「polymerase」の共起表現一覧(1語右で並び替え)
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which encode their own (single subunit) RNA | polymerase, a common characteristic among its members. |
It is a specific inhibitor of DNA | polymerase A,D in eukaryotic cells and in some viruses |
thesis of cDNA, as well as DNA-dependent DNA | polymerase activity that copies the sense cDNA strand i |
imulates T4 polynucleotide kinase and T7 RNA | polymerase activity |
Pol I: implicated in DNA repair; has 5'->3' | polymerase activity, and both 3'->5' exonuclease activi |
imulates T4 polynucleotide kinase and T7 RNA | polymerase activity, it binds to and precipitates DNA a |
end as this maximizes probability of Taq DNA | polymerase adding the terminal adenosine overhang. |
When the | polymerase advances along the DNA sequence after adding |
that accumulate ahead of a translocating DNA | polymerase, allowing DNA replication to continue unhind |
l molecules modulating the function of human | polymerase alpha which at a time modulates proliferatio |
creasing the concentration of the chosen DNA | polymerase also confers some resistance to polymerase-t |
RNA | polymerase and DNA polymerase III then replicate the si |
The RNA segments are first elongated by DNA | polymerase and then synthesized by primase. |
aining groups (phosphotransferase, including | polymerase and kinase) |
quaternary structure include hemoglobin, DNA | polymerase, and ion channels. |
ows the sigma S factor to associate with RNA | polymerase and direct the expression of the stationary |
Primase is an RNA | polymerase, and it can add a primer to an existing stra |
fic than the direct interactions between the | polymerase and the template DNA strand; because the rat |
s recognised as a termination signal for RNA | polymerase and the operon is not transcribed. |
transferase, cis-prenyl transferase, rubber | polymerase, and rubber prenyltransferase. |
These primers are then extended by a DNA | polymerase and a copy of the strand is made after each |
These genes encode a subunit of RNA | polymerase, and it is hypothesized that Lacto-rpoB RNA |
genetic systematic analyses of proteins (RNA | polymerase and viral coat). |
inae, but do not contain a phage-encoded RNA | polymerase and show greater differences at the genome o |
In 1989 Science magazine named Taq | polymerase as its first "Molecule of the Year". |
ng primer and incubated with the enzymes DNA | polymerase, ATP sulfurylase, luciferase and apyrase, an |
The | polymerase binds to the primer-template hybrid and begi |
Structure of Taq DNA | Polymerase bound to a DNA octamer |
Following base excision, the | polymerase can re-insert the correct base and replicati |
important in order to perform PCR since DNA | polymerase can act only on DNA templates. |
From the hairpin loop, a DNA | polymerase can then use it as a primer to transcribe a |
DNA | polymerase cannot add primers, and therefore, needs pri |
o the Book of Mormon to multiple articles on | polymerase chain reactions where he was the lead author |
ortant because it produces an enzyme used in | polymerase chain reaction laboratory procedures central |
menon was not feasible until the 1980s, when | polymerase chain reaction techniques for amplification |
Polymerase chain reaction itself is the process used to | |
overed that this enzyme could be used in the | polymerase chain reaction (PCR) process for amplifying |
Hot Start PCR is a modified form of | Polymerase chain reaction (PCR) which avoids non-specif |
Nested | polymerase chain reaction is a modification of polymera |
The annealing temperature during a | polymerase chain reaction determines the specificity of |
STSs can be easily detected by the | polymerase chain reaction (PCR) using specific primers. |
are used in biochemical experiments such as | polymerase chain reaction (PCR) or DNA sequencing. |
CYP2D6 genotype was determined by | polymerase chain reaction-restriction fragment length p |
In low concentrations, it is used with | polymerase chain reactions to increase yield and specif |
Nonspecific primer binding obscures | polymerase chain reaction results, as the nonspecific s |
nzyme-Linked Immunosorbent Assay (ELISA) and | polymerase chain reaction (PCR). |
od samples may also be achieved by using the | polymerase chain reaction (PCR). |
Polymerase Chain Reaction (PCR), from a sample of blood | |
