「nucleotide」の共起表現一覧(1語右で並び替え)
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mide proposes that its biosynthesis involves | nucleotide activation followed by a series of modificat |
xtension of "FAST-P" (protein) and "FAST-N" ( | nucleotide) alignment. |
U), the abnormal base found in the mutagenic | nucleotide analog BrdU. |
al probing, hydroxyl radical probing, SHAPE, | nucleotide analog interference mapping (NAIM), and in-l |
se inhibitors and include the nucleoside and | nucleotide analogues zidovudine (trade name Retrovir), |
e nucleobase analogues such as Aciclovir and | nucleotide analogues. |
el considers only the interactions between a | nucleotide and its nearest neighbors on the nucleic aci |
sphate and H2O, whereas its two products are | nucleotide and phosphate. |
2. Methyl groups on the | nucleotide are seen in the column for the nucleotide co |
ility that two lineages will evolve the same | nucleotide at the same site increases. |
That is, each | nucleotide base of that particular type has a probabili |
roduce purines, which are a component of DNA | nucleotide bases, and also myelin proteins. |
tRNAs in requiring the addition of a guanine | nucleotide before being aminoacylated by the histidine |
tent nucleophile to facilitate transfer of a | nucleotide between UDP-hexoses and hexose-1-phosphates. |
ATP hydrolysis at the catalytic | nucleotide binding sites on subunit A drives rotation o |
ABC proteins have two | nucleotide binding domains (areas where ATP binds to th |
n contains two transmembrane domains and two | nucleotide binding folds. |
he recognition of microbial pathogens, and a | nucleotide binding site for nucleoside triphosphates. |
The tops represent light emission and | nucleotide binding. |
al nutrient required by all living cells for | nucleotide biosynthesis and for the proper metabolic ma |
ve a weak association with genes involved in | nucleotide biosynthesis and transport, including severa |
talyzes the preceding reaction in pyrimidine | nucleotide biosynthesis, the transfer of ribose 5-phosp |
rate-limiting enzyme in the de novo guanine | nucleotide biosynthesis. |
n the AP site and a free 3´-OH on the normal | nucleotide, both of which are stabilized by the Mg2+ io |
k between dopamine and purine synthesis is a | nucleotide called guanosine triphosphate or 'GTP'. |
This region of repeated | nucleotide called telomeres contains non-coding DNA mat |
'-termini of flaviviruses carry a methylated | nucleotide cap, while other members of this family are |
(BER), which repairs damage due to a single | nucleotide caused by oxidation, alkylation, hydrolysis, |
being added by a DNA polymerase to a growing | nucleotide chain, no further nucleotides can be added a |
artificially from oligonucleotides, smaller | nucleotide chains with generally fewer than 30 subunits |
Nucleotide change: A to C | |
extra or missing chromosomes down to single | nucleotide changes. |
mple of these assays is again the use of the | nucleotide coenzymes NADH and NADPH. |
ate kinases regulate the adenine and guanine | nucleotide compositions within a cell by catalyzing the |
f an mRNA molecule and consists of a guanine | nucleotide connected to the mRNA via an unusual 5' to 5 |
for "operon-polarity suppressor" and has the | nucleotide consensus GGCGGUAG. |
feature is two terminal loops that have the | nucleotide consensus RUCCU, where R is either A or G. |
When a | nucleotide containing 5-bromouracil is incorporated int |
The Purine | Nucleotide Cycle is a metabolic pathway in which fumara |
ine biosynthesis and the other in the purine | nucleotide cycle. |
le and plays an important role in the purine | nucleotide cycle. |
ations (GIs) have been published in the NCBI | Nucleotide databases with GIs 77176718 and 77176720. |
Thus a lack of HGPRT may produce a | nucleotide deficiency (specifically: GTP deficiency) di |
osphopyridine diaphorase, triphosphopyridine | nucleotide diaphorase, NADPH2 dehydrogenase, and NADPH: |
measure is defined as the average number of | nucleotide differences per site between any two DNA seq |
ith and jth sequences, πij is the number of | nucleotide differences per nucleotide site between the |
In enzymology, a | nucleotide diphosphatase (EC 3.6.1.9) |
In enzymology, a | nucleotide diphosphokinase (EC 2.7.6.4) is an enzyme th |
ganic phosphate to cleave bonds they release | nucleotide disphosphates), whereas the hydrolytic enzym |
The average | nucleotide diversity in these regions is 1.7%. |
One commonly used measure of | nucleotide diversity was first introduced by Nei and Li |
Nucleotide diversity is a concept in molecular genetics | |
in3 software can be used for calculations of | nucleotide diversity and a variety of other statistical |
TPase activating proteins (GAPs) and guanine | nucleotide exchange factors (GEFs) regulate small GTPas |
ive and active forms is regulated by guanine | nucleotide exchange factors and GAPs. |
IF2 shows increased affinity for its Guanine | nucleotide exchange factor eIF2B. |
