Identically vanishing $k$-generalized Fibonacci polynomials

The Fibonacci polynomials are a generalization of the Fibonacci numbers. The $k$-generalized Fibonacci polynomials are a further generalization to $k\ge2$ summands, which satisfy the recurrence $\mathcal{F}_{n,k}(x) = x^{k-1}\mathcal{F}_{n-1,k}(x) +x^{k-2}\mathcal{F}_{n-2,k}(x) +\dots +\mathcal{F}_{n-k,k}(x)$. Most of the attention in the literature iterates the above recurrence upwards to positive values of $n$. We show that, when the recurrence is iterated downwards to negative values of $n$, there are indices where the polynomials $vanish\; identically$. This fact does not seem to have been noted in the literature. There are $k(k-1)/2$ such indices. We enumerate and prove the complete list of such indices. We also employ generating functions to derive combinatorial sums for the $k$-generalized Fibonacci polynomials, both for positive and negative $n$. (Separate generating functions and combinatorial sums are required for positive and negative $n$.) Lastly, we show that, unlike the case for positive $n$, the degree of a $k$-generalized Fibonacci polynomial (where $k\ge3$) does $not$ increase monotonically with $|n|$ for $n<0$. We conjecture a formula for the degree of the polynomial. It has been verified numerically for all values $k=2,\dots,100$ and $1 \le |n| \le 1000$.