According to currently accepted theory, does gravity behave like light, in regards to relativity?
You
keep making the same mistake of not distinguishing between the field and excitations of the field. Why is the difference so hard to understand? Do you not get the difference between an electric field and light?
Gravity is a field. The analogous field is the electric field. The field itself is not the same thing as waves in the field. If you have a stationary electric charge, it creates a static field, with no waves involved. If you have a stationary mass, it creates a gravitational field, with no waves involved.
Now, if you wiggle the source of the field (be it a charge or a mass), the field should wiggle too. Those wiggles do not propagate outwards from the source at infinite velocity, they travel at c. When a charge wiggles, it produces electromagnetic waves (light being electromagnetic waves within a certain frequency range). When you wiggle a mass, it produces gravitational waves. But the waves themselves are just variations of the fields - you can still have the fields themselves without any waves.
In simple words, does gravity propagate at the speed of light, no matter what the relative motion of a body?
It actually doesn't make a lot of sense to talk about the propagation of gravity or of the electric field. What propagates is any
changes in the field. And changes in both electric and gravitational fields do indeed propagate at c, which is always constant regardless of your reference frame.
Does it Doppler shift? Can it?
Gravitational waves can doppler shift.
Gravity doesn't doppler shift, and neither does the electric field, because Doppler shift only means a change in frequency, and the fields themselves need not have any frequency. If you change reference frames, you do need to change the gravitational field, but that also happens with electric fields too: the electric field of a moving charge gets squished along the direction of motion, and gravity will do something similar.
If Gravity is like light,
It isn't. I've said this before.
Two bodies moving relative to each other, at very high velocities, what happens to gravity? Or is that a valid question?
It's a valid question. The math is really ugly, but it can be calculated. But this problem doesn't really involve gravitational waves.
And does anybody really know?
Yes. And their ideas are being tested, too. In Newtonian physics, a rotating spherical mass has a field identical to a non-rotating spherical mass, but not in GR.
Gravity Probe B was put in orbit to detect the gravitational effects of the earth's rotation, and the results so far confirm GR, which means that their predictions for how motion should affect gravity are correct.
