Distribution of Two Subgroups of Human T-Lymphotropic Virus Type 1 (HTLV-1) in Endemic Japan

Retrovirus particles with type C morphology were found in two T-cell lymphoblastoid cell lines, HUT 102 and CTCL-3, and in fresh peripheral blood lymphocytes obtained from a patient with a cutaneous T-cell lymphoma (mycosis fungoides). The cell lines continuously produce these viruses, which are collectively referred to as HTLV, strain CR(HTLV(CR)). Originally, the production of virus from HUT 102 cells required induction with 5-iodo-2'-deoxyuridine, but the cell line became a constitutive producer of virus at its 56th passage. Cell line CTCL-3 has been a constitutive producer of virus from its second passage in culture. Both mature and immature extracellular virus particles were seen in thin-section electron micrographs of fixed, pelleted cellular material; on occasion, typical type C budding virus particles were seen. No form of intracellular virus particle has been seen. Mature particles were 100-110 nm in diameter, consisted of an electron-dense core surrounded by an outer membrane separated by an electron-lucent region, banded at a density of 1.16 g/ml on a continuous 25-65% sucrose gradient, and contained 70S RNA and a DNA polymerase activity typical of viral reverse transcriptase (RT; RNA-dependent DNA nucleotidyltransferase). Under certain conditions of assay, HTLV(CR) RT showed cation preference for Mg(2+) over Mn(2+), distinct from the characteristics of cellular DNA polymerases purified from human lymphocytes and the RT from most type C viruses. Antibodies to cellular DNA polymerase gamma and anti-bodies against RT purified from several animal retroviruses failed to detectably interact with HTLV(CR) RT under conditions that were positive for the respective homologous DNA polymerase, demonstrating a lack of close relationship of HTLV(CR) RT to cellular DNA polymerases gamma or RT of these viruses. Six major proteins, with sizes of approximately 10,000, 13,000, 19,000, 24,000, 42,000, and 52,000 daltons, were apparent when doubly banded, disrupted HTLV(CR) particles were chromatographed on a NaDodSO(4)/polyacrylamide gel. The number of these particle-associated proteins is consistent with the expected proteins of a retrovirus, but the sizes of some are distinct from those of most known retroviruses of the primate subgroups.

The geographic distribution of hepatitis B virus (HBV) genotypes in Japan and its clinical relevance are poorly understood. We studied 731 Japanese patients with chronic HBV infection. HBV genotype was determined by the restriction fragment length polymorphism (RFLP) method after polymerase chain reaction (PCR). Of the 720 patients with positive PCR, 12 (1.7%) were HBV genotype A, 88 (12.2%) were genotype B, 610 (84.7%) were genotype C, 3 (0.4%) were genotype D, and 7 (1.0%) were of mixed genotype. Over 94% of patients on the Japanese mainland had genotype C, while 60% of the patients on Okinawa, the most southern islands, and 22.9% in the Tohoku area, the northern part of the mainland, harbored genotype B. Compared with genotype C patients, genotype B patients were older (53.6 to 42.2 years; P <.01), had a lower rate of positive hepatitis B e antigen (HBeAg) (18.4% to 50.6%; P <.01), and a lower level of serum HBV DNA (5.02 to 5.87 log genome equivalents (LGE)/mL; P <.01). The mean age of the genotype B patients with hepatocellular carcinoma was 70.1 +/- 9.2 years, compared with 55.2 +/- 9.7 of genotype C patients (P <.01). These results indicate that genotypes C and B are predominant in Japan, and there are significant differences in geographic distribution and clinical characteristics among the patients with the different genotypes.

Long-term growth of lymphoblastoid T cells from tissue samples from six of six patients with cutaneous T-cell lymphoma (CTCL) and six of six patients with acute T-lymphoblastic leukemia (ALL) has been achieved by using partially purified mitogen-free human T-cell growth factor (pp-TCGF). One cell line, CTCL-2, is now independent of added growth factor; the others continue to show absolute dependency on its presence. All lines have been in continuous culture for at least 4 months and some for > 1 year. They are erythrocyte-rosette positive and are negative for Epstein-Barr virus nuclear antigen. Most of the lines are negative for Fc and complement receptors and for surface immunoglobulin except that CTCL-1 and CTCL-2 have some cells positive for these cell surface markers. Results of histochemical studies on these cell lines are similar to the known patterns for fresh cells from their disease of origin. Cell line CTCL-3 has an abnormal karyotype, but no detectable chromosomal abnormalities were found in the other lines, consistent with the karyologic features of their clinical sources. Because T cells from normal donors do not respond to pp-TCGF unless the cells are first "activated" by a lectin mitogen such as phytohemagglutinin or an antigen, the direct response to pp-TCGF of T cells from patients with T-cell neoplasias suggests that the cell lines represent a transformed neoplastic cell population. Although some of the cell lines may be normal T cells activated by the malignant cells, the morphologic and histochemical properties of the cell lines, the abnormal karyotype of CTCL-3, and the independent growth of CTCL-2 support the conclusion that most of these cell lines are of malignant origin.