Bio Exam 2 Part 2

Question

Organisms maintain dynamic homeostasis through behavioral and physiological mechanisms. Which of the following statements is an accurate explanation of a negative feedback mechanism used by animals to regulate body temperature?

Answer 1

A) Squirrels are able to cool themselves during warmer months by producing more brown fat, which contains abundant mitochondria and a rich blood supply.

Answer 2

B) Desert jackrabbits have unusually large ears that serve as solar heat collectors to enable them to maintain their body temperatures.

Answer 3

C) A ground squirrel's hypothalamus detects changes in environmental temperatures and responds by activating or suppressing metabolic heat production.

Answer 4

D) A goldfish slows its movements when the water temperature is lower.

Answer 5

A) epithelial tissue.

Answer 6

B) connective tissue.

Answer 7

C) muscle tissue.

Answer 8

D) nervous tissue.

Answer 9

A) feathers or fur

Answer 10

B) vasoconstriction

Answer 11

C) wind blowing across the body surface

Answer 12

D) countercurrent heat exchanger

Answer 13

A) elephant; mouse

Answer 14

B) elephant; human

Answer 15

C) mouse; snake

Answer 16

D) penguin; mouse

Answer 17

A) less surface area.

Answer 18

B) less surface area per unit of volume.

Answer 19

C) the same surface-area-to-volume ratio.

Answer 20

D) a smaller cytoplasm-to-nucleus ratio.

Answer 21

A) if the animal is an endotherm, which must always take in more energy because of its high metabolic rate.

Answer 22

B) if it is actively foraging for food.

Answer 23

C) if it is growing and increasing its mass.

Answer 24

D) never; due to homeostasis, these energy and material budgets always balance.

Answer 25

A) You know from its high and stable body temperature that it must be an endotherm.

Answer 26

B) You subject this reptile to various temperatures in the lab and find that its body temperature and metabolic rate change with the ambient temperature. You conclude that it is an ectotherm.

Answer 27

C) You note that its environment has a high and stable temperature. Because its body temperature matches the environmental temperature, you conclude that it is an ectotherm.

Answer 28

D) You measure the metabolic rate of the reptile, and because it is higher than that of a related species that lives in temperate forests, you conclude that this reptile is an endotherm and its relative is an ectotherm.

Answer 29

A) marine jelly (an invertebrate)

Answer 30

B) snake in a temperate forest

Answer 31

C) desert insect

Answer 32

D) desert bird

Answer 33

A) nonvascular plants that grew leafless, photosynthetic shoots

Answer 34

B) species that did not exhibit alternation of generations

Answer 35

C) vascular plants with well-defined root systems

Answer 36

D) plants with well-developed leaves

Answer 37

A) a large, still pond

Answer 38

B) a tropical rain forest

Answer 39

C) an oasis within a grassland

Answer 40

D) the floor of a deciduous forest

Answer 41

A) from leaves to shoots only

Answer 42

B) from shoots to leaves only

Answer 43

C) from sites of sugar production to storage units only

Answer 44

D) both ways between production and storage sites

Answer 45

A) to allow maximum exposure to light

Answer 46

B) to promote a leaf area index above 8

Answer 47

C) to reduce shading of lower leaves

Answer 48

D) to allow maximum exposure to light and to reduce shading of lower leaves

Answer 49

A) Mineral receptor proteins in the plant membrane were not functioning.

Answer 50

B) Mycorrhizal fungi were killed.

Answer 51

C) Active transport of minerals was inhibited.

Answer 52

D) The genes for the synthesis of transport proteins were destroyed.

Answer 53

A) stem—water and minerals are transported upward

Answer 54

B) xylem sap—transport water and nutrients from roots to shoots upward

Answer 55

C) transpiration—loss of water mostly through stomata

Answer 56

D) cork cambium—increase in stem thickness

Answer 57

A) upper leaf surface of a single plant divided by the surface area of the land on which the plant grows

Answer 58

B) lower leaf surface of a single plant divided by the surface area of the land on which the plant grows

Answer 59

C) upper leaf surface of a single plant multiplied by the surface area of the land on which the plant grows

Answer 60

D) lower leaf surface of a single plant multiplied by the surface area of the land on which the plant grows

