WEBVTT 00:00:00.840 --> 00:00:05.056 I believe that the secret to producing extremely drought-tolerant crops, 00:00:05.080 --> 00:00:08.296 which should go some way to providing food security in the world, 00:00:08.320 --> 00:00:11.016 lies in resurrection plants, 00:00:11.040 --> 00:00:14.176 pictured here, in an extremely droughted state. 00:00:14.200 --> 00:00:17.056 You might think that these plants look dead, 00:00:17.080 --> 00:00:18.376 but they're not. 00:00:18.400 --> 00:00:19.856 Give them water, 00:00:19.880 --> 00:00:25.320 and they will resurrect, green up, start growing, in 12 to 48 hours. NOTE Paragraph 00:00:26.320 --> 00:00:27.616 Now, why would I suggest 00:00:27.640 --> 00:00:32.080 that producing drought-tolerant crops will go towards providing food security? 00:00:33.040 --> 00:00:36.936 Well, the current world population is around 7 billion. 00:00:36.960 --> 00:00:39.456 And it's estimated that by 2050, 00:00:39.480 --> 00:00:42.176 we'll be between 9 and 10 billion people, 00:00:42.200 --> 00:00:45.080 with the bulk of this growth happening in Africa. NOTE Paragraph 00:00:45.880 --> 00:00:48.336 The food and agricultural organizations of the world 00:00:48.360 --> 00:00:51.496 have suggested that we need a 70 percent increase 00:00:51.520 --> 00:00:53.696 in current agricultural practice 00:00:53.720 --> 00:00:54.960 to meet that demand. 00:00:55.720 --> 00:00:58.416 Given that plants are at the base of the food chain, 00:00:58.440 --> 00:01:00.760 most of that's going to have to come from plants. NOTE Paragraph 00:01:01.360 --> 00:01:04.056 That percentage of 70 percent 00:01:04.080 --> 00:01:08.296 does not take into consideration the potential effects of climate change. NOTE Paragraph 00:01:08.320 --> 00:01:12.560 This is taken from a study by Dai published in 2011, 00:01:13.240 --> 00:01:15.176 where he took into consideration 00:01:15.200 --> 00:01:17.576 all the potential effects of climate change 00:01:17.600 --> 00:01:19.736 and expressed them -- amongst other things -- 00:01:19.760 --> 00:01:24.376 increased aridity due to lack of rain or infrequent rain. 00:01:24.400 --> 00:01:26.176 The areas in red shown here, 00:01:26.200 --> 00:01:28.256 are areas that until recently 00:01:28.280 --> 00:01:31.456 have been very successfully used for agriculture, 00:01:31.480 --> 00:01:33.880 but cannot anymore because of lack of rainfall. 00:01:34.640 --> 00:01:37.560 This is the situation that's predicted to happen in 2050. 00:01:38.840 --> 00:01:41.016 Much of Africa, in fact, much of the world, 00:01:41.040 --> 00:01:42.936 is going to be in trouble. 00:01:42.960 --> 00:01:46.616 We're going to have to think of some very smart ways of producing food. 00:01:46.640 --> 00:01:49.936 And preferably among them, some drought-tolerant crops. NOTE Paragraph 00:01:49.960 --> 00:01:52.016 The other thing to remember about Africa is 00:01:52.040 --> 00:01:54.840 that most of their agriculture is rainfed. NOTE Paragraph 00:01:56.080 --> 00:01:59.536 Now, making drought-tolerant crops is not the easiest thing in the world. 00:01:59.560 --> 00:02:01.976 And the reason for this is water. 00:02:02.000 --> 00:02:05.136 Water is essential to life on this planet. 00:02:05.160 --> 00:02:09.295 All living, actively metabolizing organisms, 00:02:09.320 --> 00:02:11.376 from microbes to you and I, 00:02:11.400 --> 00:02:13.736 are comprised predominately of water. 00:02:13.760 --> 00:02:16.296 All life reactions happen in water. 00:02:16.320 --> 00:02:19.336 And loss of a small amount of water results in death. 