The Arens-Michael envelope is an example of a natural colimit in Functional analysis. Intuitively it is an operation (a functor) that turns each topological algebra $A$ into its nearest from the outside holomorphic algebra $\text{Env}A$.
As an illustration, if $A$ is the algebra ${\mathcal P}(M)$ of polynomials on an affine algebraic manifold $M$, then its Arens-Micael envelope $\text{Env}A$ is exactly the algebra ${\mathcal O}(M)$ of holomorphic functions on $M$:
$$
\text{Env}{\mathcal P}(M)={\mathcal O}(M).
$$
Here $A$ need not be necessarily commutative, moreover the non-commutative case is especially interesting, since it generates non-trivial computations in non-commutative geometry. For example, the "polynomial version" of the so-called $az+b$-group is turned into its "holomorphic version":
$$
\text{Env}{\mathcal P}_q({\mathbb C}^\times\ltimes{\mathbb C})={\mathcal O}_q({\mathbb C}^\times\ltimes{\mathbb C}),
$$
for $|q|=1$, but the formula becomes different in the case of $|q|\ne 1$:
$$
\text{Env}{\mathcal P}_q({\mathbb C}^\times\ltimes{\mathbb C})={\mathcal O}({\mathbb C}^\times)\underset{\delta^q}{\overset{z}{\odot}}{\mathcal
R}^\star({\mathbb C})
$$
(see details in my paper).
Similarly, there are natural functors of taking
the nearest continuous topological algebra with the formula $$ \text{Env}A={\mathcal C}(M) $$
for a subalgebra $A$ in ${\mathcal C}(M)$ having $M$ as the involutive spectrum, andthe nearest smooth topological algebra with the formula $$ \text{Env}A={\mathcal C}^\infty(M) $$
for a subalgebra $A$ in ${\mathcal C}^\infty(M)$ having $M$ as the involutive spectrum and $T_x(M)$ as the involutive tangent space in each point $x\in M$.