1 00:00:00,090 --> 00:00:02,490 The following content is provided under a Creative 2 00:00:02,490 --> 00:00:04,030 Commons license. 3 00:00:04,030 --> 00:00:06,330 Your support will help MIT OpenCourseWare 4 00:00:06,330 --> 00:00:10,720 continue to offer high quality educational resources for free. 5 00:00:10,720 --> 00:00:13,320 To make a donation or view additional materials 6 00:00:13,320 --> 00:00:17,280 from hundreds of MIT courses, visit MIT OpenCourseWare 7 00:00:17,280 --> 00:00:18,240 at ocw.mit.edu. 8 00:00:21,100 --> 00:00:22,960 JOHN ESSIGMANN: We're still on storyboard 7. 9 00:00:22,960 --> 00:00:25,570 We're on panel C. Panel C is where 10 00:00:25,570 --> 00:00:28,030 I introduced the TCA cycle. 11 00:00:28,030 --> 00:00:29,830 As I mentioned earlier, respiration 12 00:00:29,830 --> 00:00:32,090 consists of three stages. 13 00:00:32,090 --> 00:00:34,810 The first is the pyruvate dehydrogenase reaction, 14 00:00:34,810 --> 00:00:38,950 which we just covered, taking pyruvate to acetyl-CoA. 15 00:00:38,950 --> 00:00:43,210 The second is the TCA cycle, or tricarboxylic acid cycle 16 00:00:43,210 --> 00:00:45,970 taking that acetyl-CoA and basically 17 00:00:45,970 --> 00:00:49,090 oxidizing it in order to generate CO2 18 00:00:49,090 --> 00:00:51,550 but also to produce more reducing equivalents 19 00:00:51,550 --> 00:00:54,920 in the form of mobile electron carriers. 20 00:00:54,920 --> 00:00:56,680 And then the third step of respiration 21 00:00:56,680 --> 00:00:58,720 is taking those reducing equivalents 22 00:00:58,720 --> 00:01:01,100 to the mitochondrial inner membrane, where 23 00:01:01,100 --> 00:01:03,970 the molecules containing those reducing equivalents 24 00:01:03,970 --> 00:01:05,470 are oxidized. 25 00:01:05,470 --> 00:01:08,890 And then, the electrons from that oxidation reaction 26 00:01:08,890 --> 00:01:12,730 are used to power proton pumps that ultimately will generate 27 00:01:12,730 --> 00:01:16,450 the proton gradient that can be used for generation of ATP 28 00:01:16,450 --> 00:01:19,990 or for generation of movement or for other things. 29 00:01:19,990 --> 00:01:22,630 The tricarboxylic acid cycle, which is sometimes 30 00:01:22,630 --> 00:01:25,630 called the Krebs cycle, takes acetyl-CoA 31 00:01:25,630 --> 00:01:27,750 from several different sources. 32 00:01:27,750 --> 00:01:30,640 One of those sources is glycolysis to pyruvate 33 00:01:30,640 --> 00:01:34,030 and pyruvate to acetyl-CoA, as we've just seen. 34 00:01:34,030 --> 00:01:35,950 And the second source of acetyl-CoA 35 00:01:35,950 --> 00:01:37,960 is from fatty acid oxidation. 36 00:01:37,960 --> 00:01:40,720 We'll come to that pathway somewhat later. 37 00:01:40,720 --> 00:01:43,660 Again, looking at panel C, the TCA cycle 38 00:01:43,660 --> 00:01:46,190 starts with the reaction of acetyl coenzyme 39 00:01:46,190 --> 00:01:49,300 A, a 2-carbon compound with oxaloacetate, 40 00:01:49,300 --> 00:01:53,950 a 4-carbon compound, to form the 6-carbon product citrate. 41 00:01:53,950 --> 00:01:57,450 Citrate will lose 2 carbons as carbon dioxide, 42 00:01:57,450 --> 00:02:00,160 and in the process, there'll be a series of oxidation steps 43 00:02:00,160 --> 00:02:04,120 that generate three NADHes one FADH2, 44 00:02:04,120 --> 00:02:08,110 and one either GTP or ATP by substrate-level 45 00:02:08,110 --> 00:02:09,430 phosphorylation. 