1 00:00:07,003 --> 00:00:09,797 Symmetry is everywhere in nature, 2 00:00:09,797 --> 00:00:12,184 and we usually associate it with beauty: 3 00:00:12,184 --> 00:00:13,831 a perfectly shaped leaf, 4 00:00:13,831 --> 00:00:17,571 or a butterfly with intricate patterns mirrored on each wing. 5 00:00:17,571 --> 00:00:21,197 But it turns out that asymmetry is pretty important, too, 6 00:00:21,197 --> 00:00:23,130 and more common than you might think, 7 00:00:23,130 --> 00:00:25,707 from crabs with one giant pincer claw 8 00:00:25,707 --> 00:00:30,629 to snail species whose shells' always coil in the same direction. 9 00:00:30,629 --> 00:00:34,944 Some species of beans only climb up their trellises clockwise, 10 00:00:34,944 --> 00:00:37,200 others, only counterclockwise, 11 00:00:37,200 --> 00:00:41,062 and even though the human body looks pretty symmetrical on the outside, 12 00:00:41,062 --> 00:00:43,735 it's a different story on the inside. 13 00:00:43,735 --> 00:00:47,404 Most of your vital organs are arranged asymmetrically. 14 00:00:47,404 --> 00:00:51,939 The heart, stomach, spleen, and pancreas lie towards the left. 15 00:00:51,939 --> 00:00:55,676 The gallbladder and most of your liver are on the right. 16 00:00:55,676 --> 00:00:57,568 Even your lungs are different. 17 00:00:57,568 --> 00:01:00,534 The left one has two lobes, and the right one has three. 18 00:01:00,534 --> 00:01:05,301 The two sides of your brain look similar, but function differently. 19 00:01:05,301 --> 00:01:10,159 Making sure this asymmetry is distributed the right way is critical. 20 00:01:10,159 --> 00:01:15,152 If all your internal organs are flipped, a condition called situs inversus, 21 00:01:15,152 --> 00:01:16,692 it's often harmless. 22 00:01:16,692 --> 00:01:19,038 But incomplete reversals can be fatal, 23 00:01:19,038 --> 00:01:22,099 especially if the heart is involved. 24 00:01:22,099 --> 00:01:24,030 But where does this asymmetry come from, 25 00:01:24,030 --> 00:01:28,564 since a brand-new embryo looks identical on the right and left. 26 00:01:28,564 --> 00:01:31,751 One theory focuses on a small pit on the embryo 27 00:01:31,751 --> 00:01:33,045 called a node. 28 00:01:33,045 --> 00:01:36,000 The node is lined with tiny hairs called cilia, 29 00:01:36,000 --> 00:01:40,189 while tilt away from the head and whirl around rapidly, 30 00:01:40,189 --> 00:01:42,437 all in the same direction. 31 00:01:42,437 --> 00:01:46,751 This synchronized rotation pushes fluid from the right side of the embryo 32 00:01:46,751 --> 00:01:48,301 to the left. 33 00:01:48,301 --> 00:01:50,201 On the node's left-hand rim, 34 00:01:50,201 --> 00:01:52,610 other cilia sense this fluid flow 35 00:01:52,610 --> 00:01:56,958 and activate specific genes on the embryo's left side. 36 00:01:56,958 --> 00:02:00,724 These genes direct the cells to make certain proteins, 37 00:02:00,724 --> 00:02:02,079 and in just a few hours, 38 00:02:02,079 --> 00:02:06,337 the right and left sides of the embryo are chemically different. 39 00:02:06,337 --> 00:02:08,126 Even though they still look the same, 40 00:02:08,126 --> 00:02:14,053 these chemical differences are eventually translated into asymmetric organs. 41 00:02:14,053 --> 00:02:17,812 Asymmetry shows up in the heart first. 42 00:02:17,812 --> 00:02:21,645 It begins as a straight tube along the center of the embryo, 43 00:02:21,645 --> 00:02:24,215 but when the embryo is around three weeks old, 44 00:02:24,215 --> 00:02:27,180 the tube starts to bend into a c-shape 45 00:02:27,180 --> 00:02:30,115 and rotate towards the right side of the body. 46 00:02:30,115 --> 00:02:32,942 It grows different structures on each side, 47 00:02:32,942 --> 00:02:36,459 eventually turning into the familiar asymmetric heart. 48 00:02:36,459 --> 00:02:40,829 Meanwhile, the other major organs emerge from a central tube 49 00:02:40,829 --> 00:02:43,664 and grow towards their ultimate positions. 50 00:02:43,664 --> 00:02:48,299 But some organisms, like pigs, don't have those embryonic cilia 51 00:02:48,299 --> 00:02:51,288 and still have asymmetric internal organs. 52 00:02:51,288 --> 00:02:54,570 Could all cells be intrinsically asymmetric? 53 00:02:54,570 --> 00:02:55,702 Probably. 54 00:02:55,702 --> 00:03:00,950 Bacterial colonies grow lacy branches that all curl in the same direction, 55 00:03:00,950 --> 00:03:04,423 and human cells cultured inside a ring-shaped boundary 56 00:03:04,423 --> 00:03:08,032 tend to line up like the ridges on a cruller. 57 00:03:08,032 --> 00:03:09,867 If we zoom in even more, 58 00:03:09,867 --> 00:03:12,562 we see that many of cells' basic building blocks, 59 00:03:12,562 --> 00:03:17,905 like nucleic acids, proteins, and sugars, are inherently asymmetric. 60 00:03:17,905 --> 00:03:20,676 Proteins have complex asymmetric shapes, 61 00:03:20,676 --> 00:03:23,860 and those proteins control which way cells migrate 62 00:03:23,860 --> 00:03:26,726 and which way embryonic cilia twirl. 63 00:03:26,726 --> 00:03:30,401 These biomolecules have a property called chirality, 64 00:03:30,401 --> 00:03:34,652 which means that a molecule and its mirror image aren't identical. 65 00:03:34,652 --> 00:03:37,652 Like your right and left hands, they look the same, 66 00:03:37,652 --> 00:03:42,342 but trying to put your right in your left glove proves they're not. 67 00:03:42,342 --> 00:03:47,621 This asymmetry at the molecular level is reflected in asymmetric cells, 68 00:03:47,621 --> 00:03:49,073 asymmetric embryos, 69 00:03:49,073 --> 00:03:51,929 and finally asymmetric organisms. 70 00:03:51,929 --> 00:03:53,926 So while symmetry may be beautiful, 71 00:03:53,926 --> 00:03:57,085 asymmetry holds an allure of its own, 72 00:03:57,085 --> 00:03:58,728 found in its graceful whirls, 73 00:03:58,728 --> 00:04:00,656 its organized complexity, 74 00:04:00,656 --> 00:04:02,647 and its striking imperfections.