00:02:19.360 --> 00:02:21.416 You and I are 65 percent water -- 00:02:21.440 --> 00:02:23.160 we lose one percent of that, we die. 00:02:23.840 --> 00:02:26.560 But we can make behavioral changes to avoid that. 00:02:27.920 --> 00:02:29.496 Plants can't. 00:02:29.520 --> 00:02:31.136 They're stuck in the ground. 00:02:31.160 --> 00:02:34.536 And so in the first instance they have a little bit more water than us, 00:02:34.560 --> 00:02:35.816 about 95 percent water, 00:02:35.840 --> 00:02:37.936 and they can lose a little bit more than us, 00:02:37.960 --> 00:02:40.920 like 10 to about 70 percent, depending on the species, 00:02:42.000 --> 00:02:43.360 but for short periods only. NOTE Paragraph 00:02:44.680 --> 00:02:48.856 Most of them will either try to resist or avoid water loss. 00:02:48.880 --> 00:02:52.816 So extreme examples of resistors can be found in succulents. 00:02:52.840 --> 00:02:55.656 They tend to be small, very attractive, 00:02:55.680 --> 00:02:58.416 but they hold onto their water at such great cost 00:02:58.440 --> 00:03:00.440 that they grow extremely slowly. 00:03:01.440 --> 00:03:06.016 Examples of avoidance of water loss are found in trees and shrubs. 00:03:06.040 --> 00:03:07.616 They send down very deep roots, 00:03:07.640 --> 00:03:09.336 mine subterranean water supplies 00:03:09.360 --> 00:03:11.816 and just keep flushing it through them at all times, 00:03:11.840 --> 00:03:13.696 keeping themselves hydrated. NOTE Paragraph 00:03:13.720 --> 00:03:15.696 The one on the right is called a baobab. 00:03:15.720 --> 00:03:17.776 It's also called the upside-down tree, 00:03:17.800 --> 00:03:21.576 simply because the proportion of roots to shoots is so great 00:03:21.600 --> 00:03:24.296 that it looks like the tree has been planted upside down. 00:03:24.320 --> 00:03:27.560 And of course the roots are required for hydration of that plant. NOTE Paragraph 00:03:28.760 --> 00:03:33.280 And probably the most common strategy of avoidance is found in annuals. 00:03:33.840 --> 00:03:37.016 Annuals make up the bulk of our plant food supplies. 00:03:37.040 --> 00:03:38.736 Up the west coast of my country, 00:03:38.760 --> 00:03:42.296 for much of the year you don't see much vegetation growth. 00:03:42.320 --> 00:03:44.976 But come the spring rains, you get this: 00:03:45.000 --> 00:03:46.240 flowering of the desert. NOTE Paragraph 00:03:47.000 --> 00:03:48.856 The strategy in annuals, 00:03:48.880 --> 00:03:51.240 is to grow only in the rainy season. 00:03:51.960 --> 00:03:54.256 At the end of that season they produce a seed, 00:03:54.280 --> 00:03:57.096 which is dry, eight to 10 percent water, 00:03:57.120 --> 00:03:58.776 but very much alive. 00:03:58.800 --> 00:04:01.696 And anything that is that dry and still alive, 00:04:01.720 --> 00:04:03.200 we call desiccation-tolerant. NOTE Paragraph 00:04:03.840 --> 00:04:05.256 In the desiccated state, 00:04:05.280 --> 00:04:07.936 what seeds can do is lie in extremes of environment 00:04:07.960 --> 00:04:09.616 for prolonged periods of time. 00:04:09.640 --> 00:04:11.856 The next time the rainy season comes, 00:04:11.880 --> 00:04:13.376 they germinate and grow, 00:04:13.400 --> 00:04:15.280 and the whole cycle just starts again. NOTE Paragraph 00:04:16.120 --> 00:04:20.176 It's widely believed that the evolution of desiccation-tolerant seeds 00:04:20.200 --> 00:04:22.376 allowed the colonization and the radiation 00:04:22.400 --> 00:04:25.920 of flowering plants, or angiosperms, onto land. NOTE Paragraph 00:04:26.960 --> 00:04:30.120 But back to annuals as our major form of food supplies. 00:04:30.800 --> 00:04:35.520 Wheat, rice and maize form 95 percent of our plant food supplies. 