46 00:02:09,430 --> 00:02:11,620 In terms of the banking system of the cell, 47 00:02:11,620 --> 00:02:14,290 the NADHes that are generated in the mitochondrion 48 00:02:14,290 --> 00:02:17,430 are exchangeable for about three ATPs. 49 00:02:17,430 --> 00:02:21,070 FADH2 is exchangeable for about two ATPs. 50 00:02:21,070 --> 00:02:22,690 So if you look up the total number 51 00:02:22,690 --> 00:02:25,990 of nucleotide triphosphate, or NTP, equivalents 52 00:02:25,990 --> 00:02:28,390 that can be produced in the TCA cycle, 53 00:02:28,390 --> 00:02:32,260 you'll get about 12 ATPs for each 2-carbon unit 54 00:02:32,260 --> 00:02:35,020 of acetyl-CoA that's oxidized. 55 00:02:35,020 --> 00:02:36,760 As a detailed point, I want to mention 56 00:02:36,760 --> 00:02:38,860 that the two carbons that entered the TCA 57 00:02:38,860 --> 00:02:42,100 cycle as acetyl-CoA are not exactly the same two 58 00:02:42,100 --> 00:02:45,190 carbons that come out as CO2 in that cycle. 59 00:02:45,190 --> 00:02:48,160 The carbon dioxides from the input acetyl-CoA 60 00:02:48,160 --> 00:02:51,940 will emerge in later turns of the TCA cycle. 61 00:02:51,940 --> 00:02:54,610 Now we're going to look at panel D. In panel D, 62 00:02:54,610 --> 00:02:57,760 we start looking at the details of the TCA cycle. 63 00:02:57,760 --> 00:03:00,550 JoAnne explained why nature uses thioesters. 64 00:03:00,550 --> 00:03:03,520 The sulfur allows enolization stabilization 65 00:03:03,520 --> 00:03:06,430 of a carbanion at carbon 2, the carbon that's 66 00:03:06,430 --> 00:03:09,630 distal to the coenzyme A functionality. 67 00:03:09,630 --> 00:03:12,400 The carbanion is then able to attack the number 2 68 00:03:12,400 --> 00:03:14,950 carbon, carbonyl, of oxaloacetate 69 00:03:14,950 --> 00:03:18,550 in the reaction catalyzed by citrate synthase. 70 00:03:18,550 --> 00:03:21,940 An intermediate is formed, citroyl coenzyme A, 71 00:03:21,940 --> 00:03:25,060 which loses its coenzyme A moiety by hydrolysis 72 00:03:25,060 --> 00:03:28,300 in a very thermodynamically irreversible step, 73 00:03:28,300 --> 00:03:30,850 resulting in the product citrate. 74 00:03:30,850 --> 00:03:33,040 This step is at the top of the pathway, 75 00:03:33,040 --> 00:03:36,940 and as is usually the case, this highly exothermic step 76 00:03:36,940 --> 00:03:41,200 makes the pathway, overall, irreversible. 77 00:03:41,200 --> 00:03:43,630 Chemically, citrate synthase does 78 00:03:43,630 --> 00:03:46,810 a mixed aldol-Claisen ester condensation. 79 00:03:46,810 --> 00:03:49,240 The product of the citrate synthase reaction, citrate, 80 00:03:49,240 --> 00:03:52,240 is a tertiary alcohol, and tertiary alcohols 81 00:03:52,240 --> 00:03:54,670 are relatively difficult to oxidize. 82 00:03:54,670 --> 00:03:57,160 The next enzyme in the pathway, aconitase, 83 00:03:57,160 --> 00:04:00,280 which is shown in storyboard 8, panel A, 84 00:04:00,280 --> 00:04:03,580 removes a water molecule and then adds a different water 85 00:04:03,580 --> 00:04:06,850 molecule back to rearrange the hydroxyl group, 86 00:04:06,850 --> 00:04:08,800 making a secondary alcohol, which 87 00:04:08,800 --> 00:04:11,200 is much easier to oxidize. 88 00:04:11,200 --> 00:04:15,010 Looking again at panel A, the hydroxyl group of high 89 00:04:15,010 --> 00:04:17,380 isocitrate is oxidized to a ketone, 90 00:04:17,380 --> 00:04:21,990 with the transfer of hydride to NAD+ to make NADH. 91 00:04:21,990 --> 00:04:25,190 This reaction is catalyzed by the enzyme isocitrate 92 00:04:25,190 --> 00:04:27,910 dehydrogenase, ICDH. 93 00:04:27,910 --> 00:04:29,470 The intermediate in this reaction 94 00:04:29,470 --> 00:04:33,310 is oxalosuccinate, which is a beta-keto acid. 95 00:04:33,310 --> 00:04:35,340 As we know from what JoAnne taught us, 96 00:04:35,340 --> 00:04:40,190 beta-keto acids are prone to spontaneous decarboxylation. 