qwertyuiopoiuytrewq V2

Question

This molecule is a product from:

Answer 1

glycolysis

Answer 2

gluconeogenesis

Answer 3

hexose phosphate pathway

Answer 4

anaerobic fermentation

Answer 5

beta-oxidation

Answer 6

soluble cytoplasm (cytosol)

Answer 7

endoplasmic reticulum (ER)

Answer 8

Golgi complex

Answer 9

Mitochondrion (beta oxidation)

Answer 10

glucose 6-phosphate

Answer 11

Fructose 1-phosphate

Answer 12

glucose 1-phosphate

Answer 13

Fructose 6-phosphate

Answer 14

glucose 3-phosphate

Answer 15

pentose phosphate pathway, non-oxidative phase

Answer 16

glycolysis

Answer 17

gluconeogenesis

Answer 18

glycogenolysis

Answer 19

glycogenesis

Answer 20

amino acids

Answer 21

fatty acids

Answer 22

ketone bodies

Answer 23

acetyl CoA

Answer 24

pyruvate kinase(also involved)

Answer 25

glyceraldehyde-3 phosphate dehydrogenase

Answer 26

Hexokinases(also invoved)

Answer 27

phosphoglycerate kinase

Answer 28

phosphofructose kinase 1(PFK1)

Answer 29

glycolysis increases

Answer 30

glycogen synthesis is stimulated

Answer 31

glycogen synthase activity increases(sysnthsis more glycogren)

Answer 32

glycated myoglobin increases (high levelm of glucose level)

Answer 33

glycogen breakdown increases

Answer 34

hepatocytes: glycogen breakdown will be stimulated

Answer 35

adipocytes: fatty acid synthesis will be stimulated

Answer 36

adipocytes: fatty acid release will be stimulated

Answer 37

hepatocytes: gluconeogenesis will be accelerated

Answer 38

skeletal muscle: glycogen breakdown will be stimulated

Answer 39

To increase lactate levels in cells in order to enhance the expression of lactate dehydrogenase.

Answer 40

Lactate can reduce the intracellular pH, which helps the cell survival

Answer 41

This process is directly coupled with substrate level phosphorylation, hence making ATP

Answer 42

To oxidize NADH to NAD+, a required cofactor for glycolysis; so ATP production via glycolysis can continue

Answer 43

Without oxygen, neurons use lactate as a fuel supply

Answer 44

on the mitochondrial inner membrane

Answer 45

in the smooth ER

Answer 46

in the peroxisomes

Answer 47

in the mitochondrial matrix

Answer 48

in the cytosol

Answer 49

skeletal muscle

Answer 50

infant sudden death

Answer 51

infant diabetes

Answer 52

malabsorption of essential fatty acids

Answer 53

stearate diarrhea

Answer 54

vitamin D insufficiency

Answer 55

Pyruvate carboxylase (coveert to oxdiatate)

Answer 56

malonyl CoA

Answer 57

fatty acid synthase (FAS)

Answer 58

acetyl CoA carboxylase

Answer 59

malic enzyme (in the cytochrome, cutralic get cleaved,use4d NADP as a cofator)

Answer 60

vitamin B3

Answer 61

vitamin B5(co A)

Answer 62

vitamin B2

Answer 63

vitamin B1

Answer 64

vitamin B6

Answer 65

vitamin B6

Answer 66

vitamin B5

Answer 67

vitamin B7

Answer 68

Vitamin B1

Answer 69

vitamin B3

Answer 70

vitamin B2

Answer 71

vitamin B3

Answer 72

vitamin B12

Answer 73

vitamin B7

Answer 74

vitamin B1

Answer 75

The acyl-CoA needs translocation into mitochondrial matrix

Answer 76

The first step is ATP-dependent activation of fatty acids to form acyl-CoA, using two ATP equivalent per fatty acid molecule.

