乙肝病毒基因型与基因组中国特色

StephenW

Hepatitis B virus genotypes and genome characteristics in China
Hong-Mei Li, Jian-Qiong Wang, Rui Wang, Qian Zhao, Li Li, Jin-Ping Zhang and Tao Shen.
Hong-Mei Li, Rui Wang, College of Life Science and Technology, Kunming University of Science and Technology, Kunming 650500, Yunnan Province, China
Hong-Mei Li, Rui Wang, Qian Zhao, Li Li, Jin-Ping Zhang, Tao Shen, Basic and Clinical Medicine Institute of Yunnan Province, Provincial Key Laboratory for Birth Defects and Genetic Diseases, the First People’s Hospital of Yunnan Province, Affiliated Hospital of Kunming University of Science and Technology, Kunming 650032, Yunnan Province, China
Jian-Qiong Wang, Clinical Laboratory, the First People’s Hospital of Yunnan Province, affiliated Hospital of Kunming University of Science and Technology, Kunming 650032, Yunnan Province, China
Qian Zhao, Kunming Medical College, Kunming 650500, Yunnan Province, China
Author contributions: Li HM, Li L and Zhang JP were in charge of information collection; Li HM, Wang R and Zhao Q participated in the statistical analysis; Li HM and Wang JQ designed the study and wrote the manuscript; Shen T provided advice and reviewed the manuscript; Li HM and Wang JQ contributed equally to this work.
Correspondence to: Dr. Tao Shen, Basic and Clinical Medicine Institute of Yunnan Province, Provincial Key Laboratory for Birth Defects and Genetic Diseases, the First People’s Hospital of Yunnan Province, Affiliated Hospital of Kunming University of Science and Technology, Kunming 650032, Yunnan Province, China. [email protected]
Telephone: +86-871-63638453 Fax: +86-871-63648772
Received December 24, 2014; Revised March 3, 2015; Accepted April 3, 2015;

References
   
Abstract
AIM: To analyze the hepatitis B virus (HBV) characters in China, as well as the correlation between several HBV mutation and hepatitis symptoms.
METHODS: A total of 1148 HBV genome sequences from patients throughout China were collected via the National Center For Biotechnology Information database (information including: genotype, territory and clinical status). HBV genotypes were classified by a direct reference from the Genbank sequence annotation, phylogenetic tree and online software analysis (http://www.ncbi.nlm.nih.gov/projects/genotyping/formpage.cgi). The phylogenetic tree was constructed based on the neighbor-joining method by MEGA5.0 software. HBV sequences were grouped based on phylogenetic tree and the distance between the groups was calculated by using the computer between group mean distance methods. Seven hundred and twelve HBV sequences with clear annotation of clinical symptoms were selected to analyses the correlation of mutation and clinical symptoms. Characteristics of sequences were analyzed by using DNAStar and BioEdit software packages. The codon usage bias and RNA secondary structures analysis were performed by RNAdraw software. Recombination analysis was performed by using Simplot software.
RESULTS: In China, HBV genotype C was the predominant in Northeastern, genotype B was predominant in Central Southern areas, genotype B and C were both dominant in Southwestern areas, and the recombinant genotype C/D was predominant in Northwestern areas. C2 and B2 were identified as the two major sub-genotypes, FJ386674 might be a putative sub-genotype as B10. The basal core promoter double mutation and pre-C mutation showed various significant differences between hepatitis symptoms. In addition to ATG, many other HBV initiation codons also exist. HBV has codon usage bias; the termination codon of X, C and P open reading frames (ORF) were TAA, TAG, and TGA, respectively. The major stop codons of S-ORF were TAA (96.45%) and TGA (83.60%) in B2 and C2 subtype, respectively.
CONCLUSION: This study recapitulated the epidemiology of HBV in China, and the information might be meaningful critical for the future prevention and therapy of HBV infections.
Keywords: Hepatitis B virus, Genotype, Phylogenetic tree, Clinical symptoms, Mutation, Codon usage bias
   
