Atp in a sentence

(1) Convert the catabolite into ATP.

(2) ATP is produced during glycolysis.

(3) Myosins are ATP-dependent enzymes.

(4) GTP is a nucleotide similar to ATP.

(5) The cytosol is where ATP is produced.

(6) ATP is a key molecule in bioenergetics.

(7) ATP is essential for muscle contraction.

(8) ATPase is an enzyme that hydrolyzes ATP.

(9) The light reaction produces ATP and NADPH.

(10) Coenzyme Q is essential for ATP production.

Atp sentence

(11) ATP is required for myosin to bind to actin.

(12) This enzyme catalyzes the production of ATP.

(13) The breakdown of fats can also generate ATP.

(14) The process of glycolysis helps generate ATP.

(15) The plant uses photosynthates to produce ATP.

(16) Adenyls are formed from the breakdown of ATP.

(17) ATP synthase is the enzyme that generates ATP.

(18) ATP is generated in the mitochondria of cells.

(19) The breakdown of glucose produces adp and atp.

(20) The krebs cycle produces ATP, NADH, and FADH2.

Atp make sentence

(21) Hexokinase is activated by the presence of ATP.

(22) The body uses ATP to power muscle contractions.

(23) Succinate is involved in the production of ATP.

(24) Glycogenolytic reactions generate ATP molecules.

(25) The anthranilate synthase reaction requires ATP.

(26) Apyrases are enzymes that hydrolyze ATP and ADP.

(27) The function of chondriosomes is to produce ATP.

(28) The production of ATP occurs in the mitochondria.

(29) ATP is involved in the process of blood clotting.

(30) ATP is required for the synthesis of RNA and DNA.

Sentence of atp

(31) Apyrase is an enzyme that hydrolyzes ATP and ADP.

(32) The chaperonin mechanism involves ATP hydrolysis.

(33) Synthase is a key enzyme in the production of ATP.

(34) ATP is generated through the breakdown of glucose.

(35) Adenosine triphosphate is often referred to as ATP.

(36) The mitochondria produce energy in the form of ATP.

(37) The Krebs cycle is another pathway to generate ATP.

(38) Oxidoreductase is involved in the synthesis of ATP.

(39) The myofibril is regulated by calcium ions and ATP.

(40) The Krebs cycle produces energy in the form of ATP.

Atp meaningful sentence

(41) The addition of a phosphate group to adp forms atp.

(42) The conversion of adp to atp requires energy input.

(43) ATP is generated through the phosphorylation of ADP.

(44) The sarcosome is highly efficient in ATP production.

(45) The endosarc is necessary for the production of ATP.

(46) Without cocarboxylases, the body cannot produce ATP.

(47) ATP is generated through the process of chemiosmosis.

(48) Cocarboxylase is essential for the production of ATP.

(49) The metabolic process involves the production of ATP.

(50) The function of ATPase is to break down ATP into ADP.

Atp sentence examples

(51) The dynein motor protein is powered by ATP hydrolysis.

(52) ATP is used by enzymes to catalyze chemical reactions.

(53) ATP is used by neurons to transmit electrical signals.

(54) The ATP Tour is the professional men's tennis circuit.

(55) ATP hydrolysis is an example of an exergonic reaction.

(56) The holoenzyme is essential for the production of ATP.

(57) Enolase plays a crucial role in the production of ATP.

(58) ATP synthesis occurs during oxidative phosphorylation.

(59) Chlorophyl, generate ATP through photophosphorylation.

(60) Adenosine triphosphate is commonly referred to as ATP.

Sentence with atp

(61) Adp is converted into atp during cellular respiration.

(62) ATP is used by the brain to maintain neuronal activity.

(63) The net gain of ATP during glycolysis is two molecules.

(64) ATP is constantly being generated and used in the body.

(65) The process of oxidative phosphorylation generates ATP.

(66) Phosphorylating is a key step in the production of ATP.

(67) Apyrases are involved in the metabolism of ATP and ADP.

(68) The adenylic acid molecule can be synthesized from ATP.

(69) Adp is a precursor to atp in the energy cycle of cells.

(70) The krebs cycle produces energy-rich molecules like ATP.

Use atp in a sentence

(71) ATP is used by the liver to detoxify harmful substances.

(72) The process of phosphorolysis requires the input of ATP.

(73) The phosphoryl group is commonly found in ATP molecules.

(74) The synthesis of atp from adp is an endergonic reaction.

(75) Magnesium ions are essential cofactors for ATP synthesis.

(76) ATP is involved in the regulation of cellular metabolism.

(77) Cytochromes play a crucial role in the production of ATP.

(78) The catabolic process releases energy in the form of ATP.

(79) ATP is generated through the oxidation of food molecules.