Answer 61

A) ground tissue

Answer 62

B) bacterial association

Answer 63

C) mycorrhizae

Answer 64

D) cuticle on leaf surface

Answer 65

A) the lumen of a xylem vessel

Answer 66

B) the lumen of a sieve tube

Answer 67

C) the cell wall of a mesophyll cell

Answer 68

D) the cell wall of a root hair

Answer 69

A) cell walls, extracellular spaces, and plasmodesmata

Answer 70

B) cell walls, extracellular spaces, and vessel elements

Answer 71

C) vessel elements, plasmodesmata, and extracellular spaces

Answer 72

D) cell walls, plasma membrane, and cytosol

Answer 73

A) NADP and channel proteins

Answer 74

B) xylem membranes and channel proteins

Answer 75

C) sodium/potassium pumps and xylem membranes

Answer 76

D) ATP, transport proteins, and a proton gradient

Answer 77

A) potassium pump

Answer 78

B) water potential

Answer 79

C) osmotic potential

Answer 80

D) sodium pump

Answer 81

A) to transfer phosphorus groups from ATP to proteins

Answer 82

B) to transfer metal ions across the plasma membrane

Answer 83

C) to transfer anions across the plasma membrane

Answer 84

D) to create a membrane potential

Answer 85

A) a difference in solute concentrations

Answer 86

B) receptor proteins in the membrane

Answer 87

C) aquaporins

Answer 88

D) a difference in water potential

Answer 89

A) prevailing weather conditions

Answer 90

B) aquaporins

Answer 91

C) level of active transport

Answer 92

D) water potentials

Answer 93

A) The pressure potential of the cells would increase.

Answer 94

B) Water would move out of the cells.

Answer 95

C) The cell walls would rupture, killing the cells.

Answer 96

D) Solutes would move out of the cells.

Answer 97

A) water potential

Answer 98

B) osmotic potential

Answer 99

C) potential gradient

Answer 100

D) pressure potential

Answer 101

A) be from the tissue into the sucrose solution

Answer 102

B) be from the sucrose solution into the tissue

Answer 103

C) be in both directions, and the concentration of water would remain equal

Answer 104

D) be impossible to determine from the values given here

Answer 105

A) water and solutes move out of one cell, across the cell wall, and into the neighboring cell

Answer 106

B) water and solutes move out of one cell, through the plasmodesmata, and into the neighboring cell

Answer 107

C) water moves out of one cell, across the cell wall, and into the neighboring cell

Answer 108

D) solutes move out of one cell, across the plasmodesmata, and into the neighboring cell

Answer 109

A) they have large central vacuoles, which provide abundant space for storage of incoming water

Answer 110

B) they have cell walls, which prevent the entry of water by osmosis

Answer 111

C) they have cell walls, which provide pressure to counteract the pressure of the incoming water

Answer 112

D) certain gated channel proteins embedded in their plasma membranes open as osmotic pressure decreases, allowing excess water to leave the cell

Answer 113

A) A flaccid cell has higher pressure potential.

Answer 114

B) A flaccid cell has lower pressure potential.

Answer 115

C) A flaccid cell has higher solute potential.

Answer 116

D) A flaccid cell has lower solute potential.

