O-glycosylation of the mammalian protein is investigated. It is serine or threonine specific, though any consensus sequence is still unknown. We have applied support vector machines (SVM) for the prediction of O-glycosylation sites from various kinds of protein information, aiming to investigate the condition for glycosylation and elucidate the mechanisms. In the present study, first we focus on the distribution of the glycosylation sites. It is observed that many O-glycosylated sites are in clusters of closely spaced glycosylated sites, whereas the other sites are found sparsely or isolated. These two types of crowded and isolated sites might have different glycosylation mechanisms. Therefore, we divide the whole O-glycosylation sites into the crowded and the isolated groups. For each group, SVM is trained to predict the O-glycosylation sites separately. The prediction results of two SVMs have different input information dependency. The results indicate that some motifs are expected for the isolated group, while the interaction between the glycosylated sites and the relative proportion of the surrounding amino acids affect the glycosylation for the crowded group. Then, we compare the statistics of amino acid sequences around the glycosylation sites of both groups. As the results, some amino acids (proline, valine, alanine etc.) have high existence probabilities at each specific position relative to a glycosylation site, especially for the isolated glycosylation. Moreover, independent component analysis for the amino acid sequences elucidates position specific existences of the above amino acids, including well known proline at −1 and +3, which are found as different independent components. Finally, we investigate the relation with O-glycosylation and the domain structure or the disordered region of the protein. It is clearly observed that O-glycosylation is more frequently observed in the disordered region and less in the domain. This could be the key feature to understand the non-conservation property, the role in functional diversity and structural stability of O-glycosylation.