The potential energy surface for opening and ring-enlargement reactions of 1,2-thiaphosphetane with different oxidation states and coordination at phosphorus has been computationally explored. The most favored [2 + 2] cycloreversions are the so-called normal Wittig-type reactions furnishing an alkene and a P=S-containing component. Somewhat unfavored are reactions involving the P-S bond cleavage and a C-to-P hydrogen shift as well as a ring enlargement to a 1,3,2-dithiaphospholane in the case of high coordinate derivatives. Apart from a two-step P-to-S oxygen transfer in 1,2 sigma(4)lambda(5)-thiaphosphetane P-oxide, an interesting reaction is the P-S bond cleavage leading to a thiabetaine which, alternatively, can be formed by the C-attack of a phosphinidene oxide on a thiirane. A similar route, energetically more favored, was found for 1,2 sigma(5)lambda(5)-thiaphosphetane starting from thiirane and the corresponding phosphane. For a wide set of P(III) reagents including HPR2 (R = Me, Ph), PR3 (R = Me, Ph, NMe2, OMe, F, Cl), and HP=O, the competitive direct S-attack was found to be the preferred pathway for the desulfurization of thiiranes, and the relative tendency for these P(III) reagents to act as an S-atom acceptor, the thermodynamic S-transfer potential (TSP) scale, was defined using the S-8/S-7 couple as a point of reference.