97 00:04:40,190 --> 00:04:43,000 So the second half of the isocitrate dehydrogenase 98 00:04:43,000 --> 00:04:46,090 reaction involves the loss of carbon dioxide 99 00:04:46,090 --> 00:04:49,810 in what's usually considered to be an irreversible step. 100 00:04:49,810 --> 00:04:51,760 I do want to point out, however, that 101 00:04:51,760 --> 00:04:54,790 under certain circumstances, you can re-add the carbon 102 00:04:54,790 --> 00:04:57,160 dioxide in order to make the reaction go 103 00:04:57,160 --> 00:04:59,200 in the other direction. 104 00:04:59,200 --> 00:05:03,850 After the ICDH reactions, which generated NADH and resulted 105 00:05:03,850 --> 00:05:06,970 in loss of CO2, the product is alpha-ketoglutarate, 106 00:05:06,970 --> 00:05:09,640 a 5-carbon keto acid. 107 00:05:09,640 --> 00:05:12,190 Take a look at the structure of alpha-ketoglutarate 108 00:05:12,190 --> 00:05:16,150 in the upper right-hand portion of storyboard 8, 109 00:05:16,150 --> 00:05:19,990 panel A. If you hold your finger over the top 2 110 00:05:19,990 --> 00:05:22,190 carbons of alpha-ketoglutarate, you'll 111 00:05:22,190 --> 00:05:24,980 notice that the residue is pyruvate. 112 00:05:24,980 --> 00:05:28,280 So pyruvate plus an acetyl functionality 113 00:05:28,280 --> 00:05:31,580 equals, effectively, alpha-ketoglutarate. 114 00:05:31,580 --> 00:05:33,830 Now take a look back at the mechanism 115 00:05:33,830 --> 00:05:39,200 by which pyruvate is oxidized by pyruvate dehydrogenase. 116 00:05:39,200 --> 00:05:42,290 It's going to be a very similar mechanism for the oxidation 117 00:05:42,290 --> 00:05:44,090 of alpha-ketoglutarate. 118 00:05:44,090 --> 00:05:46,520 The product of the alpha-ketoglutarate 119 00:05:46,520 --> 00:05:49,280 dehydrogenase reaction is succinyl-CoA. 120 00:05:49,280 --> 00:05:51,740 Again, if you look at the structure of this molecule, 121 00:05:51,740 --> 00:05:56,420 succinyl-CoA, it's actually an acetyl-CoA with an acetyl group 122 00:05:56,420 --> 00:05:57,970 put onto one end. 123 00:05:57,970 --> 00:06:01,370 Now let's go back and look at the alpha-ketoglutarate 124 00:06:01,370 --> 00:06:03,290 from a different perspective. 125 00:06:03,290 --> 00:06:07,010 I want to make a point here in that alpha-ketoglutarate 126 00:06:07,010 --> 00:06:09,280 is an alpha-keto acid, and if we were 127 00:06:09,280 --> 00:06:11,840 to replace its keto group with an amino group, 128 00:06:11,840 --> 00:06:13,460 you'd convert this keto acid into 129 00:06:13,460 --> 00:06:16,130 the amino acid glutamic acid. 130 00:06:16,130 --> 00:06:19,670 As with most enzymatic reactions involving such nitrogen 131 00:06:19,670 --> 00:06:24,440 functionalities, a pyridoxal pyridoxamine phosphate cofactor 132 00:06:24,440 --> 00:06:27,950 will be needed to interconvert the alpha-ketoglutarate and 133 00:06:27,950 --> 00:06:29,810 glutamic acid. 134 00:06:29,810 --> 00:06:33,590 So glutamic acid can serve as a source of alpha-ketoglutarate 135 00:06:33,590 --> 00:06:36,890 if the cell is starved for TCA cycle intermediates. 136 00:06:36,890 --> 00:06:38,960 Alternatively, alpha-ketoglutarate 137 00:06:38,960 --> 00:06:41,570 can be a source for glutamic acid 138 00:06:41,570 --> 00:06:45,560 when a cell may need amino acids for protein biosynthesis. 139 00:06:45,560 --> 00:06:48,280 Now, let's turn to panel B, where 140 00:06:48,280 --> 00:06:52,370 we'll start with succinyl coenzyme A. Looking 141 00:06:52,370 --> 00:06:54,980 at the molecule of succinyl-CoA, note 142 00:06:54,980 --> 00:06:58,280 that I've labeled each of the atoms with a symbol. 143 00:06:58,280 --> 00:07:00,260 The triangle and square were from 144 00:07:00,260 --> 00:07:02,690 the original acetyl-CoA molecule that came 145 00:07:02,690 --> 00:07:05,100 in at the top of the pathway. 