Difference between revisions of "Part:BBa K2259088"

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This is a ColE1 replicon with knocked-out RNA I promoter. A copy of RNA I is then placed next to RNA II.
 
This is a ColE1 replicon with knocked-out RNA I promoter. A copy of RNA I is then placed next to RNA II.
  
This construct acts as a RNA I promoter knock-out control. When RNA I promoter is disabled, plasmid copy number increases dramatically (1000-2000 copies per cell). It is difficult to tell if RNA I promoter is disabled completely, because the measurements at run-away replication are not precise enough. Yet, if RNA I gene copy is placed next to knocked-out origin of replication and the plasmid copy number goes down to wildtype amounts, we can say with certainty RNA I promoter is completely disabled.
+
This construct acts as a RNA I promoter knock-out control. When RNA I promoter is disabled, plasmid copy number increases dramatically (1000-2000 copies per cell). It is difficult to tell if RNA I promoter is disabled completely because the measurements at run-away replication are not precise enough. Yet, if RNA I gene copy is placed next to knocked-out origin of replication and the plasmid copy number goes down to wildtype amounts, we can say with certainty RNA I promoter is completely disabled.
  
 
See how this part fits into the whole SynORI framework [[#About SynORI|by pressing here!]]
 
See how this part fits into the whole SynORI framework [[#About SynORI|by pressing here!]]
Line 27: Line 27:
 
===ColE1 plasmid replication overview===
 
===ColE1 plasmid replication overview===
  
[[Image:Cole1 horizontal cropped.png|center|500px|thumb|<b>Figure 1. </b> Main principles of ColE1 plasmid family replication. (Citation needed)]]
+
[[Image:Cole1 horizontal cropped.png|center|frame|300px|<b>Figure 1. </b> Main principles of ColE1 plasmid family replication]]
<b>ColE1-type plasmid replication begins with synthesis of plasmid encoded RNA II</b> (also called primer transcript) by RNA polymerase which initiates transcription at a site 555bp upstream of origin of replication. The RNA transcript forms a RNA - DNA hybrid with template DNA near the origin of replication. Hybridized RNA is then cleaved at the replication origin by RNAse H and serves as a primer for DNA synthesis by DNA polymerase I (Figure 1. A).
+
  
<b>Initiation of replication can be inhibited by plasmid encoded small RNA, called RNA I </b>. Synthesis of RNA I starts 445 bp upstream of the replication origin and proceeds in the direction opposite to that of RNA II synthesis, and terminates near the RNA II transcription initiation site. <b>RNA I binds to RNA II</b> and thereby prevents formation of a secondary structure of RNA II that is necessary for hybridization of RNA II to the template DNA (Figure 1. B).
 
  
For RNA I to inhibit primer formation, it must bind before the nascent RNA II transcript extends to the replication origin. Consequently, the concentration of RNA I and the rate of binding of RNA I to RNA II is critical for regulation of primer formation and thus for plasmid replication.
 
  
Interaction between RNA I and RNA II can be amplified by Rop protein, see [[part:BBa_K2259010]].
+
<b>ColE1-type plasmid replication begins with the synthesis of plasmid encoded RNA II</b> (also called primer transcript) by RNA polymerase which initiates transcription at a site 555bp upstream of origin of replication. The RNA transcript forms a RNA - DNA hybrid with template DNA near the origin of replication. Hybridized RNA is then cleaved at the replication origin by RNAse H and serves as a primer for DNA synthesis by DNA polymerase I (Figure 1. A).<ref>Itoh, T. and Tomizawa, J. (1980). Formation of an RNA primer for initiation of replication of ColE1 DNA by ribonuclease H. Proceedings of the National Academy of Sciences, 77(5), pp.2450-2454.</ref>
 +
 
 +
<b>Initiation of replication can be inhibited by plasmid encoded small RNA, called RNA I </b>. Synthesis of RNA I starts 445 bp upstream of the replication origin and proceeds in the direction opposite to that of RNA II synthesis and terminates near the RNA II transcription initiation site. <b>RNA I binds to RNA II</b> and thereby prevents the formation of a secondary structure of RNA II that is necessary for hybridization of RNA II to the template DNA (Figure 1. B).<ref>Tomizawa, J. (1984). Control of cole 1 plasmid replication: The process of binding of RNA I to the primer transcript. Cell, 38(3), pp.861-870.</ref>
 +
 
