outer primers (NP1 and NP4)in the first round of PCR and a set of inner primers (NP2 andNP3) in the second round of PCR. The expected sizes of the fragmentsamplified by the first- and second-round PCR were 228 (nucleotides235 to 462, including NP1 and NP4 sequences) and 149 bp (nucleotides280 to 428, including NP2 and NP3 sequences), respectively. ThePCR products were electrophoresed and visualized by UV illumination.This RT-PCR method was shown to detect MV genomic RNA of as lowas 0.5 50% tissue culture-infective dose that had been mixed withMV-negative tissue samples (data not shown). Nucleotide sequencesof the second-round PCR products were determined, as describedpreviously (9, 10, 21).

Consistent with our previous results (9), 10 (19.6%) of 51 brain tissue samples were positive for MV mRNA (Table 1). Othertissues, such as lung, liver, spleen, and kidney, were also shownto be positive for MV mRNA, with detection rates of 13.7, 7.8,10.0, and 17.6%, respectively. There was no significant differencein the MV mRNA detection rates for the five tissues. Of the 51subjects, 15 (29.4%) had MV mRNA in only one tissue, while 8 hadMV mRNA in two or more tissues. In total, 23 (45.1%) of the 51subjects had MV mRNA in at least one tissue. Inflammatory changeswere barely observed in MV mRNA-positive tissues by ordinary histophologicalexaminations (data not shown). The cause of death of the 23 positivecases was cardiovascular disorders, such as dissecting aneurysmand myocardial infarction (12 cases), accidents (6 cases), suddendeath syndrome (2 cases), chronic obstructive pulmonary disease(2 cases), and pneumonia (1 case). No significant associationwas observed between an MV mRNA positive result and the causeof death.

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TABLE 1. Detection of MV mRNA in autopsied human tissues

Nucleotide sequences from a total of 35 tissue-derived MV clones were determined and amino acid sequences were deduced (Fig.1). Nine clones had the same amino acid sequence as the wild-typeT4 strain did. On the other hand, the remaining 26 clones hadunique amino acid sequences differing in one to three residuesfrom that of the T4 strain. It should be noted that all 14 wild-typeMV strains collected from throat swabs of typical measles patients(collected in 1995 and 1996) had the same sequence as that ofT4 at both amino acid and nucleotide levels (data not shown).These results strongly suggest that the amino acid alterationsobserved with the 26 tissue-derived MV clones were not due toartifacts that had been caused during the RT-PCR amplificationbut that the mutated MV sequences were present in the tissue samples,which probably had been generated during long-term viral persistencein the tissues in the presence of anti-MV immunity. In individualswith multiple MV-positive tissues, amino acid sequences of theMV clones often varied with different tissues (Fig. 1), suggestingthat different mutants could arise in an individual. This resultis consistent with a previous observation that a number of differentclones were detected in different areas of the brain of an SSPEpatient (2).

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FIG. 1. Alignment of deduced amino acid sequences of part of the nucleoprotein sequence from tissue-derived MV and a fresh, wild-type isolate of MV. Residues identical to those of the wild-type T4 strain are indicated by dashes. Amino acid positions are depicted at the top of the figure. The virus isolate designation (the patient number and tissue) are shown to the left of the sequences. The sequences shown correspond to 7% of the entire sequence of the nucleoprotein.

Some of the human tissues were immediately minced, without being frozen, and cocultured with B95-8 cells, a cell line highlysusceptible to MV field isolates (10), in an attempt to isolateinfectious MV. However, infectious MV could not be isolated fromthe autopsied human tissues (data not shown). This result suggeststhe possibility that replication competence of the persistingMV has been impaired drastically due to accumulated mutationsin the viral genome.