ulated by a mechanism involving both guanine | nucleotide exchange and phosphorylation. |
Family also include a guanine | nucleotide exchange factor that may function as an effe |
omain is domain found in a family of guanine | nucleotide exchange factors for Ras-like small GTPases. |
CK-A subfamily of the DOCK family of guanine | nucleotide exchange factors (GEFs) which function as ac |
is the co-chaperone for DnaK, and acts as a | nucleotide exchange factor, stimulating the rate of ADP |
to prokaryotic EF-Ts, serving as the guanine | nucleotide exchange factor for α, catalyzing the releas |
te cell processes through the use of guanine | nucleotide exchange factors. |
, the encoded protein causes the Ras guanine | nucleotide exchange factor RASGRP1 to translocate to th |
observed to associate with eIF-2B, a guanine | nucleotide exchange protein that functions in regulatio |
p are regulated by different sets of guanine | nucleotide exchange factors and GTPase-activating prote |
has been shown that RAP6 has a GEF (guanine | nucleotide exchange factor) activity specific to Rab5 a |
es upstream of the DNA damage and created 12 | nucleotide excised segment. |
first SOS repair mechanism to be induced is | nucleotide excision repair (NER), whose aim is to fix D |
l PIBI(D)S patients have a deficiency in the | nucleotide excision repair of UV-induced DNA damage tha |
Nucleotide excision repair (NER), which repairs damage | |
Excision Enzyme cuts at the | Nucleotide excision repair. |
an be removed by a specific glycosylase, the | nucleotide excision repair enzymes recognize bulky dist |
autosomal recessive genetic defect in which | nucleotide excision repair (NER) enzymes are mutated, l |
ion, transcription coupled repair (TCR), and | nucleotide excision repair (NER). |
bacteria involved in DNA repair mechanism by | nucleotide excision repair, and it is, therefore, somet |
Cyclic | nucleotide gated channel beta 1, also known as CNGB1, i |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
lly those transferring phosphorus-containing | nucleotide groups (nucleotidyltransferases). The system |
Once the first | nucleotide has been found, you determine which nucleoti |
Uridine triphosphate, which is a pyrimidine | nucleotide, has the ability to act as an energy source. |
Nucleotide identities in many places are conserved, and | |
Several regions of high conservation of | nucleotide identity are present throughout the RNA moti |
sium and by aromatic stacking between the 5' | nucleotide in the siRNA and a conserved tyrosine residu |
orithms generate phylogenetic trees for each | nucleotide in a sequence for each species, and determin |
on the detection of pyrophosphate release on | nucleotide incorporation, rather than chain termination |
Ras-binding (IPR003116), GoLoco for guanine | nucleotide inhibitor activity (IPR003109), PX for phosp |
tion of the base pairs as letters-an adenine | nucleotide is abbreviated as A, guanine as G, cytosine |
A cyclic | nucleotide is any nucleotide in which the phosphate gro |
NTP is complementary to the leading template | nucleotide it is incorporated into the growing compleme |
The lariat has the first and the third | nucleotide joined by a 2',5' phosphodiester bond and is |
ing), DPNH kinase, reduced diphosphopyridine | nucleotide kinase, and NADH kinase. |
nomenclature for an explanation of non-GATC | nucleotide letters |
Alterations in extracellular | nucleotide levels can increase or decrease P2 activity |
Light-induced changes in cyclic | nucleotide levels modulate the phosphorylation of phosd |
It has been shown that the 216 | nucleotide long 5' UTR contains internal ribosome entry |
viruses is the NV gene, an approximately 500 | nucleotide long gene located between the glycoprotein ( |
he Dicer enzyme to produce the shorter 21-24 | nucleotide mature sequence. |
cessed by the Dicer enzyme to form the 21-24 | nucleotide mature microRNA. |
Further work on | nucleotide metabolism allowed him to identify nucleosid |
aracterization, glycolate metabolism, cyclic | nucleotide metabolism, protein kinases, and a catalog o |
and negative selection of genes involved in | nucleotide metabolism. |
The mature ~21 | nucleotide microRNAs are processed from hairpin precurs |
These enzymes then perform the | nucleotide modification. |
ecule is a biopolymer composed of 13 or more | nucleotide monomers covalently bonded in a chain. |
This is the most common single | nucleotide mutation. |
Other names in common use include pyrimidine | nucleotide N-ribosidase, and Pyr5N. |
RyhB RNA is a 90 | nucleotide non-coding RNA that down-regulates a set of |
G sites' are regions of DNA where a cytosine | nucleotide occurs next to a guanine nucleotide in the l |
ted by a fluorochrome attached to a specific | nucleotide of a DNA strand. |
e encodes a member of the family of pyridine | nucleotide oxidoreductases. |
In the guanine | nucleotide pathway, there are 2 enzymes involved in con |
e retina, belong to a large family of cyclic | nucleotide PDEs that catalyze cAMP and cGMP hydrolysis. |
