It's not "binding" but precipitation. The surface of the beads only serves to nucleate precipitation.

Not in a position to add more now, but I have never seen a definitive reference that explains the precipitation chemistry. PEG/NaCl removes enough water to precipitate DNA...higher levels are required to precipitate smaller fragments. Don't add enough, small fragments don't precipitate.**


**WARNING: Molecular biologist talking solution chemistry. Use caution.

I don't know the full detail, but you have two processes:

(1) PEG/High salt precipitates polynucleotides. The higher the MW of the polynucleotide the more efficiently it precipitates.
I generally think of precipitations of this sort being the result of the PEG occupying some fraction of the water molecules that normally would be solubilizing the polynucleotides. The longer the polynucleotide, the more water atoms need to be available to keep it in solution.
We used to do hard (microfuge) spins to collect the precipitated material.

(2) The beads bind polynucleotides via their charge. I presume this interaction is not enough by itself to pull the polynucleotides out of solution. But in the presence of precipitate they gather appropriately charged molecules to their surface.

--
Phillip

Hawkins, T.L., et al. (1994). DNA purification and isolation using a solid-phase. Nucl Acid Res 22(21):4543-4. looks like the original "SPRI" paper.

Here is the comment about carboxylated beads from that paper.

Ref 6 above is Lis,J. (1980) Methods Enzymol. 65, 347-353. and is about PEG precipitation of DNA but no mention of carboxylated beads that I noticed.

The word "bind" above suggests more than a nucleation site to me. But because no mechanism is given for the binding, I have nothing to dispute a "nucleation only" hypothesis.

--
Phillip