 +
For RNA I to inhibit primer formation, it must bind before the nascent RNA II transcript extends to the replication origin. Consequently, the concentration of RNA I and the rate of binding of RNA I to RNA II is critical for regulation of primer formation and thus for plasmid replication. <ref>Tomizawa, J. (1984). Control of cole 1 plasmid replication: The process of binding of RNA I to the primer transcript. Cell, 38(3), pp.861-870.</ref>
 +
 
 +
The interaction between RNA I and RNA II can be amplified by Rop protein, see [[part:BBa_K2259010]].
  
 
==Usage with SynORI (Framework for multi-plasmid systems)==
 
==Usage with SynORI (Framework for multi-plasmid systems)==
  
 
===About SynORI===
 
===About SynORI===
[[Image:Aboutsynoritry1.png|600px|center|]]
+
[[Image:Groupspec.png|600px|center|]]
 
SynORI is a framework for multi-plasmid systems created by ''Vilnius-Lithuania 2017'' which enables quick and easy workflow with multiple plasmids, while also allowing to freely pick and modulate copy number for every unique plasmid group! Read more about [http://2017.igem.org/Team:Vilnius-Lithuania SynORI here]!
 
SynORI is a framework for multi-plasmid systems created by ''Vilnius-Lithuania 2017'' which enables quick and easy workflow with multiple plasmids, while also allowing to freely pick and modulate copy number for every unique plasmid group! Read more about [http://2017.igem.org/Team:Vilnius-Lithuania SynORI here]!
  
 
===Purpose of this construct in SynORI framework development===
 
===Purpose of this construct in SynORI framework development===
  
This construct acts as a RNA I promoter knock-out control. When RNA I promoter is disabled, plasmid copy number increases dramatically (1000-2000 copies per cell). It is difficult to tell if RNA I promoter is disabled completely, because the measurements at run-away replication are not precise enough. Yet, if RNA I gene copy is placed next to knocked-out origin of replication and the plasmid copy number goes down to wildtype amounts, we can say with certainty RNA I promoter is completely disabled.
+
This construct acts as a RNA I promoter knock-out control. When RNA I promoter is disabled, plasmid copy number increases dramatically (1000-2000 copies per cell). It is difficult to tell if RNA I promoter is disabled completely because the measurements at run-away replication are not precise enough. Yet, if RNA I gene copy is placed next to knocked-out origin of replication and the plasmid copy number goes down to wildtype amounts, we can say with certainty RNA I promoter is completely disabled.
 +
 
 +
=Characterization (Vilnius-Lithuania 2017)=
 +
==Interaction between RNA I and RNA II groups==
 +
===Constitutive promoter===
 +
 
 +
Once the RNA I promoter was [https://parts.igem.org/wiki/index.php?title=Part:BBa_K2259000#RNA_I_inactivation_in_wild_type_replicon disabled] in the ColE1 origin of replication, it could be moved to a different plasmid location and used as a separate unit. We have discovered the sequence of wild type RNA I promoter by using PromoterHunter and removed it, thus creating a wild type RNA I gene [[part:BBa_K2259005]]. First, series of Anderson promoters were cloned next to the RNA I gene ([[part:BBa_K2259021]] (0.15 Anderson), [[part:BBa_K2259023]] (0.36 Anderson), [[part:BBa_K2259027]] (0.86 Anderson), [[part:BBa_K2259028]] (1.0 Anderson)) and then placed next to RNA II ([[part:BBa_K2259067]] (0.15 Anderson), [[part:BBa_K2259068]] (0.36 Anderson), [[part:BBa_K2259069]] (0.86 Anderson), [[part:BBa_K22590671]] (1.0 Anderson)).
 +
 
 +
[[File:RNA_I_anderson.png|thumb|centre|900px|<b>Figure 4. </b> RNA I and RNA II constructs, with RNA I constructs under different-strength Anderson promoters.]]
 +
 
