Two aspects of OOP are data and the generics / methods that operate on data.
The data (especially the data that is the output of an analysis) often consists of structured and inter-related data frames or other objects, and one wishes to manage these in a coordinated fashion. Hence the OOP concept of classes, as a way to organize complex data.
Generics and the methods that implement them represent the common operations performed on data. Their utility comes when a collection of generics operate consistently across conceptually related classes. Perhaps a reasonable example is the output of lm / glm as classes, and the implementation of summary, anova, predict, residuals, etc. as generics and methods.
Many analyses follow familiar work flows; here one is a user of classes and methods, and gets the benefit of coordinated data + familiar generics. Thinking 'OOP' might lead you to explore the methods on the object,
methods(class="lm") rather than its structure, and might help you to structure your work flows so they follow the well-defined channels of established classes and methods.
Implementing a novel statistical methodology, one might think about how to organize the results in to a coherent, inter-related data structure represented as a new class, and to write methods for the class that correspond to established methods on similar classes. Here one gets to represent the data internally in a way that is convenient for subsequent calculation rather than as a user might want to 'see' it (separating representation from interface). And it is easy for the user of your class (as Chambers says, frequently yourself) to use the new class in existing work flows.
It's a useful question to ask 'why OOP' before 'how OOP'.