This post is about a study that came out this year in June and unlike most other research articles we all read, this is about teaching in the laboratory. First of all, I never heard of this journal (Adv. Physiol. Educ) before and it’s sad that most of us miss out on some really good stuff just by virtue of not knowing that some of these journals even exist. This study was born out of a Physiology course for graduate students taken by Prof. Luke Janssen at McMaster University, Canada.
Here at Penn, a small set of us meet up every Monday and we call it the Nano club and talk about recent papers in the motors field. I was pleasantly surprised when this one was listed in the spreadsheet of new papers that we circulate amongst ourselves. The revelation that molecular motors are stuff with kinetic energy and they move things around efficiently and generate force had a deep impression on me when I first learnt it. What we were taught in undergrad was these smart motors convert chemical energy of ATP hydrolysis to kinetic energy. That’s reasonable, not too hard to break your head over. Professors like to keep things simple in undergrad courses I guess. When I went about reading more about motors I realized that there is another way that scientists like to think about as well which is the Brownian ratchet model. To put it in a simple sentence – the motors can make use of their inherent random fluctuations and vibrations (present in all directions) in a way way that these motions occur only in the required direction and hence doing useful work. This is also called thermal capture. How are these vibrations filtered in one direction and negated in the other? This never made sense to me, or rather it was so hard to grasp this concept.
This study addresses just that! I could connect to the introduction of this paper where the authors talk about how this is not very easy to explain to students. They describe ways and methods to demonstrate this concept in a lab setting with things that we use almost everyday. One of their simplest models used a cell phone in the vibration mode with paper clips. Have the phone vibrate on the table and it vibrates in all directions. Have 2 long paper clips attached to it in a way that each time the phone vibrates, (due to the way the clips are attached) – one of which acts as a ratchet so the vibrations make it to move only in the direction of the paperclip* .
I strongly recommend you take a look at this if you’re even remotely interested in molecular motors and even if you’re not, just to take a peek at the elegance of such a teaching method and style.
*I wrote to Luke asking if I could use his pictures here and though as much as he appreciated my idea of having a post dedicated to their study, his mail made me realize its not the authors but the journal which has the copyright once its published. Its funny how once your study gets published in a journal, the ownership now becomes that of the journal.
You don't need permission from the journal to post pictures. There is still such a thing as fair use .
ReplyDeleteThe paper, moreover, is from a free (as in freedom, not as in free beer) journal that also seems to be publicly funded. Sli too much for all that 'how I wish I could post pictures' jazz.
Go here as well: http://researchblogging.org/
@Croor - Thanks for letting me know! I was on campus when I was writing this up and I just assumed I could access the article as I was in lab, didnt know it was free. And about jazz, I'd beg to differ. I put the picture now anyway.
ReplyDeleteHmm..interesting. The clip-on-the-phone experiment though seemed intuitive to me..the more interesting question might be what functions as the clip for a molecular motor. And I am sure it would involve more complex things. Thats what the paper might address too, should have a look..
ReplyDeleteBut the idea of the Brownian ratchet is very good - reading that one sentence makes it seem like its quite difficult to accomplish, but I guess lots of experiments and models abound..
Sathej
@Sathej - I don't recall the paper addressing that question though I think it is something that is not completely understood yet. Interesting to think about though.
ReplyDeleteThe clips on the phone + the phone make up the molecular motor. So to answer the question, the clips will be subdomains of the folded protein, and will differ depending on the molecular motor in question.
ReplyDeleteWhat's great about the model is that you can create "mutations" in the molecular motor by bending the clips. Such small changes can make a big impact on the function of the protein & this is easily visualized.
I should add: Dr. Janssen was a great instructor which made for a fun course. His teaching method & models were really helpful & hopefully many students will be able to benefit from this!
Hi Amanda
ReplyDeleteThanks for the note. Yes, the mutations part was pretty interesting, showed the importance of small changes as you mentioned - very true for motors like kinesin and dynein.
About Dr.Janssen, well I'm not surprised - the paper speaks volumes about the style of teaching.