nano antibodies

Lab Skills You Stopped Being Proud Of

Molecular biologists who were in graduate school in the 90’s learned how to isolate plasmid DNA from E. coli cultures by a method called “boil-prep” during their first lab rotation. This process involved mixing the bacterial cell pellet in a little bit of detergent, salt and sucrose, dabbed with some fresh lysozyme, and then you are ready to cook, literally! Bacterial cell membranes are disrupted by boiling this soup in a beaker of water over a Bunsen Burner for one minute, and the debris (containing the broken cell membrane and attached chromosomal DNA) is collected by centrifugation in a microfuge at top speed for 10 minutes. Then comes the step that differentiates a true master of lab skills versus a rotation student—if you knew just the right amount of bacterial culture to begin with and handled the E coli pellet by the right techniques, a skillful lab person could collect nearly all the liquid without disturbing the pellet. Pouring out the plasmid-containing supernatant without dislodging the goo on the side/bottom of the tube was such a desirable skill that would not only give you your plasmid but also give you admiration from fellow lab members. That is, of course, if you were doing it before the mid-90’s, because after the introduction of miniprep spin columns by Qiagen, nobody, even the true masters of boil-preps (or its contemporary alkali prep that also involves pelleting by centrifugation and careful removal of tiny volume of liquids surrounding small pellets) would be showing off those skills any longer.

It is actually never easy or fun to collect liquid surrounding small amount of beads or pellets as you always have to struggle to remove as much liquid as possible while trying not to lose any of the beads

Some of the old-timers used to also be very proud of being able to pour a “sequencing gel” (a very thin ~40 cm x 30 cm polyacrylamide gel). I still remember the first time I reported to the second rotation lab at USC. After describing the lab research, the PI showed me around the lab and complained how “Sarah destroyed all my sequencing gel plates”. But consider this, in order to avoid any greasy spot on either plate, you needed to wash both of them fanatically if not religiously. Why? You would have just about a minute’s time to pour non-polymerized acrylamide without leaking from the sides or bubbles forming anywhere in the DNA running lanes, and then inserting a pair of paper-thin combs, all at a speed quicker than TEMED/AP-catalyzed acrylamide polymerization. Good thing that after capillary sequencing was invented, we all happily retired our sequencing-gel pouring skills with a collective sigh of relief.

Technology will always move forward, so will the skills lab researchers will be required to perfect. Using a spin column is very much a “skill-less” technique in contrast to collecting pellets and washing beads after centrifugation, but when there is a choice, people will chose the method that requires “less skills”, such as the spin-column format as the preferred platform for the new FP-nAb™ products.

BTW, like to have information on the spin column kit? Here it is: http://www.allelebiotech.com/gfp-nab-agarose-spin-kit-20-reactions/

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Finding the Best Capture Reagents

As capture reagents, monoclonal antibodies are the most widely used reagents for specifically detecting and quantifying proteins due to their very high specificity. However, development of monoclonal antibodies is time-consuming and expensive. In addition, many antigens prove to be non-immunogenic or extremely toxic, and therefore cannot be used to generate antibodies in animals. Furthermore, the large size of monoclonal antibodies (150 kDa) may limit their use in cases where more than one binding reagent competes for space to recognize closely juxtaposed epitopes. These limitations could arguably be the biggest hurdles to using monoclonal antibodies as capture reagents for a systematic study of the complete human proteome or for clinical applications of advanced proteomics.

Therefore, alternative capture reagents with high specificity, high affinity, and flexible size and structure that can be easily and cost-effectively produced are urgently needed in order to accelerate proteomic research. Single-chain variable-fragment (scFv) antibodies have been commonly used as alternatives in this regard. scFv is comprised of only the light chain and heavy chain variable regions connected by a peptide linker and with a molecular weight of 27 kDa. Since scFv retains the antigen-binding site of the variable regions, it inherits the specificity of an intact antibody and affinity. In addition, scFv can be easily expressed in yeast or in E. coli with yields in milligrams per liter. scFv can be linked to Fc of desired species specificity and maintain binding properties. If necessary, there is also the option of converting scFv into other antibody formats such as Fab or full IgG by simple cloning steps. The converted antibodies can also be efficiently expressed and purified in yeast or E. coli.

More recently, single domain antibodies that exist in nature were discovered that can be as small as half the size of scFv, and judging from the available data, superior in binding capabilities to scFv or even traditional IgG antibodies. This type of affinity molecules, termed VHH isolated from camelid animals or nurse shark, can be highly expressed in E. coli, linked to a fluorescent protein marker, or chemically conjugated to HRP or other signal generating moieties through a one step reaction.

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