146 00:07:05,100 --> 00:07:07,900 The enzyme that processes succinyl-CoA is succinyl 147 00:07:07,900 --> 00:07:09,950 coenzyme A synthetase. 148 00:07:09,950 --> 00:07:13,070 As JoAnne taught us, synthetases are enzymes that 149 00:07:13,070 --> 00:07:15,470 typically need a nucleotide. 150 00:07:15,470 --> 00:07:17,420 In this case, the nucleotide involved 151 00:07:17,420 --> 00:07:22,550 is GDP in mammalian systems or ADP in bacterial systems. 152 00:07:22,550 --> 00:07:26,160 In the traditional clockwise direction of the TCA cycle, 153 00:07:26,160 --> 00:07:32,510 they are phosphorylated to form GTP or ATP, respectively. 154 00:07:32,510 --> 00:07:36,230 The molecule that you get after the phosphorylation reaction 155 00:07:36,230 --> 00:07:38,180 in the hydrolysis of the coenzyme A 156 00:07:38,180 --> 00:07:41,420 is succinate, a 4-carbon compound, which 157 00:07:41,420 --> 00:07:43,790 is also a dicarboxylic acid. 158 00:07:43,790 --> 00:07:46,400 This molecule is perfectly symmetrical 159 00:07:46,400 --> 00:07:49,370 and can tumble in three-dimensional space. 160 00:07:49,370 --> 00:07:52,820 The next enzyme in the pathway, succinate dehydrogenase, 161 00:07:52,820 --> 00:07:56,390 cannot distinguish one arm of its substrate, succinate, 162 00:07:56,390 --> 00:07:57,500 from the other. 163 00:07:57,500 --> 00:08:00,650 So if there were a radio label in the acetyl-CoA 164 00:08:00,650 --> 00:08:03,200 at the beginning of the pathway, that radio label 165 00:08:03,200 --> 00:08:05,390 would become scrambled at this point, 166 00:08:05,390 --> 00:08:09,740 uniformly distributed among the two carbons of the two arms. 167 00:08:09,740 --> 00:08:12,810 From this point onward in the TCA cycle, 168 00:08:12,810 --> 00:08:15,890 you will note that the label denoted as the triangle 169 00:08:15,890 --> 00:08:19,670 and box is scrambled, as indicated by triangle divided 170 00:08:19,670 --> 00:08:22,700 by 2 or box divided by 2. 171 00:08:22,700 --> 00:08:26,450 The next enzyme in the pathway is succinate dehydrogenase. 172 00:08:26,450 --> 00:08:30,680 This is the only membrane-bound enzyme in the TCA cycle. 173 00:08:30,680 --> 00:08:33,169 It is a dehydrogenase, and it uses flavin 174 00:08:33,169 --> 00:08:35,240 as a cofactor to help remove electrons 175 00:08:35,240 --> 00:08:37,390 from the succinate substrate. 176 00:08:37,390 --> 00:08:40,100 Flavin picks up electrons from succinate, 177 00:08:40,100 --> 00:08:44,250 converting FAD to FADH2 in the mitochondrial membrane. 178 00:08:44,250 --> 00:08:47,720 The product of the reaction is the alkene fumarate. 179 00:08:47,720 --> 00:08:52,100 The enzyme fumarase adds water to fumarate to form the alcohol 180 00:08:52,100 --> 00:08:53,670 product malate. 181 00:08:53,670 --> 00:08:56,300 The hydroxyl group of the alcohol malate 182 00:08:56,300 --> 00:08:59,850 is primed for oxidation by the next enzyme in the pathway, 183 00:08:59,850 --> 00:09:02,200 malate dehydrogenase, or MDH. 184 00:09:02,200 --> 00:09:07,510 MDH oxidizes malate, which is an alcohol, to a ketone. 185 00:09:07,510 --> 00:09:10,490 The ketone product is oxaloacetate. 186 00:09:10,490 --> 00:09:14,660 The hydride removed from malate is transferred to NAD+ to form 187 00:09:14,660 --> 00:09:16,010 NADH. 188 00:09:16,010 --> 00:09:18,320 As I mentioned, the product of the overall reaction 189 00:09:18,320 --> 00:09:21,740 is oxaloacetate, and its ketone functionality 190 00:09:21,740 --> 00:09:26,360 is now primed for attack by the next molecule of acetyl-CoA 191 00:09:26,360 --> 00:09:28,730 entering the TCA cycle. 