Answer 77

The translocation step needs carnitine and translocases, also known as CAT, which is rate-limiting

Answer 78

The beta-oxidation enzymes are generally located in the mitochondrial matrix

Answer 79

unsaturated fatty acids cannot be catabolized by beta-oxidation (CAN be)

Answer 80

glyceraldehyde-P dehydrogenase

Answer 81

glycogen synthase

Answer 82

lysosomal glycosidase

Answer 83

branching enzyme

Answer 84

glycogen phosphorylase

Answer 85

glucocorticoids

Answer 86

malonyl CoA association with fatty acid synthase (FAS)

Answer 87

acetyl CoA carboxylation by ACC to form malonyl CoA

Answer 88

citrate break down by citrate lyase to form acetyl CoA and OAA in the cytosol

Answer 89

dehydrogenation of malate in the cytosol by malic enzyme

Answer 90

the final step, release of palmitate from FAS

Answer 91

myocyte: endoplasmic reticulum

Answer 92

cardiac myocyte: peroxisome

Answer 93

hepatocyte: cytosol

Answer 94

adipocyte: mitochondrion

Answer 95

myocyte: mitochondrion(of myocyte and cytosol then this answer could be right)

Answer 96

phosphoglycerate mutase

Answer 97

pyruvate kinase

Answer 98

hexose kinase

Answer 99

phosphofructose kinase 1

Answer 100

phosphofructose kinase 2

Answer 101

Exercise may activate its activity in myocytes (muscle cells)

Answer 102

It synergizes with insulin, and represses the expression of PEPCK in hepatocyte

Answer 103

It is an intracellular energy sensor regulating the energy metabolism at the cellular level

Answer 104

It is a molecule binds and synergizes with insulin to promote glycolysis in multiple tissues (binds is wrongs)

Answer 105

It is a protein kinase activated by increased level of AMP in cells

Answer 106

Decrease of intracellular NADPH levels

Answer 107

Decrease of mitochondrial NADPH levels

Answer 108

Increase of ribose-phosphate levels

Answer 109

Increase of intracellular NADPH levels

Answer 110

Decrease of ribose phosphate levels

Answer 111

high level of GSH, high level of GSSG

Answer 112

irrelevant to the levels of GSH and GSSG

Answer 113

high level of GSH, low level of GSSG

Answer 114

low level of GSH, high level of GSSG

Answer 115

low level of GSH, low level of GSSG

Answer 116

chylomicron carries a protein called Apo protein B100 on its surface

Answer 117

chylomicrons will be transported to the circulation via lymph duct

Answer 118

malabsorption causes lack of essential fatty acids and lipid soluble vitamins

Answer 119

digestion needs lipases secreted by pancreas and bile juice from gallbladder

Answer 120

absorbed lipids will be incorporated into chylomicrons, which is released by intestinal mucosa

Answer 121

block glycolysis

Answer 122

decrease fatty acid synthesis

Answer 123

inhibit TCA cycle

Answer 124

stimulate acetyl CoA carboxylase activity

Answer 125

Increase fatty acid synthesis

Answer 126

Glut1 and Glut3

Answer 127

Glut1, Glut 2 and Glut3

Answer 128

An intermediate product of catabolism of fructose to generate ATP

Answer 129

An intermediate metabolite in fatty acid synthesis

Answer 130

An intermediate product of glycolysis which promote the release of O2

Answer 131

A waste byproduct of the glycolytic pathway

Answer 132

A regulatory molecule that allosterically stimulates PFK1 activity and the glycolytic pathway

Answer 133

8 mole ATP

Answer 134

38 mole ATP

Answer 135

42 mole ATP

Answer 136

30 mole ATP

Answer 137

12 mole ATP

Answer 138

The Pasteur Effect

Answer 139

The Embden–Meyerhof–Parnas (EMP Pathway)

Answer 140

The Warburg Effect

Answer 141

The Krebs Effect

Answer 142

The Entner–Doudoroff Pathway (ED Pathway)

