我们都拥有相同的基因
卡莱奥的恐龙,道尔顿的海龟,亚当的南瓜,亚历山大的狮子。 Flickr的图片由弥敦道勒克莱尔通过。
一个主要的“真麻烦因子”基因工程正在从一个物种的基因,并把它们添加到另一物种。虽然这听起来很奇怪,我们都穿着相同的基因。这是没有什么可害怕的 - 事实上,我们学到更多,变得越来越惊人。
在这个星球上的任何有机体的基因组中,你会发现至少有一些共同的基因在其他生物。这种想法的根源是进化本身。人物,恐龙,乌龟,南瓜,和狮子 - 我们都是!
系统进化树
因为我们都有一个共同的祖先,我们有共同的基因。看这个问题的方法之一是在进化树。就像一棵树,系统发育开始的一个分支,然后伸到更小的分支。生物体是紧密联系起来的树,将有更多的共同基因。
理解的演变网站的系统进化树。
虽然生物之间的相似性,最初确定的骨头,生物化学,基因组特征的出现,通过检查物理特性和后测序,使我们能够更好地了解相似之处。
该的认识演进网站(大学,加州古生物博物馆和美国国家科学教育中心)如何阅读和创建系统进化树的一个伟大的教程。
全基因组比较
另一种方式来看待的相似之处是比较完整的基因组。根据基因组新闻网,“超过180有机体的基因组被测序自1995年以来,”这包括人类,蚊子,各种细菌,更多的(他们甚至遗漏了一些,如玉米)。对齐的基因组序列可以根据它们的DNA序列的相似性,所以我们可以看到类似的基因组是作为整体。
特写的基因组,物种的种类,从“纽约时报”。点击一个更大的版本。
大块的基因组进行重排,突变,复制,并以其他方式改变,但我们仍然可以找到类似地区。此图像中显示的比较人类,黑猩猩,恒河猴,小鼠和鸡(点击查看大图)。人类基因组的部分的许多部件是非常相似的其他基因组的部分。
个人基因比较
虽然我们可以看到在整个基因组水平上的相似性,在单个基因是有用的。完全不同的生物之间有许多共同的基因。其中一些保守,令人惊讶的一些变化,而其他人几千年的突变,所以我们勉强可以告诉的基因有一个共同的祖先。
最近的一个例子是,突然出现在传统媒体和社会媒体是法尼烯合成酶 - 酶催化法尼烯的合成,这是一种化学化合物,导致气味。各种形式的法呢烯(和,使得它的酶)被发现在许多不同的生物体,包括蚜虫和苹果。在“苹果”中,金合欢烯使一个很好的苹果气味。一个稍微不同的法尼烯是蚜虫,蚜虫逃跑,因为捕食者靠近的报警信息素,告诉。
在英国洛桑研究法尼烯合成酶基因,并将其插入到小麦基因组的目标吓跑蚜虫离开。他们还使用了法呢基焦磷酸合成酶的基因,与目标表达增加的法呢烯(因为法尼基焦磷酸法呢烯)的前体。作为研究人员之一,GIA Aradottir与生物强化,在接受记者采访时,这两个基因实际上是在实验室中合成。法呢烯合酶基因基因薄荷版本,而最相似的法呢基焦磷酸合成酶基因在哺乳动物中发现的基因是最相似,有一个微小的序列特别类似的基因的牛版。
所有这一切意味着什么,这些基因会出现在许多不同类型的生物体细微的差别。这些同源基因的生物体的基因出现在一个共同的祖先,就像有一个共同的祖先。这是不可怕的,一旦你明白发生了什么,很显然,没有被转变成的薄荷或成一头牛由于增加了这些基因小麦。
原文:We’re all wearing the same genes
Kaleo the Dinosaur, Dalton the Turtle, Adam the Pumpkin, Alexander the Lion. Image by Nathan LeClair via Flickr.
One major “ick factor” of genetic engineering is taking genes from one species and adding them to another species. While it sounds strange, we are all wearing the same genes. It’s not something to be afraid of – in fact, as we learn more it becomes more and more amazing.
Look at the genome of any organism on the planet and you’ll find at least some genes in common with other organisms. The root of this idea is evolution itself. People, dinosaurs, turtles, pumpkins, and lions – we’re all related!
Phylogenetic trees
Since we all have a common ancestor, we have genes in common. One way to look at this is in a phylogenetic tree. Like a tree, phylogeny starts with one trunk that then branches out into smaller and smaller branches. Organisms that are closer together on the tree will have more genes in common.
Phylogenetic tree on the Understanding Evolution website.
While the similarities between organisms were originally determined by examining physical characteristics from bones to biochemistry, the advent of genome characterization and later sequencing has allowed us to better understand the similarities.
The Understanding Evolution website (created by the University of California Museum of Paleontology and the National Center for Science Education) has a great tutorial on how to read and create phylogenetic trees.
Whole genome comparison
Another way to look at similarities is to compare whole genomes. According to the Genome News Network, “the genomes of more than 180 organisms have been sequenced since 1995.” This includes humans, mosquitoes, various bacteria, and many more (and they’re even missing a few, such as corn!). The genomic sequences can be aligned based on the similarities of their sequences so we can see how similar the genomes are as wholes.
Close-Ups of the Genome, Species by Species, from the NY Times. Click for a larger version.
Chunks of genome may be rearranged, mutated, duplicated, and changed in other ways, but we can still find their similar areas. A comparison between human, chimpanzee, Rhesus monkey, mouse, and chicken are shown in this image (click for a larger version). Many parts of the human genome parts are very similar to parts of the other genomes.
Individual gene comparison
While we can see similarities at the whole genome level, looking at individual genes is useful, too. There are many genes in common across wildly different organisms. Some of them are conserved with amazingly few changes while others have mutated over millennia so we can just barely tell the genes had a common ancestor.
A recent example is that popped up in traditional and social media isfarnesene synthase – an enzyme that catalyses the synthesis of farnesene, which is a chemical compound that causes odor. Various forms of farnesene (and the enzyme that makes it) are found in many different organisms, including aphids and apples. In apples, farnesene makes a nice apple smell. In aphids, a slightly different farnesene is an alarm pheromone that tells the aphids to run away because a predator is near.
Rothamsted Research in England took a farnesene synthase gene and inserted it into the wheat genome with the goal of scaring aphids away. They also used a farnesyl pyrophosphate synthase gene, with the goal of increasing expression of farnesene (because farnesyl pyrophosphate is a precursor of farnesene). As one of the researchers, Gia Aradottir, described in an interview with Biofortified, both genes were actually synthesized in a lab. The farnesene synthase gene was most similar to the peppermint version of the gene while the farnesyl pyrophosphate synthase gene was most similar to the gene found in mammals, with one tiny sequence particularly similar to the cow version of the gene.
What all this means is that these genes appear in many different types of organisms with minor differences. Thesehomologous genes have a common ancestor, just as the organisms that the genes appear in have a common ancestor. It’s not scary once you understand what’s happening, and it’s clear that the wheat hasn’t been turned into mint or into a cow due to the addition of these genes.