(80) Oxaloacetate is an intermediate in the production of ATP.

Sentence using atp

(81) Pyruvic acid is a key component in the production of ATP.

(82) Ubiquinone plays a crucial role in the production of ATP.

(83) The synthesis of adenylates requires the presence of ATP.

(84) Enolase is involved in the production of ATP in the body.

(85) Glyceraldehyde is a key molecule in the production of ATP.

(86) ATP is required for DNA replication and protein synthesis.

(87) ATP is generated through the transfer of phosphate groups.

(88) The body stores a limited amount of ATP for immediate use.

(89) Plants generate ATP through the process of photosynthesis.

(90) The breakdown of glucose in glycolysis helps generate ATP.

Atp example sentence

(91) Chlorophyl, participate in the formation of ATP and NADPH.

(92) ATP is used by the immune system to power immune responses.

(93) ATP is used by the kidneys to maintain electrolyte balance.

(94) ATP is used by the heart to pump blood throughout the body.

(95) The hydrolysis of ATP releases inorganic phosphate and ADP.

(96) Hexokinase is an important enzyme in the production of ATP.

(97) ATP is the primary source of energy for cellular processes.

(98) The electron transport chain is involved in generating ATP.

(99) The body can generate ATP through the breakdown of lactate.

(100) Pyruvic acid plays a crucial role in the production of ATP.

Sentence with word atp

(101) The kinase can phosphorylate with ATP as a phosphate donor.

(102) The subunit of the ATP synthase enzyme is the F0F1 complex.

(103) Pyruvate is an important molecule for the production of ATP.

(104) ATP is often referred to as the energy currency of the cell.

(105) The mitochondria is responsible for generating ATP in cells.

(106) The thylakoids are responsible for generating ATP and NADPH.

(107) The breakdown of purines produces energy in the form of ATP.

(108) The cristae are crucial for the generation of ATP molecules.

(109) The breakdown of pyruvate releases energy in the form of ATP.

(110) The breakdown of ATP releases energy for cellular activities.

Sentence of atp

(111) The exergonic process is a key step in the production of ATP.

(112) The hydrolysis of ATP provides energy for cellular processes.

(113) The metabolism of malates is linked to the production of ATP.

(114) The breakdown of ATP is an example of an endergonic reaction.

(115) The process of anabolisms requires energy in the form of ATP.

(116) The adenylic acid molecule can be phosphorylated to form ATP.

(117) ATP is used by our muscles to power contraction and movement.

(118) Protonic gradients across cell membranes drive ATP synthesis.

(119) The kinase can phosphorylate with a phosphate group from ATP.

(120) Glucose is metabolized across various tissues to produce ATP.

Atp used in a sentence

(121) The activity of ATPase is essential for the synthesis of ATP.

(122) The cristae provide a site for ATP synthesis in mitochondria.

(123) The transmembrane transporter uses ATP to drive ion transport.

(124) Mitochondrial dysfunction can lead to impaired ATP production.

(125) ATP is a molecule that provides energy for cellular processes.

(126) ATP is involved in the regulation of cell growth and division.

(127) ATP is involved in the process of cell adhesion and migration.

(128) The activity of hexokinase is inhibited by high levels of ATP.

(129) The dissimilatory reaction releases energy in the form of ATP.

(130) The oxidation of glucose in cellular respiration produces ATP.

Atp sentence in English

(131) The carboxylating reaction requires energy in the form of ATP.

(132) Enzymes phosphorylate with ATP to activate metabolic pathways.

(133) The hydrolyzing of ATP provides energy for cellular processes.

(134) The water hydrolyses the ATP into ADP and inorganic phosphate.

(135) The cristae are responsible for generating ATP in mitochondria.

(136) The body can generate ATP through the breakdown of nucleotides.

(137) The translocating process is energy-dependent and requires ATP.

(138) The process of exocytosis is energy-dependent and requires ATP.

(139) The formation of adenylates is a crucial step in ATP synthesis.

(140) Actomyosin contraction is dependent on the availability of ATP.

(141) The hydrolysis of glyceride releases energy in the form of ATP.

(142) The flagellar rotation in archaea is powered by ATP hydrolysis.

(143) ATP is a nucleotide that consists of adenosine and diphosphate.

(144) ATP is required for the movement of flagella and cilia in cells.

(145) Monosaccharides are important for the synthesis of ATP in cells.

(146) Chemiosmotic coupling is a highly efficient way to generate ATP.

(147) The process of pinocytosis is energy-dependent and requires ATP.

(148) The hydrolysis of ATP releases energy that can be used by cells.

(149) The ion pump is powered by ATP, the energy currency of the cell.

(150) The production of Acetyl CoA is inhibited by high levels of ATP.

(151) The activity of ATPase is dependent on the concentration of ATP.

