Bacterial small regulatory RNAs (sRNAs) are the most abundant class of post-transcriptional regulators and have been well studied in Gram-negative bacteria. Little is known about the functions and mechanisms of sRNAs in high GC Gram-positive bacteria including
Mycobacterium
and
Streptomyces
. Here, we performed an in-depth study of 6C sRNA of
Mycobacterium tuberculosis
, which is conserved among high GC Gram-positive bacteria. Forty-seven genes were identified as possible direct targets of 6C sRNA and 15 of them were validated using an
in vivo
translational
lacZ
fusion system. We found that 6C sRNA plays a pleotropic role and regulates genes involved in various cellular processes, including DNA replication and protein secretion. Mapping the interactions of 6C sRNA with mRNA targets
panD
and
dnaB
revealed that the C-rich loops of 6C sRNA act as direct binding sites to mRNA targets. Unlike in Gram-negative bacteria where RNA binding proteins Hfq and ProQ are required, the interactions of 6C sRNA with mRNAs appear to be independent of RNA chaperones. Our findings suggest that the multiple G–C pairings between single stranded regions are sufficient to establish stable interactions between 6C sRNA and mRNA targets, providing a mechanism for sRNAs in high GC Gram-positive bacteria.
Background
The ongoing COVID-19 pandemic has resulted in 185 million recorded cases and over 4 million deaths worldwide. Several COVID-19 vaccines have been approved for emergency use in humans and are being used in many countries. However, all the approved vaccines are administered by intramuscular injection and this may not prevent upper airway infection or viral transmission.
Results
Here, we describe a novel, intranasally delivered COVID-19 vaccine based on a helper-dependent adenoviral (HD-Ad) vector. The vaccine (HD-Ad_RBD) produces a soluble secreted form of the receptor binding domain (RBD) of the SARS-CoV-2 spike protein and we show it induced robust mucosal and systemic immunity. Moreover, intranasal immunization of K18-hACE2 mice with HD-Ad_RBD using a prime-boost regimen, resulted in complete protection of the upper respiratory tract against SARS-CoV-2 infection.
Conclusion
Our approaches provide a powerful platform for constructing highly effective vaccines targeting SARS-CoV-2 and its emerging variants.
Tuberculosis (TB) is the global leading cause of death from an infectious agent with approximately 10 million new cases of TB and 1.45 million deaths in 2018. Bacille Calmette-Guérin (BCG) remains the only approved vaccine for Mycobacterium tuberculosis (M. tb, causative agent of TB), however clinical studies have shown BCG has variable effectiveness ranging from 0–80% in adults. With 1.7 billion people latently infected, it is becoming clear that vaccine regimens aimed at both post-exposure and pre-exposure to M. tb will be crucial to end the TB epidemic. The two main strategies to improve or replace BCG are subunit and live attenuated vaccines. However, following the failure of the MVA85A phase IIb trial in 2013, more varied and innovative approaches are being developed. These include recombinant BCG strains, genetically attenuated M. tb and naturally attenuated mycobacteria strains, novel methods of immunogenic antigen discovery including for hypervirulent M. tb strains, improved antigen recognition and delivery strategies, and broader selection of viral vectors. This article reviews preclinical vaccine work in the last 5 years with focus on those tested against M. tb challenge in relevant animal models.
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