Core tip: This study recapitulated the epidemiology of hepatitis B virus (HBV) in China. Genotype C was the predominant HBV genotype in Northeastern, genotype B was predominant in Central Southern areas, genotype B and C were both dominant in Southwestern areas, and the recombinant genotype C/D was predominant in Northwestern areas. C2 and B2 were identified as the two major subgenotypes, FJ386674 might be a putative sub-genotype as B10. Moreover, the termination codon usage bias of B2 (TAA) and C2 (TGA) subtype and the correlation between HBV sequence mutations and clinical symptoms were also determined.
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Genotype distribution in the Chinese territory
HBV genotypes and sub-genotypes had obvious geographic features according to previous reports[34-36]. The current study also suggested a differential distribution of HBV genotypes in China. Within the northern areas of the Qinling Mountains-Huaihe River Line, genotype C (75.3%) was predominant, followed by a smaller percentage of type B (23.4%) and D (1.3%). While Sunbul[37] reported that genotype B was the major genotype in southern China, our results showed that the ratios of genotype B and C in the southern areas of China were 41% and 57%, respectively. This inconsistency may be due to differences in the selection of subjects and quantity of tested samples. Meanwhile, Northwestern China was dominated by recombinant genotype C/D and genotype D, with percentages of 49.3% and 24.6%, respectively. This result is consistent with a study by Yin et al[38]. Additionally, our investigation indicated that genotype I (originally reported as recombinant genotype A/C/G) was mainly located in the Guangxi[39], Shaanxi[40], Yunnan[41], and Sichuan Provinces[42], and I1 was the major sub-genotype in China.
From a geological perspective, many of the identified provinces were located on the Silk Route. For instance, the Guangdong Province was adjacent to Hong Kong and Macao; the Hainan and Taiwan regions were separated by the strait; Hong Kong, Macao, and Taiwan were once European colonies, where genotype A and D were dominant. Thus, we postulated that genotype I and recombinant genotype C/D was the result of a mixed genotype infection since it has already been discovered that recombination can occur in different genotypes of parental HBV strains[40,43]. Moreover, some studies proposed that genotype I may have existed for a long time in Shaanxi Province without being recognized, creating the question of how genotype I arose historically[40]. We hypothesized that a mixed genotype infection in patients from these areas may have occurred at first and subsequently resulted in recombinants. Furthermore, multiple factors, including extreme environmental effects[44] and special religious influences[42,45], may have helped preserved the resultant recombinant by natural selection.
Putative sub-genotype B10
To date, the definition of a new sub-genotype has been classified utilizing several major instructions. Firstly, a novel sub-genotype should be different from the known sub-genotype by 4% over the complete sequences. Secondly, a new sub-genotype should be an independent branch in the phylogenetic tree. Finally, a novel sub-genotype should have a bootstrap value over 75%[46].
In this study, Simplot results showed that FJ386674 represented a recombinant of genotypes B, C and H, with its two recombination breakpoints: one between nucleotides 500 and 960, and another from nucleotides 1700 to 1820 (Figure 3). Considering the results of phylogenetic tree and genetic distance, we designated FJ386674 as a putative sub-genotype B10.
However, despite the development of several new criteria for new sub-genotype classification, a number of controversial results still exist[32,33]. For instance, in this study, we found that 23 sequences had different genotyping and/or sub-genotyping due to different classification methods, and evolutionary distance among B3 and B5, B7-B9 (0.03 ± 0.00) was < 4%, a result consistent with a previous report indicating that B5, B7-B9 should be classified as a quasi-strain of B3[20,46]. Thus, the systematic approach of HBV putative sub-genotype classification needs to be further improved.
Correlation analysis of HBV BCP and pre-C to clinical symptoms
Many HBV mutations might be tightly associated with liver disease progression[47-49]. This study showed BCP double mutations were significantly different in ACLF and HCC. The results suggested that HCC had a lower mutation rate in the BCP region as compared with that of ACLF, which is consistent with a previous report[32]. However, other studies indicated that the BCP double mutation was associated with liver disease progression[47,48]. This inconsistency between current studies might be affected by many factors, like the genetic background of selected patients, the numbers of samples, and/or genotypes[49]. Some studies suggested a synergenistic action of the BCP double mutation and HBV genotype C in liver disease progression[50]. Although no statistically significant difference was observed between genotype B and C (P = 0.253) for all other hepatitis symptoms, the ratio of the BCP double mutation in genotype C has a tendency to be higher than that in genotype B (Figure 4), which is consistent with a previous study[51]. This might explain the intriguing relationship between genotype C and liver disease progression. Thus, the investigation of liver disease progression should not only look at the genotypes, but should also consider BCP mutations.
It has been suggested that the pre-C mutation is also tightly associated with liver disease progression[48,52]. In this study, we revealed that the pre-C mutation showed significant differences in HCC and LC, the mutation rate of the pre-C in ACLF, LC and HCC were higher than that of CHB (Figure 4), which is consistent with previous studies[48,52-55]. Thus, an HBV pre-C mutation might be tightly associated with liver disease progression.
In addition, some studies have reported the hepatitis B virus genotype C is associated with the process of liver disease[51,56]. This study also suggested no statistically significant difference in the HBV pre-C mutation between types B and C (P = 0.199). The detailed analysis indicated that only AHB was significantly different between types B and C (P = 0.038), while the mutation ratio in the same region was higher in type C without statistical significance for the other symptoms. This may explain why patients infected with genotype C HBV are more susceptible to the development of ACLF LC and HCC. We also found that the mutation rate of pre-C in ACLF was as high as 49.66% (Figure 4), which may be supported by a report that identified this mutation as a potential biomarker for ACLF onset[32]. Thus, the investigation of liver disease progression should always consider multiple factors, including the HBV genotype and associated mutations in order to achieve the most comprehensive understanding of the disease.

