使用biopython解析kegg数据库
在biopython中,通过Bio.KEGG模块,对kegg官方的API进行了封装,允许在python环境中使用kegg API。KEGG API与python代码的对应关系如下
/list/hsa:10458+ece:Z5100 -> REST.kegg_list(["hsa:10458", "ece:Z5100"])
/find/compound/300-310/mol_weight -> REST.kegg_find("compound", "300-310", "mol_weight")
/get/hsa:10458+ece:Z5100/aaseq -> REST.kegg_get(["hsa:10458", "ece:Z5100"], "aaseq")
>>> from Bio.KEGG import REST
>>> pathway = REST.kegg_get('hsa00010')
对于查询获得的内容,通过read方法可以转换为纯文本,示例如下
>>> pathway = REST.kegg_get('hsa00010')
>>> res = pathway.read().split("\n")
>>> res[0]
'ENTRY hsa00010 Pathway'
>>> res[1]
'NAME Glycolysis / Gluconeogenesis - Homo sapiens (human)'
>>> res[2]
'DESCRIPTION Glycolysis is the process of converting glucose into pyruvate and generating small amounts of ATP (energy) and NADH (reducing power). It is a central pathway that produces important precursor metabolites: six-carbon compounds of glucose-6P and fructose-6P and three-carbon compounds of glycerone-P, glyceraldehyde-3P, glycerate-3P, phosphoenolpyruvate, and pyruvate [MD:M00001]. Acetyl-CoA, another important precursor metabolite, is produced by oxidative decarboxylation of pyruvate [MD:M00307]. When the enzyme genes of this pathway are examined in completely sequenced genomes, the reaction steps of three-carbon compounds from glycerone-P to pyruvate form a conserved core module [MD:M00002], which is found in almost all organisms and which sometimes contains operon structures in bacterial genomes. Gluconeogenesis is a synthesis pathway of glucose from noncarbohydrate precursors. It is essentially a reversal of glycolysis with minor variations of alternative paths [MD:M00003].'
这样就可以通过字符串解析,来获取通路对应的编号,名称,注释等信息。对于KEGG数据的解析,biopython还提供了专门的解析函数,但是解析函数并不完整,目前只覆盖了compound, map, enzyme等子数据库。以enzyme数据库为例,用法如下
>>> from Bio.KEGG import REST
>>> request = REST.kegg_get("ec:5.4.2.2")
>>> open("ec_5.4.2.2.txt", "w").write(request.read())
>>> records = Enzyme.parse(open("ec_5.4.2.2.txt"))
>>> record = list(records)[0]
>>> record
<Bio.KEGG.Enzyme.Record object at 0x02EE7D18>
>>> record.classname
['Isomerases;', 'Intramolecular transferases;', 'Phosphotransferases (phosphomutases)']
>>> record.entry
'5.4.2.2'
通过biopython,我们不仅可以在python环境中使用kegg api, 更重要的是,可以借助python的逻辑处理,来实现复杂的筛选逻辑,比如查找human中DNA修复相关的基因,基本思路如下
1. 通过list API获取human所有的pathway编号;
2. 通过get API获取每条pathway, 解析其description信息,筛选出现了repair关键词的通路;
3. 对于筛选出的通路,通过文本解析获取该通路对应的基因;
完整的代码如下
>>> from Bio.KEGG import REST
>>> human_pathways = REST.kegg_list("pathway", "hsa").read()
>>> repair_pathways = []
>>> for line in human_pathways.rstrip().split("\n"):
... entry, description = line.split("\t")
... if "repair" in description:
... repair_pathways.append(entry)
...
>>> repair_pathways
['path:hsa03410', 'path:hsa03420', 'path:hsa03430']
>>> repair_genes = []
>>> for pathway in repair_pathways:
... pathway_file = REST.kegg_get(pathway).read()
... current_section = None
... for line in pathway_file.rstrip().split("\n"):
... section = line[:12].strip()
... if not section == "":
... current_section = section
... if current_section == "GENE":
... gene_identifiers, gene_description = line[12:].split("; ")
... gene_id, gene_symbol = gene_identifiers.split()
... if not gene_symbol in repair_genes:
... repair_genes.append(gene_symbol)
...
>>> repair_genes
['OGG1', 'NTHL1', 'NEIL1', 'NEIL2', 'NEIL3', 'UNG', 'SMUG1', 'MUTYH', 'MPG', 'MBD4', 'TDG', 'APEX1', 'APEX2', 'POLB', 'POLL', 'HMGB1', 'XRCC1', 'PCNA', 'POLD1', 'POLD2', 'POLD3', 'POLD4', 'POLE', 'POLE2', 'POLE3', 'POLE4', 'LIG1', 'LIG3', 'PARP1', 'PARP2', 'PARP3', 'PARP4', 'FEN1', 'RBX1', 'CUL4B', 'CUL4A', 'DDB1', 'DDB2', 'XPC', 'RAD23B', 'RAD23A', 'CETN2', 'ERCC8', 'ERCC6', 'CDK7', 'MNAT1', 'CCNH', 'ERCC3', 'ERCC2', 'GTF2H5', 'GTF2H1', 'GTF2H2', 'GTF2H2C_2', 'GTF2H2C', 'GTF2H3', 'GTF2H4', 'ERCC5', 'BIVM-ERCC5', 'XPA', 'RPA1', 'RPA2', 'RPA3', 'RPA4', 'ERCC4', 'ERCC1', 'RFC1', 'RFC4', 'RFC2', 'RFC5', 'RFC3', 'SSBP1', 'PMS2', 'MLH1', 'MSH6', 'MSH2', 'MSH3', 'MLH3', 'EXO1']
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