Synthetic Biology:Abstraction hierarchy
After lab meeting, a few of us were having a discussion on what the schema for the Registry should look like. (Some notes from that discussion are posted here). During the discussion, we started talking about the abstraction hierarchy that is on the Registry page and originally from one of Drew's slides.
Abstraction hierarchies are useful in general because they enable an engineer to cope with very complex systems by ignoring unnecessary detail. Thinking about what an abstraction hierarchy in synthetic biology should look like might help us think about the "right" way to engineer biological systems.
Parts, devices and systems
Ad hoc definitions
The question that arose is, what is the distinction between a device and system? Generally, to date we haven't had a crisp distinction between parts, devices and systems. The working definitions to date are something like
- DNA = low level DNA sequence ... a string of A,T,G,C's
- Part = RBS, CDS, promoter, terminator; a piece of DNA in BioBricks format that has a specific function.
- Device = inverter; something else with a higher level function; composed of multiple parts
- System = ring oscillator; composed of many devices
- DNA = low level DNA sequence ... a string of A,T,G,C's
- Part = a piece of DNA in BioBricks format which usually has a specific function.
- a terminator stop transcription
- a promoter initiates transcription
- Device = a basic or composite part whose input OR output has units of PoPS (or whatever units the general information signal in the devices have).
Another way of thinking of this definition is that a device is any part for which a transfer curve can be drawn in which one of the axes is in PoPS.
The key thing to note in this description is that certain BioBricks in the database might be considered a part in one context and a device in another context.
I think this definition could be rephrased to say - A device is any basic or composite part that can be combined with at least one other device using the PoPS framework. I think this might make the reason for defining a device as you have done more clear (at least to me). --BC 09:30, 15 Sep 2005 (EDT)
Jason has been using an operational distinction between devices and systems saying that a device is something whose behavior you can screen for whereas a system's behavior cannot be screened. Thus, what is a system today might be a device tomorrow if a clever screen is devised. We should think about whether that definition is more useful than this one or if the two could be merged.
- an inverter is a device. Its input and output are PoPS
- an RBS.GFP.Term is a device. Its input is PoPS and its output is fluorescence.
- a constitutive promoter is a device. It has no input and its output is PoPS. (Note: a promoter is a part in other contexts).
- UT-Austin's photons to PoPS converter is a device.
- System = Any device which has neither an input nor an output in PoPS.
Some systems can easily be transformed to devices.
- a promoter.GFP.Term is a system. It has no input and its output is fluorescence.
- The UT-Austin's project is a system. Its input is photons and its output is blue/white color.
- the repressilator is a system. It has no input (or its input could be IPTG/aTc) and its output is fluorescence. The repressilator could easily become a device however. If a duplicate copy of one of the promoters is present. Then that promoter has an output of PoPS which could be hooked up to some device. Thus in this case, the repressilator becomes a device.
When you add the promoter, I think the repressilator is still a system but it is part of a device. I'm not sure you can add another promoter and still say that it is the repressilator since you have added a new output. You cant connect I7101 or the repressilator to another device via the PoPS framework hence they are exlusively systems.--BC 09:30, 15 Sep 2005 (EDT)
Following on from what I wrote above - A system is a collection of parts that does not have a PoPS input or output to allow composition with other parts or devices via the PoPS framework. So a device has at least one input or output that can be connected to other devices and so can form part of a larger system whereas a system is a complete and "closed" collection of parts. I don't think I'm changing the definitions too much, just wording them in a way that makes more sense to me. Worded this way I think they emphasize the composability property of the element which seems like the most clear, since interpreting the function of the elements is subjective as we all agree.--BC 09:30, 15 Sep 2005 (EDT)
Thus, the exact classification of a particular BioBrick is not fixed. In some situations, you might think of promoter as a part because you are referring to a promoter than can be regulated by a certain repressor. In another situation, you think of a promoter as a device because you need a constant PoPS source in your device/system. In other words, parts, devices and systems are not disjoint.
So if I get this right, everything that is on the one piece of DNA is always a part. However, I think that systems and devices are disjoint sets. The caveat being that you can easily convert one to the other by adding or removing a PoPS i/o. --BC 09:30, 15 Sep 2005 (EDT)
Actually this might mean -
- Part = a piece of DNA that can be combined with other parts via BioBricks standard assembly.
- Device = a part or composite part that can be combined with other parts via PoPS-based composition.
- System = a part or composite part that cannot be combined with other parts via PoPS-based composition.
I like these definitions ... they capture the same ideas in a much more concise way. Some minor revisions.
- Part = a piece of DNA with specific function that can be combined with other parts via an assembly standard.
- Device = a part or composite part that can be combined with other devices via composition based on a univeral signal (i.e. PoPS, RiPS, PhPS).
- System = a part or composite part that cannot be combined with other parts via composition.
- Added a caveat to the part definition: i.e. "a piece of DNA with specific function." Thus, not just any sequence of DNA in BioBricks format can be a part ... it must have a specified function associated with it. Note that a random piece of DNA could be a part, if its purpose was to be random (like the spacer part).
- Tried to describe parts, devices and systems more generally. For example, a part can be combined with other parts via an assembly standard rather than BioBricks standard assembly. And instead of PoPS-based composition, just composition.
Note that I am not satisfied with the wording I use above. So if you have a better idea, feel free to revise. --Reshma 11:02, 27 Sep 2005 (EDT)
- Part = a sequence of DNA that can be physically combined with other parts via an assembly standard.
- Device = a part or composite part that can be functionally combined with other devices via a common, standard signal(i.e. PoPS, RiPS, PhPS).
- System = a part or composite part that cannot be functionally combined with other parts via a common, standard signal.
- Suggested the removal of the specific function clause (see discussion below).
- Tried to make clear that parts can be physically combined, whereas the important composition at the device level is a functional composition.
I like the more generalized definitions of Attempt 3. However, I'm not sure if we need to define a part as having a specific function. I feel that as long as it is composable it must be a part, even if not necessarily a useful part. I don't think we lose or gain a lot by including the specific function clause other than forcing people to define a function for their part which might be a good idea. Parts also may or may not have only one specific function.
We should discuss this idea of specific function further at the device and system level. Is a non-functioning device a device? Probably. Is a system that doesn't do anything a system? Maybe. Again, I feel that a well-formed device/system (i.e one that conforms to the composition standard) can't not have a function and hence we don't necessarily need the specific function clause at these levels either.
One hair-splitting problem I see with the definitions we are using here is that they imply that a system (and a device) must be a part. This might not need to be true even though the current assembly standard forces any combination of parts to also be a part. We might need to replace part or composite part with just sequence of DNA in the device and system definition. Or we can just make a more limited definition of these that does require them to also be parts as defined here.
Finally, I like Austin's idea below but believe that the above definitions are also of practical benefit so I think it would be worth trying to amalgamate the two at some point. -BC
Just brainstorming ... edit excessively.
One appealing aspect of this composition-based distinction between parts, devices and systems is that it makes it easier to think about classes of standards that might be useful. There are assembly standards which apply to parts and performance standards (for instance, definitions of high and low signal thresholds) that apply to devices. These standards facilitate interoperability of parts with other parts and devices with other devices. Systems, on the other hand, are unlikely (?) to be subject to standards. Instead, systems are designed to meet a set of specifications. For example, I want to design a system in which cells that detect a chemical X glow green. At this point the line between parts, devices and systems might be somewhat artificial but might help stimulate discussion on how to systematically engineer biological systems.