StephenW

乙肝病毒基因型与基因组中国特色
鸿梅李，建王琼，王锐，赵谦，李锂，金平张和沉涛。
鸿梅李，王锐，生命科学与技术学院，科技，昆明650500昆明理工大学，云南，中国
鸿梅李，王锐，赵谦，李锂，金平张，沉涛，云南省省级重点实验室基础医学与临床医学研究所出生缺陷和遗传性疾病，云南省附属第一人民医院科技，昆明650032，中国云南省昆明理工大学医院
建王琼，临床实验室，云南省科学技术的昆明大学附属医院，昆明650032，中国云南省第一人民医院
赵倩，昆明医学院，昆明650500，云南省，中国
作者投稿：李HM，李L和张JP分别负责信息收集的;李HM，王锐和赵群参加了统计分析;李HM和王JQ设计的研究和撰写文章;沉牛逼提供咨询和审查的手稿;李HM和王JQ同等贡献这项工作。
通讯作者：沉涛博士，基本和云南省省级重点实验室临床医学研究所出生缺陷和遗传性疾病，云南省第一人民医院，科学和昆明理工大学的附属医院，昆明650032，云南省，中国。 [email protected]
电话：+ 86-871-63638453传真：+ 86-871-63648772
收到的2014年12月24日;修订后的2015年3月3日;接受2015年4月3日;

参考

抽象
目的：分析乙型肝炎病毒（HBV）在中国的字符，以及几个HBV变异和肝炎的症状之间的相关性。
方法：1148 HBV基因组序列，从患者遍及中国通过了国家生物技术信息中心数据库（：基因型，领土和临床状态信息，包括）收集。 HBV基因型分类从基因库序列的注释，进化树和在线软件分析（http://www.ncbi.nlm.nih.gov/projects/genotyping/formpage.cgi）的直接引用。的系统发生树基于由MEGA5.0软件邻接法构建。基于系统发生树和组之间的距离，计算通过使用计算机组之间平均距离的方法的HBV序列进行分组。有临床症状明确标注七百一十二乙肝病毒序列进行选择分析突变和临床症状的相关性。序列的特征用DNAStar软件和BIOEDIT软件包进行分析。密码子使用偏好和RNA二级结构分析，通过RNAdraw软件来执行。通过使用辛普劳软件进行重组分析。
结果：在中国，乙肝病毒C基因型是东北主要的，B型是主要在中亚南部地区，B型和C都是占主导地位的西南地区，以及重组型C / D是主要在西北地区。 C2和B2被确定为两个主要的子基因型，FJ386674可能是一个推定的子基因型为B10。基底核心启动子双重突变和前C区变异乙肝表现症状之间的各种差异显著。除了ATG，许多其他的HBV起始密码子也存在。乙肝病毒已经密码子使用偏好;的X，C和P的开放阅读框（ORF）的终止密码子是TAA，TAG和TGA结束，分别。 S-ORF的主要终止密码子的TAA（96.45％）和TGA（83.60％）的B2和C2的亚型，分别。
结论：本研究概括的HBV的流行病学在中国，信息可能是有意义的关键为未来预防HBV感染和治疗。
关键词：乙型肝炎病毒，基因型，进化树，临床症状，突变，密码子使用偏好

