Biomod/2011/Caltech/DeoxyriboNucleicAwesome/Domain Level Project Design

From OpenWetWare

< Biomod | 2011 | Caltech/DeoxyriboNucleicAwesome(Difference between revisions)
Jump to: navigation, search
Current revision (15:30, 3 November 2011) (view source)
 
(7 intermediate revisions not shown.)
Line 6: Line 6:
=== Overall Domain Design ===  
=== Overall Domain Design ===  
-
[[Image: DomainLevelDesign.jpg | 700px]]
+
[[Image: DomainLevelDesign.jpg | thumb|center|800px | Figure 1. Overall domain level desin]]
 +
Probes are the extended part of staples which are complementary to the bottom part of the strands which should be anchored on the origami surface. Different kinds of probes were designed for each strand. Origami will be annealed with certain staples extended with probes at predetermined positions, and some strands, such as tracks or cargo goals, will be planted on those specific positions using interaction between probe regions.
-
The random Walker consists of a body which is a 15nt long domain (b in figure 1), and two arms each which are 6nt short toeholds (a1 and a2 in figure 1) at at each end of the body. Tracks on which it walks contain the complement of one of the two toeholds: track 1 with a1* domain and track 2 with a2* domain. When a walker is on track 1, a2 domain is unpaired and searches for a complementary single strand. When track 2 is adjacent, it serves as a complementary sequence to which it can bind. After an arm of the walker (a2 domain) binds to an adjacent track 2, which serves as a "distal toehold", the hybridization extends by the rest of track 2. By this branch migration, the whole walker moves from track 1 to track 2. Similarly, a walker can move randomly from one kind of track to another kind.
+
=== Random Walking Mechanism ===
 +
The backbone of our design is a random walker that moves across the surface of a rectangular origami. The mechanism by which said walker moves is simply strand displacement, whereby the walker contains a toehold on each end of the body, and the track strands on which it walks contains the complement of one of the two toeholds on the walker. This particular arrangement allows the walker to move randomly between track strands without modifying previously visited track segments.
-
To accomplish a cargo-reorganizing-task, a walker is extended to have picking up arm which is complementary to cargos (domain x and l in figure 1). When walker randomly walks and encounters a cargo molecule, it picks up the cargo by strand displacement using toehold l. It continues random walking after picking up, and when a walker gets to the cargo goal, cargo is dropped off at the cargo goal using toehold u/u*, which both cargo and cargo goal share. Therefore, random walking process is purely stochastic, yet a deterministic end result can be achieved by specific recognition between the cargo molecules and their destinations.
+
The random Walker consists of a body which is a 15nt long domain (black), and two arms each which are 6nt short toeholds (red and blue toehold) at at each end of the body. Tracks on which it walks contain the complement of one of the two toeholds: track 1 with red domain and track 2 with blue domain. When a walker is on track 1, blue toehold is unpaired and searches for a complementary single strand. When track 2 is adjacent, it serves as a complementary sequence to which it can bind. After an blue toehold of the walker binds to an adjacent track 2, which serves as a "distal toehold", the hybridization extends by the rest of track 2. By this branch migration, the whole walker moves from track 1 to track 2. Similarly, a walker can move randomly from one kind of track to another kind.
-
Another important stand is walker goal. Since walker goal contains both a1* and a2* which are complementary to the both of the toeholds of the walker, walker stays on the walker goal when it gets there. Walker goal will be used in verifying random walking on origami, and its use will be explained in later section.
+
[[Image: ssslide14.jpg | 600px | thumb|center | Figure 2 (a). Random walking mechanism from track 1 to track 2]]
 +
 
 +
[[Image: ssslide15.jpg | 600px| thumb|center | Figure 2 (b). Random walking mechanism from track 2 to track 1]]
-
While the system is under construction, (e.g. track being planted), a walker or cargo goal should be deactivated to prevent undesired random walking or cargo sorting. Walker inhibitor and cargo goal inhibitor are thus designed. Later, walker trigger and cargo goal trigger will rip off the inhibitors by strand displacement using toehold wi and cgi. Detacher stands were designed to detach particular strands from samples with origami for the future gel experiments. Probes are the extended part of staples which are complementary to the bottom part of the strands which should be anchored on the origami surface. Different kinds of probes were designed for each strand. Origami will be annealed with certain staples extended with probes at predetermined positions, and some strands, such as tracks or cargo goals, will be planted on those specific positions using interaction between probe regions.
 