192 00:09:28,730 --> 00:09:31,850 As a final point, I've mentioned several times 193 00:09:31,850 --> 00:09:36,050 that oxaloacetate is present at a very low concentration, only 194 00:09:36,050 --> 00:09:38,960 in the micromolar range, inside the mitochondrion 195 00:09:38,960 --> 00:09:40,880 of a mammalian cell. 196 00:09:40,880 --> 00:09:44,660 So it's always at rather limiting concentration. 197 00:09:44,660 --> 00:09:47,210 The cell has to work very hard to preserve enough 198 00:09:47,210 --> 00:09:51,410 of the oxaloacetate to enable the next cycle of the TCA 199 00:09:51,410 --> 00:09:54,960 cycle, that is the acquisition of the next acetyl coenzyme 200 00:09:54,960 --> 00:09:56,150 A group. 201 00:09:56,150 --> 00:09:59,810 One of the ways that the cell can generate oxaloacetate 202 00:09:59,810 --> 00:10:05,060 is by deamination, or transamination of aspartic acid 203 00:10:05,060 --> 00:10:08,870 to the keto acid oxaloacetate. 204 00:10:08,870 --> 00:10:11,020 We typically have plenty of aspartic acid 205 00:10:11,020 --> 00:10:13,220 and this PLP-mediated reaction helps 206 00:10:13,220 --> 00:10:17,510 to maintain a critical level of oxaloacetate. 207 00:10:17,510 --> 00:10:20,390 I want to return to storyboard 7 to make some comments 208 00:10:20,390 --> 00:10:22,700 about the importance of prochirality 209 00:10:22,700 --> 00:10:25,190 in some enzymatic reactions. 210 00:10:25,190 --> 00:10:27,170 This short interlude will help explain 211 00:10:27,170 --> 00:10:29,730 how to track a radio label in a TCA cycle 212 00:10:29,730 --> 00:10:32,210 intermediate as that intermediate progresses 213 00:10:32,210 --> 00:10:33,830 through the TCA cycle. 214 00:10:33,830 --> 00:10:35,370 As you will note, at first glance, 215 00:10:35,370 --> 00:10:37,980 the label does some unexpected things. 216 00:10:37,980 --> 00:10:39,440 But at the end of the day, the fact 217 00:10:39,440 --> 00:10:41,120 that the label does surprising things 218 00:10:41,120 --> 00:10:44,270 helped early biochemists figure out mechanistically how 219 00:10:44,270 --> 00:10:47,540 several enzymes work in concert during the linear steps 220 00:10:47,540 --> 00:10:49,590 of a pathway. 221 00:10:49,590 --> 00:10:52,830 We're going to look at storyboards 7, 8, and 9, 222 00:10:52,830 --> 00:10:54,300 starting with the chemical reaction 223 00:10:54,300 --> 00:10:56,720 at the bottom right of storyboard 7, 224 00:10:56,720 --> 00:10:59,670 panel D. This is the chemical reaction that's 225 00:10:59,670 --> 00:11:02,202 catalyzed by citrate synthase. 226 00:11:02,202 --> 00:11:03,660 You'll notice that I've highlighted 227 00:11:03,660 --> 00:11:08,220 the two carbons with either a triangle or a box. 228 00:11:08,220 --> 00:11:11,310 As we have seen, the nucleophile on acetyl-CoA 229 00:11:11,310 --> 00:11:13,680 attacks the electropositive carbon 230 00:11:13,680 --> 00:11:18,260 of the carbonyl functionality of oxaloacetate. 231 00:11:18,260 --> 00:11:22,710 The carbonyl functionality is a flat sp2 hybridized center. 232 00:11:22,710 --> 00:11:25,830 So if this were a typical organic chemical reaction, 233 00:11:25,830 --> 00:11:29,070 the electrophile could come in from either the top 234 00:11:29,070 --> 00:11:32,250 or the bottom, and you'd get two different stereochemistries 235 00:11:32,250 --> 00:11:33,360 in the product. 