The target DNA undergoes the first run of | polymerase chain reaction with the first set of primers |
Isothermal amplification is similar to the | polymerase chain reaction (PCR) but does not require th |
possible the invention of a procedure called | polymerase chain reaction. |
been used for disposable microplates for the | polymerase chain reaction (PCR) method of DNA amplifica |
o replication of the damaged molecule by the | polymerase chain reaction. |
urora kinase B was identified in humans by a | polymerase chain reaction screen for kinases that are o |
Smith and Kary Mullis, who had invented the | Polymerase Chain Reaction independently of Smith's work |
ng amplified and quantified by a form of the | Polymerase chain reaction known as Quantitative PCR or |
DNA, in its genetic code, and replicates via | polymerase chain reaction. |
ttached to desired regions on the DNA, and a | polymerase chain reaction (PCR) is employed to discover |
Sodium iodide is used in | polymerase chain reactions, and also (as an acetone sol |
n using molecular diagnostic methods such as | polymerase chain reaction (PCR). |
thod for in vitro DNA amplification like the | polymerase chain reaction (PCR), but that works at cons |
e protein, which can then be replicated in a | polymerase chain reaction to yield a significant amount |
A PCR primer binding site is a site where a | polymerase chain reaction (PCR) primer binds, to prime |
e sequence of interest, subsequent rounds of | polymerase chain reaction can be performed upon the pro |
polymerase chain reaction | |
regions of the extracted DNA by means of the | polymerase chain reaction. |
ng seed tested via a grow out, sweat box, or | polymerase chain reaction method to ensure that it is c |
In recognition of his improvement of the | polymerase chain reaction (PCR) technique, he shared th |
Touchdown | polymerase chain reaction or touchdown style polymerase |
April: Kary Mullis discovers | polymerase chain reaction (PCR). |
Books @ your local library about nested | polymerase chain reacitons |
This pausing of the | polymerase coincides with transcription of the poly-ura |
ture allows gene regulatory proteins and RNA | polymerase complexes to bind to the DNA sequence, which |
ncodes a protein that interacts with the DNA | polymerase delta p50 subunit. |
Since DNA | polymerase delta is involved in resynthesis of excised |
DNA | polymerase delta is an enzyme complex found in eukaryot |
Polymerase delta-interacting protein 3 is an enzyme tha | |
Recently, a DNA | polymerase derived from these bacteria, Bst polymerase, |
e genome from a single replication fork, the | polymerase DNA Pol III is the enzyme primarily responsi |
Use of the thermostable Taq | polymerase eliminates the need for having to add new en |
An example of a core enzyme is a RNA | polymerase enzyme without the sigma factor (σ). |
A | polymerase enzyme is used to extend the chain by adding |
ociates with the promoter it affects the RNA | polymerase enzyme's ability to bind and initiate transc |
nds to a single amino acid change in the DNA | polymerase enzyme, which is an essential enzyme for rep |
atures can be prevented by using "hot-start" | polymerase enzymes whose active site is blocked by an a |
DNA | polymerase eta (Pol η) is a eukaryotic DNA polymerase i |
Polymerase eta is particularly important for allowing a | |
The gene encoding DNA | polymerase eta is POLH, also known as XPV, because loss |
idence that mutation rates (as determined by | polymerase fidelity) are under selection to be neither |
They also use a typical protein primed DNA | polymerase for replication, a property shared with the |
tion factor that affects the affinity of RNA | polymerase for specific promoters on DNA |
re from expression systems; particularly DNA | polymerase for PCR, reverse transcriptase for RNA analy |
nd to operators or promoters, preventing RNA | polymerase from transcribing RNA. |
pressor protein physically obstructs the RNA | polymerase from transcribing the genes. |
the conclusion that it was most notably the | polymerase genes and the HA and NA genes that caused th |
Bst | polymerase has a helicase-like activity, making it able |
tion by stabilizing the formation of the RNA | polymerase holoenzyme enabling faster clearance of the |