-
=== Random Walking Mechanism ===
 
-
:Main Article: ''[[Biomod/2011/Caltech/DeoxyriboNucleicAwesome/Random Walking|Random Walking Mechanism]]''
 
-
The backbone of our design is a random walker that moves across the surface of a rectangular
 
-
origami. The mechanism by which said walker moves is simply strand displacement, whereby the walker
 
-
contains a toehold on each end of the body, and the track strands on which it walks contains the
 
-
complement of one of the two toeholds on the walker. This particular arrangement allows the walker to
 
-
move randomly between track strands without modifying previously visited track segments.
 
===Cargo Pick-Up Mechanism===
===Cargo Pick-Up Mechanism===
-
:Main Article: ''[[Biomod/2011/Caltech/DeoxyriboNucleicAwesome/Cargo Pick-Up|Cargo Pick-Up Mechanism]]''
+
 
 +
To accomplish a cargo-reorganizing-task, a walker is extended to have picking up arm which is complementary to cargos (green domain). When walker randomly walks and encounters a cargo molecule, it picks up the cargo by strand displacement using yellow toehold.
 +
 
 +
[[Image: ssslide16.jpg | 600px| thumb|center |Figure 3. Cargo ick-up mechanism]]
===Cargo Drop-Off Mechanism===
===Cargo Drop-Off Mechanism===
-
:Main Article: ''[[Biomod/2011/Caltech/DeoxyriboNucleicAwesome/Cargo Drop-Off|Cargo Drop-Off Mechanism]]''
+
 
 +
It continues random walking after picking up, and when a walker gets to the cargo goal, cargo is dropped off at the cargo goal using purple toehold, which both cargo and cargo goal share. Therefore, random walking process is purely stochastic, yet a deterministic end result can be achieved by specific recognition between the cargo molecules and their destinations.
 +
 
 +
[[Image: ssslide17.jpg | 600px| thumb|center |Figure 4. Cargo drop-off mechanism]]
 +
 
 +
 
 +
===Walking to the Walker Goal Mechanism (for verification of random walking) ===
 +
 
 +
Another important stand is walker goal. Since walker goal contains both red and blue toeholds which are complementary to the both of the toeholds of the walker, walker stays on the walker goal when it gets there. Walker goal will be used in verifying random walking on origami, and its use will be explained in later section.
 +
 
 +
[[Image: ssslide19.jpg | 600px| thumb|center| Figure 5. Walking to the walker goal mechanism]]
 +
 
 +
=== Triggering Mechanism===
 +
 
 +
While the system is under construction, (e.g. track being planted), a walker or cargo goal should be deactivated to prevent undesired random walking or cargo sorting. Walker inhibitor and cargo goal inhibitor are thus designed. Later, walker trigger and cargo goal trigger will rip off the inhibitors by strand displacement using corresponding toeholds.
 +
 
 +
====Walker Triggering====
 +
 
 +
[[Image: ssslide12.jpg | 600px| thumb|center| Figure 6. Walker triggering mechanism]]
 +
 
 +
====Cargo Goal Triggering====
 +
 
 +
[[Image: ssslide13.jpg | 600px| thumb|center|Figure 7. Cargo goal triggering mechanism]]
 +
 
