MESI protocols apply to caches, store buffering is essentially pre-cache, meaning that it's a store that was not yet "released" to the outside world, and its synchronization point was not yet determined.
You also need to keep in mind that cache coherency only guarantees that writes don't occur on stale copies of a cacheline and get lost along the way. The only guarantee of such protocols is to hide the fact that you have caches with copied values (a performance optimization in itself), and expose to the programmer/OS the illusion of a single level flat physical memory.
That, by itself, gives you no guarantee on the ordering of writes and reads from multiple cores, for that purpose you need to manage your code using additional constructs that the ISA provides, like locks, fences, and relying on memory ordering rules.
The situation you describe is not possible as it breaks the first part - a core that does not own a line can't write to memory since it would miss the updated data in the core that does own the line (if such exists). What would happen under a MESI protocol is that the write will be buffered for a while, and when its turn comes to be issued - it would send a request for ownership that would invalidate all copies of that line in other cores (triggering a writeback if there's a modified copy), and fetch the updated data. Only then the writer core may modify the line and mark it as modified.
However, if 2 cores write to the same line simultaneously, MESI protocol only guarantees that these write will have some order, not a specific one you might want. Worse - if each core write several lines and you want atomicity around these writes, MESI doesn't guarantee that. You'll need to actively add a mutex or a barrier of some sort to force the HW to perform the writes the way you want.