in which assists in the formation of the RNA | polymerase holoenzyme, or may operate through a coactiv |
when, in 1969, John Cairns isolated a viable | Polymerase I mutant that lacked the polymerase activity |
omains in the Klenow Fragment (left) and DNA | Polymerase I (right). |
d with transcription termination factor, RNA | polymerase I or TTF1. |
It is transcribed by RNA | polymerase I as part of the 45S precursor that also con |
DNA | polymerase I comes in and fills in the correct nucleoti |
DNA | polymerase I removes the primer, replacing it with DNA, |
cterisation, it quickly became apparent that | Polymerase I was not the enzyme responsible for most DN |
zyme is found as an N-terminal domain of DNA | polymerase I, but some prokaryotes appear to encode a s |
eing repressed, TATA-binding protein and RNA | Polymerase II were still bound to the SER3 DNA in such |
fically, it inhibits the assembly of the RNA | polymerase II transcription complex and DNA polymerase |
nd proposed to guide the modification of RNA | polymerase II transcribed spliceosomal RNAs U1, U2, U4, |
first person to purify and characterise DNA | polymerase II and DNA polymerase III. |
RNA | polymerase II holoenzyme is a form of eukaryotic RNA po |
r element that promotes transcription by RNA | polymerase II when it is located precisely at positions |
transcription factor that is part of the RNA | polymerase II holoenzyme, interacts with promoters cont |
DNA | polymerase II (also known as DNA Pol II or Pol II) is a |
transcriptase, lack LTRs, transcribed by RNA | polymerase II |
asal transcriptional machinery including RNA | polymerase II to the promoter. |
Initiation of transcription by RNA | polymerase II requires the activities of more than 70 p |
MED12, or mediator of RNA | polymerase II trancription, subunit 12 homolog of S. ce |
y subunit cyclin C are components of the RNA | polymerase II holoenzyme complex, which phosphorylates |
Upon ingestion, it binds to the RNA | polymerase II enzyme, effectively causing cytolysis of |
DNA-directed RNA | polymerase II subunit RPB11-a is an enzyme that in huma |
or and binds to the C-terminal domain of RNA | polymerase II holoenzyme, acting as a bridge between th |
The carboxy-terminal domain of RNA | polymerase II typically consists of up to 52 repeats of |
l transcription factors that make up the RNA | polymerase II preinitiation complex. |
l transcription factors that make up the RNA | polymerase II preinitiation complex. |
l transcription factors that make up the RNA | polymerase II preinitiation complex. |
ly or positively affect transcription by RNA | polymerase II (Pol II). |
The enzymes for capping can only bind to RNA | polymerase II ensuring specificity to only these transc |
An Inr for mammalian RNA | polymerase II can be defined as a DNA sequence element |
Upon ingestion, it binds to the RNA | polymerase II enzyme which completely prevents mRNA syn |
protein complex that affects eukaryotic RNA | polymerase II (Pol II) transcription elongation both in |
jal bodies and guide the modification of RNA | polymerase II transcribed spliceosomal RNAs U1, U2, U4, |
jal bodies and guide the modification of RNA | polymerase II transcribed spliceosomal RNAs U1, U2, U4, |
jal bodies and guide the modification of RNA | polymerase II transcribed spliceosomal RNAs U1, U2, U4, |
ation factor (CStF) are transferred from RNA | Polymerase II to the RNA molecule. |
jal bodies and guide the modification of RNA | polymerase II transcribed spliceosomal RNAs U1, U2, U4, |
us 35S promoter (CaMV35S), in which case RNA | Polymerase II is used to express the transcript destine |
02), to cause transcriptional pausing of RNA | polymerase II (see MIM 180660). |
T-box motifs typically present in eukaryotic | polymerase II promoters. |
to science include the identification of RNA | polymerase II(B), the identification of transcriptional |
This gene encodes a subunit of RNA | polymerase II, the polymerase responsible for synthesiz |
They are transcribed by RNA | polymerase II, include both intron and exon, and code f |
It consists of RNA | polymerase II, a subset of general transcription factor |
BRCA1 associates with RNA | polymerase II, and through the C-terminal domain, also |
eneral transcription factors, as well as RNA | polymerase II, and is essential for activator-dependent |
TAF9 RNA | polymerase II, TATA box binding protein (TBP)-associate |