Answer 117

A) all cell components without a nucleus

Answer 118

B) all cell components without a cell membrane

Answer 119

C) only the cytoplasm and nucleus

Answer 120

D) the living part of the cell, including the cell membrane

Answer 121

A) have a faster rate of osmosis

Answer 122

B) have a lower water potential

Answer 123

C) have a higher water potential

Answer 124

D) have a faster rate of active transport

Answer 125

A) does not enter the cell; solutes and low water potential

Answer 126

B) enter the cell; solutes and low water potential

Answer 127

C) enter the cell; solutes and high water potential

Answer 128

D) does not enter the cell; solutes and high water potential

Answer 129

A) +0.75 MPa

Answer 130

B) -0.75 MPa

Answer 131

C) -0.15 MPa

Answer 132

D) +0.15 MPa

Answer 133

A) II, III, IV, and V

Answer 134

B) I, III, IV, and V

Answer 135

C) I, II, IV, and V

Answer 136

D) I, II, III, and V

Answer 137

A) be from the tissue into the sucrose solution

Answer 138

B) be from the sucrose solution into the tissue

Answer 139

C) be in both directions and the concentrations would remain equal

Answer 140

D) occur only as ATP was hydrolyzed in the tissue

Answer 141

A) dehydration

Answer 142

B) respiration

Answer 143

C) gas exchange

Answer 144

D) transpiration

Answer 145

A) II and III

Answer 146

B) I, III, and IV

Answer 147

C) I, II, and IV

Answer 148

D) I, II, III, and IV

Answer 149

A) positive

Answer 150

B) negative

Answer 151

C) neutral

Answer 152

A) a guard cell

Answer 153

B) the root epidermis

Answer 154

C) the endodermis

Answer 155

D) the root cortex

Answer 156

A) 10-20 m/hr

Answer 157

B) 15-45 m/hr

Answer 158

C) 5-10 m/hr

Answer 159

D) >50 m/hr

Answer 160

A) aids in the uptake of nutrients

Answer 161

B) provides energy for the active transport of minerals into the stele from the cortex

Answer 162

C) ensures that all minerals are absorbed from the soil in equal amounts

Answer 163

D) ensures that all water and dissolved substances must pass through a cell membrane before entering the stele

Answer 164

A) Not all soils have high concentrations of ions.

Answer 165

B) Root pressure requires movement of water into the xylem from surrounding cells in the roots.

Answer 166

C) Over long distances, the force of root pressure is not enough to overcome the force of gravity.

Answer 167

D) There is no water potential gradient between roots and shoots.

Answer 168

A) transpiration rates are high

Answer 169

B) root pressure exceeds transpiration pull

Answer 170

C) preceding evening was hot, windy, and dry

Answer 171

D) roots are not absorbing minerals from the soil

Answer 172

A) used as a solvent

Answer 173

B) used as a hydrogen source in photosynthesis

Answer 174

C) lost during transpiration

Answer 175

D) used to keep cells turgid

Answer 176

A) I, III, IV, and V

Answer 177

B) I, II, IV, and V

Answer 178

C) I, II, III, and V

Answer 179

D) I, II, III, and IV

Answer 180

A) lowers due to accumulation of minerals

Answer 181

B) increases due to accumulation of minerals

Answer 182

C) lowers due to loss of minerals

Answer 183

D) increases due to loss of minerals

Answer 184

A) active transport of ions into the stele

Answer 185

B) evaporation of water through stoma

Answer 186

C) the force of root pressure

Answer 187

D) osmosis in the root

Answer 188

A) mesophyll cells of the leaf

Answer 189

B) xylem vessels in leaves

Answer 190

C) xylem vessels in roots

Answer 191

D) cells of the root cortex

Answer 192

A) the upward pull of gravity on the water column in the tube

Answer 193

B) downward pressure from the atmosphere on the topmost layer of water molecules

Answer 194

C) the water molecules being pulled upward by adhesion to the air

Answer 195

D) the topmost layer of water molecules being pulled downward by the hydrogen bonds to the water molecules below

Answer 196

A) carbon dioxide

Answer 197

B) nitrogen

Answer 198

C) potassium

Answer 199

A) an increase in the solute concentration of the guard cells

Answer 200

B) active transport of water out of the guard cells

Answer 201

C) decreased turgor pressure in guard cells

Answer 202

D) movement of K+ from the guard cells

Answer 203

A) more light absorption

Answer 204

B) less light absorption

Answer 205

C) CO2 absorption

Answer 206

D) transpiration

Answer 207

A) a cool, dry day

Answer 208

B) a very hot, dry, windy day

Answer 209

C) a warm, humid day

Answer 210

D) a cool, humid day

Answer 211

A) the chlorophyll in wilting leaves is degraded

Answer 212

B) flaccid mesophyll cells are incapable of photosynthesis

Answer 213

C) stomata close, preventing carbon dioxide from entering the leaf

Answer 214

D) accumulation of carbon dioxide in the leaf inhibits enzymes

Answer 215

A) increased turgor and increased growth

Answer 216

B) mineral transport and increased growth

Answer 217

C) evaporative cooling and increased turgor

Answer 218

D) evaporative cooling and mineral transport

Answer 219

A) subjecting the leaves of the plant to a partial vacuum

Answer 220

B) increasing the level of carbon dioxide around the plant

Answer 221

C) putting the plant in drier soil

Answer 222

D) decreasing the relative humidity around the plant

Answer 223

A) Size of stomatal openings would decrease.