(152) The function of reductase is essential for the production of ATP.

(153) Monophosphate is an important component in the production of ATP.

(154) ATPase is an enzyme that helps in the breakdown of ATP molecules.

(155) ATP is used by white blood cells to engulf and destroy pathogens.

(156) The activity of phosphorylase is inhibited by high levels of ATP.

(157) The breakdown of pyruvic acid releases energy in the form of ATP.

(158) Gluconeogenesis is an energy-demanding process that requires ATP.

(159) Phosphocreatine is synthesized in the body from creatine and ATP.

(160) The ligating reaction requires the presence of ATP as a cofactor.

(161) ATP synthetase is a key enzyme involved in the production of ATP.

(162) Endergonic reactions play a crucial role in the production of ATP.

(163) The hydrolysis of ATP molecules helps break them down into energy.

(164) Endergonic reactions are often coupled with the hydrolysis of ATP.

(165) The ATP produced through anaerobic glycolysis is quickly depleted.

(166) Phosphocreatine plays a crucial role in the ATP-PCr energy system.

(167) The production of ATP is a fundamental process that sustains life.

(168) Nitrogen fixation is an energy-intensive process that requires ATP.

(169) ATP is used as a signaling molecule in various biological pathways.

(170) ATP is hydrolyzed to ADP and inorganic phosphate to release energy.

(171) ATP is used by sperm cells to power their movement towards the egg.

(172) Hexose sugars can be easily metabolized by the body to produce ATP.

(173) Replicative DNA helicases require ATP for their unwinding activity.

(174) The phosphorate step is crucial for the production of ATP in cells.

(175) Phosphocreatine is involved in the rephosphorylation of ADP to ATP.

(176) The ATP molecule acts as a carrier of chemical energy within cells.

(177) ATP is involved in signal transduction pathways and cell signaling.

(178) The luciferase reaction requires the presence of luciferin and ATP.

(179) Creatine is believed to increase the production of ATP in the body.

(180) Adenyl is a critical component of the energy currency molecule ATP.

(181) ATP is involved in the process of muscle contraction and relaxation.

(182) The energy released during ATP hydrolysis is used for cellular work.

(183) The availability of oxaloacetate affects the rate of ATP production.

(184) Endergonic reactions are often associated with the formation of ATP.

(185) The synthesis of ribonucleotides requires energy in the form of ATP.

(186) The contraction of muscle fibers requires energy in the form of ATP.

(187) The lumenal space of the mitochondria is where ATP synthesis occurs.

(188) The contraction of myocytes is dependent on the availability of ATP.

(189) The energy required for muscle-fibre contraction is provided by ATP.

(190) The process of ATP hydrolysis breaks down ATP molecules into energy.

(191) The function of ATPase is to release energy stored in ATP molecules.

(192) The process of glycolysis involves phosphorylating glucose with ATP.

(193) Chemiosmotic theory explains how ATP is synthesized in mitochondria.

(194) The addition of ATP allowed the kinase to phosphorylate the protein.

(195) The electron transport process is essential for the synthesis of ATP.

(196) The electron transport process is highly efficient in generating ATP.

(197) Dehydrogenase is essential for the production of ATP in mitochondria.

(198) ATP is recycled and regenerated in cells through metabolic processes.

(199) The end products of glycolysis can be used for the production of ATP.

(200) The process of muscle contraction requires energy in the form of ATP.

(201) The chelation of magnesium ions is important for the function of ATP.

(202) The enzyme is catalysing the synthesis of ATP from ADP and phosphate.

(203) The dark reaction is influenced by the availability of ATP and NADPH.

(204) Researchers go through phosphate to study its role in ATP production.

(205) The breakdown of oxaloacetic acid releases energy in the form of ATP.

(206) Phosphocreatine is involved in the production of ATP during exercise.

(207) To generate ATP, cells undergo a process called cellular respiration.

(208) ATP is required for active transport processes across cell membranes.

(209) Oxidative phosphorylation is a highly efficient way of producing ATP.

(210) The thylakoid membrane is involved in the synthesis of ATP and NADPH.

(211) Active transport is a process that requires the use of ATP molecules.

(212) The cristae contain proteins and enzymes necessary for ATP production.

(213) The cristae provide a compartmentalized environment for ATP synthesis.

(214) ATP is synthesized through a process called oxidative phosphorylation.

(215) ATP is involved in the active transport of ions across cell membranes.

(216) The hydrolytic reaction of ATP provides energy for cellular processes.

(217) The metabolism of fumarate is closely linked to the production of ATP.

(218) Nephridial excretion is an energy-intensive process that requires ATP.

(219) The function of chondriosomes is to produce energy in the form of ATP.

(220) The process of fermentation can generate ATP in the absence of oxygen.