In general, replication-competent, nonmutated MV would eventually be eliminated by strong immunity against the virus afterrecovery from acute measles. Host immune responses are directedto various antigenic epitopes in MV proteins. As for the nucleoprotein,a number of cytotoxic T-cell epitopes and B-cell epitopes havebeen determined in the murine experimental system (3, 4,6, 8). The partial nucleoprotein sequence analyzed in thepresent study (amino acids 66 to 100) contains one of the cytotoxicT-cell epitopes and was shown to have mutations (Fig. 1). Suchmutated MV, with highly impaired replication competence, mightescape from the anti-MV immune surveillance to persist in thehost without causing apparent symptoms. This idea is in line withprevious observations that MV mRNA and antigens were detectedin certain tissues and cells, including bone marrow cells andperipheral blood mononuclear cells, obtained from healthy individuals,though at low frequencies (14, 15). If such an MV mutant regainedreplication competence during persistent infection, it could causeinjury to infected cells through cytopathic effect of the virusand/or antiviral immune responses of the host. In fact, besidesSSPE, possible associations between persistent MV infection andcertain diseases, such as Crohn's disease (16, 22, 23),otosclerosis (1, 14, 17), Paget's disease (15, 18),epilepsy (11), aseptic chronic meningitis (13), and autoimmunehepatitis (12) have recently been documented. Further studyis necessary to elucidate the mechanism and clinical significanceof MV persistence in human tissues.

Nucleotide sequence accession numbers. The nucleotide sequences reported in this study will appear in DDBJ/EMBL/GenBank Nucleotide Sequence Databases with the accessionnumbers AB006495 to AB006529.

	ACKNOWLEDGMENTS

This work was supported in part by a Research Program for Slow Virus Infection from the Ministry of Health and Welfare ofJapan and by a research grant from Yakult Co., Ltd.

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Microbiology, Kobe University School of Medicine, 7-5-1 Kusunoki-cho,Chuo-ku, Kobe, Hyogo 650, Japan. Phone: 81-78-341-7451, ext. 3300.Fax: 81-78-351-6347. E-mail: hotta{at}kobe-u.ac.jp.

REFERENCES

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Abstract
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References

1. Arnold, W., H. P. Niedermeyer, N. Lehn, W. Neubert, and H. Hofler. 1996. Measles virus in otosclerosis and the specific immune response of the inner ear. Acta Otolaryngol. 116:705-709[Medline].

2. Baczko, K., J. Lampe, U. G. Liebert, U. Brinckmann, V. ter Meulen, I. Pardowitz, H. Budka, S. L. Cosby, S. Isserte, and B. K. Rima. 1993. Clonal expansion of hypermutated measles virus in a SSPE brain. Virology 197:188-195[Medline].

3. Beauverger, P., A. I. Cardoso, L. Daviet, R. Buckland, and T. F. Wild. 1996. Analysis of the contribution of CTL epitopes in the immunobiology of morbillivirus infection. Virology 219:133-139[Medline].

4. Beauverger, P., J. Chadwick, R. Buckland, and T. F. Wild. 1994. Serotype-specific and canine distemper virus cross-reactive H-2K^k-restricted cytotoxic T lymphocyte epitopes in the measles virus nucleoprotein. Virology 203:172-177[Medline].

5. Billeter, M. A., R. Cattaneo, A. Schmid, D. Eschle, K. Kaelin, G. Rebmann, S. A. Udem, R. D. Sheppard, K. Baczko, U. G. Liebert, S. Schneider-Schaulies, U. Brinckmann, and V. ter Meulen. 1989. Host and viral features in persistent measles virus infection of the brain, p. 356-366. In B. W. J. Mahy, and D. Kolakofsky (ed.), Genetics and pathogenicity of negative strand viruses. Elsevier/North-Holland Publishing Co., Amsterdam, The Netherlands.

6. Buckland, R., P. Giraudon, and F. Wild. 1989. Expression of measles virus nucleoprotein in Escherichia coli: use of deletion mutants to locate the antigenic sites. J. Gen. Virol. 70:435-441[Abstract/Free Full Text].

