We consider $n\times n$ complex matrices. Let $i_+(A), i_-(A), i_0(A)$ be the number of eigenvalues of $A$ with positive real part, negative real part and pure imaginary. It is well known if two Hermitian matrices $A$ and $B$ are $*-$congruent, then
 $$(i_+(A), i_-(A), i_0(A))=(i_+(B), i_-(B), i_0(B)).\qquad{(1)}$$
If two general matrices $A$ and $B$ are $*-$congruent, (1) may not hold. But I have come up a counterexample for this.
Moreover, whether a matrix and its transpose are always $*-$congruent?