 +
In theory (see “Modelling” at [http://2017.igem.org/Team:Vilnius-Lithuania team Vilnius-Lithuania wiki]), lower-strength Anderson promoters should yield lower concentrations of RNA I, hence higher copy numbers of plasmids per cell.  Our constitutive copy number device experiment results prove it to be true in practice as well. The stronger Anderson promoter is used, the less copy number per cell we get. With the strongest Anderson we get only 21+-6.84 plasmids per cell.
 +
 
 +
Worth to mention is that the closest to wild type ColE1 replicon is the 0.86 strength Anderson promoter ([[Part:BBa_J23102]]), measured by copy number alone.
 +
 
 +
We can state with certainty that we are now able to control the plasmid copy number in a constitutive manner, and we simply call it the SynORI constitutive copy number device.
 +
 
 +
===Inducible promoter===
 +
 
 +
We wanted to move one step further and try to build an inducible copy number system. We first had to make sure that at least part of our construct is well characterized and to do so we chose the Rhamnose promoter from the biobrick registry ([[Part:BBa_K914003]])
 +
 
 +
For this experiment we have built a Rhamnose promoter and RNA I construct [[part:BBa_K2259065]] and then cloned this construct next to RNA II [[part:BBa_K2259091]]. We have used different concentration of Rhamnose in our media in order to see if this approach was possible and if so, to figure out the dependency between the plasmid copy number and rhamnose concentration.
 +
 
 +
[[File:Rha_rnr.png|thumb|centre|900px|<b>Figure 5. </b> RNA I and RNA II constructs, with RNA I gene being under the Rhamnose promoter, inducided by different rhamnose concentrations.]]
 +
 
 +
The first thing we noticed was that Rhamnose promoter was very strong in terms of plasmid copy number reduction. It was also considerably leaky (promoter can be enabled even without any inducer). At zero induction there were approximately only 9 plasmids per cell and at 1 percent induction the number dropped to approximately 1 plasmid per cell.
 +
 
 +
RNA I rhamnose-induced promoter seemed to be working well, with higher concentrations of inductor giving lower plasmid copy number.
 +
 
 +
We called it the SynORI copy number induction device.
 +
 
 +
So now when we can flexibly control the copy number of a plasmids, the only question is - what will come next?
 +
 
 +
===Interaction between RNA II and RNA I of different groups===
 +
 
 +
When different groups of SynORI system were created the abilty of corresponding RNA I to inhibit the replication of RNA II were measured by calculating the plasmid copy number with and without RNA I in the system
 +
 
 +
[[File:Difgr.png|thumb|centre|900px|<b>Figure 6. </b>Different RNA II group copy number with and without RNA I of the same group]]
 +
 
 +
As can be seen in <b>Figure 6</b>, RNA I introduction into the system has a significant effect on the plasmid copy number of the specific group, thus we can conclude that RNA I works on corresponding RNA II.
 +
 
 +
To prove that RNA I works only on the specific RNA II, different groups of SynORI devices were placed in a cell by co-transformation and plasmid copy numbers were calculated. SynORI global copy number control devices ([[part:BBa_K2259072]] (0 Anderson), [[part:BBa_K2259073]] (0.15 Anderson), [[part:K2259074]] (0.24 Anderson)) were co-transformed together with B-GC SynORI device ([[BBa_K2259078]]) and ([[part:BBa_K2259072]] (0 Anderson), [[part:BBa_K2259073]] (0.15 Anderson), [[part:K2259074]] (0.24 Anderson)) with D-GC SynORI device ([[BBa_K2259079]]).
 +
 
 +
[[File:Abkot.png|thumb|centre|900px|<b>Figure 7.</b>SynORI A device with Rop under different Anderson promoters together with SynORI B-GC device.]]
 +
 
 +
[[File:Adkot.png|thumb|centre|900px|<b>Figure 8.</b>SynORI A device with Rop under different Anderson promoters together with SynORI D-GC device.]]
 +
 
 +
As can be seen in <b>Figure 7</b> and <b>Figure 8</b> RNA II A, RNA II B and RNA II D act as different ORIs and their corresponding RNA I inhibits the replication of SynORI groups specifically.
 +
 
 +
It can also be concluded that Rop protein placed in a single plasmid lowered the plasmid copy number of both plasmid groups, this proves that Rop works by  binding to a kissing-loop complex and is able to bypass the individual control of different groups.
 +
  
=Characterization of RNA II (Vilnius-Lithuania 2017)=
 
==RNA I inactivation in wild type replicon==
 
  
 
==References==
 
==References==
 
<references />
 
<references />

Latest revision as of 03:47, 2 November 2017


ColE1 replicon (Deactivated RNA I, placed next to RNA II)

This is a ColE1 replicon with knocked-out RNA I promoter. A copy of RNA I is then placed next to RNA II.