Answer 224

B) Transpiration would increase.

Answer 225

C) The leaves would become more turgid.

Answer 226

D) The uptake of carbon dioxide would be enhanced.

Answer 227

A) increased transpiration rate

Answer 228

B) decreased transpiration rate

Answer 229

C) increased efficiency of light capture

Answer 230

D) decreased efficiency of light capture

Answer 231

A) indole-3-acetic acid

Answer 232

B) gibberellin

Answer 233

C) abscisic acid (ABA)

Answer 234

D) ethylene

Answer 235

A) mesophytes

Answer 236

B) xerophytes

Answer 237

C) psilophytes

Answer 238

D) halophytes

Answer 239

A) stomata recessed in cavities

Answer 240

B) guard cells

Answer 241

C) hairs (trichomes)

Answer 242

D) lower epidermal cells

Answer 243

A) new leaves in early spring

Answer 244

B) fruits in summer

Answer 245

C) roots in early spring

Answer 246

D) roots in early autumn

Answer 247

A) 1, 2, 3, 4, 5

Answer 248

B) 2, 4, 3, 1, 5

Answer 249

C) 4, 2, 1, 3, 5

Answer 250

D) 2, 4, 1, 3, 5

Answer 251

A) sucrose has been actively transported into the sieve tube, making it hypertonic

Answer 252

B) water pressure outside the sieve tube forces in water

Answer 253

C) the companion cell of a sieve tube actively pumps in water

Answer 254

D) sucrose has been transported out of the sieve tube by active transport

Answer 255

A) Sucrose occurs in higher concentrations in companion cells than in the mesophyll cells where it is produced.

Answer 256

B) Movement of water occurs from xylem to phloem and back again.

Answer 257

C) Strong pH differences exist between the cytoplasm of the companion cell and the mesophyll cell.

Answer 258

D) ATPases are abundant in the plasma membranes of the mesophyll cells.

Answer 259

A) Solute particles are actively transported from phloem at the source.

Answer 260

B) Companion cells control the rate and direction of movement of phloem sap.

Answer 261

C) Differences in osmotic concentration at the source and sink cause a hydrostatic pressure gradient to be formed.

Answer 262

D) A sink is the part of a plant where a particular solute is produced.

Answer 263

A) plasmodesmata

Answer 264

B) facilitated diffusion

Answer 265

C) sucrose-H+ symporters

Answer 266

D) sucrose-H+ antiporters

Answer 267

A) Diffusion can account for the observed rates of transport.

Answer 268

B) Movement can occur both upward and downward in the plant.

Answer 269

C) Sugar is translocated from sinks to sources.

Answer 270

D) Only phloem cells with nuclei can perform sugar movement.

Answer 271

A) only the xylem

Answer 272

B) only the phloem

Answer 273

C) only the endodermis

Answer 274

D) both the xylem and the phloem

Answer 275

A) cell wall

Answer 276

B) cell membrane

Answer 277

C) vacuole

Answer 278

D) plasmodesmata

Answer 279

A) macromolecules

Answer 280

B) ribosomes

Answer 281

C) chloroplasts

Answer 282

D) mitochondria

Answer 283

A) sugars, mRNA, and mitochondria

Answer 284

B) mRNA, mitochondria, and proteins

Answer 285

C) mitochondria, mRNA, and viruses

Answer 286

D) viruses, sugars, and mRNA

Answer 287

A) mycorrhizae

Answer 288

B) pumping through plasmodesmata

Answer 289

C) active uptake by vessel elements

Answer 290

D) rhythmic contractions by cells in the root cortex

Answer 291

A) the interior of a vessel element

Answer 292

B) the interior of a sieve tube

Answer 293

C) the cell wall of a mesophyll cell

Answer 294

D) an extracellular air space

Answer 295

A) occurs through the apoplast of sieve-tube elements.

Answer 296

B) depends ultimately on the activity of proton pumps.

Answer 297

C) depends on tension, or negative pressure potential.

Answer 298

D) results mainly from diffusion.

Answer 299

A) the chlorophyll in wilting leaves is degraded.