核心提示：本研究概括乙型肝炎病毒（HBV）在中国的流行病学调查。 C基因型是东北主要的HBV基因型，B型是主要在中亚南部地区，B型和C都是占主导地位的西南地区，以及重组型C / D是主要在西北地区。 C2和B2被确定为两个主要亚型，FJ386674可能是一个推定的子基因型为B10。此外，B 2（TAA）和C2（TGA）亚型和HBV序列的突变和临床症状之间的相关性的终止密码子使用偏好也被确定。
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在中国境内基因型分布
HBV基因型和亚基因型根据之前的报道[34-36]具有明显的地理特征。目前的研究还表明HBV基因型在中国的微分分布。在秦岭 - 淮河线的北部地区，C型（75.3％）是主要的，其次是B型（23.4％）和D（1.3％）的比例较小。虽然Sunbul [37]报道，B基因型是中国南方主要的基因型，我们的研究结果显示，B，C基因型在中国南部地区的比例分别为41％和57％。此不一致可能是由于在受试者的选择和测试的样品的量的差异。同时，中国西北地区是通过重组基因型C / D和D基因型为主，以49.3％和24.6％，百分比。这一结果与研究由Yin等[38]一致。此外，我们的调查表明，基因型I（最初报告为重组型A / C / G）主要分布在广西[39]，陕西[40]，云南[41]，和四川省[42]，和I1是主要子基因型在中国。
从地质的角度来看，许多确定的省份分别位于丝绸之路。例如，广东省是毗邻香港和澳门;海南和台湾地区是由海峡隔开;香港，澳门，台湾曾经是欧洲殖民地，其中基因型A和D是占主导地位。因此，我们假定，基因型I和重组基因型C / D为混合基因型感染的结果，因为它已经被发现，重组可以发生在不同基因型的亲本的HBV株[40,43]。此外，一些研究提出基因型我可能已经存在了很长一段时间在陕西省而不被认同，如何创造型的问题，我在历史上出现[40]。我们假设一个混合基因型感染的患者，这些区域可能发生在第一和随后导致重组体。此外，多个因素，包括极端环境的影响[44]和特殊宗教的影响[42,45]，可能有助于保存所得的重组自然选择。
假定子基因型B10
迄今为止，一个新的子基因型的定义已被归类利用几个主要指示。首先，新的子基因型应当从已知的子基因型不同4％以上的完整序列。其次，一个新的子基因型应在系统发生树的独立分支。最后，一​​个新颖的子基因型应该具有超过75％的[46]的自举值。
在这项研究中，辛普劳结果表明FJ386674代表基因型B，C和H的重组的，与它的两个重组断点：1的核苷酸500和960之间，而另一个从核苷酸一七零零年至1820年（图3）。考虑系统发生树和遗传距离的结果，我们指定FJ386674作为推定的子基因型B10。
然而，尽管新的子基因型分类的几个新标准的发展，一些有争议的结果仍然存在[32,33]。例如，在这项研究中，我们发现，23种序列具有不同的基因分型和/或亚基因型由于不同的分类方法，和进化距离之间B3和B5，B7〜B9（0.03±0.00）为<4％，其结果与先前的报告表明B5，B7〜B9一致应归类为一个准菌株B3 [20,46]。因此，需要对HBV推定分型分类系统的方法还有待进一步完善。
HBV BCP的相关分析和预-C临床症状
很多乙肝病毒基因突变可能与肝病的进展[47-49]紧密相关。这项研究表明BCP双突变在ACLF和HCC显著不同。结果表明，肝癌有较低的突变率在BCP区域与ACLF，这与以前的报道[32]一致的比较。然而，其他的研究表明，将BCP双突变与肝脏疾病进展[47,48]相关联。目前的研究之间的不一致性可能受多种因素影响，如选择的患者的遗传背景，样品的数量，和/或基因型的[49]。一些研究建议BCP双突变和HBV C基因型的synergenistic行动肝脏疾病进展[50]。虽然基因型B和C（P = 0.253）之间观察到的所有其他肝炎症状无统计学显著差异，C基因型将BCP双突变的比率有一种倾向比B型的要高（图4），其与先前的研究[51]相一致。这或许可以解释C基因型和肝脏疾病进展之间的关系耐人寻味。因此，肝病进展的调查不应该只看基因型，但也应考虑BCP突变。
有人建议，该前C突变也紧密地与肝脏疾病进展[48,52]相关联。在这项研究中，我们发现，前C突变表明在肝癌和LC的前C在ACLF突变率显著差异，LC和肝癌均高于CHB（图4），这与以前的一致的高研究[48,52-55]。因此，HBV前C突变可能被紧密地与肝病进展相关。
此外，一些研究已经报道了乙肝病毒基因型C与肝病[51,56]的过程相关联。这项研究还表明在B型和C组（P = 0.199）之间的HBV前C区变异无统计学差异显著。详细的分析表明，只有AHB是B型和C组（P = 0.038）之间显著不同，而在相同区域中的突变率在C型更高而不对其它症状统计学意义。这也许可以解释为什么患者感染C基因型HBV更容易受到ACLF LC和HCC的发展。我们还发现，前C在ACLF突变率高达49.66％（图4），其可以由一个报告，识别该突变为ACLF发病[32]一个潜在的生物标志物来支持。因此，肝脏疾病进展的调查总是应该考虑多种因素，包括HBV基因型和相关的突变，以实现该疾病的最全面的了解。

StephenW

StephenW

http://www.wjgnet.com/1007-9327/full/v21/i21/6684.htm

MP4

说明靠北的病人可能更危险，要更积极治疗

crystalandtiger

MP4 发表于 2015-6-17 21:17
说明靠北的病人可能更危险，要更积极治疗

作为一个北方人表示很惶恐