9. Impaired DNA Repair and Adaptive Immunity
The immune system and the DNA repair system are the two primary systems
that higher organisms rely on for defense against diverse threats, and
they share common elements. Loss of function of key DNA repair proteins
leads to defects in repair that inhibit the production of functional B
and T cells, resulting in immunodeficiency. Non-homologous end joining
(NHEJ) repair plays a critical role in lymphocyte-specific V(D)J
recombination, which is essential for producing the highly diverse
repertoire of B-cell antibodies in response to antigen exposure
[143]. Impaired DNA repair is also a direct pathway towards cancer.
A seminal study conducted by researchers in Shanghai, China monitored
several parameters associated with immune function in a cohort of
patients by conducting single-cell mRNA sequencing of peripheral blood
mononuclear cells (PBMCs) harvested from the patients before and 28 days
after the first inoculation of a COVID-19 vaccine based on a weakened
version of the virus [52]. While these vaccines are different from
the mRNA vaccines, they also work by injecting the contents of the
vaccine into the deltoid muscle, bypassing the mucosal and vascular
barriers. The authors found consistent alteration of gene expression
following vaccination in many different immune cell types. Observed
increases in NF-κB signaling and reduced type I IFN responses were
further confirmed by biological assays. Consistent with other studies,
they found that STAT2 and IRF7 were significantly downregulated 28 days
after vaccination, indicative of impaired type I IFN responses. They
wrote: “Together, these data suggested that after vaccination, at least
by day 28, other than generation of neutralizing antibodies, people’s
immune systems, including those of lymphocytes and monocytes, were
perhaps in a more vulnerable state.” [52].
These authors also identified disturbing changes in gene expression that
would imply impaired ability to repair DNA. Up to 60% of the total
transcriptional activity in growing cells involves the transcription of
ribosomal DNA (rDNA) to produce ribosomal RNA (rRNA). The enzyme that
transcribes ribosomal DNA into RNA is RNA polymerase I (Pol I). Pol I
also monitors rDNA integrity and influences cell survival [144].
During transcription, RNA polymerases (RNAPs) actively scan DNA to find
bulky lesions (double-strand breaks) and trigger their repair. In
growing eukaryotic cells, most transcription involves synthesis of
ribosomal RNA by Pol I. Thus, Pol I promotes survival following DNA
damage [144]. Many of the downregulated genes identified by Liu et
al. (2021) were linked to the cell cycle, telomere maintenance, and both
promoter opening and transcription of POL I, indicative of impaired DNA
repair processes [52]
One of the gene sets that were suppressed was due to “deposition of new
CENPA [centromere protein A] containing nucleosomes at the
centromere.” Newly synthesized CENPA is deposited in nucleosomes at the
centromere during late telophase/early G1 phase of the cell cycle. This
points to arrest of the cell cycle in G1 phase as a characteristic
feature of the response to the inactivated SARS-CoV-2 vaccine. Arrest of
pluripotent embryonic stem cells in the G1 phase (prior to replication
initiation) would result in impaired self-renewal and maintenance of
pluripotency [145].
Two checkpoint proteins crucially involved in DNA repair and adaptive
immunity are BRCA1 and 53BP1, which facilitate both homologous
recombination (HR) and NHEJ, the two primary repair processes
[146,147]. In an in vitro experiment on human cells, the SARS-CoV-2
full-length spike protein was specifically shown to enter the nucleus
and hinder the recruitment of these two repair proteins to the site of a
double-strand break [143]. The authors summarized their findings by
saying, “Mechanistically, we found that the spike protein localizes in
the nucleus and inhibits DNA damage repair by impeding key DNA repair
protein BRCA1 and 53BP1 recruitment to the damage site.”
Another mechanism by which the mRNA vaccines could interfere with DNA
repair is through miR-148. This microRNA has been shown to downregulate
HR in the G1 phase of the cell cycle [148]. As was mentioned earlier
in this paper, this was one of the two microRNAs found in exosomes
released by human cells following spike protein synthesis in the
experiments by Mishra and Banerjea (2021) [50].