Answer 300

B) accumulation of CO2 in the leaf inhibits enzymes.

Answer 301

C) stomata close, preventing CO2 from entering the leaf.

Answer 302

D) photolysis, the water-splitting step of photosynthesis, cannot occur when there is a water deficiency.

Answer 303

A) decreasing the Ψ of the surrounding solution

Answer 304

B) positive pressure on the surrounding solution

Answer 305

C) the loss of solutes from the cell

Answer 306

D) increasing the Ψ of the cytoplasm

Answer 307

A) ΨP of +0.65 MPa.

Answer 308

B) Ψ of -0.65 MPa.

Answer 309

C) ΨP of +0.35 MPa.

Answer 310

D) ΨP of 0 MPa.

Answer 311

A) have a faster rate of osmosis.

Answer 312

B) have a lower water potential.

Answer 313

C) have a higher water potential.

Answer 314

D) accumulate water by active transport.

Answer 315

A) spiny leaves

Answer 316

B) sunken stomata

Answer 317

C) a thicker cuticle

Answer 318

D) higher stomatal density

Answer 319

A) those of birds, with a four-chambered heart

Answer 320

B) the portal systems of mammals, where two capillary beds occur sequentially, without passage of blood through a pumping chamber

Answer 321

C) those of sponges, where gas exchange in all cells occurs directly with the external environment

Answer 322

D) those of humans, where there are four pumping chambers to drive blood flow

Answer 323

A) an open circulatory system

Answer 324

B) a closed circulatory system

Answer 325

C) a gastrovascular cavity

Answer 326

D) branched tracheae

Answer 327

A) annelids

Answer 328

D) insects

Answer 329

A) amphibians

Answer 330

C) mammals

Answer 331

D) reptiles

Answer 332

A) open circulatory system

Answer 333

B) hemocoel

Answer 334

C) two-chambered heart

Answer 335

D) four-chambered heart

Answer 336

A) animal had evolved from birds

Answer 337

B) animal was endothermic and had a high metabolic rate

Answer 338

C) animal was most closely related to alligators and crocodiles

Answer 339

D) species had little to no need to regulate blood pressure

Answer 340

A) always inside of vessels and is under higher pressure than in closed circulatory systems

Answer 341

B) not always confined to blood vessels and is under higher pressure than in closed circulatory systems

Answer 342

C) always inside of vessels and is under lower pressure than in closed circulatory systems

Answer 343

D) not always confined to blood vessels and is under lower pressure than in closed circulatory systems

Answer 344

A) temperature differences between the lungs and the active tissue

Answer 345

B) the slow rate at which diffusion occurs over large distances

Answer 346

C) the problem of communication systems involving only the nervous system

Answer 347

D) the need to cushion animals from trauma

Answer 348

A) systole of the left atrium

Answer 349

B) diastole of the right ventricle

Answer 350

C) systole of the left ventricle

Answer 351

D) diastole of the right atrium

Answer 352

A) left ventricle → aorta → lungs → systemic circulation

Answer 353

B) vena cava → right atrium → right ventricle → pulmonary vein

Answer 354

C) pulmonary vein → left atrium → left ventricle → pulmonary circuit

Answer 355

D) vena cava → right atrium → right ventricle → pulmonary artery

Answer 356

A) 1,000 mL/minute

Answer 357

B) 1,400 mL/minute

Answer 358

C) 2,800 mL/minute

Answer 359

D) 4,900 mL/minute

Answer 360

A) block conductance between the bundle branches and the Purkinje fibers

Answer 361

B) have a negative effect on peripheral resistance

Answer 362

C) disrupt the rate and timing of cardiac muscle contractions

Answer 363

D) have a direct effect on blood pressure monitors in the aorta

Answer 364

A) Their cardiac output did not change. Only their respiratory rate changed.

Answer 365

B) During exercise, their cardiac output decreased by 11,400 ml/minute.

Answer 366

C) During exercise, their cardiac output increased by 60 ml/beat.

Answer 367

D) Their cardiac output increased from 4,200 ml/minute to 15,600 ml/minute after jogging.

