This can be done without invoking the Beta function explicitly. Directly from the integral definition of $\Gamma(x)$,the product in question is a double integral:
$$
\Gamma(x)\Gamma(1-x) =\int^\infty_0\int^\infty_0 (u/v)^x u^{-1} e^{-(u+v)} du\, dv
$$
Switching to polar coordinates via $u=X^2=r^2\cos^2\phi$, $v=Y^2=r^2\sin^2\phi$, the $r$ and $\phi$ integrals decouple and we have
$$
\Gamma(x)\Gamma(1-x)= 4\int_0^{\pi/2} (\tan\phi)^{2x-1} \, d\phi \int_0^\infty r e^{-r^2}\, dr = 2\int_0^{\pi/2} (\tan\phi)^{2x-1} d\phi
$$
Finally, $\phi= \tan^{-1}\sqrt{s}$, brings us to 
$$
\Gamma(x)\Gamma(1-x)=\int^\infty_0 {s^{x-1} ds\over 1+s}
$$
which can be evaluated straightforwardly by contour integration as above.