7. Cattaneo, R., A. Schmid, P. Spielhofer, K. Kaelin, K. Baczko, V. ter Meulen, J. Pardowitz, S. Flanagan, B. K. Rima, S. A. Udem, and M. Billeter. 1989. Mutated and hypermutated genes of persistent measles viruses which cause lethal human brain disease. Virology 173:415-425[Medline].

8. Gombart, A. F., A. Hirano, and T. C. Wong. 1993. Conformational maturation of measles virus nucleocapsid protein. J. Virol. 67:4133-4141[Abstract/Free Full Text].

9. Katayama, Y., H. Hotta, A. Nishimura, T. Tatsuno, and M. Homma. 1995. Detection of measles virus nucleoprotein mRNA in autopsied brain tissues. J. Gen. Virol. 76:3201-3204[Abstract/Free Full Text].

10. Katayama, Y., K. Shibahara, T. Kohama, M. Homma, and H. Hotta. 1997. Molecular epidemiology and changing distribution of genotypes of measles virus field strains in Japan. J. Clin. Microbiol. 35:2651-2653[Abstract].

11. Kawashima, H., T. Miyajima, T. Mori, L. Yuan, M. Ogihara, K. Kinoue, K. Takekuma, and A. Hoshika. 1996. A case of intractable epilepsy positive for the detection of measles virus genome in the cerebrospinal fluid and peripheral mononuclear cells using reverse transcriptase-polymerase chain reaction. Brain Dev. 18:220-223[Medline].

12. Kawashima, H., T. Mori, K. Takekuma, A. Hoshika, M. Hata, and T. Nakayama. 1996. Polymerase chain reaction detection of the hemagglutinin gene from an attenuated measles vaccine strain in the peripheral mononuclear cells of children with autoimmune hepatitis. Arch. Virol. 141:877-884[Medline].

13. Luzi, P., L. Leoncini, M. Valassina, A. Federico, and L. Palma. 1997. Chronic progressive leptomeningitis associated with measles virus. Lancet 350:338-339[Medline].

14. McKenna, M. J., A. G. Kristiansen, and J. Haines. 1996. Polymerase chain reaction amplification of a measles virus sequence from human temporal bone sections with active otosclerosis. Am. J. Otol. 17:827-830[Medline].

15. Mills, B. G., A. Frausto, F. R. Singer, Y. Ohsaki, A. Demulder, and G. D. Roodman. 1994. Multinucleated cells formed in vitro from Paget's bone marrow express viral antigens. Bone 15:443-448[Medline].

16. Miyamoto, H., T. Tanaka, N. Kitamoto, Y. Fukuda, and T. Shimoyama. 1995. Detection of immunoreactive antigen, with a monoclonal antibody to measles virus, in tissue from a patient with Crohn's disease. J. Gastroenterol. 30:28-33[Medline].

17. Niedermeyer, H. P., and W. Arnold. 1995. Otosclerosis: a measles virus associated inflammatory disease. Acta Otolaryngol. 115:300-303[Medline].

18. Reddy, S. V., F. R. Singer, and G. D. Roodman. 1995. Bone marrow mononuclear cells from patients with Paget's disease contain measles virus nucleocapsid messenger ribonucleic acid that has mutations in a specific region of the sequence. J. Clin. Endocrinol. Metab. 80:2108-2111[Abstract].

19. Rota, J. S., J. L. Heath, P. A. Rota, G. E. King, M. L. Celma, J. Carabaña, R. Fernandez-Muñoz, D. Brown, L. Jin, and W. J. Bellini. 1996. Molecular epidemiology of measles virus: identification of pathways of transmission and implication for measles elimination. J. Infect. Dis. 173:32-37[Medline].

20. Schneider-Schaulies, S., L. Schneider-Schaulies, L. M. Dunster, and V. ter Meulen. 1995. Measles virus expression in neural cells, p. 101-116. In V. ter Meulen, and M. A. Billeter (ed.), Measles virus. Springer-Verlag, Berlin, Germany.

