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="a1a2...anZ". Let S1'="a1a2...an". 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 S2i="b1b2...bkiZbki+1...". Assume S2'="b1b2...bki". 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 2N 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).