00:04:36.480 --> 00:04:38.016 And it's been a great strategy 00:04:38.040 --> 00:04:41.216 because in a short space of time you can produce a lot of seed. 00:04:41.240 --> 00:04:43.860 Seeds are energy-rich so there's a lot of food calories, 00:04:43.884 --> 00:04:47.804 you can store it in times of plenty for times of famine, 00:04:48.480 --> 00:04:49.720 but there's a downside. 00:04:50.560 --> 00:04:51.936 The vegetative tissues, 00:04:51.960 --> 00:04:54.136 the roots and leaves of annuals, 00:04:54.160 --> 00:04:55.416 do not have much 00:04:55.440 --> 00:04:59.536 by way of inherent resistance, avoidance or tolerance characteristics. 00:04:59.560 --> 00:05:00.856 They just don't need them. 00:05:00.880 --> 00:05:02.296 They grow in the rainy season 00:05:02.320 --> 00:05:05.696 and they've got a seed to help them survive the rest of the year. NOTE Paragraph 00:05:05.720 --> 00:05:08.416 And so despite concerted efforts in agriculture 00:05:08.440 --> 00:05:10.976 to make crops with improved properties 00:05:11.000 --> 00:05:13.176 of resistance, avoidance and tolerance -- 00:05:13.200 --> 00:05:15.096 particularly resistance and avoidance 00:05:15.120 --> 00:05:18.016 because we've had good models to understand how those work -- 00:05:18.040 --> 00:05:20.376 we still get images like this. 00:05:20.400 --> 00:05:21.856 Maize crop in Africa, 00:05:21.880 --> 00:05:23.296 two weeks without rain 00:05:23.320 --> 00:05:24.520 and it's dead. NOTE Paragraph 00:05:25.560 --> 00:05:26.800 There is a solution: 00:05:27.520 --> 00:05:28.760 resurrection plants. 00:05:29.320 --> 00:05:33.096 These plants can lose 95 percent of their cellular water, 00:05:33.120 --> 00:05:36.976 remain in a dry, dead-like state for months to years, 00:05:37.000 --> 00:05:38.736 and give them water, 00:05:38.760 --> 00:05:40.640 they green up and start growing again. 00:05:41.560 --> 00:05:44.856 Like seeds, these are desiccation-tolerant. 00:05:44.880 --> 00:05:49.000 Like seeds, these can withstand extremes of environmental conditions. 00:05:49.760 --> 00:05:51.776 And this is a really rare phenomenon. 00:05:51.800 --> 00:05:56.176 There are only 135 flowering plant species that can do this. NOTE Paragraph 00:05:56.200 --> 00:05:57.616 I'm going to show you a video 00:05:57.640 --> 00:06:00.256 of the resurrection process of these three species 00:06:00.280 --> 00:06:01.496 in that order. 00:06:01.520 --> 00:06:02.776 And at the bottom, 00:06:02.800 --> 00:06:05.536 there's a time axis so you can see how quickly it happens. NOTE Paragraph 00:06:44.160 --> 00:06:46.200 (Applause) NOTE Paragraph 00:06:50.240 --> 00:06:51.776 Pretty amazing, huh? NOTE Paragraph 00:06:51.800 --> 00:06:56.016 So I've spent the last 21 years trying to understand how they do this. 00:06:56.040 --> 00:06:58.440 How do these plants dry without dying? 00:06:59.080 --> 00:07:01.856 And I work on a variety of different resurrection plants, 00:07:01.880 --> 00:07:04.296 shown here in the hydrated and dry states, 00:07:04.320 --> 00:07:05.776 for a number of reasons. NOTE Paragraph 00:07:05.800 --> 00:07:08.656 One of them is that each of these plants serves as a model 00:07:08.680 --> 00:07:11.056 for a crop that I'd like to make drought-tolerant. NOTE Paragraph 00:07:11.080 --> 00:07:14.016 So on the extreme top left, for example, is a grass, 00:07:14.040 --> 00:07:16.296 it's called Eragrostis nindensis, 00:07:16.320 --> 00:07:18.696 it's got a close relative called Eragrostis tef -- 00:07:18.720 --> 00:07:20.736 a lot of you might know it as "teff" -- 00:07:20.760 --> 00:07:22.496 it's a staple food in Ethiopia, 00:07:22.520 --> 00:07:23.776 it's gluten-free, 00:07:23.800 --> 00:07:26.816 and it's something we would like to make drought-tolerant. NOTE Paragraph 00:07:26.840 --> 00:07:29.256 The other reason for looking at a number of plants, 00:07:29.280 --> 00:07:30.656 is that, as least initially, 00:07:30.680 --> 00:07:32.936 I wanted to find out: do they do the same thing? 