Add an R+C. This way you can always use the lone C (R = zero ohm jumper), or add a "shelf" or pole-zero compensation.
If this is more about signals than control loops, it may be desirable to add filtering or bypass at the signal input and/or output, away from the op-amp itself.
Consider,
Q: When is an op-amp not an op-amp?
A: Near GBW.
An active filter only works while the amp gain is high. As amp gain drops to 1 (and below), the compensation capacitor ceases to compensate, and becomes a feed-forward capacitor instead. Typically, for the circuit shown, the frequency response has a low-pass response, where gain falls from nominal (below fc) to maximum attenuation at some modest frequency, then rising again. This is accompanied by a notch, where phase reversal occurs. Above that frequency, gain is determined by the resistor ratios between input and output (including the op-amp's output impedance, which is nonzero, despite what the textbooks say).
So, you can't get unlimited, asymptotic response from a GBW limited amplifier. But you can get close with a passive filter. Keep this in mind when you need squeaky clean filters!
Also, filter RFI away from any wires that leave the board. Only use the bandwidth you need, and filter away the rest.
Tim