(221) The breakdown of ATP into ADP and inorganic phosphate releases energy.

(222) The cristae increase the efficiency of ATP production in mitochondria.

(223) The formation of pyrophosphates is a key step in the synthesis of ATP.

(224) The enzyme was phosphorylated by the ATP molecule during the reaction.

(225) Diaphorase is important for the production of ATP in the mitochondria.

(226) The process of hydrolyzing ATP releases energy for cellular processes.

(227) The production of ATP in cells relies on oxidation-reduction reactions.

(228) The chaperonin molecule undergoes ATP-dependent conformational changes.

(229) Glycolytic metabolism is important for red blood cells to generate ATP.

(230) The cristae are responsible for the majority of ATP synthesis in cells.

(231) Glucose is used to make ATP, which is the energy currency of our cells.

(232) Cellular respiration is a complex biological process that produces ATP.

(233) The thylakoid is where the synthesis of ATP occurs through chemiosmosis.

(234) The breakdown of glucose-6-phosphate releases energy in the form of ATP.

(235) The tricarboxylic acid cycle is a key pathway for the production of ATP.

(236) The enzyme phosphorylates ATP to generate energy for cellular processes.

(237) The chemiosmotic theory explains how ATP is synthesized in mitochondria.

(238) The glycolytic pathway is a major source of ATP during intense exercise.

(239) Coenzyme A is necessary for the production of energy in the form of ATP.

(240) Adenosine is a building block for ATP, the energy currency of our cells.

(241) The chondriosome is responsible for producing energy in the form of ATP.

(242) The granum is essential for the production of ATP during photosynthesis.

(243) ATP is used in active transport to move molecules across cell membranes.

(244) The energy from ATP is used to power the movement of cilia and flagella.

(245) The exergonic reaction of ATP hydrolysis powers many cellular processes.

(246) The production of ATP is dependent on the presence of creatine phosphate.

(247) ATPase is essential for the synthesis of ATP during cellular respiration.

(248) ATPase is an enzyme that hydrolyzes ATP into ADP and inorganic phosphate.

(249) The mitochondrion is responsible for producing energy in the form of ATP.

(250) Ligations require the presence of ATP for the ligation reaction to occur.

(251) The F1F0 ATPase complex is responsible for ATP synthesis in mitochondria.

(252) Glucose is important for our body to make ATP, which is a type of energy.

(253) The process of glycolysis is highly efficient in terms of ATP production.

(254) The citric acid cycle is a series of chemical reactions that generate ATP.

(255) The glycolytic pathway is highly efficient in generating ATP from glucose.

(256) The hydrolysis of ATP by ATPase releases energy that can be used by cells.

(257) The cristae are highly folded to maximize the efficiency of ATP synthesis.

(258) The transport of calcium is an energy-dependent process that requires ATP.

(259) The efficiency of electron transport determines the overall ATP production.

(260) The fundamental mechanism of cellular respiration is the production of ATP.

(261) The hydrolyzing of ATP releases energy that is used for cellular processes.

(262) The thylakoid membrane is where ATP synthesis occurs during photosynthesis.

(263) ATPase is responsible for hydrolyzing ATP into ADP and inorganic phosphate.

(264) The molecule of ATP is the primary source of energy for cellular processes.

(265) The activity of hexokinase is inhibited by the presence of ATP in the cell.

(266) The dimeric ATPase hydrolyzed ATP to provide energy for cellular processes.

(267) The activity of ATPase is influenced by the availability of ATP in the cell.

(268) The synthesis of adenosine diphosphate occurs through the hydrolysis of ATP.

(269) The ATP molecule is composed of adenine, ribose, and three phosphate groups.

(270) The ATP molecule is highly unstable and readily releases energy when needed.

(271) ATP is essential for the functioning of enzymes and other cellular proteins.

(272) ATP is constantly being regenerated in our cells to maintain energy balance.

(273) The glycolytic pathway produces ATP through substrate-level phosphorylation.

(274) The production of ATP through oxidative phosphorylation is highly efficient.

(275) Oxidative phosphorylation is a highly efficient mechanism for ATP synthesis.

(276) The purpose of internal respiration is to produce energy in the form of ATP.

(277) The process of respiration in cells helps break down phosphate bonds in ATP.

(278) ATP is a nucleotide composed of adenine, ribose, and three phosphate groups.

(279) The concentration of ATP in a cell can be measured using various techniques.

(280) The compound glyceraldehyde-3-phosphate is involved in the production of ATP.

(281) ATPase is an important component of the ATP synthase complex in mitochondria.

(282) ATP is used by plants to transport sugars and nutrients throughout the plant.

(283) ATP is required for the synthesis of neurotransmitters in the nervous system.