21. Shibahara, K., H. Hotta, Y. Katayama, and M. Homma. 1994. Increased binding activity of measles virus to monkey red blood cells after long-term passage in Vero cell cultures. J. Gen. Virol. 75:3511-3516[Abstract/Free Full Text].

22. Wakefield, A. J., R. M. Pittilo, R. Sim, S. L. Cosby, J. R. Stephenson, A. P. Dhillon, and R. E. Pounder. 1993. Evidence of persistent measles virus infection in Crohn's disease. J. Med. Virol. 39:345-353[Medline].

23. Wakefield, A. J., R. Sim, A. N. Akbar, R. E. Pounder, and A. P. Dhillon. 1997. In situ immune responses in Crohn's disease: a comparison with acute and persistent measles virus infection. J. Med. Virol. 51:90-100[Medline].

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1.	Arnold, W., H. P. Niedermeyer, N. Lehn, W. Neubert, and H. Hofler. 1996. Measles virus in otosclerosis and the specific immune response of the inner ear. Acta Otolaryngol. 116:705-709[Medline].
2.	Baczko, K., J. Lampe, U. G. Liebert, U. Brinckmann, V. ter Meulen, I. Pardowitz, H. Budka, S. L. Cosby, S. Isserte, and B. K. Rima. 1993. Clonal expansion of hypermutated measles virus in a SSPE brain. Virology 197:188-195[Medline].
3.	Beauverger, P., A. I. Cardoso, L. Daviet, R. Buckland, and T. F. Wild. 1996. Analysis of the contribution of CTL epitopes in the immunobiology of morbillivirus infection. Virology 219:133-139[Medline].
4.	Beauverger, P., J. Chadwick, R. Buckland, and T. F. Wild. 1994. Serotype-specific and canine distemper virus cross-reactive H-2K^k-restricted cytotoxic T lymphocyte epitopes in the measles virus nucleoprotein. Virology 203:172-177[Medline].
5.	Billeter, M. A., R. Cattaneo, A. Schmid, D. Eschle, K. Kaelin, G. Rebmann, S. A. Udem, R. D. Sheppard, K. Baczko, U. G. Liebert, S. Schneider-Schaulies, U. Brinckmann, and V. ter Meulen. 1989. Host and viral features in persistent measles virus infection of the brain, p. 356-366. In B. W. J. Mahy, and D. Kolakofsky (ed.), Genetics and pathogenicity of negative strand viruses. Elsevier/North-Holland Publishing Co., Amsterdam, The Netherlands.
6.	Buckland, R., P. Giraudon, and F. Wild. 1989. Expression of measles virus nucleoprotein in Escherichia coli: use of deletion mutants to locate the antigenic sites. J. Gen. Virol. 70:435-441[Abstract/Free Full Text].
7.	Cattaneo, R., A. Schmid, P. Spielhofer, K. Kaelin, K. Baczko, V. ter Meulen, J. Pardowitz, S. Flanagan, B. K. Rima, S. A. Udem, and M. Billeter. 1989. Mutated and hypermutated genes of persistent measles viruses which cause lethal human brain disease. Virology 173:415-425[Medline].
8.	Gombart, A. F., A. Hirano, and T. C. Wong. 1993. Conformational maturation of measles virus nucleocapsid protein. J. Virol. 67:4133-4141[Abstract/Free Full Text].
9.	Katayama, Y., H. Hotta, A. Nishimura, T. Tatsuno, and M. Homma. 1995. Detection of measles virus nucleoprotein mRNA in autopsied brain tissues. J. Gen. Virol. 76:3201-3204[Abstract/Free Full Text].
10.	Katayama, Y., K. Shibahara, T. Kohama, M. Homma, and H. Hotta. 1997. Molecular epidemiology and changing distribution of genotypes of measles virus field strains in Japan. J. Clin. Microbiol. 35:2651-2653[Abstract].
