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TaxTree of Organism Rattus norvegicus Sprague-Dawley
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EC NUMBER 
COMMENTARY 
-
preliminary BRENDA-supplied EC number
preliminary BRENDA-supplied EC number
preliminary BRENDA-supplied EC number
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PATHWAY
BRENDA Link
KEGG Link
MetaCyc Link
(4Z,7Z,10Z,13Z,16Z)-docosapentaenoate biosynthesis (6-desaturase)
-
-
PWY-7726
(S)-lactate fermentation to propanoate, acetate and hydrogen
-
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PWY-8086
1,3-propanediol biosynthesis (engineered)
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-
PWY-7385
1,4-dichlorobenzene degradation
-
-
14DICHLORBENZDEG-PWY
11-oxyandrogens biosynthesis
-
-
PWY-8202
1D-myo-inositol hexakisphosphate biosynthesis II (mammalian)
-
-
PWY-6362
1D-myo-inositol hexakisphosphate biosynthesis III (Spirodela polyrrhiza)
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PWY-4661
1D-myo-inositol hexakisphosphate biosynthesis IV (Dictyostelium)
-
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PWY-6372
1D-myo-inositol hexakisphosphate biosynthesis V (from Ins(1,3,4)P3)
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PWY-6554
2-amino-3-hydroxycyclopent-2-enone biosynthesis
-
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PWY-7536
2-arachidonoylglycerol biosynthesis
-
-
PWY-8052
2-deoxy-D-ribose degradation II
-
-
PWY-8058
2-oxobutanoate degradation I
-
-
PWY-5130
3,4,6-trichlorocatechol degradation
-
-
PWY-6094
3,5-dichlorocatechol degradation
-
-
PWY-6084
3-chlorocatechol degradation I (ortho)
-
-
PWY-6089
3-chlorocatechol degradation II (ortho)
-
-
PWY-6193
3-hydroxypropanoate cycle
-
-
PWY-5743
3-hydroxypropanoate/4-hydroxybutanate cycle
-
-
PWY-5789
3-phosphoinositide biosynthesis
-
-
PWY-6352
4,5-dichlorocatechol degradation
-
-
PWY-6093
4-aminobutanoate degradation I
-
-
PWY-6535
4-aminobutanoate degradation II
-
-
PWY-6537
4-aminobutanoate degradation III
-
-
PWY-6536
4-aminobutanoate degradation V
-
-
PWY-5022
4-chlorocatechol degradation
-
-
PWY-6087
4-hydroxy-2-nonenal detoxification
-
-
PWY-7112
5-oxo-L-proline metabolism
-
-
PWY-7942
ABH and Lewis epitopes biosynthesis from type 1 precursor disaccharide
-
-
PWY-7832
alpha-linolenate metabolites biosynthesis
-
-
PWY-8398
ammonia assimilation cycle III
-
-
AMMASSIM-PWY
anaerobic energy metabolism (invertebrates, cytosol)
-
-
PWY-7383
anandamide biosynthesis I
-
-
PWY-8051
anandamide biosynthesis II
-
-
PWY-8053
anandamide degradation
-
-
PWY6666-1
anandamide lipoxygenation
-
-
PWY-8056
androgen biosynthesis
-
-
PWY66-378
anteiso-branched-chain fatty acid biosynthesis
-
-
PWY-8173
apratoxin A biosynthesis
-
-
PWY-8361
arachidonate metabolites biosynthesis
-
-
PWY-8397
backdoor pathway of androgen biosynthesis
-
-
PWY-8200
beta-alanine biosynthesis II
-
-
PWY-3941
C4 photosynthetic carbon assimilation cycle, NAD-ME type