(284) The concentration of adenosine diphosphate affects the rate of ATP synthesis.

(285) Nucleosomes can be remodeled by ATP-dependent chromatin remodeling complexes.

(286) Aldolase is involved in the production of ATP through the glycolytic pathway.

(287) The addition of ATP allows the kinase to phosphorylate into its active state.

(288) The mitochondria in our cells generate ATP through oxidative phosphorylation.

(289) The process of phosphorylation adds a phosphate group to ADP to generate ATP.

(290) The breakdown of ATP molecules releases stored energy for cellular processes.

(291) The process of photosynthesis requires plants to take off phosphate from ATP.

(292) The synthesis of oxalacetate requires the input of energy in the form of ATP.

(293) The sarcosome is responsible for generating ATP through cellular respiration.

(294) The enzyme adenylate cyclase is responsible for converting ATP to cyclic AMP.

(295) The energy stored in ATP is used to power the movement of cilia and flagella.

(296) The thylakoids contain the electron transport chain involved in ATP synthesis.

(297) Ligase with ATP as a cofactor catalyzes the formation of phosphodiester bonds.

(298) The movement of meromyosin along actin filaments is powered by ATP hydrolysis.

(299) The process of chemiosmosis is involved in generating ATP in the mitochondria.

(300) The energy released from ATP hydrolysis is used to drive endergonic reactions.

(301) Fos is a vital component of ATP, which is the primary energy source for cells.

(302) The molecular structure of ATP is responsible for its role in energy transfer.

(303) The sarcosomal mitochondria are responsible for producing ATP in muscle cells.

(304) Canalicular ATP-binding cassette transporters are involved in drug resistance.

(305) The exergonic reaction of DNA replication is powered by the hydrolysis of ATP.

(306) The energy change in the food we eat is converted into ATP for cellular energy.

(307) Anaerobically respiring cells produce less ATP compared to aerobic respiration.

(308) During exercise, our muscles generate ATP to meet the increased energy demands.

(309) The isoenzyme is essential for cellular respiration, and it helps generate ATP.

(310) Protonic gradients across cell membranes are involved in the generation of ATP.

(311) The activity of phosphatase with magnesium ions is important for ATP synthesis.

(312) The chondriosome is responsible for producing ATP through cellular respiration.

(313) ATP is used in the process of photosynthesis to power the synthesis of glucose.

(314) The process of glycolysis produces ATP, but it also produces pyruvate and NADH.

(315) The thylakoids are involved in the production of high-energy molecules like ATP.

(316) Aldolase is an essential enzyme for the production of energy in the form of ATP.

(317) The energy released during the electron transport chain is used to generate ATP.

(318) The dynein motor protein uses ATP to generate force and move along microtubules.

(319) The release of diphosphate during ATP hydrolysis drives many cellular processes.

(320) The F-type ATPase is involved in ATP synthesis during oxidative phosphorylation.

(321) The subunit of the ATP synthase was found to be essential for energy production.

(322) The mitochondrion is the powerhouse of the cell, and it produces ATP for energy.

(323) The chemiosmotic mechanism is responsible for the generation of ATP in bacteria.

(324) The body uses phosphocreatine to quickly regenerate ATP during intense exercise.

(325) The exergonic reaction of muscle contraction is powered by the breakdown of ATP.

(326) The thylakoid is essential for the production of ATP and NADPH in photosynthesis.

(327) The release of triphosphate during ATP hydrolysis powers many cellular processes.

(328) The enzyme functioned enzymatically to facilitate the conversion of ATP into ADP.

(329) The movement of meromyosin is powered by the energy released from ATP hydrolysis.

(330) The breakdown of fats and proteins can also generate ATP when glucose is limited.

(331) The ability to perform aerobic respiration allows organisms to generate more ATP.

(332) The process of deaminating nucleosides is important for the synthesis of new ATP.

(333) The endosarc, which is involved in cellular respiration, produces ATP for energy.

(334) Triose is a key component in the production of ATP, the energy currency of cells.

(335) The enzyme adenylate cyclase is responsible for converting ATP to adenyl cyclase.

(336) Anabolism is an energy-intensive process that requires ATP as a source of energy.

(337) Phos is an important element in the production of energy-rich compounds like ATP.

(338) The semiquinone form of coenzyme Q is involved in the production of ATP in cells.

(339) Adp is a low-energy molecule that needs to be converted to atp for cellular work.

(340) Ectoenzyme CD73 plays a role in the conversion of extracellular ATP to adenosine.

(341) The electrogenic nature of the mitochondria is crucial for the production of ATP.

(342) ATP is used in many metabolic pathways, and it is also involved in DNA synthesis.

(343) The citric acid cycle produces ATP, but it also produces carbon dioxide and NADH.

