Why is the anti-commutation relation $lbrace psi_a(x), bar{psi}_b(y) rbrace = 0$ enough to ensure causality?

I think it's easier to start from the general expression for a field operator $phi$:

$$ hatphi_{A,B}(x) = int frac{mathrm{d}^3 mathbf{p}}{(2pi)^3}frac{1}{2E_{mathbf{p}}} sum_s left [ mathrm{e}^{-mathrm{i}px}f_{A,B}(mathbf{p},s)hat a(mathbf{p},s) + mathrm{e}^{mathrm{i}px}h_{A,B}(mathbf{p},s)hat a^dagger(mathbf{p},s) right ]biggvert_{p^0=E_mathbf{p}},$$

where $A$ and $B$ are just labels for two different particles.

The bosonic or fermionic nature of the particles is reflected in the (anti-)commutation relationship between the creation and annihilator operators $a^dagger$ and $a$.

Because operators $mathcal{O}(x)$ are usually just a product of field operators, so that $mathcal{O}(x) propto prod_i hatphi_i(x)$, requiring $[mathcal{O}_1(x), mathcal{O}_2(y)]=0$ is the same as requiring $[hatphi_A(x), hatphi_B(y)]=0$.

For bosons, you have that: $$ [hat a(mathbf{p},s), hat a^dagger(mathbf{p}',s')] = 2E_mathbf{p}(2pi)^3 delta^{(3)}(mathbf{p}-mathbf{p}')delta_{s,s'},$$ while for fermions, you have that: $$ {hat a(mathbf{p},s), hat a^dagger(mathbf{p}',s')} = 2E_mathbf{p}(2pi)^3 delta^{(3)}(mathbf{p}-mathbf{p}')delta_{s,s'}.$$

Then you can show that this results in: $$ text{For bosons: }[hatphi_A(x), hatphi_B(y)] propto 1 - (-1)^{2s} stackrel{!}{=} 0 implies s text{ is an integer.}$$ $$ text{For fermions: }[hatphi_A(x), hatphi_B(y)] propto 1 + (-1)^{2s} stackrel{!}{=} 0 implies s text{ is a half-integer.}$$

The maths is done in Weinberg's The quantum theory of fields volume I, in the chapter called General causal fields.