-
-
PWY-7115
C4 photosynthetic carbon assimilation cycle, NADP-ME type
-
-
PWY-241
C4 photosynthetic carbon assimilation cycle, PEPCK type
-
-
PWY-7117
caffeine degradation III (bacteria, via demethylation)
-
-
PWY-6538
camalexin biosynthesis
-
-
CAMALEXIN-SYN
CDP-diacylglycerol biosynthesis I
-
-
PWY-5667
CDP-diacylglycerol biosynthesis II
-
-
PWY0-1319
cell-surface glycoconjugate-linked phosphocholine biosynthesis
-
-
PWY-7886
ceramide de novo biosynthesis
-
-
PWY3DJ-12
cholesterol biosynthesis (diatoms)
-
-
PWY-8239
cholesterol biosynthesis (plants, early side-chain reductase)
-
-
PWY18C3-1
cholesterol biosynthesis II (via 24,25-dihydrolanosterol)
-
-
PWY66-3
choline biosynthesis I
-
-
PWY-3385
choline biosynthesis III
-
-
PWY-3561
CMP-N-acetylneuraminate biosynthesis I (eukaryotes)
-
-
PWY-6138
CO2 fixation into oxaloacetate (anaplerotic)
-
-
PWYQT-4429
complex N-linked glycan biosynthesis (vertebrates)
-
-
PWY-7426
creatine biosynthesis
-
-
GLYCGREAT-PWY
curacin A biosynthesis
-
-
PWY-8358
cyanate degradation
cylindrospermopsin biosynthesis
-
-
PWY-8045
D-arabinose degradation V
-
-
PWY-8334
D-galactose degradation IV
-
-
PWY-6693
D-myo-inositol (1,4,5)-trisphosphate biosynthesis
-
-
PWY-6351
D-myo-inositol (1,4,5)-trisphosphate degradation
-
-
PWY-6363
D-myo-inositol (1,4,5,6)-tetrakisphosphate biosynthesis
-
-
PWY-6366
D-myo-inositol (3,4,5,6)-tetrakisphosphate biosynthesis
-
-
PWY-6365
D-myo-inositol-5-phosphate metabolism
-
-
PWY-6367
detoxification of reactive carbonyls in chloroplasts
-
-
PWY-6786
di-homo-gamma-linolenate metabolites biosynthesis
-
-
PWY-8396
diacylglycerol and triacylglycerol biosynthesis
-
-
TRIGLSYN-PWY
docosahexaenoate biosynthesis III (6-desaturase, mammals)
-
-
PWY-7606
docosahexaenoate metabolites biosynthesis
-
-
PWY-8400
dolichol and dolichyl phosphate biosynthesis
ergothioneine biosynthesis I (bacteria)
-
-
PWY-7255
even iso-branched-chain fatty acid biosynthesis
-
-
PWY-8175
fatty acid biosynthesis initiation (type I)
-
-
PWY-5966-1
ferrichrome A biosynthesis
-
-
PWY-7571
formaldehyde assimilation I (serine pathway)
-
-
PWY-1622
fructose 2,6-bisphosphate biosynthesis
-
-
PWY66-423
GABA shunt I
-
-
GLUDEG-I-PWY
GABA shunt II
-
-
PWY-8346
gamma-glutamyl cycle
-
-
PWY-4041
gamma-linolenate biosynthesis II (animals)
-
-
PWY-6000
ganglio-series glycosphingolipids biosynthesis
-
-
PWY-7836
ginkgotoxin biosynthesis
-
-
PWY-8077
gliotoxin biosynthesis
-
-
PWY-7533
globo-series glycosphingolipids biosynthesis
-
-
PWY-7838
gluconeogenesis I
-
-
GLUCONEO-PWY
gluconeogenesis II (Methanobacterium thermoautotrophicum)
-
-
PWY-6142
gluconeogenesis III
-
-
PWY66-399
glutaminyl-tRNAgln biosynthesis via transamidation
-
-
PWY-5921
glutathione biosynthesis
-
-
GLUTATHIONESYN-PWY
glutathione-mediated detoxification I
-
-
PWY-4061
glutathione-mediated detoxification II
-
-
PWY-6842
glutathione-peroxide redox reactions
-
-
PWY-4081