(344) Creatine phosphate is converted back into ATP during periods of rest and recovery.

(345) The proton is used in proton motive force to generate ATP in cellular respiration.

(346) Chromatin remodeling complexes use ATP hydrolysis to alter nucleosome positioning.

(347) The hydrolysis of ATP releases energy that is used by cells for various functions.

(348) Phosphoryl groups are essential for the production of ATP in cellular respiration.

(349) The contraction of a muscle cell is an energy-dependent process that requires ATP.

(350) The energy stored in ATP is released when the terminal phosphate group is removed.

(351) Leucoplasts, unlike mitochondria, do not produce ATP through cellular respiration.

(352) Ribonucleotides are involved in the synthesis of ATP, a universal energy molecule.

(353) The enzyme diphosphate kinase transfers a phosphate group from ATP to diphosphate.

(354) The conversion of Acetyl CoA to ATP is an important source of energy for the body.

(355) The process of respiration allows cells to transform energy from glucose into ATP.

(356) Adenylate kinase is important for maintaining the balance of ATP and ADP in cells.

(357) Carbohydrates are necessary for the body to produce ATP, which is used for energy.

(358) The electron transport chain is a series of exergonic reactions that generate ATP.

(359) Glucose-6-phosphate is an essential molecule for the production of ATP in the cell.

(360) The breakdown of glucose during anaerobic respiration produces ATP and lactic acid.

(361) ATP is generated through the movement of electrons in the electron transport chain.

(362) Hexokinase is an enzyme that phosphorylates glucose using ATP as a phosphate donor.

(363) The electron transport chain is responsible for generating ATP in the mitochondria.

(364) The field of bioenergetics encompasses the study of ATP production and utilization.

(365) The phosphoryl group is commonly found in biological molecules such as ATP and DNA.

(366) The ATP molecule consists of a nitrogenous base, sugar, and three phosphate groups.

(367) The amount of ATP stored in the body is limited and must be constantly replenished.

(368) As ATP levels decrease, the body's ability to perform physical activity diminishes.

(369) The ATPase enzyme is responsible for the breakdown of ATP during muscle contraction.

(370) Coenzyme Q10 is involved in the production of ATP, the body's main source of energy.

(371) Glucose is used to make ATP, which is used by the body for many different processes.

(372) Glycolysis breaks down glucose into two molecules of pyruvate, and it generates ATP.

(373) The mitochondria are responsible for oxidatively phosphorylating ADP to produce ATP.

(374) Phosphokinase is involved in the breakdown of ATP, the main energy source for cells.

(375) The products of phosphorolysis can be used in the glycolysis pathway to produce ATP.

(376) Sarcoplasmic calcium release is influenced by the concentration of intracellular ATP.

(377) The activity of ATPase is influenced by the concentration of ATP and ADP in the cell.

(378) The human body produces less ATP during anaerobic metabolism than aerobic metabolism.

(379) The chlorophylls in plants are able to absorb light energy and use it to produce ATP.

(380) The breakdown of glucose produces ATP, but it also produces carbon dioxide and water.

(381) The conversion of adenosine diphosphate to ATP is an essential step in energy storage.

(382) Chondriosomes are able to generate ATP through both aerobic and anaerobic respiration.

(383) Obligate anaerobes are unable to perform oxidative phosphorylation for ATP production.

(384) ATP is a high-energy molecule that can be used to drive endergonic reactions in cells.

(385) The electron transport chain is responsible for the majority of ATP synthesis in cells.

(386) The cristae are highly folded structures that increase the efficiency of ATP synthesis.

(387) Catabolic reactions are essential for the production of energy-rich molecules like ATP.

(388) Hexose sugars play a crucial role in the production of ATP during cellular respiration.

(389) The chemiosmotic gradient across the inner mitochondrial membrane drives ATP synthesis.

(390) Dehydrogenases are essential for the production of ATP in the electron transport chain.

(391) Acetyl-CoA is an important molecule for the production of ATP in the citric acid cycle.

(392) The process of photosynthesis produces ATP, but it also produces oxygen as a byproduct.

(393) ATP is used by plants during photosynthesis to convert light energy into chemical energy.

(394) The process of cellular respiration involves breaking down glucose into molecules of ATP.

(395) The inner membrane of chondriosomes contains proteins that are involved in ATP synthesis.

(396) The process of respiration in living organisms helps transform energy from food into ATP.

(397) The ATP-PC system is a rapid way to generate ATP during short bursts of intense exercise.

(398) The release of diphosphate during ATP hydrolysis provides energy for cellular activities.

(399) Carbohydrates are necessary for the body to produce ATP, the energy currency of the body.

(400) ATP is transported across cell membranes by specialized proteins called ATP transporters.

(401) The cristae are essential for maintaining the proton gradient necessary for ATP synthesis.

