The cell cycle, which typically includes G2, M, G1, and S phases, plays a pivotal role in the reproduction of all living cells and organisms. Molecular biology of the cell cycle has been established over the decades, but intracellular dynamics of molecular species involved in the cell cycle, including proteins and lipids, remain largely unexplored. Label-free Raman imaging has proven itself powerful for studying such dynamic behaviors in vivo and at the molecular level. Here, we present time-lapse Raman imaging of a single live fission yeast cell achieved with a laboratory-built high-sensitivity Raman microspectrometer. We visualize dynamic changes in molecular composition and distribution during the yeast cell cycle (G2 → M → G1/S → G2). We construct Raman images by two approaches, namely, univariate and multivariate data analyses. Univariate data analysis is a simple and convenient approach to obtain Raman images. However, it may suffer from overlapped spectral information, especially for biological samples. To overcome this difficulty, we also attempt multivariate curve resolution (MCR). Time-dependent variations in distributions and compositions during the cell cycle are well accounted for by assuming six components in the MCR analysis. Time-lapse Raman images and normalized integrated intensities for the three major components derived from MCR show that the concentrations of lipids and proteins increase from G2 to M and G1/S phases and reach their maxima right before cytoplasmic division takes place. Moreover, the results show a drastic decrease in amount of lipids by ~50 % after cell division. Interestingly, the MCR analysis uncovers a protein-associated component that has not been detected with the univariate approach.