BACKGROUND: Streptococcus pneumoniae serotype 3 is one of the most prevalent serotypes that cause invasive pneumococcal disease (IPD) in children and adults worldwide. Serotype 3 is associated with vaccine failures and breakthrough episodes in children vaccinated with 13-valent pneumococcal conjugate vaccine (PCV13). In this study, we aimed to investigate potential genetic mechanisms that could explain the increase in cases of serotype 3 IPD in Spain. METHODS: We analysed the epidemiology of serotype 3 causing IPD in Spain, during 2009-23, in different age groups. Molecular characterisation was performed by whole-genome sequencing. Host-pathogen interactions of the different lineages were evaluated in terms of interaction with lung epithelial cells, biofilm formation, and capsular polysaccharide production, using opsonophagocytosis assays and mouse models of pneumonia. We used Poisson regression models to compare incidence and chi-square test calculations to identify clonal variations across vaccine periods. FINDINGS: Genomic analyses confirmed the predominance of clade I-α/clonal complex (CC) 180 in Spain, which shows increased resistance to complement-mediated immunity and phagocytosis and enhanced potential to infect lung cells. In all isolates of this lineage, we observed a single amino acid substitution (166His→Tyr) in the crucial virulence factor LytA, which increased its enzymatic activity. On evaluating the phagocytosis of mutants without LytA of the two major lineages of serotype 3 (CC180 and CC260), LytA was responsible for the increased phagocytosis-evasion pattern of clade I-α/CC180. Evaluation of individuals with IPD caused by different serotype 3 genotypes confirmed a significant (p<0·05) association between cardiac and respiratory comorbidities and infection by sequence type 180/CC180, which showed the importance of CC180 in IPD. INTERPRETATION: Our findings confirm that PCV13 reduced IPD cases caused by the susceptible CC260 lineage until CC260 was replaced by the clade I-α/CC180 lineage, which has a higher potential to cause IPD and divert the host immune system. A key mutation on LytA protein was associated with this hypervirulent phenotype. Emerging lineages jeopardise the effectiveness of pneumococcal conjugate vaccines. FUNDING: Ministerio de Ciencia e Innovación, Instituto de Salud Carlos III, and PubMLST.