236 00:11:33,360 --> 00:11:36,000 That is the citrate at the very bottom 237 00:11:36,000 --> 00:11:39,330 would have equally labeled acetyl arms at the top 238 00:11:39,330 --> 00:11:41,930 and bottom of the molecule as I've drawn it. 239 00:11:41,930 --> 00:11:45,480 You would have a delta divided by 2 for the blue methylene 240 00:11:45,480 --> 00:11:47,460 group, and a box or square divided 241 00:11:47,460 --> 00:11:50,760 by 2 for the red carboxylate group in each 242 00:11:50,760 --> 00:11:53,010 of the two acetyl arms. 243 00:11:53,010 --> 00:11:56,610 Again, these arms are at the bottom and top of the molecule 244 00:11:56,610 --> 00:11:58,800 as drawn in the lower right of panel 245 00:11:58,800 --> 00:12:03,360 D. You'll note, however, that only the top acetyl group 246 00:12:03,360 --> 00:12:05,520 of citrate has the labels. 247 00:12:05,520 --> 00:12:09,390 Initially, the observation that only the top arm acquired label 248 00:12:09,390 --> 00:12:12,350 was a puzzle to early biochemists. 249 00:12:12,350 --> 00:12:15,090 One way to think about the citrate synthase reaction 250 00:12:15,090 --> 00:12:17,970 is to think about the oxaloacetate laying 251 00:12:17,970 --> 00:12:21,180 on the surface of the citrate synthase enzyme. 252 00:12:21,180 --> 00:12:25,080 Now imagine that the enzyme precludes, or blocks, access 253 00:12:25,080 --> 00:12:29,010 to the carbonyl from the bottom and allows access only 254 00:12:29,010 --> 00:12:31,290 to the top, giving rise to only one 255 00:12:31,290 --> 00:12:34,980 stereochemical outcome, the one that I've shown in the citrate 256 00:12:34,980 --> 00:12:37,030 to the right. 257 00:12:37,030 --> 00:12:39,790 Now move ahead to the storyboard number 258 00:12:39,790 --> 00:12:43,810 9, panel B. This panel shows a more cartoon-like 259 00:12:43,810 --> 00:12:46,390 representation of the molecule of citrate. 260 00:12:46,390 --> 00:12:51,070 You can see the acetyl arm on the top, the pro-S arm, 261 00:12:51,070 --> 00:12:52,600 as having the labels. 262 00:12:52,600 --> 00:12:56,290 And the pro-R arm, the one that came from oxaloacetate, 263 00:12:56,290 --> 00:12:58,840 at the bottom, is label free. 264 00:12:58,840 --> 00:13:04,280 So while the pro-R and pro-S arms are chemically identical, 265 00:13:04,280 --> 00:13:06,430 they're going to be handled by the next enzyme 266 00:13:06,430 --> 00:13:09,250 in the series, aconitase, as being chemically 267 00:13:09,250 --> 00:13:11,260 different from one another. 268 00:13:11,260 --> 00:13:13,540 All biochemistry is going to be occurring 269 00:13:13,540 --> 00:13:16,300 on the pro-R arm, that is the arm that 270 00:13:16,300 --> 00:13:19,690 came in from oxaloacetate and not the arm that 271 00:13:19,690 --> 00:13:23,480 came in for acid 2 with acetyl coenzyme A. 272 00:13:23,480 --> 00:13:25,650 In the bottom right of panel B, I've 273 00:13:25,650 --> 00:13:30,400 sketched out an imaginary active site for the aconitase enzyme. 274 00:13:30,400 --> 00:13:32,670 I show a base picking up a proton 275 00:13:32,670 --> 00:13:35,880 from the pro-R arm of the citrate molecule. 276 00:13:35,880 --> 00:13:38,460 And you can see the elimination of the water molecule 277 00:13:38,460 --> 00:13:40,600 from the 3 carbon. 278 00:13:40,600 --> 00:13:43,930 So despite the fact that the citrate molecule is chemically 279 00:13:43,930 --> 00:13:48,250 symmetrical, aconitase, the next enzyme in the reaction series, 280 00:13:48,250 --> 00:13:54,060 is able to distinguish between the pro-R and the pro-S arms. 281 00:13:54,060 --> 00:13:57,240 At this point, I want you to look back at storyboard 8, 282 00:13:57,240 --> 00:14:00,030 panel A. Look once again at the citrate that 283 00:14:00,030 --> 00:14:03,910 is at the upper left-hand corner of storyboard number 8, 284 00:14:03,910 --> 00:14:07,290 and let's imagine that the aconitase chemistry 285 00:14:07,290 --> 00:14:11,500 has happened on the pro-S arm, that is the one in the box. 286 00:14:11,500 --> 00:14:13,680 Keep in mind that these experiments have shown 287 00:14:13,680 --> 00:14:15,540 that this does not happen. 