This construct acts as a RNA I promoter knock-out control. When RNA I promoter is disabled, plasmid copy number increases dramatically (1000-2000 copies per cell). It is difficult to tell if RNA I promoter is disabled completely because the measurements at run-away replication are not precise enough. Yet, if RNA I gene copy is placed next to knocked-out origin of replication and the plasmid copy number goes down to wildtype amounts, we can say with certainty RNA I promoter is completely disabled.

See how this part fits into the whole SynORI framework by pressing here!


Sequence and Features


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    COMPATIBLE WITH RFC[12]
  • 21
    COMPATIBLE WITH RFC[21]
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    COMPATIBLE WITH RFC[25]
  • 1000
    COMPATIBLE WITH RFC[1000]



Introduction

Biology

ColE1 plasmid replication overview

Figure 1. Main principles of ColE1 plasmid family replication


ColE1-type plasmid replication begins with the synthesis of plasmid encoded RNA II (also called primer transcript) by RNA polymerase which initiates transcription at a site 555bp upstream of origin of replication. The RNA transcript forms a RNA - DNA hybrid with template DNA near the origin of replication. Hybridized RNA is then cleaved at the replication origin by RNAse H and serves as a primer for DNA synthesis by DNA polymerase I (Figure 1. A).[1]

Initiation of replication can be inhibited by plasmid encoded small RNA, called RNA I . Synthesis of RNA I starts 445 bp upstream of the replication origin and proceeds in the direction opposite to that of RNA II synthesis and terminates near the RNA II transcription initiation site. RNA I binds to RNA II and thereby prevents the formation of a secondary structure of RNA II that is necessary for hybridization of RNA II to the template DNA (Figure 1. B).[2]

For RNA I to inhibit primer formation, it must bind before the nascent RNA II transcript extends to the replication origin. Consequently, the concentration of RNA I and the rate of binding of RNA I to RNA II is critical for regulation of primer formation and thus for plasmid replication. [3]

The interaction between RNA I and RNA II can be amplified by Rop protein, see part:BBa_K2259010.

Usage with SynORI (Framework for multi-plasmid systems)

About SynORI

Groupspec.png

SynORI is a framework for multi-plasmid systems created by Vilnius-Lithuania 2017 which enables quick and easy workflow with multiple plasmids, while also allowing to freely pick and modulate copy number for every unique plasmid group! Read more about [http://2017.igem.org/Team:Vilnius-Lithuania SynORI here]!

Purpose of this construct in SynORI framework development

This construct acts as a RNA I promoter knock-out control. When RNA I promoter is disabled, plasmid copy number increases dramatically (1000-2000 copies per cell). It is difficult to tell if RNA I promoter is disabled completely because the measurements at run-away replication are not precise enough. Yet, if RNA I gene copy is placed next to knocked-out origin of replication and the plasmid copy number goes down to wildtype amounts, we can say with certainty RNA I promoter is completely disabled.

Characterization (Vilnius-Lithuania 2017)

Interaction between RNA I and RNA II groups

Constitutive promoter

Once the RNA I promoter was disabled in the ColE1 origin of replication, it could be moved to a different plasmid location and used as a separate unit. We have discovered the sequence of wild type RNA I promoter by using PromoterHunter and removed it, thus creating a wild type RNA I gene part:BBa_K2259005. First, series of Anderson promoters were cloned next to the RNA I gene (part:BBa_K2259021 (0.15 Anderson), part:BBa_K2259023 (0.36 Anderson), part:BBa_K2259027 (0.86 Anderson), part:BBa_K2259028 (1.0 Anderson)) and then placed next to RNA II (part:BBa_K2259067 (0.15 Anderson), part:BBa_K2259068 (0.36 Anderson), part:BBa_K2259069 (0.86 Anderson), part:BBa_K22590671 (1.0 Anderson)).

