Alterations in DNA methylation have been implicated in mammalian development. Hence, the identification of tissue-specific differentially methylated regions (TDMs) is indispensable for understanding its role. Using restriction landmark genomic scanning of six mouse tissues, 150 putative TDMs were identified and 14 were further analyzed. The DNA sequences of the 14 mouse TDMs are analyzed in this study. Six of the human homologous regions show TDMs to both mouse and human and genes in five of these regions have conserved tissue-specific expression: preferential expression in testis. A TDM, DDX4, is further analyzed in nine testis tissues. An increase in methylation of the promoter region is significantly associated with a marked reduction of the gene expression and defects in spermatogenesis, suggesting that hypomethylation of the DDX4 promoter region regulates DDX4 gene expression in spermatogenic cells. Our results indicate that some genomic regions with tissue-specific methylation and expression are conserved between mouse and human and suggest that DNA methylation may have an important role in regulating differentiation and tissue-/cell-specific gene expression of some genes.
Although the "gold standard" for diagnosis of tuberculous meningitis (TBM) is bacterial isolation of Mycobacterium tuberculosis, there are still several complex issues. Recently, we developed an internally controlled novel wide-range quantitative nested real-time PCR (WR-QNRT-PCR) assay for M. tuberculosis DNA in order to rapidly diagnose TBM. For use as an internal control calibrator to measure the copy number of M. tuberculosis DNA, an original new-mutation plasmid (NM-plasmid) was developed. Due to the development of the NM-plasmid, the WR-QNRT-PCR assay demonstrated statistically significant accuracy over a wide detection range (1 to 10 5 copies). In clinical applications, the WR-QNRT-PCR assay revealed sufficiently high sensitivity (95.8%) and specificity (100%) for 24 clinically suspected TBM patients. In conditional logistic regression analysis, a copy number of M. tuberculosis DNA (per 1 ml of cerebrospinal fluid) of >8,000 was an independent risk factor for poor prognosis for TBM (i.e., death) (odds ratio, 16.142; 95% confidence interval, 1.191 to 218.79; P value, 0.0365). In addition, the copy numbers demonstrated by analysis of variance statistically significant alterations (P < 0.01) during the clinical treatment course for 10 suspected TBM patients. In simple regression analysis, the significant correlation (R 2 ؍ 0.597; P < 0.0001) was demonstrated between copy number and clinical stage of TBM. We consider the WR-QNRT-PCR assay to be a useful and advanced assay technique for assessing the clinical treatment course of TBM.Tuberculous meningitis (TBM) is the severest form of infection of Mycobacterium tuberculosis, causing death or severe neurological defects in more than half of those affected in spite of antituberculosis treatment (ATT) (1,2,8,18). The diagnosis of TBM remains a complex issue, because the most widely used conventional bacteriological detection methods, such as direct smear for acid-fast bacilli (AFB) and culture for M. tuberculosis, are unable to rapidly detect M. tuberculosis with sufficient sensitivity in the acute phase of TBM (3-13, 18, 19). In 2006, we designed a novel internally controlled quantitative nested real-time PCR (QNRT-PCR) assay based on TaqMan PCR (Applied Biosystems) (15). Moreover, based on this original QNRT-PCR (OR-QNRT-PCR) assay, an improved wide-range QNRT-PCR (WR-QNRT-PCR) assay was developed (17). For use as a "calibrator" in WR-QNRT-PCR assay, a new internal control was constructed (17).In the preliminary experiments, the WR-QNRT-PCR assay demonstrated significantly improved quantitative accuracy and had a wide detection range (1 to 10 5 copies) compared to what was seen for the OR-QNRT-PCR assay (17).In this study, we tried to quantitatively detect M. tuberculosis DNA in actual cerebrospinal fluid (CSF) samples by using the WR-QNRT-PCR assay. In addition, the clinical usefulness of this novel assay technique for the rapid and accurate diagnosis of TBM and for assessing the clinical course of TBM was examined. MATERIALS AND METHODSThis study was approv...
The t(16;21)(q24;q22) translocation is a rare but recurrent chromosomal abnormality associated with therapy-related myeloid malignancies and a variant of the t(8;21) translocation in which theAML1 gene on chromosome 21 is rearranged. Here we report the molecular definition of this chromosomal aberration in four patients. We cloned cDNAs from the leukemic cells of a patient carrying t(16;21) by the reverse transcription polymerase chain reaction using anAML1-specific primer. The structural analysis of the cDNAs showed that AML1 was fused to a novel gene named MTG16(Myeloid Translocation Gene on chromosome16) which shows high homology to MTG8(ETO/CDR) and MTGR1. Northern blot analysis usingMTG16 probes mainly detected 4.5 kb and 4.2 kb RNAs, along with several other minor RNAs in various human tissues. As in t(8;21), the t(16;21) breakpoints occurred between the exons 5 and 6 ofAML1, and between the exons 1 and 2 or the exons 3 and 4 ofMTG16. The two genes are fused in-frame, resulting in the characteristic chimeric transcripts of this translocation. Although the reciprocal chimeric product, MTG16-AML1, was also detected in one of the t(16;21) patients, its protein product was predicted to be truncated. Thus, the AML1-MTG16 gene fusion in t(16;21) leukemia results in the production of a protein that is very similar to the AML1-MTG8 chimeric protein.
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