Answer 143

Condensation-reduction-hydration-reduction

Answer 144

Condensation-dehydrogenation-reduction, reduction

Answer 145

Condensation-reduction-dehydration-reduction

Answer 146

Condensation-reduction-dehydrogenation-reduction

Answer 147

Dehydrogenation, condensation, dehydration, reduction

Answer 148

one NADH, one NADPH and one ribose phosphate

Answer 149

two NADH and one pentose phosphate

Answer 150

one NADPH and one pentose phosphate

Answer 151

two NADPH and two pentose phosphate

Answer 152

two NADPH and one pentose phosphate

Answer 153

Increased level of malonyl CoA, which represses CAT activity, thus slowing down the translocation of acyl-CoA to mitochondria

Answer 154

Increased glucagon level, thus promoting the utilization of glucose, repressing utilization of fatty acids

Answer 155

Increase of Ca++ in mitochondrial matrix, which speed up TCA cycle and increased ATP inhibits beta-oxidation

Answer 156

Lack of ATP, fatty acids cannot be activated

Answer 157

Lipogenesis depletes ATP, which activates AMPK and inhibits energy consumption, so cell does not need a fast beta oxidation

Answer 158

inhibiting glycogen breakdown

Answer 159

enhancing glycogen synthase activity

Answer 160

inhibiting glycolysis

Answer 161

stimulating glycogen synthesis

Answer 162

inhibiting glucogenolysis

Answer 163

dehydrogenation-dehydrogenation-hydration-cleavage

Answer 164

dehydrogenation-hydration-dehydrogenation-cleavage

Answer 165

dehydrogenation-hydration-dehydration -cleavage

Answer 166

dehydrogenation-dehydration-dehydrogenation-cleavage

Answer 167

hydration-dehydrogenation-dehydrogenation-cleavage

Answer 168

beta-oxidation, resulting in cleavage by thiolase to form acetyl CoA in mitochondrion

Answer 169

ATP-dependent activation of free fatty acid to form acyl-CoA in the cytosol

Answer 170

insulin signaling activates hormone sensitive lipase on white adipose tissue (adipocytes), which releases fatty acids

Answer 171

transport free fatty acids by the circulatory system to cells which need fatty acids as fuel

Answer 172

translocation of acyl-CoA into mitochondria, a carnitine-dependent process

Answer 173

OAA from aspartate catabolism

Answer 174

riboses from pentose pathway

Answer 175

acetyl CoA from beta oxidation

Answer 176

glycerol-3 phosphate released from breakdown of phospholipids

Answer 177

alpha-ketoglutarate from glutamate and glutamine catabolism

Answer 178

its target organs/tissues include liver, muscle and adipose

Answer 179

its release is triggered by increased ATP levels in β cells

Answer 180

it promotes glycogen phosphorolysis and glycolysis to generate large amount of ATP in muscle (not promote glycogen phosphorolysis)

Answer 181

it may regulate the expression of metabolic enzymes.

Answer 182

it is produced by pancreatic β cells

Answer 183

converting phosphorylated glucose to glucose

Answer 184

converting glycogen phosphorylase a to phosphorylase b

Answer 185

converting glycogen synthase a to glycogen synthase b

Answer 186

increasing internalized Glut4

Answer 187

converting glycogen phosphorylase b to phosphorylase a

Answer 188

hexokinase-catalyzed formation of G6P

Answer 189

pyruvate kinase-catalyzed formation of pyruvate

Answer 190

PFK1-catalyzed formation of F1,6BP

Answer 191

Phosphoenolpyruvate to pyruvate, accompanied by substrate level phosphorylation

Answer 192

F1,6BP broken by aldolase

Answer 193

are produced by hepatocytes

Answer 194

can be used by all tissues, such as neurons and hepatocytes

Answer 195

is an alternative fuel, particularly important for brain

Answer 196

are produced from acetyl CoA

Answer 197

overproduction of ketone bodies may occur in diabetic patients, even with hyperglycemia

