Flash freeze and chill – and keep your proteins chill until return you will! I’m wrapping up an experiment and it looks like I might be out of the lab for a while to help flatten the curve, so I need to make sure that the protein I’ve invested so much time into will be safe until I return. So I flash-froze my now pure protein with liquid nitrogen – but I didn’t “really” freeze them, thanks to the biochemist’s favorite “antifreeze” glycerol acting to keep them cryoprotected.
I was watching Gilmore Girls a while ago, and I was so disappointed in Rory because she told someone “For you, how water freezes is probably fascinating” – she said it as an insult?! But water-freezing is fascinating! And s a protein biochemist you develop a strong appreciation of the freezing phenomenon – because you don’t want the little rivers of water flowing in and around your proteins to “really freeze” (as in crystallize into ice) when you “freeze” your proteins! So we add glycerol as a CRYOPROTECTANT (antifreeze) to act as chaperones breaking up the molecular “dance partners” and then use liquid nitrogen to supercool them – “flash freezing” them before they have a chance to organize into orderly crystals.
A prep’s not over til it’s aliquoted & in the -80. I love protein purification, but I always have this weight of worry that – no matter how well things have gone so far – something can always still go wrong. The last step in a protein prep is preparing it for storage. And at the end of the prep you’re often really exhausted so it can be easy to feel the urge to just toss it in the freezer – but you want to do it right – future you will thank current you!
If you you imagine a molecular “prom dance” – in a liquid the dancers are free to glide around & swap dance partners – they just can’t leave the dance hall. But in a solid the molecules can only stand in place and do that awkward sway thing with their partner(s). The difference between them is that in a solid the molecules don’t have the energy to “un-hug” their dance partners and go find someone else. What the molecules really want to do is leave the dance hall all together (escape as a gas) but that requires making their way to the exit without having new dance partners ask for a dance. So that takes a lot of energy.
The stronger the partners are hugging the more energy is needed to un-hug and water’s really huggy because the oxygen doesn’t share fairly – it hogs electrons, making it partly positive & the H’s partly negative – and opposites attract so they like to hang with oxygens from other water molecules.
Molecules would rather be on their own (where they have more entropy (randomness/disorder – basically they can move more ways and this makes them happier), but if they have to be there, and they have to get stuck in the super slow dance of solid-ness they’d rather be stuck with dance partners they like. So if they have “advance warning” that a slow song is coming they can link up to their preferred partners and doing so generates a rigid orderly arrangement of molecules we call a crystal.
And that linking-upness may require pushing out the “noncool kids” (🙋♀️). So with slow freezing you end up freezing with different “cliques” in different areas of the dance hall – a “heterogeneous” mix instead of the nice evenly-distributed molecular crowd that we call a “homogenous solution”. And if you’re dealing with water, the molecules literally get “pushed” because water expands when it freezes (even if the water’s inside pockets & channels of your protein!)
But if you can switch on the slow song without that advance warning, the molecules get stuck in place – this is the principle behind “flash freezing” And if you add cryoprotectants like glycerol that act like “dance chaperones” that break up the dance partners and make it harder for partners to find each other, you buy yourself more time
In a SOLID, molecules are “stuck in place” & only have enough energy to vibrate (as opposed to liquids where they can slide around & gases where they can go wherever they want). In some solids (like ice & diamonds), the molecules are arranged in an orderly lattice, & we call this a CRYSTAL or CRYSTALLINE SOLID
But going doing that whole LIQUID ➡️ CRYSTAL thong (CRYSTALLIZATION) takes a lot of coordination – It requires NUCLEATION. Kinda like an unplanned flash mob dance – you need “trendsetting” molecules to freeze together in the “right” orientation (NUCLEATE) to form a “seed” & then others join in & those others have to be able to find that seed & get there before they run out of energy themselves.
