TMPRSS2 activation of Omicron lineage Spike glycoproteins is regulated by TMPRSS2 cleavage of ACE2 (preprint)

Continued high levels spread of SARS-CoV-2 globally enabled accumulation of changes within the Spike glycoprotein, leading to resistance to neutralising antibodies and concomitant changes to entry requirements that increased viral transmission fitness. Herein, we demonstrate a significant change in ACE2 and TMPRSS2 use by primary SARS-CoV-2 isolates that occurred upon arrival of Omicron lineages. Mechanistically we show this shift to be a function of two distinct ACE2 pools based on cleavage or non-cleavage of ACE2 by TMPRSS2 activity. In engineered cells overexpressing ACE2 and TMPRSS2, ACE2 was cleaved by TMPRSS2 and this led to either augmentation or progressive attenuation of pre-Omicron and Omicron lineages, respectfully. In contrast, TMPRSS2 resistant ACE2 restored infectivity across all Omicron lineages through enabling ACE2 binding that facilitated TMPRSS2 spike activation. Therefore, our data support the tropism shift of Omicron lineages to be a function of evolution towards the use of uncleaved pools of ACE2 with the latter consistent with its role as a chaperone for many tissue specific amino acid transport proteins.

Rapid isolation and resolution immune evasion and viral fitness across contemporary SARS-CoV-2 variants (preprint)

From late 2020 the world observed the rapid emergence of many distinct SARS-CoV-2 variants. At the same time, pandemic responses coalesced into significant global vaccine roll-out that have now significantly lowered Covid-19 hospital and mortality rates in the developed world. Over this period, we developed a rapid platform (R-20) for viral isolation and characterisation using primary remnant diagnostic swabs. This combined with quarantine testing and genomics surveillance, enabled the rapid isolation and characterisation of all major SARS-CoV-2 variants (all variants of concern and 6 variants of interest) globally with a 4-month period. This platform facilitated viral variant isolation and enabled rapid resolution of variant phenotype by allowing determining end point viral titers from primary nasopharyngeal swabs and through ranking of evasion of neutralising antibodies. In late 2021, when the Delta variant was dominating, Omicron rapidly emerged. Using this platform, we isolated and tested the first cases of this variant within Australia. In this setting we observed Omicron to diverge from other variants at two levels: Firstly, it ranks at the mots evasive to neutralisation antibodies compared to all VOCs and major VUIs. Secondly, it no longer engages TMPRSS2 during the late stages of fusion.