00:07:32.960 --> 00:07:34.656 Do they all use the same mechanisms 00:07:34.680 --> 00:07:37.256 to be able to lose all that water and not die? NOTE Paragraph 00:07:37.280 --> 00:07:39.976 So I undertook what we call a systems biology approach 00:07:40.000 --> 00:07:42.176 in order to get a comprehensive understanding 00:07:42.200 --> 00:07:44.216 of desiccation tolerance, 00:07:44.240 --> 00:07:45.696 in which we look at everything 00:07:45.720 --> 00:07:48.632 from the molecular to the whole plant, ecophysiological level. NOTE Paragraph 00:07:48.657 --> 00:07:50.291 For example we look at things like 00:07:50.316 --> 00:07:52.513 changes in the plant anatomy as they dried out 00:07:52.537 --> 00:07:53.776 and their ultrastructure. 00:07:53.800 --> 00:07:56.976 We look at the transcriptome, which is just a term for a technology 00:07:57.000 --> 00:07:58.416 in which we look at the genes 00:07:58.440 --> 00:08:00.856 that are switched on or off, in response to drying. 00:08:00.880 --> 00:08:04.096 Most genes will code for proteins, so we look at the proteome. 00:08:04.120 --> 00:08:06.520 What are the proteins made in response to drying? 00:08:07.480 --> 00:08:11.376 Some proteins would code for enzymes which make metabolites, 00:08:11.400 --> 00:08:12.976 so we look at the metabolome. NOTE Paragraph 00:08:13.000 --> 00:08:16.296 Now, this is important because plants are stuck in the ground. 00:08:16.320 --> 00:08:20.416 They use what I call a highly tuned chemical arsenal 00:08:20.440 --> 00:08:23.856 to protect themselves from all the stresses of their environment. 00:08:23.880 --> 00:08:25.376 So it's important that we look 00:08:25.400 --> 00:08:27.840 at the chemical changes involved in drying. NOTE Paragraph 00:08:28.520 --> 00:08:31.176 And at the last study that we do at the molecular level, 00:08:31.200 --> 00:08:32.456 we look at the lipidome -- 00:08:32.480 --> 00:08:34.535 the lipid changes in response to drying. 00:08:34.559 --> 00:08:35.816 And that's also important 00:08:35.840 --> 00:08:38.655 because all biological membranes are made of lipids. 00:08:38.679 --> 00:08:41.256 They're held as membranes because they're in water. 00:08:41.280 --> 00:08:43.520 Take away the water, those membranes fall apart. 00:08:44.240 --> 00:08:47.280 Lipids also act as signals to turn on genes. NOTE Paragraph 00:08:48.200 --> 00:08:50.896 Then we use physiological and biochemical studies 00:08:50.920 --> 00:08:54.136 to try and understand the function of the putative protectants 00:08:54.160 --> 00:08:57.096 that we've actually discovered in our other studies. 00:08:57.120 --> 00:08:59.296 And then use all of that to try and understand 00:08:59.320 --> 00:09:01.640 how the plant copes with its natural environment. NOTE Paragraph 00:09:03.480 --> 00:09:07.816 I've always had the philosophy that I needed a comprehensive understanding 00:09:07.840 --> 00:09:10.096 of the mechanisms of desiccation tolerance 00:09:10.120 --> 00:09:13.960 in order to make a meaningful suggestion for a biotic application. NOTE Paragraph 00:09:15.000 --> 00:09:16.656 I'm sure some of you are thinking, 00:09:16.680 --> 00:09:17.936 "By biotic application, 00:09:17.960 --> 00:09:20.880 does she mean she's going to make genetically modified crops?" 