**Case 3:**

Let me define $t=x\sqrt{2\gamma}$, then it is known from random-matrix theory (see, for example, <A HREF="https://press.princeton.edu/books/hardcover/9780691128290/log-gases-and-random-matrices-lms-34">Forrester's book</A>) that for a fixed $\gamma$ the probability distribution $P(x_1)$ of a single eigenvalue $x_1$ tends in the limit $n\rightarrow\infty$ to the $\gamma$-independent semicircle
$$P(x)=\frac{1}{\pi n}\sqrt{2n-x^2},\;\;|x|\leq\sqrt{2n}.$$
The desired ratio $\nu$ then evaluates to
$$\nu=\frac{\int (2\gamma x^2-1)P(x)\,dx}{\left[\int (2\gamma x^2-1)^2P(x)\,dx\right]^{1/2}}=\frac{\gamma n-1}{\sqrt{2 \gamma n (\gamma n-1)+1}}\rightarrow \frac{1}{\sqrt 2}\;\;\text{for}\;\;n\rightarrow\infty.$$

**Case 2:**

The case that $n\rightarrow\infty$, $\gamma\rightarrow 0$ at fixed $\gamma n=\alpha>0$ has been studied in <A HREF="https://projecteuclid.org/euclid.ecp/1465320995">The mean spectral measures of random Jacobi matrices related to Gaussian beta ensembles</A> (2014), see also <A HREF="https://arxiv.org/abs/1611.09476">arXiv:1611.09476</A>. The probability distribution $P(\lambda)$ is given in this limit by
$$P(\lambda)=\frac{e^{-\lambda^2/2}}{\sqrt{2\pi}}\frac{1}
{|f(\lambda)|^2},\;\;f(\lambda)=\sqrt{\frac{\alpha}{\Gamma(\alpha)}}\int_0^\infty t^{\alpha-1}e^{i\lambda t-t^2/2}\,dt.$$
From the desired $\nu$ can be readily computed (I will do so shortly).