Figure 4. RNA I and RNA II constructs, with RNA I constructs under different-strength Anderson promoters.

In theory (see “Modelling” at [http://2017.igem.org/Team:Vilnius-Lithuania team Vilnius-Lithuania wiki]), lower-strength Anderson promoters should yield lower concentrations of RNA I, hence higher copy numbers of plasmids per cell. Our constitutive copy number device experiment results prove it to be true in practice as well. The stronger Anderson promoter is used, the less copy number per cell we get. With the strongest Anderson we get only 21+-6.84 plasmids per cell.

Worth to mention is that the closest to wild type ColE1 replicon is the 0.86 strength Anderson promoter (Part:BBa_J23102), measured by copy number alone.

We can state with certainty that we are now able to control the plasmid copy number in a constitutive manner, and we simply call it the SynORI constitutive copy number device.

Inducible promoter

We wanted to move one step further and try to build an inducible copy number system. We first had to make sure that at least part of our construct is well characterized and to do so we chose the Rhamnose promoter from the biobrick registry (Part:BBa_K914003)

For this experiment we have built a Rhamnose promoter and RNA I construct part:BBa_K2259065 and then cloned this construct next to RNA II part:BBa_K2259091. We have used different concentration of Rhamnose in our media in order to see if this approach was possible and if so, to figure out the dependency between the plasmid copy number and rhamnose concentration.

Figure 5. RNA I and RNA II constructs, with RNA I gene being under the Rhamnose promoter, inducided by different rhamnose concentrations.

The first thing we noticed was that Rhamnose promoter was very strong in terms of plasmid copy number reduction. It was also considerably leaky (promoter can be enabled even without any inducer). At zero induction there were approximately only 9 plasmids per cell and at 1 percent induction the number dropped to approximately 1 plasmid per cell.

RNA I rhamnose-induced promoter seemed to be working well, with higher concentrations of inductor giving lower plasmid copy number.

We called it the SynORI copy number induction device.

So now when we can flexibly control the copy number of a plasmids, the only question is - what will come next?

Interaction between RNA II and RNA I of different groups

When different groups of SynORI system were created the abilty of corresponding RNA I to inhibit the replication of RNA II were measured by calculating the plasmid copy number with and without RNA I in the system

Figure 6. Different RNA II group copy number with and without RNA I of the same group

As can be seen in Figure 6, RNA I introduction into the system has a significant effect on the plasmid copy number of the specific group, thus we can conclude that RNA I works on corresponding RNA II.

To prove that RNA I works only on the specific RNA II, different groups of SynORI devices were placed in a cell by co-transformation and plasmid copy numbers were calculated. SynORI global copy number control devices (part:BBa_K2259072 (0 Anderson), part:BBa_K2259073 (0.15 Anderson), part:K2259074 (0.24 Anderson)) were co-transformed together with B-GC SynORI device (BBa_K2259078) and (part:BBa_K2259072 (0 Anderson), part:BBa_K2259073 (0.15 Anderson), part:K2259074 (0.24 Anderson)) with D-GC SynORI device (BBa_K2259079).

Figure 7.SynORI A device with Rop under different Anderson promoters together with SynORI B-GC device.
Figure 8.SynORI A device with Rop under different Anderson promoters together with SynORI D-GC device.

As can be seen in Figure 7 and Figure 8 RNA II A, RNA II B and RNA II D act as different ORIs and their corresponding RNA I inhibits the replication of SynORI groups specifically.

It can also be concluded that Rop protein placed in a single plasmid lowered the plasmid copy number of both plasmid groups, this proves that Rop works by binding to a kissing-loop complex and is able to bypass the individual control of different groups.


References

  1. Itoh, T. and Tomizawa, J. (1980). Formation of an RNA primer for initiation of replication of ColE1 DNA by ribonuclease H. Proceedings of the National Academy of Sciences, 77(5), pp.2450-2454.
  2. Tomizawa, J. (1984). Control of cole 1 plasmid replication: The process of binding of RNA I to the primer transcript. Cell, 38(3), pp.861-870.
  3. Tomizawa, J. (1984). Control of cole 1 plasmid replication: The process of binding of RNA I to the primer transcript. Cell, 38(3), pp.861-870.