roxidase, TPN peroxidase, triphosphopyridine | nucleotide peroxidase, and NADPH2 peroxidase. |
Numerous cyclic | nucleotide phosphodiesterases (PDE) can degrade cGMP by |
The cyclic | nucleotide phosphodiesterases comprise a group of enzym |
ase, 2',3'-cyclic nucleotidase, cyclic 2',3' | -nucleotide 2'-phosphodiesterase, cyclic 2',3'-nucleoti |
o complementary strands of a double-stranded | nucleotide polymer, in the strand which is to be copied |
s defined by the presence of the M346 Single | Nucleotide Polymorphism (SNP) and may therefore be refe |
pidemiology studies have identified a single | nucleotide polymorphism (SNP) which varies between EHV- |
m of the association P-value for each single | nucleotide polymorphism displayed on the Y-axis. |
ilinial) ancestor of all men with the single | nucleotide polymorphism mutation on the Y chromosome kn |
Breast cancer, a mutation or single | nucleotide polymorphism (SNP) in intron 2 of the FGFR2 |
The risk allele is a cluster of 10 single | nucleotide polymorphism in the first intron of FTO call |
ade is generally considered to be the single | nucleotide polymorphism (SNP), M70. |
A single | nucleotide polymorphism (SNP) in ADH1B is rs1229984, th |
A single | nucleotide polymorphism (SNP) in the 3' untranslated re |
A single | nucleotide polymorphism (SNP), a variation at a single |
Val66Met (rs6265) is a single | nucleotide polymorphism in the gene where adenine and g |
us infection who harbor a HSPA1B-1267 single | nucleotide polymorphism have a higher risk for developi |
Ohio State University have shown that single | nucleotide polymorphism A118G in the gene encoding the |
vitamin D receptor gene variants is a single | nucleotide polymorphism in the start codon of the gene |
A single | nucleotide polymorphism, C-116G, in the promoter region |
ld-type protein CYP2C9*1, at least 32 single | nucleotide polymorphisms (SNPs) have been reported with |
More than 50 single | nucleotide polymorphisms (SNPs) have been described in |
dividuals carrying point mutations or single | nucleotide polymorphisms in their genes for factor H ma |
morphisms are known most of which are single | nucleotide polymorphisms (SNP). |
of DNAFETs can be used for detecting single | nucleotide polymorphisms (causing many hereditary disea |
Numerous single | nucleotide polymorphisms of this gene are significantly |
ensional LC procedure for identifying single | nucleotide polymorphisms (SNPs) in proteins. |
sequence length polymorphisms, SSLPs, single | nucleotide polymorphisms), they become valuable genetic |
including detection of mutations and single | nucleotide polymorphisms, analysis of DNA methylation, |
and some of these variations, called single | nucleotide polymorphisms, or SNPs. |
with a combination of FTO and INSIG2 single | nucleotide polymorphisms. |
shown a mis-sense transversion of A to T at | nucleotide position 364, which results in substitution |
ding site is not known, the number of random | nucleotide positions in the template must be large |
iRNAs are transcribed as an approximately 70 | nucleotide precursor and subsequently processed by the |
miRNAs are transcribed as ~70 | nucleotide precursors and subsequently processed by the |
microRNAs are transcribed as ~70 | nucleotide precursors and subsequently processed by the |
Animal miRNAs are transcribed as ~70 | nucleotide precursors and subsequently processed by the |
microRNAs are transcribed as ~70 | nucleotide precursors and subsequently processed by the |
miRNAs are transcribed as ~70 | nucleotide precursors (modelled here) and subsequently |
The miRNAs are transcribed as ~70 | nucleotide precursors and subsequently processed by the |
This results in the depletion of | nucleotide precursors and inhibition of DNA, RNA, and p |
Also, if the body needs | nucleotide precursors of DNA for growth and synthesis, |
t uses the enzyme DNA ligase to identify the | nucleotide present at a given position in a DNA sequenc |
This is then followed by detection by either | nucleotide probes (for a northern blot and Southern blo |
coronavirus genomes contains a conserved ~55 | nucleotide pseudoknot structure which is necessary for |
Other names in common use include | nucleotide pyrophosphatase, and nucleotide-sugar pyroph |
ucleotide triphosphate diphosphohydrolases), | Nucleotide pyrophosphatase/phosphodiesterase (NPP)-type |
Other names in common use include | nucleotide pyrophosphokinase, ATP:nucleotide pyrophosph |
U21 snoRNA has a 13 | nucleotide region of complementarity with an invariant |
The RprA RNA gene encodes a 106 | nucleotide regulatory non-coding RNA. |
snoRNA although the selection of the target | nucleotide requires the antisense element and the conse |
It cleaves base-paired | nucleotide residues. |
The 109 | nucleotide RNA is thought to be composed of three stem- |
35 amino acid peptide toxin (ldrD) and a 60 | nucleotide RNA antitoxin. |
ransferase converts hypoxanthine into IMP in | nucleotide salvage. |
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