00:09:22.240 --> 00:09:23.936 And the answer to that question is: 00:09:23.960 --> 00:09:26.341 depends on your definition of genetic modification. NOTE Paragraph 00:09:27.200 --> 00:09:30.016 All of the crops that we eat today, wheat, grass and maize, 00:09:30.040 --> 00:09:33.256 are highly genetically modified from their ancestors, 00:09:33.280 --> 00:09:35.256 but we don't consider them GM 00:09:35.280 --> 00:09:37.920 because they're being produced by conventional breeding. 00:09:38.880 --> 00:09:42.656 If you mean, am I going to put resurrection plant genes into crops, 00:09:42.680 --> 00:09:43.976 your answer is yes. NOTE Paragraph 00:09:44.000 --> 00:09:47.136 In the essence of time, we have tried that approach. 00:09:47.160 --> 00:09:50.016 More appropriately, some of my collaborators at UCT, 00:09:50.040 --> 00:09:51.976 Jennifer Thomson, Suhail Rafudeen, 00:09:52.000 --> 00:09:53.616 have spearheaded that approach 00:09:53.640 --> 00:09:55.593 and I'm going to show you some data soon. NOTE Paragraph 00:09:57.200 --> 00:10:01.216 But we're about to embark upon an extremely ambitious approach, 00:10:01.240 --> 00:10:04.696 in which we aim to turn on whole suites of genes 00:10:04.720 --> 00:10:07.416 that are already present in every crop. 00:10:07.440 --> 00:10:10.345 They're just never turned on under extreme drought conditions. 00:10:10.800 --> 00:10:12.256 I leave it up to you to decide 00:10:12.280 --> 00:10:14.233 whether those should be called GM or not. NOTE Paragraph 00:10:15.560 --> 00:10:19.016 I'm going to now just give you some of the data from that first approach. 00:10:19.040 --> 00:10:20.296 And in order to do that 00:10:20.320 --> 00:10:22.976 I have to explain a little bit about how genes work. NOTE Paragraph 00:10:23.000 --> 00:10:24.256 So you probably all know 00:10:24.280 --> 00:10:26.336 that genes are made of double-stranded DNA. 00:10:26.360 --> 00:10:28.296 It's wound very tightly into chromosomes 00:10:28.320 --> 00:10:31.480 that are present in every cell of your body or in a plant's body. 00:10:32.080 --> 00:10:35.160 If you unwind that DNA, you get genes. 00:10:35.840 --> 00:10:38.296 And each gene has a promoter, 00:10:38.320 --> 00:10:40.696 which is just an on-off switch, 00:10:40.720 --> 00:10:42.136 the gene coding region, 00:10:42.160 --> 00:10:43.416 and then a terminator, 00:10:43.440 --> 00:10:47.040 which indicates that this is the end of this gene, the next gene will start. NOTE Paragraph 00:10:47.720 --> 00:10:50.616 Now, promoters are not simple on-off switches. 00:10:50.640 --> 00:10:53.336 They normally require a lot of fine-tuning, 00:10:53.360 --> 00:10:57.400 lots of things to be present and correct before that gene is switched on. 00:10:58.240 --> 00:11:01.296 So what's typically done in biotech studies 00:11:01.320 --> 00:11:03.136 is that we use an inducible promoter, 00:11:03.160 --> 00:11:04.736 we know how to switch it on. 00:11:04.760 --> 00:11:06.776 We couple that to genes of interest 00:11:06.800 --> 00:11:09.480 and put that into a plant and see how the plant responds. NOTE Paragraph 00:11:10.120 --> 00:11:12.696 In the study that I'm going to talk to you about, 00:11:12.720 --> 00:11:15.176 my collaborators used a drought-induced promoter, 00:11:15.200 --> 00:11:17.616 which we discovered in a resurrection plant. 00:11:17.640 --> 00:11:20.776 The nice thing about this promoter is that we do nothing. 00:11:20.800 --> 00:11:22.880 The plant itself senses drought. 00:11:23.600 --> 00:11:28.696 And we've used it to drive antioxidant genes from resurrection plants. 00:11:28.720 --> 00:11:30.576 Why antioxidant genes? 