glycerol-3-phosphate shuttle
-
-
PWY-6118
glycine betaine degradation I
-
-
PWY-3661
glycine betaine degradation II (mammalian)
-
-
PWY-3661-1
glyoxylate assimilation
-
-
PWY-5744
glyoxylate cycle
-
-
GLYOXYLATE-BYPASS
guadinomine B biosynthesis
-
-
PWY-7693
heme degradation I
-
-
PWY-5874
histamine biosynthesis
-
-
PWY-6173
homocysteine and cysteine interconversion
-
-
PWY-801
homoglutathione biosynthesis
-
-
PWY-6840
hydrogen sulfide biosynthesis II (mammalian)
-
-
PWY66-426
icosapentaenoate biosynthesis II (6-desaturase, mammals)
-
-
PWY-7049
icosapentaenoate metabolites biosynthesis
-
-
PWY-8399
incomplete reductive TCA cycle
-
-
P42-PWY
indole glucosinolate activation (intact plant cell)
-
-
PWYQT-4477
isoprene biosynthesis II (engineered)
-
-
PWY-7391
ketogenesis
-
-
PWY66-367
L-alanine biosynthesis I
-
-
ALANINE-VALINESYN-PWY
L-arabinose degradation II
-
-
PWY-5515
L-arginine biosynthesis I (via L-ornithine)
-
-
ARGSYN-PWY
L-arginine biosynthesis II (acetyl cycle)
-
-
ARGSYNBSUB-PWY
L-arginine biosynthesis IV (archaea)
-
-
PWY-7400
L-arginine degradation XIII (reductive Stickland reaction)
-
-
PWY-8187
L-arginine degradation XIV (oxidative Stickland reaction)
-
-
PWY-6344
L-asparagine biosynthesis III (tRNA-dependent)
-
-
PWY490-4
L-citrulline biosynthesis
-
-
CITRULBIO-PWY
L-citrulline degradation
-
-
CITRULLINE-DEG-PWY
L-cysteine biosynthesis III (from L-homocysteine)
-
-
HOMOCYSDEGR-PWY
L-cysteine biosynthesis VI (reverse transsulfuration)
-
-
PWY-I9
L-glutamate biosynthesis I
-
-
GLUTSYN-PWY
L-glutamine degradation I
-
-
GLUTAMINDEG-PWY
L-isoleucine biosynthesis I (from threonine)
-
-
ILEUSYN-PWY
L-isoleucine biosynthesis II
-
-
PWY-5101
L-isoleucine biosynthesis III
-
-
PWY-5103
L-isoleucine biosynthesis IV
-
-
PWY-5104
L-isoleucine biosynthesis V
-
-
PWY-5108
L-isoleucine degradation I
-
-
ILEUDEG-PWY
L-isoleucine degradation II
-
-
PWY-5078
L-isoleucine degradation III (oxidative Stickland reaction)
-
-
PWY-8184
L-leucine biosynthesis
-
-
LEUSYN-PWY
L-leucine degradation I
-
-
LEU-DEG2-PWY
L-leucine degradation III
-
-
PWY-5076
L-leucine degradation IV (reductive Stickland reaction)
-
-
PWY-7767
L-leucine degradation V (oxidative Stickland reaction)
-
-
PWY-8185
L-lysine biosynthesis IV
-
-
LYSINE-AMINOAD-PWY
L-lysine biosynthesis V
-
-
PWY-3081
L-lysine degradation II (L-pipecolate pathway)
-
-
PWY66-425
L-lysine degradation V
-
-
PWY-5283
L-lysine degradation XI
-
-
LYSINE-DEG1-PWY
L-methionine degradation I (to L-homocysteine)
-
-
METHIONINE-DEG1-PWY
L-methionine salvage from L-homocysteine
-
-
ADENOSYLHOMOCYSCAT-PWY
L-threonine degradation V
-
-
PWY66-428
L-valine biosynthesis
-
-
VALSYN-PWY
L-valine degradation I
-
-
VALDEG-PWY
L-valine degradation II
-
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PWY-5057
L-valine degradation III (oxidative Stickland reaction)
-
-
PWY-8183
lacto-series glycosphingolipids biosynthesis
-
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PWY-7839