nt and specific attraction to the enzyme RNA | polymerase II. |
amatoxins, amanullin is an inhibitor of RNA | polymerase II. |
hat inhibits transcription elongation by RNA | Polymerase II. |
matoxins, amaninamide is an inhibitor of RNA | polymerase II. |
er amatoxins, ε-amanitin an inhibitor of RNA | polymerase II. |
osphorylated carboxyl-terminal domain of RNA | polymerase II; therefore it is specific to RNAs synthes |
This protein forms a stable complex with RNA | polymerase IIB and is required for transcriptional init |
It was not until the discovery of DNA | polymerase III that the main replicative DNA polymerase |
As a critical component of the DNA | polymerase III holoenzyme, the clamp protein binds DNA |
Once priming is complete, DNA | polymerase III holoenzyme is loaded into the DNA and re |
The beta chain of bacterial DNA | polymerase III is composed of three topologically non-e |
mposed of two identical beta subunits of DNA | polymerase III and hence is referred to as the beta cla |
clamp (also known as β sliding clamp) of DNA | polymerase III in prokaryotes. |
The catalytic mechanism of DNA | polymerase III involves the use of two metal ions in th |
DNA | polymerase III is then able to start DNA replication. |
Eukaryotic 5S rRNA is synthesised by RNA | polymerase III, whereas most other eukaroytic rRNAs are |
6 snRNA genes , which are transcribed by RNA | polymerase III, one of three major nuclear RNA polymera |
o serve as a primer for DNA synthesis by DNA | polymerase III. |
RNA | polymerase III: transcribes genes encoding tRNAs and ot |
eins often bind the C-terminal domain of RNA | polymerase in order to activate polymerase activity. |
Pol III: the main | polymerase in bacteria (responsible for elongation); ha |
Cell Nuclear Antigen (PCNA) assists the DNA | polymerase in the reaction, and Replication protein A ( |
Unlike many viruses they do not have any | polymerase in the virus particle as the genome can be r |
The viral | polymerase incorporates these compounds with non-canoni |
DNA | polymerase incorporates the correct, complementary dNTP |
ral product with anti-HIV activity and a DNA | polymerase inhibitor. |
class of antiviral drugs known as nucleoside | polymerase inhibitors that was created by chemist Jerem |
ative-sense genomes and so must carry an RNA | polymerase inside the virion. |
Hepatitis B virus DNA | polymerase is a hepatitis B viral protein. |
The | polymerase, is a monomeric protein with two distinct fu |
RNA | polymerase is then used to generate long double strande |
If a scanning | polymerase is involved in start site selection, TFIIB m |
DNA | polymerase is added, which copies each fragment repeate |
In biotechnology applications, T7 RNA | polymerase is commonly used to transcribe DNA that has |
Pfu DNA | polymerase, isolated from the archean Pyrococcus furios |
This | polymerase lacks 3' to 5' proofreading activity and, wi |
A DNA | Polymerase may perform this replacement via nick transl |
omains of the metaphorically hand-shaped DNA | polymerase molecule. |
fragments that target the 3'UTR of viral DNA | polymerase mRNA. |
n the coding region of the RNA-dependent RNA | polymerase NS5B. |
xamples include: oligomeric: hemoglobin, DNA | polymerase, nucleosomes and multimeric: ion channels, m |
ack) and when mutations in mitochondrial DNA | polymerase occur. |
stability of the open complex formed by RNA | polymerase on DNA and therefore affect promoter clearan |
RNAPII could affect the conformation of the | polymerase on the DNA, thereby affecting subsequent sta |
nd the sub-nanometer stepping motions of RNA | polymerase on a DNA template. |
Pol V: a Y-family DNA | polymerase; participates in bypassing DNA damage. |
erfering with their interaction with the DNA | polymerase, PCR is inhibited. |
f this enzyme class is ATP:[DNA-directed RNA | polymerase] phosphotransferase. |
s primers for DNA synthesis by bacterial DNA | polymerase Pol III. |
philic bacteria and archaea, such as Pfu DNA | polymerase, possessing a proofreading activity, and are |
200 adenylate residues is added by a nuclear | polymerase post-transcriptionally. |
be converted to positive-sense RNA by an RNA | polymerase prior to translation. |
reduce transcription simply by blocking RNA | polymerase progression along the DNA template. |
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