Answer 198

The production of pentose phosphate for biosynthesis of some cofactors

Answer 199

the production of NADPH to help prevent oxidative stress in erythrocytes

Answer 200

The transfer of electrons to the electron transport chain for ATP production

Answer 201

the production of pentoses necessary for nucleotide synthesis

Answer 202

the production of NADPH for reductive biosynthesis in adipose cells

Answer 203

gluconeogenesis in muscle and glycogenolysis in liver

Answer 204

glycolysis in muscle and gluconeogenesis in liver

Answer 205

glycolysis in muscle and the pentose phosphate pathway in liver

Answer 206

pentose phosphate pathway in muscle and gluconeogenesis in liver

Answer 207

beta-oxidation in muscle and ketogenesis in liver

Answer 208

hepatocytes and skeletal myocytes

Answer 209

erythrocytes and neurons

Answer 210

erythrocytes and adipocytes

Answer 211

skeletal myocytes and adipocytes

Answer 212

neurons and the hepatocytes

Answer 213

They know our students like beer.

Answer 214

They are required to complete the oxidation of glucose and maximizing ATP production

Answer 215

They are required to re-oxidize limited amounts of NADH to NAD+ and decrease pyruvate level, thus sustaining continuous glycolysis to ensure ATP production

Answer 216

They are required to remove pyruvate, ensuring ATP production.

Answer 217

They are required to oxidize NADH to generate ATP

Answer 218

succinyl-CoA

Answer 219

They are part of the cell components, and cannot be oxidized for energy in this tissue.

Answer 220

They are primarily bound to albumin and stored in lipid droplets.

Answer 221

There is a constant movement of fatty acids in and out of adipose tissues, which is independent of hormone signals.

Answer 222

Upon glucagon signaling, fatty acids are converted into ketone bodies in adipocytes

Answer 223

In adipocytes, fatty acids up-taken from the bloodstream are assembled into triglycerides by directly esterifying to glycerol.

Answer 224

The cytosolic and mitochondrial matrix pools of coenzyme A are separated by biomembranes

Answer 225

It is not a rate-limiting step in the oxidation of these fatty acids.

Answer 226

Once these fatty acyl molecules are in the matrix, carnitine can be transported out of mitochondria.

Answer 227

It is inhibited by the increase of malonyl-CoA levels

Answer 228

Patients with a carnitine deficiency are likely to have impaired betaoxidation of fatty acids

Answer 229

decarboxylation initiated deaminination

Answer 230

hydrolysis to remove α-amino group

Answer 231

transamination to remove α-amino group

Answer 232

dehydration initiated deamination

Answer 233

oxidative deamination

Answer 234

30 mole ATP

Answer 235

32 mole ATP

Answer 236

42 mole ATP

Answer 237

48 mole ATP

Answer 238

38 mole ATP

Answer 239

dehydrogenation to generate FADH2, Reduction, dehydrogenation to generate NADH, cleavage to for to acetyl CoA and a new acyl CoA.

Answer 240

dehydrogenation to generate FADH2, Hydration, dehydrogenation to generate NADH, cleavage to for to acetyl CoA and a new acyl CoA.

Answer 241

dehydrogenation to generate NADH, Hydration, dehydrogenation to generate FADH2, cleavage to for to acetyl CoA and a new acyl CoA.

Answer 242

dehydrogenation to generate FADH2, dehydration, dehydrogenation to generate NADH, cleavage to for to acetyl CoA and a new acyl CoA.

Answer 243

transportation into mitochondria

Answer 244

biosynthesis of fatty acyl CoA in the mitochondria

Answer 245

Activation by ATP

Answer 246

biosynthesis of fatty acyl-CoA in the cytosol

Answer 247

Fatty acyl CoA dehydrogenation

Answer 248

Propionyl-CoA is a rare metabolite, which cannot be further catabolized by human cells, thus being disposed by urine

Answer 249

further converting methylmalonyl-Coa to succinyl-CoA depends on vitamin B12

Answer 250

Propionyl-CoA may arise from diet, or catabolism of fatty acids and some amino acids.