leukotriene biosynthesis
-
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PWY66-375
linoleate metabolites biosynthesis
-
-
PWY-8395
lipoxin biosynthesis
-
-
PWY66-392
malate/L-aspartate shuttle pathway
-
-
MALATE-ASPARTATE-SHUTTLE-PWY
maresin biosynthesis
-
-
PWY-8356
methylaspartate cycle
methylglyoxal degradation III
-
-
PWY-5453
mevalonate pathway I (eukaryotes and bacteria)
-
-
PWY-922
mevalonate pathway II (haloarchaea)
-
-
PWY-6174
mevalonate pathway III (Thermoplasma)
-
-
PWY-7524
mevalonate pathway IV (archaea)
-
-
PWY-8125
mixed acid fermentation
-
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FERMENTATION-PWY
monoacylglycerol metabolism (yeast)
-
-
PWY-7420
N-acetylneuraminate and N-acetylmannosamine degradation I
-
-
PWY0-1324
neolacto-series glycosphingolipids biosynthesis
-
-
PWY-7841
nicotine degradation I (pyridine pathway)
-
-
P181-PWY
nitric oxide biosynthesis II (mammals)
-
-
PWY-4983
odd iso-branched-chain fatty acid biosynthesis
-
-
PWY-8174
oleate beta-oxidation
-
-
PWY0-1337
oleate biosynthesis III (cyanobacteria)
-
-
PWY-7587
ophthalmate biosynthesis
-
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PWY-8043
palmitate biosynthesis I (type I fatty acid synthase)
-
-
PWY-5994
palmitoyl ethanolamide biosynthesis
-
-
PWY-8055
pentachlorophenol degradation
-
-
PCPDEG-PWY
pentose phosphate pathway (oxidative branch) I
-
-
OXIDATIVEPENT-PWY
peptido-conjugates in tissue regeneration biosynthesis
-
-
PWY-8355
phosphatidate biosynthesis (yeast)
-
-
PWY-7411
phosphatidate metabolism, as a signaling molecule
-
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PWY-7039
phosphatidylcholine biosynthesis I
-
-
PWY3O-450
phosphatidylcholine biosynthesis II
-
-
PWY4FS-2
phosphatidylcholine biosynthesis III
-
-
PWY4FS-3
phosphatidylcholine biosynthesis IV
-
-
PWY4FS-4
phosphatidylcholine biosynthesis V
-
-
PWY-6825
phospholipases
-
-
LIPASYN-PWY
phosphopantothenate biosynthesis I
-
-
PANTO-PWY
phosphopantothenate biosynthesis II
-
-
PWY-3961
plasmalogen biosynthesis I (aerobic)
-
-
PWY-7782
procollagen hydroxylation and glycosylation
-
-
PWY-7894
protectin biosynthesis
-
-
PWY-8357
protein N-glycosylation processing phase (plants and animals)
-
-
PWY-7919
pyridoxal 5'-phosphate salvage II (plants)
-
-
PWY-7204
pyrimidine deoxyribonucleotides biosynthesis from CTP
-
-
PWY-7210
pyruvate fermentation to propanoate I
-
-
P108-PWY
reductive TCA cycle I
-
-
P23-PWY
reductive TCA cycle II
-
-
PWY-5392
resolvin D biosynthesis
-
-
PWY66-397
retinoate biosynthesis I
-
-
PWY-6872
S-adenosyl-L-methionine salvage II
-
-
PWY-5041
spermine biosynthesis
-
-
ARGSPECAT-PWY
sphingolipid biosynthesis (mammals)
-
-
PWY-7277
sphingolipid biosynthesis (plants)
-
-
PWY-5129
sphingomyelin metabolism
-
-
PWY3DJ-11281
stigma estolide biosynthesis
-
-
PWY-6453
superpathway of coenzyme A biosynthesis III (mammals)
-
-
COA-PWY-1
superpathway of glyoxylate cycle and fatty acid degradation