Answer 368

A) occurs at the same time as ventricular diastole

Answer 369

B) pumps blood to the aorta

Answer 370

C) refers to the relaxation of the cardiac muscle

Answer 371

D) only occurs in the left heart chambers

Answer 372

A) the pulmonary vein and the superior vena cava

Answer 373

B) the veins from the right and left legs

Answer 374

C) the pulmonary artery and the inferior vena cava

Answer 375

D) the pulmonary vein and the aorta

Answer 376

A) one capillary bed

Answer 377

B) two capillary beds

Answer 378

C) three capillary beds

Answer 379

D) four capillary beds

Answer 380

A) the pressure of blood in the heart chambers

Answer 381

B) the rhythm of heart contractions

Answer 382

C) the amount of oxygen in the blood as it leaves the heart

Answer 383

D) the speed of blood flow through the blood vessels

Answer 384

C) hippopotamus

Answer 385

D) giraffe

Answer 386

A) the capillaries have internal valves that slow the flow of blood

Answer 387

B) the diastolic blood pressure is too low to deliver blood to the capillaries at a high flow rate

Answer 388

C) the systemic capillaries are supplied by the left ventricle, which has a lower cardiac output than the right ventricle

Answer 389

D) the total cross-sectional area of the capillaries is greater than the total cross-sectional area of the arteries or any other part of the circulatory system

Answer 390

A) The animal is likely small and compact, without the need to pump blood very far from the heart.

Answer 391

B) The species likely has very wide-diameter veins.

Answer 392

C) The animal likely has a very long distance between its heart and its brain.

Answer 393

D) The animal likely has a relatively inactive lifestyle.

Answer 394

A) increased activity of the immune system

Answer 395

B) blood sugar that is abnormally high

Answer 396

C) dehydration

Answer 397

D) sodium depletion

Answer 398

A) The infected human's immune system is fighting the worms.

Answer 399

B) The worm infection is causing a decrease in cardiac output.

Answer 400

C) The worms are blocking the lymph vessels.

Answer 401

D) More blood is flowing through precapillary sphincters.

Answer 402

A) bursting of blood vessels in capillary beds

Answer 403

B) inability of the right ventricle to contract

Answer 404

C) reversal of normal blood flow direction in arteries

Answer 405

D) destruction of red blood cells

Answer 406

A) only I and II

Answer 407

B) only I and III

Answer 408

C) only II and III

Answer 409

D) I, II, and III

Answer 410

A) Blood flow through the capillaries is essentially frictionless, and this reduces the amount of pressure on their walls.

Answer 411

B) The total cross-sectional diameter of the arterial circulation increases with progression from artery to arteriole to capillary, leading to a reduced blood pressure.

Answer 412

C) Fluid loss from the arteries is high enough that pressure drops off significantly by the time blood reaches the capillaries.

Answer 413

D) Capillary beds have the thickest walls of any blood vessel to resist these high pressures.

Answer 414

A) blood vessels farthest from the heart must have valves

Answer 415

B) capillaries must have a thick endothelium

Answer 416

C) arteries must be elastic

Answer 417

D) pressure in all vessels must be equal

Answer 418

A) hemoglobin will not release oxygen

Answer 419

B) fluid will tend to accumulate in tissues

Answer 420

C) the pH of the interstitial fluids will increase

Answer 421

D) plasma proteins will escape through the endothelium of the capillaries

Answer 422

A) loss of osmotic pressure in the capillaries

Answer 423

B) development of an osmotic pressure difference across capillary walls

Answer 424

C) loss of fluid from capillaries

Answer 425

D) increased diffusion of hemoglobin

Answer 426

A) platelets

Answer 427

B) leukocytes

Answer 428

C) erythrocytes

Answer 429

D) thrombi

Answer 430

A) one membrane—that of the lining in the lungs—and then bind directly to hemoglobin, a protein dissolved in the plasma of the blood

Answer 431

B) two membranes—in and out of the cell lining the lung—and then bind directly to hemoglobin, a protein dissolved in the plasma of the blood

Answer 432

C) four membranes—in and out of the cell lining the lung, in and out of the endothelial cell lining an alveolar capillary—and then bind directly to hemoglobin, a protein dissolved in the plasma of the blood

Answer 433

D) five membranes—in and out of the cell lining the lung, in and out of the endothelial cell lining an alveolar capillary, and into the red blood cell—to bind with hemoglobin