(402) The breaking of phosphodiester bonds is necessary for the release of energy stored in ATP.

(403) The nitrogenase reaction is energetically demanding and requires a constant supply of ATP.

(404) The movement of zoospores is an energy-intensive process that requires ATP for propulsion.

(405) The speed of muscle contraction is influenced by the rate of ATP hydrolysis by meromyosin.

(406) Adenylate kinase deficiency is a rare genetic disorder that affects the production of ATP.

(407) The molecular structure of ATP is responsible for its role as a source of energy in cells.

(408) Creatine phosphate is involved in the production of ATP, the body's primary energy source.

(409) Nicotinamide adenine dinucleotide is required for the synthesis of ATP in the mitochondria.

(410) Don't discard phosphate, as it's an essential component of ATP, the body's energy currency.

(411) Although ATP is a small molecule, its importance in cellular function cannot be overstated.

(412) ATP is essential for cellular energy production, and it is synthesized in the mitochondria.

(413) The hydrolysis of ATP is an exergonic reaction that provides energy for cellular processes.

(414) Glycolysis is the main source of energy for red blood cells, and it provides them with ATP.

(415) Anaerobic glycolysis is a metabolic pathway that allows cells to produce ATP without oxygen.

(416) The proton gradient across the inner mitochondrial membrane is essential for generating ATP.

(417) The nadp molecule is involved in the production of ATP through the electron transport chain.

(418) Creatine has been shown to increase the production of ATP, the body's main source of energy.

(419) The synthesis of ATP requires energy input from the breakdown of glucose or other molecules.

(420) ATP is used to power muscle contractions, and it is also used in nerve impulse transmission.

(421) The breakdown of glucose is an exergonic process, and it releases energy in the form of ATP.

(422) The mitochondrion is able to generate ATP through a process called oxidative phosphorylation.

(423) The speed of muscle contraction is influenced by the rate at which meromyosin hydrolyzes ATP.

(424) Uropoiesis is an energy-intensive process that requires ATP for various transport mechanisms.

(425) ATP synthase is the enzyme that helps generate ATP in the final step of cellular respiration.

(426) The tricarboxylic acid cycle produces ATP, NADH, and FADH2 through oxidative phosphorylation.

(427) The citrate cycle is a vital process in cellular respiration, and it produces ATP for energy.

(428) Glyceraldehyde-3-phosphate is an important molecule for the production of ATP in mitochondria.

(429) The mitochondrion is able to produce reactive oxygen species as a byproduct of ATP production.

(430) The breakdown of ATP molecules in muscle cells helps break them down into energy for movement.

(431) Adenylate cyclase is an enzyme that converts ATP to cAMP in response to extracellular signals.

(432) The process of respiration in living organisms involves energy conversion from glucose to ATP.

(433) If active transport is insufficient, the muscle cell may not be able to properly generate ATP.

(434) The alternative pathway for the synthesis of ATP in mitochondria is oxidative phosphorylation.

(435) The hydrolysis of ATP is an exergonic reaction, and it releases energy for cellular processes.

(436) The tricarboxylic acid cycle is an essential process for the production of ATP in mitochondria.

(437) It is crucial to hold on to phosphate for the production of ATP, the body's main energy source.

(438) ATP is constantly being generated and used in our bodies to support various cellular processes.

(439) Aspartate is a key component in the citric acid cycle, which is responsible for generating ATP.

(440) Kinases are enzymes that catalyze the transfer of phosphate groups from ATP to other molecules.

(441) Adenylate kinase is an enzyme that catalyzes the transfer of a phosphate group from ATP to AMP.

(442) Glycogenolysis is an energy-consuming process, as it requires ATP for the breakdown of glycogen.

(443) The multienzyme cascade involved in the production of ATP is known as oxidative phosphorylation.

(444) The hydrolysis of ATP is an exergonic reaction that releases energy to power cellular processes.

(445) Glyceraldehyde-3-phosphate is an essential component in the production of ATP through glycolysis.

(446) The process of fermentation produces ATP, but it is much less efficient than aerobic respiration.

(447) The process of oxidative phosphorylation produces ATP, but it also produces water as a byproduct.

(448) The carboxyl group in succinic acid is involved in the production of ATP in the citric acid cycle.

(449) ATP is constantly being used and regenerated in the body, but it can also be stored for later use.

(450) The release of triphosphate during ATP hydrolysis is coupled with the synthesis of other molecules.

(451) Nitrogen transport in plants is an energy-intensive process that requires ATP for active transport.

(452) The chemiosmotic gradient across the thylakoid membrane drives ATP synthesis during photosynthesis.

(453) Adenosine diphosphate can be converted back to ATP through the process of oxidative phosphorylation.