Answer 251

Propionyl-CoA (3C) can be converted to Methylmainyl-CoA (4C) after a carboxylation reaction facilitated by vitamin B7

Answer 252

The structure of vitamin B12 is very complicate and contains cobalt.

Answer 253

ATP and NADH

Answer 254

phosphoenolpyruvate

Answer 255

High fuel efficiency

Answer 256

oxygen-independent

Answer 257

electron-transport chain independent

Answer 258

mitochondrion-independent

Answer 259

Rapid production of ATP

Answer 260

After absorption to mucosa cells, free fatty acids are used to re-synthesize TAG, which is then packed into chylomicron.

Answer 261

chylomicron is transported to liver via portal vein, an via hepatic vein to reach circulation

Answer 262

Fat digested to free fatty acids, which are absorbed into mucosa cells and released into blood circulation directly.

Answer 263

chylomicron is purely compose of lipids, without protein components.

Answer 264

E1: pyruvate dehydrogenase; E1: pyruvate transacetylase; E3: dihydrolipoyl dehydrogenase

Answer 265

E1: pyruvate decarboxylase; E2: dihydrolipoyl transacetylase; E3: dihydrolipoyl dehydrogenase

Answer 266

E1: pyruvate dehydrogenase; E2: dihydrolipoyl transacetylase; E3: dihydrolipoyl dehydrogenase

Answer 267

E1: pyruvate dehydrogenase; E2: dihydrolipoyl dehydrogenase; E3: dihydrolipoyl transacetylase

Answer 268

E1: dihydrolipoyl dehydrogenase; E2: dihydrolipoyl transacetylase; E3: pyruvate dehydrogenase

Answer 269

The Embden–Meyerhof–Parnas (EMP Pathway)

Answer 270

The Warburg Effect

Answer 271

The Pasteur Effect

Answer 272

The Krebs Effect

Answer 273

The Entner-Doudoroff Pathway (ED Pathway)

Answer 274

Synthesized into fatty acyl CoA, transported into, Activation by ATP, beta-oxidation to generate Acetyl coA

Answer 275

Activation by ATP in cytosol, converting to Fatty acyl CoA, transported into mitochondrion, beta-oxidation to generate Acetyl coA

Answer 276

Activation by ATP in cytosol, converting to Fatty acyl CoA, beta-oxidation to generate Acetyl coA, transporting acetyl coA into mitochondrion

Answer 277

Activation by ATP in cytosol, transported into mitochondrion, converting to Fatty acyl CoA, beta-oxidation to generate Acetyl coA

Answer 278

Transported into mitochondrion, activation by ATP, converting to fatty acyl CoA, beta-oxidation to generate Acetyl coA

Answer 279

dehydration initiated deamination

Answer 280

transamination to remove a-amino group

Answer 281

hydrolysis to remove a-amino group

Answer 282

decarboxylation initiated deaminination

Answer 283

oxidative deamination

Answer 284

In human cells, anaerobic glycolysis generates alcohol, which later on degraded by alcohol dehydrogenase to acetaldehyde upon reoxygenation.

Answer 285

Anaerobic glycolysis in human cells generates lactate, not alcohol

Answer 286

Anaerobic glycolysis to produce ATP is developed earlier than oxidative phosphorylation method evolutionarily.

Answer 287

in some bacteria, anaerobic glycolysis generates lactate to recover NAD+ (oxidized)

Answer 288

In yeast, anaerobic glycolysis generates alcohol to regenerated NAD+ (oxidized)

Answer 289

phosphofructokinase-1 (PFK1), which converts F6P to F1,6BP.

