This is basically a regular expression match problem.

First let's get rid of the "last character matches" condition. We want to reduce the problem to a "plain number of equal subsequences problem, without any conditions.

Suppose S1="a_{1}a_{2}...a_{n}Z". Let S1'="a_{1}a_{2}...a_{n}". Suppose further there are N occurrences of Z in S2. For each occurrence we can write

Suppose there are N occurrences of Z in S2. For each occurrence *i* we can write S2_{i}="b_{1}b_{2}...b_{ki}Zb_{ki+1}...". Assume S2'="b_{1}b_{2}...b_{ki}". Now solve the plain problem for S1' and S2'_{i}, for each i in 1..N.

Now, how to solve the plain problem?

Take the shorter string, say it's S1. Let's now write it `"abc…t"`

. Transform it into `".*a?.*b?.*…t?.*"`

. This is your regular expression. You now need to count how many ways there are for the regular expression to match S2. The match can be done with an NFA-based algorithm.

To actually count the number of matches, one needs to understand the internal workings of an NFA-based match algorithm. There's a set of states that are active at any given moment. A state can split in two, or two states can merge. A state can die if it encounters a wrong character. So you assign a score of 1 to the initial state. When a state splits, each new state inherits the parent's score. When two states merge, the new state gets the sum of the scores. When a state dies, its score is dropped.

I'm not sure if this is any different from what you call the dynamic programming approach. There are up to 2^{N} matches, so on some inputs this *will* take a long time.

**Update**: It looks like it should be also possible to solve the "last character matches" problem directly, without reducing it to the plain problem. Suppose there are 2 occurrences of Z in S2: S2="ab…pZq…yZ". (One can ignore all characters after the last Z anyway). One can build a regex out of S2: `".*a?.*b?.*…p?.*(Z|Z?.*q?.*…y?.*Z)"`

. More occurrences are handled in the same way. A seemingly redundant regexp is needed to maintain the correct number of matches (not just the fact that there's a match).