00:11:30.600 --> 00:11:33.656 Well, all stresses, particularly drought stress, 00:11:33.680 --> 00:11:35.976 results in the formation of free radicals, 00:11:36.000 --> 00:11:38.336 or reactive oxygen species, 00:11:38.360 --> 00:11:41.080 which are highly damaging and can cause crop death. 00:11:41.680 --> 00:11:44.280 What antioxidants do is stop that damage. NOTE Paragraph 00:11:45.360 --> 00:11:49.256 So here's some data from a maize strain that's very popularly used in Africa. 00:11:49.280 --> 00:11:52.576 To the left of the arrow are plants without the genes, 00:11:52.600 --> 00:11:53.856 to the right -- 00:11:53.880 --> 00:11:55.936 plants with the antioxidant genes. 00:11:55.960 --> 00:11:57.776 After three weeks without watering, 00:11:57.800 --> 00:12:00.280 the ones with the genes do a hell of a lot better. NOTE Paragraph 00:12:01.720 --> 00:12:03.056 Now to the final approach. 00:12:03.080 --> 00:12:06.616 My research has shown that there's considerable similarity 00:12:06.640 --> 00:12:11.056 in the mechanisms of desiccation tolerance in seeds and resurrection plants. 00:12:11.080 --> 00:12:12.496 So I ask the question, 00:12:12.520 --> 00:12:13.960 are they using the same genes? 00:12:14.480 --> 00:12:16.736 Or slightly differently phrased, 00:12:16.760 --> 00:12:21.256 are resurrection plants using genes evolved in seed desiccation tolerance 00:12:21.280 --> 00:12:22.536 in their roots and leaves? 00:12:22.560 --> 00:12:24.616 Have they retasked these seed genes 00:12:24.640 --> 00:12:26.680 in roots and leaves of resurrection plants? NOTE Paragraph 00:12:27.760 --> 00:12:29.616 And I answer that question, 00:12:29.640 --> 00:12:32.056 as a consequence of a lot of research from my group 00:12:32.080 --> 00:12:35.616 and recent collaborations from a group of Henk Hilhorst in the Netherlands, 00:12:35.640 --> 00:12:37.216 Mel Oliver in the United States 00:12:37.240 --> 00:12:39.840 and Julia Buitink in France. 00:12:39.880 --> 00:12:41.296 The answer is yes, 00:12:41.320 --> 00:12:44.176 that there is a core set of genes that are involved in both. NOTE Paragraph 00:12:44.200 --> 00:12:47.616 And I'm going to illustrate this very crudely for maize, 00:12:47.640 --> 00:12:50.056 where the chromosomes below the off switch 00:12:50.080 --> 00:12:53.655 represent all the genes that are required for desiccation tolerance. 00:12:53.680 --> 00:12:57.936 So as maize seeds dried out at the end of their period of development, 00:12:57.960 --> 00:12:59.320 they switch these genes on. 00:13:00.680 --> 00:13:03.576 Resurrection plants switch on the same genes 00:13:03.600 --> 00:13:05.256 when they dry out. 00:13:05.280 --> 00:13:07.056 All modern crops, therefore, 00:13:07.080 --> 00:13:09.136 have these genes in their roots and leaves, 00:13:09.160 --> 00:13:10.896 they just never switch them on. 00:13:10.920 --> 00:13:12.880 They only switch them on in seed tissues. NOTE Paragraph 00:13:13.440 --> 00:13:15.176 So what we're trying to do right now 00:13:15.200 --> 00:13:17.816 is to understand the environmental and cellular signals 00:13:17.840 --> 00:13:20.280 that switch on these genes in resurrection plants, 00:13:21.280 --> 00:13:23.040 to mimic the process in crops. NOTE Paragraph 00:13:23.680 --> 00:13:25.416 And just a final thought. 00:13:25.440 --> 00:13:27.656 What we're trying to do very rapidly 00:13:27.680 --> 00:13:31.496 is to repeat what nature did in the evolution of resurrection plants 00:13:31.520 --> 00:13:33.360 some 10 to 40 million years ago. NOTE Paragraph 00:13:34.160 --> 00:13:36.656 My plants and I thank you for your attention. NOTE Paragraph 00:13:36.680 --> 00:13:42.915 (Applause)