ขั้นตอนการจำลองตัวเองของโปรคาริโอตก

The process of replication services ot Pro rakhaGetting started (Initiation) in the DNA of bacteria, it is the start point for DNA replication. Incoming protein to DNA at the origin it relaxes HELIOS case hydrogen bond between the cutting wire into DNA. DNA by Ding get protein to prevent creating a hydrogen bond.DNA generation cables (Elongation) is when two DNA string of DNA polymerase III separately and then to point to create a new line because the DNA DNA pol III is the ability to create a new line from DNA 5 ' to 3 ' only. A template is a string of 3 ' to 5 ', but the DNA template with a 3 ' to 5 ' and 5 ' to 3 ', so. To create a string of DNA, it's divided into 2.Continuous (Leading strand) string is a string that is a 3 ' to 5 ' DNA polymerase III in this line to create DNA cables. Started by Primase generate primers that are RNA alongside 10-nucleotide 26 tide into the match with the DNA polymerase from the DNA extraction point III. dNTPs in the direction 5 ' to 3 ' so.The airline is not continuous (Lagging strand), because the template DNA is the 5 ' to 3 ' The creation of the DNA, so long as one does not have to happen, but it will use DNA, DNA pol III to bend over, DNA polymerase III created the DNA cables in the direction 5 ' to 3 ' is a small piece of. This is a small piece called piece o Casa (Okazaki fragment) created by Primase is RNA primers alongside a piece o Casa each hotels. DNA polymerase III subunit beta's to catch the primers and DNA polymerase III when it is connected to all the pieces to create a new piece. The original beta subunit is. New beta subunit will come into the match with a stunning primers here continuously.The authorization. Part of that is the RNA primers are checked by DNA polymerase I and create a DNA repair part cut off. The missing point occurs on a string of DNA polymerase I is not because of DNA per fotfo Dal ester bond 5 ' end of the intersections will be linked by DNA Lai guest by continuing to cut once. Best line is continuing to cut the price of primers o Saki every piece.The end (Termination) during each starting point will be the end of the assigned applications. There are 20 double bass called a protein sequence ter remembered this position came in DNA polymerase III is easy to handle, to know that DNA model to come around.Karina Yu otThe simulation itself at the University complex than Karina ot. By default, the protein spots remembered this particular position is added to DNA relaxes. There are many types of DNA polymerase by using DNA polymerase α and nucleus in the DNA polymerase δ by DNA polymerase III is similar to the DNA polymerase α acts on DNA polymerase δ Pro rakha River ot act like DNA polymerase III beta units of DNA polymerase and DNA polymerase I act similar to ε, rakha ot services. The end of the assigned application in u Karina ot is related to the synthesis of special structures called Te lo Premier at end of chromosome.

The process of self replication of prokaryotic the
beginning (Initiation) in the DNA of bacteria that are starting points for DNA replication. A protein to stimulate DNA at the beginning of the release. Heligoland case to cut the hydrogen bonds between DNA strands. DNA by Golding protein shake to prevent hydrogen bonding to the
creation of DNA, new lines (Elongation) on DNA, the two separated, then the DNA polymerase III came to the junction to DNA because DNA pol III. has the ability to create DNA from 5 'to 3', which is like a template that is a 3 'to 5', but DNA templates with a 3 'to 5' and 5 'to 3', thus creating a line. DNA is divided into two types:
Line, continuous (Leading strand) is a line that is 3 'to 5' in the DNA polymerase III to create DNA have steadily started by Primase build primer on the art. RNA short line size 10-26 nucleotide come to grips with DNA directly extracted from the DNA polymerase III will fill the dNTPs in the direction 5 'to 3' indefinitely
line is not continuous (Lagging. strand) because this DNA template, a 5 'to 3' DNA to create a long line to it so it can not happen. But using DNA to bend the DNA pol III DNA to create new DNA polymerase III in the direction 5 'to 3' is a small piece. The piece is a piece Ocala Misaki (Okazaki fragment) by Primase build primers are RNA short line. To create a piece o Casa Guillermo each piece. Beta subunit of DNA polymerase III is to capture the primer and DNA polymerase III is connected to the end pieces to create new pieces. Beta subunits of the original is lost. The new beta subunits to come to grips with the following primers. This is so
checked. The primers are RNA will be checked with DNA polymerase I and DNA repair the cut. The break occurred on the DNA, because DNA polymerase I do not have to be bound phospholipid esters in the 5 'end of the intersection will be connected with. Guest coli DNA By continuing to cut once. The line is constantly cutting primer parts of Ocala Misaki all
end. (Termination) between the beginning of each of the end of replication by a 20 bp called ter sequence, which are proteins that recognize this position, he was arrested and told DNA polymerase III that DNA replication. Then comes the anniversary of eukaryotes replication in eukaryotes, there are more complicated. The starting point is a protein that recognizes the particular he urged the DNA relaxes DNA polymerase There are many types of nuclei using DNA polymerase α and DNA polymerase δ by DNA polymerase α acts like DNA polymerase III in prokaryote. eukaryota DNA polymerase δ acts as a beta unit of DNA polymerase III and DNA polymerase ε similar acts in prokaryotic DNA polymerase I termination of replication in eukaryotes Connecticut. With the synthesis of a special structure called the telomere at the ends of chromosomes.

The replication of horseshoe crab
.Start (Initiation) in the DNA of bacteria to a point for starting simulation DNA. Protein to encourage DNA at the beginning such relaxed. Heli case cut hydrogen bonding between DNA.Creating a new Long Branch (Elongation) when DNA both lines were separated DNA polymerase III come ตรงจุดแยก to create a long branch line. Because DNA pol III features to create a long branch line from the new 5 'to 3'.3 'to 5', but DNA templates are both 3 'to 5' and 5 'to 3', thus creating a line of DNA is divided as follows 2
.Continuous lines (Leading strand) is a line 3 'to 5' in this line DNA polymerase III will create a new long branch has continued. Start by creating a Primase primer RNA short line size 10 - 26 nucleotidesThen DNA polymerase III will fill dNTPs into the direction 5 'to 3' around
.Discrete line (Lagging strand) because this line DNA template is 5 'to 3' DNA structure is a general สายยา it happened. But the method is used to line DNA bend through DNA pol III to DNA polymerase III.5 'to 3' into small pieces, called small pieces of this piece Okazaki (Okazaki fragment) by Primase build enterprise is a short line เมอร์ที่ RNA For the Okazaki each piece of DNA subunit beta polymerase III.DNA polymerase III when all the pieces to create new pieces. Subunit beta originally is lost. Subunit beta is new to catch with a primer next be passive
.Check part of the primers are RNA will be checked with DNA polymerase I and construct DNA repair section. The point of what happened on the line due to DNA DNA polymerase I not on bonding phosphoric ester Forex directory at the end of the 5 'DNA ligase by continuous lines are cut once. The line to cut discrete primer of parts, Okazaki every piece
.The end (Termination) between the beginning of each will be the end of RAE apps in the 20 base pairs, called ter sequence. Which is a protein that recognizes this position to catch to tell DNA polymerase III.Eukaryotic cell


.Replication in eukaryotic cell is more complex than By the beginning there is a protein that remembers this position, especially to encourage relaxed DNA DNA polymerase types by in the nucleus. DNA polymerase α and DNA polymerase δ by DNA polymerase α.DNA polymerase III in prokaryote DNA polymerase δ duties similar to unit of DNA beta and polymerase III DNA polymerase ε duties similar to DNA polymerase I in prokaryote, end of RAE apps in the eukaryotic cell.