Long-term amiodarone treatment causes cardioselective hypothyroid-like alteration in gene expression profile.

The long-term cardiac effects of amiodarone resemble many aspects of hypothyroidism. The anti-arrhythmic potential of amiodarone may therefore be the result of a drug-induced, local hypothyroid-like condition. To investigate this controversial issue, we compared gene expression profiles in the hearts of rats treated with amiodarone with those of rats with hypothyroidism. Wistar male rats were assigned to 3 groups (n=6-8): Control, systemic hypothyroidism (hypothyroidism) and amiodarone treatment (amiodarone, 150 mg/kg/day, p.o., 4 weeks). Electrocardiogram (ECG) recordings, gene profiling by DNA microarray and Northern blotting were carried out. Amiodarone, like hypothyroidism, caused significant prolongation of RR and QT intervals in ECGs. Microarray analysis of 8435 genes in the left ventricular myocardium revealed a significant similarity in expression profiles between hypothyroidism and amiodarone (R=0.63, p<0.00001). The gene expression profiles of hypothyroidism and amiodarone showed closer correlation when top 100 up-regulated and 100 down-regulated genes in hypothyroidism (total 200 genes) were analyzed (R=0.78, p<0.00001). Northern blots of left ventricular myocardium showed a parallel decrease in mRNAs for myosin heavy chain (MHC)-alpha and a parallel increase for myosin heavy chain (MHC)-beta in hypothyroidism and amiodarone. In the liver and pituitary, in contrast, Northern blots showed quite different changes in the transcripts of the representative T3-responsive genes in the hypothyroidism and amiodarone. In conclusion, long-term treatment with amiodarone causes cardioselective hypothyroid-like alterations in gene expression profiles. The potent anti-arrhythmic activity of amiodarone may be attributable, in part at least, to this unique transcriptional remodeling.

Distribution of the CCR5 gene 32-basepair deletion in 11 Chinese populations.

A mutant allele of the chemokine receptor gene CCR5 bearing a 32-basepair deletion (delta 32CCR5) could increase the resistance to HIV-1 infection or delayed progression to AIDS. The frequency of this mutation is higher in Europeans than in Asians. To investigate the distribution of this polymorphism in China, 715 individuals from 11 Chinese populations were screened by PCR, including the Han and 10 other ethnic groups. The delta 32CCR5 gene was found in 16 individuals from 5 ethnic groups. All of them were heterozygous. The frequency of the mutant alleles of delta 32CCR5 is low in China and reflects (or might reflect) ancestral gene flow from Europe to Chinese ethnic groups and recent intermarriage within the ethnic groups.

[Y chromosome variations and hyplogroups from 15 biallelic markers in six Chinese populations].

By using 15 biallelic markers, 342 male individuals from six populations in China were genotyped with ASPCR (allele specific PCR). The 15 biallelic markers included M1 (YAP), M15 (9 bp insertion), M89 (C-->T), M9 (C-->G), M119 (A-->C), M50 (T-->C), M110 (T-->C), M103 (C-->T), M95 (C-->T), M88 (A-->G), M111 (2-bp deletion), M45 (G-->A), M122 (T-->C), M7 (C-->G) and M134 (1 bp deletion). The distribution of variation frequencies of 15 biallelic markers in six populations showed that with the extremely high frequencies of M9G (96.20% & 96.43%) and Han nationality displayed higher diversity than the four minority populations. It's noteworthy that M95T (82.14%) in Sichuan Han and M45A (18.57%) in Hui gave prominace to the two populations. The six populations displayed 34 (Fujian Han), 21 (Sichuan Han), 14 (Mongol), 26 (Hui), 10 (Xibo) and 8 (Hezhe) haplogroups respectively with 2, 1, 2, 1, 2 and 2 prominent haplogroups among them. Furthermore, the haplogroup analysis revealed that one predominant haplogroup was shared in the four minority populations and even two predominant haplogroups were shared in Mongol, Hezhe and Xibo. Unlike Han populations, the minority populations showed strikingly different haplogroups which were close to the ancestral pattern. However, the two Han populations exhibited divergence between them with the distinct frequencies of M89T and M95T. With the comparison of the number of people sharing the common haplogroups between any two of the four minority populations, relative genetic distance among them was deduced.

A new haplogroup pattern displayed in Fujian Han in China.

Human Y-chromosomal binary polymorphisms have been considered to preserve the paternal genetic legacy and provide evidence on human evolution and the genetic relationships among and demographic history of different populations. To reveal the genetic origin and immigration of the Fujian Han, 13 binary markers on the Y chromosome were used to screen Fujian Han by allele-specific polymerase chain reaction. The results indicated that the M9G marker was highly prevalent (96.20%), suggesting a significant genetic drift. In addition, M122C frequency was only 22.78%, and M45A and M103T were default. The distinctive haplogroup frequencies (H1, H5, and H6/7/8) imply that the haplogroup pattern is a relatively ancestral and interim type.

[Establishment and preservation of immortal lymphoblastoid cell lines of the 10 ethnic groups in China].

The immortal lymphoblastoid cell lines were established by EBV transformation of B cells and addition of cyclosporin A to inhibit the activity of T cells. In the present study,549 immortal cell lines of different ethnic groups of Hazak, Manchu, Korea, Hozhe, Mongolia, Sibe, Hui, Puyi, Han in Fujian and Han in Sichuan were established. Through our research,we found it is harmful for B lymphocytes to transform if excessful leucocytes are inoculated.And it is crisis that cyclosporine A shoud be added the last. Our work is an important part of the research of human genome diversity for the exploration of the origin and evolution of different ethnic groups,and it also provides enough research materials for further studies.Moreover,we have sent 50 cell lines of Hozhe, Mongolia, Sibe, Daur, Oroqen to CEPH. Thus it is possible for us to utilize the genetic resources of CEPH freely.