-
-
PWY-561
superpathway of polyamine biosynthesis II
-
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POLYAMINSYN3-PWY
TCA cycle I (prokaryotic)
-
-
TCA
TCA cycle II (plants and fungi)
-
-
PWY-5690
TCA cycle III (animals)
-
-
PWY66-398
TCA cycle IV (2-oxoglutarate decarboxylase)
-
-
P105-PWY
TCA cycle V (2-oxoglutarate synthase)
-
-
PWY-6969
TCA cycle VIII (Chlamydia)
-
-
TCA-1
terminal O-glycans residues modification (via type 2 precursor disaccharide)
-
-
PWY-7434
testosterone and androsterone degradation to androstendione (aerobic)
-
-
PWY-6943
tetrapyrrole biosynthesis I (from glutamate)
-
-
PWY-5188
tetrapyrrole biosynthesis II (from glycine)
-
-
PWY-5189
theophylline degradation
-
-
PWY-6999
thymine degradation
-
-
PWY-6430
triacylglycerol degradation
-
-
LIPAS-PWY
type IV lipoteichoic acid biosynthesis (S. pneumoniae)
-
-
PWY-7818
uracil degradation I (reductive)
-
-
PWY-3982
urea cycle
UTP and CTP dephosphorylation I
-
-
PWY-7185
UTP and CTP dephosphorylation II
-
-
PWY-7177
valproate beta-oxidation
-
-
PWY-8182
zymosterol biosynthesis
-
-
PWY-6074
cyanate degradation
-
-
CYANCAT-PWY
dolichol and dolichyl phosphate biosynthesis
-
-
PWY-6129
methylaspartate cycle
-
-
PWY-6728
urea cycle
-
-
PWY-4984
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ORGANISM
COMMENTARY
LITERATURE
UNIPROT
SEQUENCE DB
SOURCE
-
209287, 209381, 209386, 438422, 441235, 485967, 485972, 650198, 696112, 713122, 713722, 714699, 714940, 715124, 715153, 717679, 718168, 719539, 721429, 722192, 723027, 723270, 723596, 725062, 726334, 726668, 730038, 730239, 731627, 732697, 736014, 744863, 749543, 754040, 763378
-
-
SwissProt
-
729630, 732550, 740916, 741098, 743056, 753882, 754128, 754903, 758981, 759852, 762716, 764443, 765779
UniProt
genes CCT1-5, 6A, 7, and 8 encoding subunits CCT-alpha, CCT-beta, CCT-gamma, CCT-delta, CCT-epsilon, CCT-zeta, CCT-eta, and CCT-theta
P28480, Q5XIM9, Q6P502, Q7TPB1, Q68FQ0, Q3MHS9, D4AC23, D4ACB8
UniProt
inducible isozyme HO-1, constitutive isozyme HO-2
UniProt
Sprague-Dawley
2271, 2423, 135460, 135465, 137135, 137149, 208432, 285217, 285357, 286014, 286023, 286647, 286665, 286827, 287336, 389979, 389981, 391706, 438005, 440196, 440197, 440203, 440228, 440230, 440236, 485053, 485054, 485559, 485599, 485605, 486295, 486297, 486298, 486323, 486489, 486490, 486502, 487123, 487429, 487488, 487492, 487493, 487494, 487570, 487978, 488102, 488120, 489307, 489405, 489421, 489870, 489934, 636612, 636888, 637267, 637288, 639901, 639979, 640017, 640393, 640395, 640399, 640585, 640592, 640830, 641391, 641392, 644829, 644832, 644955, 644958, 644967, 644973, 644980, 644985, 645390, 645717, 645726, 645727, 645728, 646406, 646570, 653657, 667146, 667150, 669600, 669911, 677467, 677489, 677945, 678098, 679127, 679298, 682272, 683003, 684981, 687757, 691394
-
-
Please wait a moment until the data is sorted. This message will disappear when the data is sorted.