11.	Kawashima, H., T. Miyajima, T. Mori, L. Yuan, M. Ogihara, K. Kinoue, K. Takekuma, and A. Hoshika. 1996. A case of intractable epilepsy positive for the detection of measles virus genome in the cerebrospinal fluid and peripheral mononuclear cells using reverse transcriptase-polymerase chain reaction. Brain Dev. 18:220-223[Medline].
12.	Kawashima, H., T. Mori, K. Takekuma, A. Hoshika, M. Hata, and T. Nakayama. 1996. Polymerase chain reaction detection of the hemagglutinin gene from an attenuated measles vaccine strain in the peripheral mononuclear cells of children with autoimmune hepatitis. Arch. Virol. 141:877-884[Medline].
13.	Luzi, P., L. Leoncini, M. Valassina, A. Federico, and L. Palma. 1997. Chronic progressive leptomeningitis associated with measles virus. Lancet 350:338-339[Medline].
14.	McKenna, M. J., A. G. Kristiansen, and J. Haines. 1996. Polymerase chain reaction amplification of a measles virus sequence from human temporal bone sections with active otosclerosis. Am. J. Otol. 17:827-830[Medline].
15.	Mills, B. G., A. Frausto, F. R. Singer, Y. Ohsaki, A. Demulder, and G. D. Roodman. 1994. Multinucleated cells formed in vitro from Paget's bone marrow express viral antigens. Bone 15:443-448[Medline].
16.	Miyamoto, H., T. Tanaka, N. Kitamoto, Y. Fukuda, and T. Shimoyama. 1995. Detection of immunoreactive antigen, with a monoclonal antibody to measles virus, in tissue from a patient with Crohn's disease. J. Gastroenterol. 30:28-33[Medline].
17.	Niedermeyer, H. P., and W. Arnold. 1995. Otosclerosis: a measles virus associated inflammatory disease. Acta Otolaryngol. 115:300-303[Medline].
18.	Reddy, S. V., F. R. Singer, and G. D. Roodman. 1995. Bone marrow mononuclear cells from patients with Paget's disease contain measles virus nucleocapsid messenger ribonucleic acid that has mutations in a specific region of the sequence. J. Clin. Endocrinol. Metab. 80:2108-2111[Abstract].
19.	Rota, J. S., J. L. Heath, P. A. Rota, G. E. King, M. L. Celma, J. Carabaña, R. Fernandez-Muñoz, D. Brown, L. Jin, and W. J. Bellini. 1996. Molecular epidemiology of measles virus: identification of pathways of transmission and implication for measles elimination. J. Infect. Dis. 173:32-37[Medline].
20.	Schneider-Schaulies, S., L. Schneider-Schaulies, L. M. Dunster, and V. ter Meulen. 1995. Measles virus expression in neural cells, p. 101-116. In V. ter Meulen, and M. A. Billeter (ed.), Measles virus. Springer-Verlag, Berlin, Germany.
21.	Shibahara, K., H. Hotta, Y. Katayama, and M. Homma. 1994. Increased binding activity of measles virus to monkey red blood cells after long-term passage in Vero cell cultures. J. Gen. Virol. 75:3511-3516[Abstract/Free Full Text].
22.	Wakefield, A. J., R. M. Pittilo, R. Sim, S. L. Cosby, J. R. Stephenson, A. P. Dhillon, and R. E. Pounder. 1993. Evidence of persistent measles virus infection in Crohn's disease. J. Med. Virol. 39:345-353[Medline].
23.	Wakefield, A. J., R. Sim, A. N. Akbar, R. E. Pounder, and A. P. Dhillon. 1997. In situ immune responses in Crohn's disease: a comparison with acute and persistent measles virus infection. J. Med. Virol. 51:90-100[Medline].