It's a bit easier to see this using a slightly non-standard definition of topological K-theory. Given a locally compact Hausdorff space $X$, let $\bf{E}$ be a complex of vector bundles, i.e. a sequence $$0 \to E_0 \xrightarrow{\alpha_0} E_1 \xrightarrow{\alpha_1} \ldots \xrightarrow{\alpha_{n-1}} E_n \to 0$$ where the $\alpha_i$'s are bundle maps and $\alpha_{i+1} \circ \alpha_i = 0$. The *support* of $\bf{E}$ is by definition the set of all $x \in X$ such that the fiber of $\bf{E}$ over $x$ is not exact. A *homotopy* between complexes $\bf{E}$ and $\bf{F}$ is a complex over $X \times [0,1]$ whose restriction to $X \times 0$ is isomorphic to $\bf{E}$ and whose restriction to $X \times 1$ is isomorphic to $\bf{F}$. Finally, declare that two compactly supported complexes of vector bundles over $X$ are equivalent if there is a compactly supported homotopy between them, and let $C(X)$ denote the set of all equivalence classes. $C(X)$ is an abelian group under Whitney sum of complexes, and it has a subgroup $C_0(X)$ consisting of complexes with empty support, i.e. the complex is exact over every point in $X$. **Proposition:** $K(X) \cong C(X) / C_0(X)$ There is a proof in Atiyah's book on K-theory, for example. With that in hand, let $D$ be an elliptic operator mapping smooth sections of a vector bundle $E$ to smooth sections of a vector bundle $F$ over the same compact base manifold $M$. Let $\pi \colon TM \to M$ denote the tangent bundle of $M$. For each $x \in M$ and $V \in T_x M$, the symbol of $D$ is a linear map $$\sigma(x, V) \colon E_x \to F_x$$ which varies smoothly in $x$ and $V$. Thus it defines a complex of vector bundles over TM: $$0 \to \pi^* E \xrightarrow{\sigma} \pi^* F \to 0$$ The condition that $D$ is elliptic means that $\sigma$ is invertible - and hence the complex above is exact - outside of the zero section of $TM$, which is compact since $M$ is compact. So by the definition of K-theory above we get a class $[\sigma] \in K(TM)$.