Preface. Mathematical background: The Poincar^D'e group, the Lorentz group; Finite-dimensional representations of ^ISpin(3,1); The Lorentz algebra; Two-component and four-component spinors; Representations of the Poincar^D'e group; Elements of differential geometry and gravity; The conformal group; The mass-shell field representation; Elements of algebra with supernumbers; Elements of analysis with supernumbers; The supergroup of general coordinate transformations on R^Tp/q. Supersymmetry and superspace: Introduction: from R^Tp/q to supersymmetry; Superalgebras, Grassmann-shells and super Lie groups; The Poincar^D'e superalgebra; Unitary representation of the Poincar^D'e superalgebra; Real superspace R^T4/4 and superfields; Complex superspace C^T4/2, chiral superfields and covariant derivatives; The on-shell massive superfield representations; The on-shell massless superfield representations; From superfields to component fields; The superconformal group. Field theory in superspace: Supersymmetric field theory; Wess-Zumino model; Supersymmetric nonlinear sigma-models; Vector multiplet models; Supersymmetric Yang-Mills theories; Geometric approach to super Yang-Mills theories; Classically equivalent theories. Quantized superfields: Picture-change operators; Equivalence of component field and superfield perturbation theories; Effective action (super) funtional; The Wess-Zumino model: perturbative analysis; Note about gauge theories; Feynman rules for super Yang-Mills theories; Renormalization; Examples of counterterm calculations: an alternative technique; Superfield effective potential. Superspace geometry of supergravity: Gauge group of supergravity and supergravity fields; Superspace differential geometry; Supergeometry with conformal supergravity constraints; Prepotentials; Einstein supergravity; Prepotential de formations; Supercurrent and supertrace; Supergravity in components. Dynamics in supergravity: Pure supergravity dynamics; Linearized supergravity; Superg.