288 00:14:15,540 --> 00:14:18,940 This is just a hypothetical scenario. 289 00:14:18,940 --> 00:14:21,820 In this hypothetical case, the hydroxyl group 290 00:14:21,820 --> 00:14:24,550 would end up on the number 2 carbon, 291 00:14:24,550 --> 00:14:26,470 the one with the blue triangle. 292 00:14:26,470 --> 00:14:28,450 You have to draw it out, but if you 293 00:14:28,450 --> 00:14:31,720 traced this molecule, in which the chemistry happened 294 00:14:31,720 --> 00:14:36,280 on the pro-S arm, all the way around to alpha-ketoglutarate, 295 00:14:36,280 --> 00:14:38,780 you would find out that the alpha-ketoglutarate 296 00:14:38,780 --> 00:14:42,970 dehydrogenase would liberate CO2 from the carboxylate that 297 00:14:42,970 --> 00:14:44,890 has the red box on it. 298 00:14:44,890 --> 00:14:48,070 This is in contrast to the molecule succinate that appears 299 00:14:48,070 --> 00:14:51,640 on storyboard 8, panel B. Succinate is another 300 00:14:51,640 --> 00:14:54,460 symmetrical molecule, but for some reason, 301 00:14:54,460 --> 00:14:58,380 succinate dehydrogenase cannot distinguish between the two 302 00:14:58,380 --> 00:15:00,160 acetyl arms. 303 00:15:00,160 --> 00:15:03,200 Because the enzyme is unable to distinguish the two arms, 304 00:15:03,200 --> 00:15:05,710 in this case, unlike that of aconitase, 305 00:15:05,710 --> 00:15:08,680 the radio label would become scrambled. 306 00:15:08,680 --> 00:15:10,780 The reason that I'm belaboring this point 307 00:15:10,780 --> 00:15:13,660 is because one of the ways that biochemists work out 308 00:15:13,660 --> 00:15:16,560 the chemical reactions involved in a biochemical pathway 309 00:15:16,560 --> 00:15:19,360 is by putting in some kind of labeled molecule. 310 00:15:19,360 --> 00:15:22,750 It could be a radio label or a heavy isotope. 311 00:15:22,750 --> 00:15:26,590 And then they trace the position of the label in the molecule 312 00:15:26,590 --> 00:15:30,830 as you move from molecule to molecule along the pathway. 313 00:15:30,830 --> 00:15:33,340 So label tracer studies are ones that are absolutely 314 00:15:33,340 --> 00:15:36,340 central to all of biochemistry. 315 00:15:36,340 --> 00:15:38,200 And as I mentioned earlier, you'll 316 00:15:38,200 --> 00:15:40,930 get lots of experience in the problem sets 317 00:15:40,930 --> 00:15:44,290 in using labels to work out the details of a pathway. 318 00:15:44,290 --> 00:15:46,240 Before leaving the TCA cycle, there 319 00:15:46,240 --> 00:15:49,540 are a couple of big picture points that I want to make. 320 00:15:49,540 --> 00:15:52,940 You put in two carbons as acetyl-CoA, 321 00:15:52,940 --> 00:15:56,450 deposit them into oxaloacetate to form citrate, 322 00:15:56,450 --> 00:15:59,260 a 6-carbon compound, and then in the cycle, 323 00:15:59,260 --> 00:16:02,770 you lose 2 carbons as carbon dioxide. 324 00:16:02,770 --> 00:16:05,530 That means that there's no loss or gain 325 00:16:05,530 --> 00:16:07,870 of carbon in this cycle. 326 00:16:07,870 --> 00:16:10,720 If you had just one molecule of oxaloacetate, 327 00:16:10,720 --> 00:16:13,600 you'd be able to complete the TCA cycle. 328 00:16:13,600 --> 00:16:15,940 What happens, however, when the cell 329 00:16:15,940 --> 00:16:20,470 is in an, let's say, "energy needed" situation, where 330 00:16:20,470 --> 00:16:22,750 it needs to buff up this cycle, that 331 00:16:22,750 --> 00:16:25,270 is increase the number of molecules cycling 332 00:16:25,270 --> 00:16:28,660 to be able to accommodate the processing of more and more 333 00:16:28,660 --> 00:16:31,510 molecules of acetyl-CoA? 334 00:16:31,510 --> 00:16:34,450 Those molecules of acetyl-CoA might flood in 335 00:16:34,450 --> 00:16:37,530 from carbohydrate metabolism or, as we'll see later, 336 00:16:37,530 --> 00:16:39,760 from catabolism of lipids. 