(454) The structure of ATPase consists of multiple subunits that work together to catalyze ATP hydrolysis.

(455) ATP hydrolysis releases energy that can be used for muscle contraction and other cellular processes.

(456) The citric acid cycle is a cyclic pathway that generates ATP through substrate-level phosphorylation.

(457) Chondriosomes are able to convert glucose and oxygen into ATP through a series of chemical reactions.

(458) Triose is an essential molecule for the production of ATP, the energy source for cellular activities.

(459) Adenylate kinase is an enzyme that catalyzes the transfer of a phosphate group from ATP to adenylate.

(460) The phosphoryl group can be transferred from ATP to other molecules during energy-requiring processes.

(461) The endosarc is involved in the production of ATP, and it also provides energy for cellular processes.

(462) The conversion of glucose into starch by leucoplasts is an energy-intensive process that requires ATP.

(463) The transfer of a phosphoryl group from ATP to a molecule is a common way to transfer energy in cells.

(464) Glucose is broken down into pyruvate, and it is used to produce ATP through the process of glycolysis.

(465) The thylakoid is where the light energy is converted into chemical energy in the form of ATP and NADPH.

(466) The concentration of adenosine diphosphate can affect the activity of ATP-sensitive potassium channels.

(467) The electron transport chain is an exergonic process that generates a proton gradient for ATP synthesis.

(468) When glucose is broken down in the body, it produces ATP, which is the primary energy currency of cells.

(469) Creatine phosphate is involved in the regeneration of ATP during short bursts of high-intensity activity.

(470) The metabolism of aerobioses is characterized by the production of ATP through oxidative phosphorylation.

(471) The citric acid cycle, also known as the Krebs cycle, generates ATP through a series of chemical reactions.

(472) Biochemically, the breakdown of glucose during cellular respiration produces ATP, carbon dioxide, and water.

(473) Glucose is broken down in the body, and it is used to produce ATP, which is the energy currency of the body.

(474) Glycogenolytic breakdown in the liver is inhibited by high levels of ATP, indicating sufficient energy supply.

(475) The transfer of a phosphoryl group from ATP to a substrate is a common mechanism in cellular energy metabolism.

(476) Hydrogen ions are essential for many biological processes, such as the production of ATP in cellular respiration.

(477) The tricarboxylic acid cycle is an example of a metabolic pathway that generates both ATP and reducing equivalents.

(478) The electron transport chain in mitochondria relies on nicotinamide adenine dinucleotide phosphate to generate ATP.

(479) The absorption of light by chlorophyll a triggers the release of electrons, which are used to generate ATP and NADPH.

(480) Biophysically, the process of cellular respiration involves the conversion of glucose into ATP for energy production.

(481) Isoleucine is converted into acetyl-CoA, which is a key molecule in the citric acid cycle, and it helps generate ATP.

(482) The hydrolysis of ATP, a molecule used for energy in cells, releases energy and produces ADP and inorganic phosphate.

(483) Glycolysis is a crucial pathway in the production of ATP, and it provides the energy needed for many cellular processes.

(484) The breakdown of glucose in the presence of nicotinamide adenine dinucleotide produces ATP, the energy currency of cells.

(485) The process of cellular respiration involves both exergonic and endergonic reactions, which work together to produce ATP.

(486) The conversion of glyceraldehyde-3-phosphate to 1,3-bisphosphoglycerate is coupled with the phosphorylation of ADP to ATP.

(487) The infolding of the inner mitochondrial membrane is essential for the production of ATP, the energy currency of the cell.

(488) The isoenzyme is crucial for the production of energy in the form of ATP, and it is involved in various metabolic pathways.

(489) Glycin is a precursor for the synthesis of purines, which are important for the production of ATP, the energy currency of cells.

(490) The enzyme glyceraldehyde-3-phosphate dehydrogenase is involved in the generation of ATP through substrate-level phosphorylation.

(491) Isoleucine is converted into acetyl-CoA, which is used in the citric acid cycle to produce ATP, the body's main source of energy.

(492) The endosarc is involved in the production of ATP, which is the cell's main source of energy, and it powers various cellular processes.

(493) As the chlorophyll molecules in the reaction center become excited, they release high-energy electrons that are used to generate ATP and NADPH.

(494) The sodium-potassium pump is an example of active transport, as it moves ions against their concentration gradient and requires ATP to function.

(495) If the endosarc's ATP production is impaired, the cell may not have enough energy to carry out its functions, and it can result in cellular dysfunction.

(496) Active transport is a complex process that involves multiple steps, including the binding of molecules to carrier proteins and the use of ATP to power the movement of these molecules across the membrane.

The word usage examples above have been gathered from various sources to reflect current and historical usage of the word Atp. They do not represent the opinions of TranslateEN.com.