Answer 434

A) measurement of fatty deposits on the endothelium of arteries

Answer 435

B) measurement of the LDL/HDL ratio in peripheral blood

Answer 436

C) percentage of blood volume made up of platelets

Answer 437

D) blood pressure being greater than 140 mm Hg systolic and/or greater than 90 mm Hg diastolic

Answer 438

A) retain the normal cell shape, but the mitochondria will be poisoned

Answer 439

B) lyse as the cyanide concentration increases inside the cell

Answer 440

C) switch to anaerobic metabolism

Answer 441

D) be unaffected

Answer 442

A) production of erythropoietin

Answer 443

B) conversion of fibrin to fibrinogen

Answer 444

C) activation of prothrombin to thrombin

Answer 445

D) synthesis of hemoglobin

Answer 446

A) Platelets are not functioning properly, or there are too few to be effective.

Answer 447

B) Mast cells are not releasing their chemical messengers.

Answer 448

C) There are too many antigens to allow clotting.

Answer 449

D) Hemoglobin levels are too high to allow clotting.

Answer 450

A) Growth hormone; pancreas

Answer 451

B) Erythropoietin; kidney

Answer 452

C) Cortisol; adrenal gland

Answer 453

D) Acetylcholine; bone marrow

Answer 454

A) water across the gills of a fish and the blood within those gills

Answer 455

B) blood in the dorsal vessel of an insect and that of air within its tracheae

Answer 456

C) air within the primary bronchi of a human and the blood within the pulmonary veins

Answer 457

D) water across the skin of a frog and the blood flow within the ventricle of its heart

Answer 458

A) blood pressure

Answer 459

B) diffusion

Answer 460

C) active transport

Answer 461

D) osmosis

Answer 462

A) The respiratory medium for fish carries more oxygen than the respiratory medium of mammals.

Answer 463

B) A countercurrent exchange mechanism between the respiratory medium and blood flow is seen in mammals but not in fish.

Answer 464

C) The movement of the respiratory medium in mammals is bidirectional, but in fish it is unidirectional.

Answer 465

D) In blood, oxygen is primarily transported by plasma in fish, but by red blood cells in mammals.

Answer 466

A) Both mammals and insects have similar oxygen needs.

Answer 467

B) When air is the respiratory medium, there is a greater risk that the tracheal tubes will collapse.

Answer 468

C) Insects and mammals both keep their internal temperature constant.

Answer 469

D) A decrease in environmental carbon dioxide made structural support necessary.

Answer 470

A) 400 mm Hg

Answer 471

B) 82 mm Hg

Answer 472

C) 40 mm Hg

Answer 473

D) 4 mm Hg

Answer 474

A) the carbon dioxide content will increase

Answer 475

B) the oxygen content will decrease

Answer 476

C) it will be better able to sustain aerobic organisms

Answer 477

D) it will become more dense

Answer 478

A) blocks the openings into the tracheal system

Answer 479

B) interferes with gas exchange across the capillaries

Answer 480

C) clogs their bronchi

Answer 481

D) prevents gases from leaving the atmosphere

Answer 482

A) 53 mm Hg

Answer 483

B) 157 mm Hg

Answer 484

C) 255 mm Hg

Answer 485

D) 760 mm Hg

Answer 486

A) the sudden change from the uterine environment to the air

Answer 487

B) the overproduction of surfactants

Answer 488

C) lung collapse due to inadequate production of surfactant

Answer 489

D) mutations in the genes involved in lung formation

Answer 490

A) trachea → bronchioles → bronchi → alveoli

Answer 491

B) larnyx → trachea → bronchi → bronchioles → alveoli

Answer 492

C) trachea → tracheoles → bronchi → alveoli

Answer 493

D) alveoli → tracheoles → bronchi → trachea

Answer 494

A) decrease; increase

Answer 495

B) increase; decrease

Answer 496

C) not change; also not change

Answer 497

D) decrease; decrease

Answer 498

A) The percentage of oxygen in the air at high elevations is lower than at sea level.

Answer 499

B) The percentage of oxygen in the air at high elevations is higher than at sea level.

Answer 500

C) The partial pressure of oxygen in the air at high elevations is lower than at sea level.

Answer 501

D) The partial pressure of oxygen in the air at high elevations is higher than at sea level.