337 00:16:39,760 --> 00:16:42,850 Let's look at panel A of storyboard 11. 338 00:16:42,850 --> 00:16:45,730 As shown in this figure, one way to accomplish 339 00:16:45,730 --> 00:16:49,330 increasing the carbon content of the TCA cycle 340 00:16:49,330 --> 00:16:51,550 is to take an amino acid, such as glutamate, 341 00:16:51,550 --> 00:16:55,870 and remove its amino group to form alpha-ketoglutarate. 342 00:16:55,870 --> 00:16:59,740 Note that if you increase the concentration of any one 343 00:16:59,740 --> 00:17:03,580 molecule in the TCA cycle, for example, alpha-ketoglutarate, 344 00:17:03,580 --> 00:17:06,160 you're effectively increasing the concentrations 345 00:17:06,160 --> 00:17:08,920 of all molecules in the cycle. 346 00:17:08,920 --> 00:17:11,290 Because it's a cycle, many of the molecules 347 00:17:11,290 --> 00:17:13,450 are in equilibrium with one another. 348 00:17:13,450 --> 00:17:17,230 Going clockwise around the TCA cycle from alpha-ketoglutarate, 349 00:17:17,230 --> 00:17:19,540 we come to succinyl-CoA. 350 00:17:19,540 --> 00:17:23,290 Succinyl-CoA is an entry point into the TCA cycle 351 00:17:23,290 --> 00:17:26,240 from odd-chain fatty acids in certain amino acids, 352 00:17:26,240 --> 00:17:27,640 such as methionine. 353 00:17:27,640 --> 00:17:32,020 So these molecules can give rise to succinyl-CoA 354 00:17:32,020 --> 00:17:34,570 that itself will then increase the concentration 355 00:17:34,570 --> 00:17:37,570 of all molecules in the TCA cycle. 356 00:17:37,570 --> 00:17:41,570 Our third primary input point is at oxaloacetate. 357 00:17:41,570 --> 00:17:46,930 It involves aspartic acid being deaminated into oxaloacetate. 358 00:17:46,930 --> 00:17:49,450 This is a very common way to increase 359 00:17:49,450 --> 00:17:53,110 the amount of oxaloacetate available for the TCA cycle. 360 00:17:53,110 --> 00:17:56,320 This reaction can dramatically increase the rate of processing 361 00:17:56,320 --> 00:17:59,230 of molecules by the TCA cycle. 362 00:17:59,230 --> 00:18:01,600 Finally, there's an enzyme we'll look at later 363 00:18:01,600 --> 00:18:04,960 called pyruvate carboxylase, or PC, 364 00:18:04,960 --> 00:18:08,770 which can take pyruvate in the mitochondrion, add CO2 to it, 365 00:18:08,770 --> 00:18:10,864 and form oxaloacetate. 366 00:18:10,864 --> 00:18:12,280 We're going to come to this enzyme 367 00:18:12,280 --> 00:18:16,370 later when we talk about carboxylase enzymes as a class. 368 00:18:16,370 --> 00:18:21,020 This is an important enzyme in the pathway of gluconeogenesis. 369 00:18:21,020 --> 00:18:23,950 So overall, I think you can see that there are several ways 370 00:18:23,950 --> 00:18:26,500 that a cell can increase the overall concentration 371 00:18:26,500 --> 00:18:29,680 of the intermediates of the TCA cycle. 372 00:18:29,680 --> 00:18:33,700 Increasing any one intermediate increases all of them. 373 00:18:33,700 --> 00:18:35,660 And that will increase the rate by which 374 00:18:35,660 --> 00:18:38,500 acetyl-CoA molecules can be processed ultimately 375 00:18:38,500 --> 00:18:40,300 to generate energy. 376 00:18:40,300 --> 00:18:44,290 The general word describing this buffing up of the TCA cycle 377 00:18:44,290 --> 00:18:48,220 is anapleurosis, which comes from the Greek word "filling 378 00:18:48,220 --> 00:18:49,770 up."