researchers at the allen institute for brain science have found that the same 2 have different activity patterns in the brain in individuals with different 3 backgrounds. these findings may help to explain individual differences in the effectiveness and side-effect profiles of 4 drugs and thus have implications(含意,影响) for personalized medicine. the study is available in this week's online early edition of the 5 of the national academy of sciences (www.pnas.org). in this study, the authors compared where in the brain each of 49 different 6 related genes is expressed, or turned on, in seven 7 distinct groups of mice with known genealogical(宗谱的,家系的) relationships. by 8 203 distinct brain areas over 15,000 thin sections of tissue, they 9 mapped where these genes are active, down to the level of individual cells. the genes all encode 10 targets of well-known 11, such as antidepressants, antipsychotics(抗精神病药) and pain relievers including prozac, imitrex, and aricept.
more than half of the genes examined showed striking, localized differences in expression patterns between the different genetic groups, or strains, of mice. for example, the dopamine(多巴胺) d2 receptor 1—which encodes a target of action of zyprexa, a drug used for schizophrenia(精神分裂症) and bipolar 12(躁郁症) —is active in a memory-related area called the entorhinal cortex in one strain of mice, but not in two others. because different parts of the brain have different functions, variations in the localization of gene activity likely have 13 implications.
"it is clear that to understand how genes translate to behavioral and other differences between individuals and species, we need to look beyond just the inherited sequences of the genes themselves," said allan jones, chief executive officer of the allen institute for brain science. "our results show that genetic background—the specific blend of gene 14 comprising(包含) an ingedividual genome—can influence how the activity of a given gene is regulated and where it is expressed."
taken all together, the data from the study demonstrate that closer genetic relatives exhibit fewer differences in gene expression patterns, whereas more distant relatives show greater variation. interestingly, the researchers found that the expression variations between genetic strains were more likely to be found in areas of the brain that evolved more recently. these regions are most commonly linked to higher order functions such as cognition, social behavior, learning and memory.
"this study shows how large-scale datasets can be used to reveal fundamental biological patterns that would likely be missed otherwise," said jones. "it is likely that many important differences between individuals and species may result from combinations of many small but clear differences in gene expression."
jones added, "our 15 allen human brain 16 project, which will provide gene expression data across the brains of multiple 17, will help researchers translate these results from an animal model to a human system."
收听单词发音 
