Post by Nadica (She/Her) on Jul 19, 2024 1:25:21 GMT
Virological characteristics of the SARS-CoV-2 KP.3.1.1 variant - Preprint Posted July 17, 2024
Abstract
The SARS-CoV-2 JN.1 variant (BA.2.86.1.1), arising from BA.2.86.1 with spike protein (S) substitution S:L455S, outcompeted the previously predominant XBB lineages by the beginning of 2024. Subsequently, JN.1 subvariants including KP.2 (JN.1.11.1.2) and KP.3 (JN.1.11.1.3), which acquired additional S substitutions e.g., S:R346T, S:F456L, and S:Q493E, have emerged concurrently. Thereafter, JN.1 subvariants, such as LB.1 (JN.1.9.2.1), KP.2.3 (JN.1.11.1.2.3), and KP.3.1.1 (JN.1.11.1.3.1.1), which convergently acquired a deletion of Serine at the 31st position in S (S:S31del) in addition to the above substitutions, have emerged and spread as of June 2024. We recently reported the virological features of JN.1 subvariants including KP.2, KP.3, LB.1, and KP.2.3.2,3 Here, we investigated the virological properties of KP.3.1.1. First, we estimated the relative effective reproduction number (Re) of KP.3.1.1 using a Bayesian multinomial logistic model4 based on genome surveillance data from Spain, the USA, France, Canada, and the UK, where this variant has spread as of June 2024. In Spain, the Re of KP.3.1.1 is over 1.2 fold higher than that of JN.1 and even higher than those of KP.2, KP.3, LB.1, and KP.2.3. Additionally, the other countries under investigation herein show higher Re for KP.3.1.1. However, it must be noted there is the possibility of overestimation in these countries due to more limited KP.3.1.1 sequence numbers. These results suggest that KP.3.1.1 will spread worldwide along with other JN.1 sublineages. We then assessed the virological properties of KP.3.1.1 using pseudoviruses. The pseudovirus of KP.3.1.1 had significantly higher infectivity than that of KP.3. Neutralization of KP.3.1.1 was tested using i) convalescent sera after breakthrough infection (BTI) with XBB.1.5 or EG.5, ii) convalescent sera after the infection with HK.3 or JN.1, and iii) sera after monovalent XBB.1.5 vaccination. The 50% neutralization titer (NT50) against KP.3.1.1 was significantly lower than KP.3 (1.4-1.6 fold) in all four groups of convalescent sera tested. KP.3.1.1 also showed a 1.3 fold lower NT50 against XBB.1.5 vaccine sera than KP.3. Moreover, KP.3.1.1 showed stronger resistance with a 1.3 fold lower NT50 with statistical significances to the convalescent sera infected with EG.5 and HK.3 than KP.2.3. Altogether, KP.3.1.1 exhibited a higher Re, higher pseudovirus infectivity, and higher neutralization evasion than KP.3. These results align with our recent report that the JN.1 subvariants with S:S31del (e.g., KP.2.3 and LB.1) exhibited enhanced Re and immune evasion compared to the other JN.1 subvariants without S:S31del (e.g., JN.1, KP.2, and KP.3), highlighting the evolutionary significance of S:S31del in the JN.1 lineages.
Competing Interest Statement
J.I. has consulting fees and honoraria for lectures from Takeda Pharmaceutical Co. Ltd. K.S. has consulting fees from Moderna Japan Co., Ltd. and Takeda Pharmaceutical Co. Ltd., and honoraria for lectures from Moderna Japan Co., Ltd. and Shionogi & Co., Ltd. The other authors declare no competing interests. All authors have submitted the ICMJE Form for Disclosure of Potential Conflicts of Interest. Conflicts that the editors consider relevant to the content of the manuscript have been disclosed.
Abstract
The SARS-CoV-2 JN.1 variant (BA.2.86.1.1), arising from BA.2.86.1 with spike protein (S) substitution S:L455S, outcompeted the previously predominant XBB lineages by the beginning of 2024. Subsequently, JN.1 subvariants including KP.2 (JN.1.11.1.2) and KP.3 (JN.1.11.1.3), which acquired additional S substitutions e.g., S:R346T, S:F456L, and S:Q493E, have emerged concurrently. Thereafter, JN.1 subvariants, such as LB.1 (JN.1.9.2.1), KP.2.3 (JN.1.11.1.2.3), and KP.3.1.1 (JN.1.11.1.3.1.1), which convergently acquired a deletion of Serine at the 31st position in S (S:S31del) in addition to the above substitutions, have emerged and spread as of June 2024. We recently reported the virological features of JN.1 subvariants including KP.2, KP.3, LB.1, and KP.2.3.2,3 Here, we investigated the virological properties of KP.3.1.1. First, we estimated the relative effective reproduction number (Re) of KP.3.1.1 using a Bayesian multinomial logistic model4 based on genome surveillance data from Spain, the USA, France, Canada, and the UK, where this variant has spread as of June 2024. In Spain, the Re of KP.3.1.1 is over 1.2 fold higher than that of JN.1 and even higher than those of KP.2, KP.3, LB.1, and KP.2.3. Additionally, the other countries under investigation herein show higher Re for KP.3.1.1. However, it must be noted there is the possibility of overestimation in these countries due to more limited KP.3.1.1 sequence numbers. These results suggest that KP.3.1.1 will spread worldwide along with other JN.1 sublineages. We then assessed the virological properties of KP.3.1.1 using pseudoviruses. The pseudovirus of KP.3.1.1 had significantly higher infectivity than that of KP.3. Neutralization of KP.3.1.1 was tested using i) convalescent sera after breakthrough infection (BTI) with XBB.1.5 or EG.5, ii) convalescent sera after the infection with HK.3 or JN.1, and iii) sera after monovalent XBB.1.5 vaccination. The 50% neutralization titer (NT50) against KP.3.1.1 was significantly lower than KP.3 (1.4-1.6 fold) in all four groups of convalescent sera tested. KP.3.1.1 also showed a 1.3 fold lower NT50 against XBB.1.5 vaccine sera than KP.3. Moreover, KP.3.1.1 showed stronger resistance with a 1.3 fold lower NT50 with statistical significances to the convalescent sera infected with EG.5 and HK.3 than KP.2.3. Altogether, KP.3.1.1 exhibited a higher Re, higher pseudovirus infectivity, and higher neutralization evasion than KP.3. These results align with our recent report that the JN.1 subvariants with S:S31del (e.g., KP.2.3 and LB.1) exhibited enhanced Re and immune evasion compared to the other JN.1 subvariants without S:S31del (e.g., JN.1, KP.2, and KP.3), highlighting the evolutionary significance of S:S31del in the JN.1 lineages.
Competing Interest Statement
J.I. has consulting fees and honoraria for lectures from Takeda Pharmaceutical Co. Ltd. K.S. has consulting fees from Moderna Japan Co., Ltd. and Takeda Pharmaceutical Co. Ltd., and honoraria for lectures from Moderna Japan Co., Ltd. and Shionogi & Co., Ltd. The other authors declare no competing interests. All authors have submitted the ICMJE Form for Disclosure of Potential Conflicts of Interest. Conflicts that the editors consider relevant to the content of the manuscript have been disclosed.