SOURCE TISSUE
ORGANISM
UNIPROT
COMMENTARY
LITERATURE
SOURCE
-
granuloma pouch model of granulation tissue, organ culture
-
expression of MMP-8 does not change significantly in ovariectomized rat
-
mucosa, urothelium, no FAAH immunoreactivity in other structures of the bladder
-
in the urine of the fatigued rats, the ALA level increases (approximately 2fold) as compared with that of the control rats
additional information
-
arteries from hypertensive rats, vascular PDE1A, PDE1B, PDE1C, and PDE5 isoforms
-
PDE 1 vascular expression is increased in arteries from angiotensin II hypertensive rats
-
PDE5 vascular expression is decreased in arteries from angiotensin II hypertensive rats compared to control rats
-
transcriptional regulation of ACE2 mRNA in astrocytes is dependent on the relative concentrations of both angiotensin II and angiotensin(17) as well as on interaction with their respective receptors
-
plasma ALA level of the fatigued rats is slightly higher (approximately 1.4fold) than that of the control or food-restricted animals
-
in situ and in vitro enzymatic activity of transglutaminase isoforms on brain tissue sections and brain extract, monitoring of differences in post-translational protein modifications during neurodegeneration, overview. TG6 shows only a faint vascular signal as compared to a prominent cellular staining in rat tissue
-
increased expression of 12/15-LOX, predominantly in neurons, and elevated production of 12(S)-hydroperoxyicosatetraenoate and 15(S)-hydroperoxyicosatetraenoate in ischemic brain
-
the distributions of H3-K4 mono-, di-, and tri-methylated histones exhibit exactly the same pattern as the LSD1 protein, immunofluoresecence histochemic analysis, overview
-
transcriptional regulation of ACE2 mRNA in astrocytes is dependent on the relative concentrations of both angiotensin II and angiotensin(17) as well as on interaction with their respective receptors
-
enzyme activity is significantly elevated at 8 h after intradermal injection of carageenan or urate crystals, falling to normal levels by day 3
-
restricted to the canalicular membrane domain of hepatocytes
-
activity in colonic tissue is 25-50times lower than in liver
-
activity is 20fold lower in colonic mucosa than in liver
-
colonic mucosa: normal mucosa, non-malignant mucosa in azomethane treated animals, low activity in azomethane-induced tumor tissue
-
enzyme activity is equal to or only 2fold lower than in liver
-
normal, non-malignant. Low activity in tumour cells
-
jejunal sucrase-isomaltase gene is induced during postnatal development
-
inner medullary collecting ducts, proteomic analysis of the cytoplasmic fraction of inner medullary collecting ducts, overview
-
enzyme activity is significantly elevated at 8 h after intradermal injection of carrageenan or urate crystals, falling to normal levels by day 3
-
expression of isozymes NTPDase1, -2, and -8 in distinct liver compartments in normal and fibrotic rat liver
-
HMG-CoA reductase activity is higher in both female and male Nagase analbumimetic rats than in Sprague-Dwwley rats. Ovariectomy results in no significant changes in total hepatic HMG-CoA reductase in female Sprague-Dawley rats
-
modified HMG-CoA reductase and low density lipoprotein receptor regulation is deeply involved in age-related hypercholesterolemia
-
alveolar macrophages purified from the lung by lavage, and interstitial macrophages. Inflammatory cells express high levels of XOR activity, while in resident alveolar macrophage the enzyme content is extremely low prior to cytokine insufflation
-
endogenous GPX4 is mainly expressed in neurons, usage of primary cultured cortical neurons
-
neurons of the tuberomammillary nucleus of the posterior hypothalamus
-
nitrergic neurons in the rat stomach, the myenteric cell bodies have single axons, type I morphology and a wide range of sizes. Nitrergic terminals do not provide baskets of terminals around myenteric neurons. The nitrergic neuron populations in the stomach supply the muscle layers and intramural arteries, but, unlike in the intestine, gastric interneurons do not express nNOS
-
primary cortical neurons, increased expression of 12/15-LOX, predominantly in neurons, and elevated production of 12(S)-hydroperoxyicosatetraenoate and 15(S)-hydroperoxyicosatetraenoate in ischemic brain
-
primary sympathetic and cultured primary, isozyme CTbeta2 mRNA and protein are abundant in distal axons of mouse sympathetic neurons, whereas isozyme CTalpha mRNA and protein are not detected
-
enzyme content decreases 0.7fold after running exercise for 5 weeks
-
soleus slow-twitch oxidative, RG, red gastrocnemius fast-twitch oxidative glycolytic, and WG, white gastrocnemius fast-twitch glycolytic muscles
-
nitrergic neurons in the rat stomach comprising similar proportions of myenteric neurons, about 30%, in all gastric regions, e.g. the longitudinal, circular and oblique layers of the external muscle, the muscularis mucosae and arteries within the gastric wall
additional information
-
a higher proportion of doubly-capped 26S proteasome (19S-20S-19S) in the brain cortex than in the liver or kidney