Answer 502

A) reduce efficiency of gas exchange

Answer 503

B) change the exchange of gases in the body from carbon dioxide out and oxygen in to carbon dioxide in and oxygen out

Answer 504

C) increase the efficiency of gas exchange

Answer 505

A) has more dissolved oxygen than seawater

Answer 506

B) has less dissolved oxygen than seawater

Answer 507

C) can hold 10-40 times more carbon dioxide than air

Answer 508

D) can hold 10-40 times more oxygen than air

Answer 509

A) amount of carbon dioxide would increase

Answer 510

B) bicarbonate in the blood would increase

Answer 511

C) amount of oxygen in the blood will decrease

Answer 512

D) amount of protons in the blood will increase

Answer 513

A) Airflow through the avian lung is bidirectional like in mammals.

Answer 514

B) There is more dead space within the avian lung so that oxygen can be stored for future use.

Answer 515

C) Countercurrent circulation is present in the avian lung.

Answer 516

D) Gas exchange occurs during both inhalation and exhalation.

Answer 517

A) the brain directly measures and monitors oxygen levels and causes breathing changes accordingly

Answer 518

B) the medulla oblongata, which is in contact with cerebrospinal fluid, monitors pH and uses this measure to control breathing

Answer 519

C) the brain alters the pH of the cerebrospinal fluid to force the animal to retain more or less carbon dioxide

Answer 520

D) stretch receptors in the lungs cause the medulla oblongata to speed up or slow breathing

Answer 521

A) 1450 mL

Answer 522

B) 4000 mL

Answer 523

C) 4450 mL

Answer 524

D) 5000 mL

Answer 525

A) nitrogen

Answer 526

C) carbon dioxide

Answer 527

D) carbon monoxide

Answer 528

A) release all bound carbon dioxide molecules

Answer 529

B) bind more oxygen molecules

Answer 530

C) decrease its binding of H+

Answer 531

D) give up more of its oxygen molecules

Answer 532

A) converted to bicarbonate ions

Answer 533

B) bound to hemoglobin

Answer 534

C) transported in the erythrocytes as carbonic acid

Answer 535

D) simply dissolved in the plasma

Answer 536

A) Oxygen delivery to muscle is increased when more carbon dioxide is produced by the muscle.

Answer 537

B) Because of the change in blood pH, the blood can carry more oxygen.

Answer 538

C) The amount of oxygen in venous blood will increase.

Answer 539

D) Arterial blood entering the capillaries will carry more oxygen.

Answer 540

A) have larger lungs

Answer 541

B) can store more oxygen in their muscles

Answer 542

C) use gills for gas exchange

Answer 543

D) always keep blood flowing to their lungs during a dive

Answer 544

A) Hyperventilation results in inefficient gas exchange, and not enough oxygen is absorbed by the blood.

Answer 545

B) More metabolic waste is released into the blood, thus reducing the pH.

Answer 546

C) Rapid breathing depletes the blood of carbon dioxide, thus the blood pH increases.

Answer 547

D) Excess production of carbon dioxide decreases the affinity of hemoglobin for oxygen.

Answer 548

A) the lungs of a vertebrate

Answer 549

B) the gills of a fish

Answer 550

C) the tracheal system of an insect

Answer 551

D) the skin of an earthworm

Answer 552

A) left atrium.

Answer 553

B) right atrium.

Answer 554

C) left ventricle.

Answer 555

D) right ventricle.

Answer 556

A) blood pressure.

Answer 557

B) stroke volume.

Answer 558

C) cardiac output.

Answer 559

D) heart rate.

Answer 560

A) rising O2

Answer 561

B) falling O2

Answer 562

C) rising CO2

Answer 563

D) falling CO2

Answer 564

A) the number of heart chambers.

Answer 565

B) a complete separation of circuits for circulation.

Answer 566

C) the number of circuits for circulation.

Answer 567

D) a low blood pressure in the systemic circuit.

Answer 568

A) the pulmonary vein.

Answer 569

B) the trachea.

Answer 570

C) the right atrium.

Answer 571

D) the right ventricle.

Answer 572

A) higher PO2.

Answer 573

B) higher PCO2.

Answer 574

C) greater bicarbonate concentration.

Answer 575

D) lower pH.

	Created by Hannah Moore about 6 years ago

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