Microtubules grow by incorporating αβ-tubulin heterodimers into the dynamic plus ends while their minus ends are often anchored at microtubule organizing centers. Plus ends exhibit a stochastic “dynamic instability,” so that neighboring microtubules oscillate between phases of growth and shrinkage independently of one another. The frequency with which microtubules change from growth to shrinkage is influenced by a variety of stimuli so that the distribution of the microtubule cyto-skeleton changes in response to developmental or positional cues (Kirschner and Mitchison 1986). The class of microtubule-associated proteins (MAPs) known as +TIPs plays a critical role in regulating microtubule dynamics. +TIPs associate with the dynamic, plus ends to modulate microtubule dynamics to mediate interactions between microtubule ends and specific docking sites within the cell (Akhmanova and Hoogenraad 2005; Galjart 2005). All major metazoan +TIPs studied so far including the dynactin component p150glued, Lis1, CLASP (CLIP170-associated protein), and EB1 are physically or functionally linked with the founder +TIP CLIP170 (Coquelle et al. 2002; Goodson et al. 2003; Lansbergen et al. 2004; Mimori-Kiyosue et al. 2005). Although there are functional distinctions between different +TIPs, they do physically interact with one another and so presumably influence each other's function. Importantly, an individual +TIP can interact with two partner +TIPs by distinct mechanisms (Coquelle et al. 2002; Goodson et al. 2003; Mimori-Kiyosue et al. 2005; Wolyniak et al. 2006), highlighting the complexity of the integration of +TIP function at microtubule ends. CLASP molecules were first identified by genetic approaches (Pasqualone and Huffaker 1994; Inoue et al. 2000) but subsequently gained their name by virtue of their physical association with CLIP170 and CLIP115 (Akhmanova et al. 2001). CLASPs are required to maintain a stem cell component in Drosophila and for ordered cell migration in vertebrates (Mathe et al. 2003; Lee et al. 2004) and can be critically important for localized modulation of microtubule dynamics (Inoue et al. 2004). Mammalian CLASPs stabilize the association of microtubules and the cell cortex (Mimori-Kiyosue et al. 2005). The simple fission yeast cytoskeleton offers unique opportunities for the analysis of conserved aspects of microtubule function. A differentiated interphase cytoskeleton, in which the plus ends extend away from a centrally placed nucleus, distributes mitochondria, maintains the central position of the nucleus, and delivers cell polarity determinants such as the Kelch domain protein Tea1 to the cell tips (Mata and Nurse 1997; Hagan 1998). Tea1 is transported to cell tips as a result of its association with the +TIPs Tea2 (kinesin-related protein), Tip1 (CLIP170), and Mal3 (EB1) (Browning et al. 2000, 2003; Brunner and Nurse 2000). Exactly how they mediate Tea1 transport remains to be established; however, all four molecules move along the microtubule lattice as well as associating with the growing plus ends. Although Tip1 can associate with microtubules in cells from which the tea2 + gene has been deleted (Busch and Brunner 2004), a large part of the movement of the Tea1/ Tip1/Mal3 complex along the microtubule lattice is mediated by Tea2 activity, and the physical association between Mal3 and Tea2 stimulates the ATPase activity of the kinesin (Browning et al. 1998, 2000; Browning and Hackney 2005). We now show that the Schizosaccharomyces pombe CLASP Peg1 destabilized microtubules in interphase and yet promoted microtubule stability in mitosis. Focusing on interphase, we did not find a strong link between the function of Peg1 and that of Mal3 or Tip1; rather, we revealed a strong functional link between Peg1 and dynein.