Answer 290

phosphoglycerate kinase, which catalyzes the first production of ATP

Answer 291

Glyceraldehyde-3-phospate dehydrogenase, which catalyzes the generation of NADH

Answer 292

Aldolase A, which breaks the 6C hexose-phosphate to 3C triose phosphate

Answer 293

pyruvate kinase, which chatalyzes the 2nd production of ATP

Answer 294

phosphofructose kinase 1

Answer 295

PEP carboxykinase

Answer 296

pyruvate kinase

Answer 297

pyruvate carboxylase

Answer 298

F1,6 bisphosphatase

Answer 299

Golgi complex

Answer 300

endoplasmic reticulum (ER)

Answer 301

mitochondrion

Answer 302

soluble cytoplasm (cytosol)

Answer 303

condensation of malony-CoA with growing fatty acyl chain

Answer 304

beta oxidation to generate acetyl CoA as substrates

Answer 305

transfer citrate out of mitochondria

Answer 306

recognizing and binding malonyl CoA by Acyl carrier protein (ACP)

Answer 307

carboxylation of acetyl CoA to form malonyl CoA

Answer 308

lysosomal glycosidase

Answer 309

branching enzyme

Answer 310

glycogen synthase

Answer 311

glycogen phosphorylase

Answer 312

glycerol 3-P dehydrogenase

Answer 313

infant sudden death

Answer 314

vitamin D insufficiency

Answer 315

malabsorption of essential fatty acids

Answer 316

stearate diarrhea

Answer 317

infant diabetes

Answer 318

myocyte: mitochondrion

Answer 319

cardiac myocyte: peroxisome

Answer 320

hepatocyte: mitochondrion

Answer 321

hepatocyte: cytosol

Answer 322

myocyte: endoplasmic reticulum

Answer 323

Condensation-reduction-dehydrogenation-reduction

Answer 324

Dehydrogenation, condensation, dehydration, reduction

Answer 325

Condensation-dehydrogenation-reduction, reduction

Answer 326

Condensation-reduction-dehydration-reduction

Answer 327

Condensation-reduction-hydration-reduction

Answer 328

pentose phosphate

Answer 329

erythrose 4-phosphate

Answer 330

NADPH and pentose phosphate

Answer 331

NADPH, pentose phophate and erythrose 4-phosphate

Answer 332

phosphoglucomutase

Answer 333

Glycogen synthetase

Answer 334

Glycogen synthase

Answer 335

UDP-Sugar Pyrophosphorylase

Answer 336

glycogen branching enzyme

Answer 337

released to circulation directly and carried by plasma proteins

Answer 338

carried by a lipoprotein called VLDL through the circulation

Answer 339

carried by a lipoprotein called LDL through the circulation

Answer 340

carried by either VLDL or chylomicron through the circulation

Answer 341

carried by a lipoprotien called chylomicron through the circulation

Answer 342

pentose pathway

Answer 343

glycolytic pathway

Answer 344

krebs cycle

Answer 345

gluconeogenesis

Answer 346

fatty acid beta oxidation

Answer 347

mitochondria

Answer 348

rough endoplasmic reticulum

Answer 349

smooth endoplasmic reticulum

Answer 350

cell surface

Answer 351

A. hexokinase catalyzed Glucose to G6P

Answer 352

B. phosphofructokinase (PFK) catalyzed F6P to F1, 6BP

Answer 353

C. Pyruvate kinase catalyzed PEP to enol pyruvate

Answer 354

A, B, and C

Answer 355

carbon skeletons from catabolism of most amino acids

Answer 356

fatty acids from TAG break down

Answer 357

propionyl-CoA from catabolism of odd-numbered fatty acids

Answer 358

glycerol from TAG breakdown

Answer 359

acetyl CoA from fatty acid beta-oxidation

	Creado por Joseph Jung hace más de 2 años

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qwertyuiopoiuytrewq V2

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