 +
 
 +
 
===See Also===
===See Also===
*[[Biomod/2011/Caltech/DeoxyriboNucleicAwesome/Sequence Design|Sequence Design]]
*[[Biomod/2011/Caltech/DeoxyriboNucleicAwesome/Sequence Design|Sequence Design]]
{{Template:DeoxyriboNucleicAwesomeFooter}}
{{Template:DeoxyriboNucleicAwesomeFooter}}

Current revision

Image:DeoxyriboNucleicAwesomeHeader.jpg

Monday, September 22, 2014

Home

Members

Project

Protocols

Progress

Discussion

References


Contents


Domain Level Design

Overall Domain Design

Figure 1. Overall domain level desin
Figure 1. Overall domain level desin

Probes are the extended part of staples which are complementary to the bottom part of the strands which should be anchored on the origami surface. Different kinds of probes were designed for each strand. Origami will be annealed with certain staples extended with probes at predetermined positions, and some strands, such as tracks or cargo goals, will be planted on those specific positions using interaction between probe regions.

Random Walking Mechanism

The backbone of our design is a random walker that moves across the surface of a rectangular origami. The mechanism by which said walker moves is simply strand displacement, whereby the walker contains a toehold on each end of the body, and the track strands on which it walks contains the complement of one of the two toeholds on the walker. This particular arrangement allows the walker to move randomly between track strands without modifying previously visited track segments.

The random Walker consists of a body which is a 15nt long domain (black), and two arms each which are 6nt short toeholds (red and blue toehold) at at each end of the body. Tracks on which it walks contain the complement of one of the two toeholds: track 1 with red domain and track 2 with blue domain. When a walker is on track 1, blue toehold is unpaired and searches for a complementary single strand. When track 2 is adjacent, it serves as a complementary sequence to which it can bind. After an blue toehold of the walker binds to an adjacent track 2, which serves as a "distal toehold", the hybridization extends by the rest of track 2. By this branch migration, the whole walker moves from track 1 to track 2. Similarly, a walker can move randomly from one kind of track to another kind.

Figure 2 (a). Random walking mechanism from track 1 to track 2
Figure 2 (a). Random walking mechanism from track 1 to track 2
Figure 2 (b). Random walking mechanism from track 2 to track 1
Figure 2 (b). Random walking mechanism from track 2 to track 1


Cargo Pick-Up Mechanism

To accomplish a cargo-reorganizing-task, a walker is extended to have picking up arm which is complementary to cargos (green domain). When walker randomly walks and encounters a cargo molecule, it picks up the cargo by strand displacement using yellow toehold.

Figure 3. Cargo ick-up mechanism
Figure 3. Cargo ick-up mechanism

Cargo Drop-Off Mechanism

It continues random walking after picking up, and when a walker gets to the cargo goal, cargo is dropped off at the cargo goal using purple toehold, which both cargo and cargo goal share. Therefore, random walking process is purely stochastic, yet a deterministic end result can be achieved by specific recognition between the cargo molecules and their destinations.

Figure 4. Cargo drop-off mechanism
Figure 4. Cargo drop-off mechanism


Walking to the Walker Goal Mechanism (for verification of random walking)

Another important stand is walker goal. Since walker goal contains both red and blue toeholds which are complementary to the both of the toeholds of the walker, walker stays on the walker goal when it gets there. Walker goal will be used in verifying random walking on origami, and its use will be explained in later section.

Figure 5. Walking to the walker goal mechanism
Figure 5. Walking to the walker goal mechanism

Triggering Mechanism

While the system is under construction, (e.g. track being planted), a walker or cargo goal should be deactivated to prevent undesired random walking or cargo sorting. Walker inhibitor and cargo goal inhibitor are thus designed. Later, walker trigger and cargo goal trigger will rip off the inhibitors by strand displacement using corresponding toeholds.

Walker Triggering

Figure 6. Walker triggering mechanism
Figure 6. Walker triggering mechanism

Cargo Goal Triggering

Figure 7. Cargo goal triggering mechanism
Figure 7. Cargo goal triggering mechanism



See Also

Personal tools