So if you don’t want a crystal to form you can
- make them too tired to find each other – molecular movement requires energy – and heat is a form of energy – so if you lower the temperature, you sap their energy so they’re “stuck with swaying in place”
- not give them enough time to find each other (cool it really quickly)
- make it harder to get there – use viscous (syrupy) liquids that are hard to move through
- make it harder to find each other – add CRYOPROTECTANTS like glycerol that act as “dance chaperones,” breaking the molecules up and making it harder to “find Waldo” – the “costliest” part of crystallization is that initial trend-setting (nucleation) – so that’s what you really really want to make it hard to do
- make them like each other less – how much molecules like each other versus the liquid their in or other molecules around depends on things like the pH and salt concentration of the liquid – we often take advantage of this – but in the opposite way – in protein crystallography. There we where we *want* our *proteins* (but not the water in them) to form nice orderly crystals so that we can shine x-ray beams at them and have those beams bounce off a uniformly-arranged object so we can work backwards from them and figure out what the protein looks like. So we can gradually change pH and salt concentration and stuff to get the molecules to like each other and/or hate the water more. Lots more starting here: http://bit.ly/2qlzlRS
But for normal protein work, I don’t want the proteins linking together either. Instead I want to “freeze” them in place – basically just take away their energy – I want them to be as much like how they are now when I wake them up as possible. So what I want is a disordered, AMORPHOUS SOLID 👉 we call this a GLASS & the process of forming it is VITRIFICATION
the GLASS TRANSITION TEMPERATURE (Tg) is the range of temperatures in which a glass can form & it’s ⬇️ than the freezing temperature (when you go liquid ➡️ crystal). So in order to get to it you have to quickly skip past the freezing point to get to a SUPERCOOLED STATE (which you can do bc of the coordination required for crystallization) and cryoprotectants ⬇️ freezing point & ⬆️ Tg (so u have less time in “danger zone” between them) – to form a crystal the water molecules must “push away” the glycerol molecules in between them and link together in their exclusive “clique.”
Today I finished those protein purifications I started yesterday – yesterday I did the lysis (cell-breaking-open) & affinity chromatography (getting my protein to stick to a column of little beads (resin) that bind an artificial tag I engineered onto the end of my protein, then washing all the other gunk off and then competing off my protein. And then I added a site-specific endonuclease (protein scissors) that recognizes a sequence of protein letters (amino acids) that’s in between my protein and the tag. And then I ran ion exchange chromatography to separate the protein from the tag and the tag cleaver and any other lingering proteins by their charge.
Then today I did the “polishing” step of my protein prep – size exclusion chromatography (SEC) which separates proteins by size. Then, after concentrating them, it was time for the “freezing” – and remember, when I say I freeze my proteins I’m not *really* freezing them – my proteins are way too cool to do that to – instead I “supercool” them before I store them away for safe keeping in the -80°C freezer – this way the water in & around my protein molecules doesn’t crystallize (form ice) (which, remember could push out salts, push on my protein, etc.)
So “freezing time” is really vitreous glass making time. Since the molecules stay where they were as a liquid, you don’t get the expansion you get with ice & the solutes can stay put too so the environment stays the same
The great thing about vitrification here is that we can “wake up” the protein and it’ll act the same – but it’s never really quite the same – when you thaw a frozen sample, you’re adding energy that lets the molecules break free from one another & seek out new binding partners. But if you remove the energy again, they get stuck in place again (re-freeze). You can keep doing this freeze-thawing, but each time you do this you have more chances of crystals forming and damaging your sample. So you want to avoid multiple freeze-thaws.
But I have way more protein than I’d ever want to use at once – and I want to store it frozen to prevent degradation – so what to do? Make aliquots! These are like “single-portion” packages so that when I want to use some I only have to unfreeze what I want to use.
But since I usually don’t need to use a lot each time, I want to make fairly small aliquots but if I were to do this to all of my sample I’d have a lot a lot of aliquots. So instead I aliquot out 10-15 portions and then store the rest in bigger portions. If I go through the small aliquots I can dip into these “stocks” & aliquot those out.
I use glycerol as my cryoprotectant because it’s water-like so it’s not a big shock to my protein – but it’s less sticky than water. Then I dunk tubes of protein in liquid nitrogen to race through the freezing point & outrun ice formation
Liquid nitrogen is sometimes abbreviated LN2 , referring to the fact that the atoms of nitrogen (N) are present in pairs (it’s diatomic). Nitrogen has a freezing point of −210 °C (−346 °F) so it can exist in a liquid form at very very cold temperatures (temperatures at which water w/a freezing point of 0°C (32 °F) would be frozen solid). So even though I’m using it as a liquid, it’s really really cold! (remember to take safety precautions – freeze your samples not your skin!)
With water, I’m worried about freezing, but with LN2, the bigger concern is *boiling*! When it comes into contact with warmer things (such as my samples), the heat from the warmer thing is transferred to the LN2. As a result, the sample is rapidly frozen, but the LN2 evaporates into N2 gas. This looks really cool but also means you’ll need more of the liquid form than you expect (our lab goes through a ton of it!). more here: http://bit.ly/30JJBni
In undergrad we didn’t have tons of liquid N like we do here, so I would use wire to wrap around the tube and stick it in – but one time the wire broke and my tube fell in 😥 But here we have a great machine shop down the hall that has a laser cutter and they made us these plastic “freezing aids” (don’t know what their technical term is) with spaced out holes to hold eppendorf tubes on ice (*on* but not *in*!) while I’m making the portions – then I pull it off the ice and stick it in the nitrogen. Let it freeze then whisk the tubes off to the -80.