additional information
-
BCKD protein expression is higher in primarily cultured cortical neurons than in astrocytes, whereas pBCKD protein level is higher in astrocytes than in cortical neurons
additional information
-
determination of NADPH diaphorase staining in preganglionic terminals, staining generally ascribed to NADH diaphorase activity in aldehyde-treated tissues
additional information
-
enzyme activity in rats of different strains and with different sexes, the enzyme is upregulated in both female and male Nagase analbuminemic rats compared to Sprague-Dawley rats, overview
additional information
-
enzyme tissue localization by in situ immunohistochemistry, overview
additional information
-
immunohistochemic enzyme and NADPH histochemic analysis, distributions of nNOS neurons and their terminals throughout the rat stomach, overview. NADPH diaphorase is the colour reaction that reveals the presence of NADPH oxidases, and because nNOS is a NADPH oxidase, it is revealed by NADPHd histochemistry
additional information
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immunolocalization of histamine, with rabbit anti-L-histidine decarboxylase (HDC) antiserum, within the tuberomammillary nucleus is validated using carbodiimide. Rapid eye movement sleep deprivation (REM-SD) increases immunoreactive L-histidine decarboxylase by day 5, and it remains elevated in both dorsal and ventral aspects of the tuberomammillary complex
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light-driven translocation of PIPKIIalpha from the rod inner segment to rod outer segment, and subsequent binding to the ROS membrane
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no glutamine transaminase activity in skeletal muscle, testis, spleen, pancreas, lung and intestine
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not in leukocytes and ascites tumor cells
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TG6 expression seems to localize to neurons but not to astrocytes or microglia
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the enzyme activity decreases with age in all the tissues studied
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LOCALIZATION
ORGANISM
UNIPROT
COMMENTARY
GeneOntology No.
LITERATURE
SOURCE
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tPA activity in both the cellular extract and the supernatant of cultured astrocytes
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tPA activity in both the cellular extract and the supernatant of cultured astrocytes
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associated with membranes, structural integrity of the microsomal membranes is essential for activity
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rough microsomes, integral part of rough endoplasmic reticulum, exposed to cytoplasmic side
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the enzyme carries dual nuclear localization signals
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GGTalpha and GGTbeta are enriched in synaptosome and postsynaptic density fractions from P14 hippocampus
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GGTalpha and GGTbeta are enriched in synaptosome and postsynaptic density fractions from P14 hippocampus
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additional information
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although both hepatic microsomes and cytosol exhibit RALDHs enzyme activity in the presence of NADP+ or NAD+, the contribution of hepatic microsomes to all-trans retinoic acid formation is less than that of hepatic cytosol. Hepatic cytosol catalyzes the oxidation of retinal into all-trans retinoic acid with NAD+ or NADP+ as cofactor, but the cytosolic RALDHs activity prefers NAD+, evidenced by greater contribution of NAD+-dependent all-trans retinoic acid formation
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additional information
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enzyme is not associated with synaptosomes and myelin
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subcellular distribution is dependent on the developmental stage
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additional information
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the spatiotemporal expression pattern of GGT is correlated with the synaptogenesis in vivo
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additional information
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unlike findings in classical calpains, which are characterized as being mainly cytosolic, CAPN5 is predominantly a noncytosolic calpain, present in the nucleus in the nucleic acidbinding protein fraction. The enzyme is associated with nuclear promyelocytic leukemia protein bodies
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LINKS TO OTHER DATABASES (specific for Rattus norvegicus Sprague-Dawley)
SILVA: 16S/18S rRNA, 23S/28S rRNA
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Release 2023.1 (January 2023)
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