Generic programming is slightly different from object oriented programming.
mTuple is an example of a nondependent name. As far as the compiler is concerned, at the time the template definition is processed the compiler doesn't know that the class template has inherited a data member named
mTuple. It might be obvious to you, but it is not obvious to the compiler. At this stage, the compiler is oblivious to the obvious.
If the methods of the derived class template wish to use some member of the parent class template, the compiler needs to be explicitly told to do so. Hence the
The above was a bit terse. It is important to remember that those class templates are not classes. They are templates that eventually define a class. Up until the moment that the class template is used to define a class that class template isn't quite real. More importantly, for a class template that inherits from some other class template, that inheritance isn't quite real. The compiler doesn't know about that inheritance unless it is explicitly told about it. That's why you will see derived class templates import the parent class's members via
using ParentClass<Type>::member (for example).
Marshall Cline discusses this topic in his C++-FAQ at http://www.parashift.com/c++-faq-lite/templates.html#faq-35.19
(Per request) Just because some code compiles on your compiler does not mean it compiles on every compiler (for the same language). Compiler vendors add their own 'features' to a language, sometimes very intentionally, sometimes just because the vendors themselves goofed up, and sometimes because the standard itself is buggy. This issue of not-quite-standard compilers has been a problem for a long time, with many languages. The problem apparently is quite rampant when it comes to generic programming.
You can do everything right (or so you think): Turn on all standard warnings and then some, run your code through some commercial code analyzer, and you still might not have portable code.