Consider the complete graph on n vertices. To each vertex assign an Ising spin that can take the values -1 or +1. Each spin i in [n]={1,2,dots , n} interacts with a magnetic field h in [0,infty ), while each pair of spins i,j in [n] interact with each other at coupling strength n^{-1} J(i)J(j), where J=(J(i))_{i in [n]} are i.i.d. non-negative random variables drawn from a probability distribution with finite support. Spins flip according to a Metropolis dynamics at inverse temperature beta in (0,infty ). We show that there are critical thresholds beta _c and h_c(beta ) such that, in the limit as nrightarrow infty , the system exhibits metastable behaviour if and only if beta in (beta _c, infty ) and h in [0,h_c(beta )). Our main result is a sharp asymptotics, up to a multiplicative error 1+o_n(1), of the average crossover time from any metastable state to the set of states with lower free energy. We use standard techniques of the potential-theoretic approach to metastability. The leading order term in the asymptotics does not depend on the realisation of J, while the correction terms do. The leading order of the correction term is sqrt{n} times a centred Gaussian random variable with a complicated variance depending on beta ,h, on the law of J and on the metastable state. The critical thresholds beta _c and h_c(beta ) depend on the law of J, and so does the number of metastable states. We derive an explicit formula for beta _c and identify some properties of beta mapsto h_c(beta ). Interestingly, the latter is not necessarily monotone, meaning that the metastable crossover may be re-entrant.