Long noncoding RNAs (lncRNAs) play multiple key regulatory roles in various cellular pathways. However, their functions in HIV-1 latent infection remain largely unknown. Here we show that a lncRNA named NRON, which is highly expressed in resting CD4+ T lymphocytes, could be involved in HIV-1 latency by specifically inducing Tat protein degradation. Our results suggest that NRON lncRNA potently suppresses the viral transcription by decreasing the cellular abundance of viral transactivator protein Tat. NRON directly links Tat to the ubiquitin/proteasome components including CUL4B and PSMD11, thus facilitating Tat degradation. Depletion of NRON, especially in combination with a histone deacetylase (HDAC) inhibitor, significantly reactivates the viral production from the HIV-1-latently infected primary CD4+ T lymphocytes. Our data indicate that lncRNAs play a role in HIV-1 latency and their manipulation could be a novel approach for developing latency-reversing agents.
Messenger RNA (mRNA) vaccine is a promising candidate in cancer immunotherapy as it can encode tumorassociated antigens with an excellent safety profile. Unfortunately, the inherent instability of RNA and translational efficiency are major limitations of RNA vaccine. Here, we report an injectable hydrogel formed with graphene oxide (GO) and polyethylenimine (PEI), which can generate mRNA (ovalbumin, a model antigen) and adjuvants (R848)-laden nanovaccines for at least 30 days after subcutaneous injection. The released nanovaccines can protect the mRNA from degradation and confer targeted delivering capacity to lymph nodes. The data show that this transformable hydrogel can significantly increase the number of antigen-specific CD8 + T cells and subsequently inhibit the tumor growth with only one treatment. Meanwhile, this hydrogel can generate an antigen specific antibody in the serum which in turn prevents the occurrence of metastasis. Collectively, these results demonstrate the potential of the PEI-functionalized GO transformable hydrogel for effective cancer immunotherapy.
Efficient delivery of tumor antigens and immunostimulatory adjuvants into lymph nodes is crucial for the maturation and activation of antigen-presenting cells (APCs), which subsequently induce adaptive antitumor immunity. A dissolving microneedle (MN) has been considered as an attractive method for transcutaneous immunization due to its superior ability to deliver vaccines through the stratum corneum in a minimally invasive manner. However, because dissolving MNs are mostly prepared using water-soluble sugars or polymers for their rapid dissolution in intradermal fluid after administration, they are often difficult to formulate with poorly water-soluble vaccine components. Here, we develop amphiphilic triblock copolymer-based dissolving MNs in situ that generate nanomicelles (NMCs) upon their dissolution after cutaneous application, which facilitate the efficient encapsulation of poorly water-soluble Toll-like receptor 7/8 agonist (R848) and the delivery of hydrophilic antigens. The sizes of NMCs range from 30 to 40 nm, which is suitable for the efficient delivery of R848 and antigens to lymph nodes and promotion of cellular uptake by APCs, minimizing systemic exposure of the R848. Application of MNs containing tumor model antigen (OVA) and R848 to the skin of EG7-OVA tumor-bearing mice induced a significant level of antigen-specific humoral and cellular immunity, resulting in significant antitumor activity.
The successful control of coronavirus disease 2019 (COVID-19) pandemic is not only
relying on the development of vaccines, but also depending on the storage,
transportation, and administration of vaccines. Ideally, nucleic acid vaccine should be
directly delivered to proper immune cells or tissue (such as lymph nodes). However,
current developed vaccines are normally treated through intramuscular injection, where
immune cells do not normally reside. Meanwhile, current nucleic acid vaccines must be
stored in a frozen state that may hinder their application in developing countries.
Here, we report a separable microneedle (SMN) patch to deliver polymer encapsulated
spike (or nucleocapsid) protein encoding DNA vaccines and immune adjuvant for efficient
immunization. Compared with intramuscular injection, SMN patch can deliver nanovaccines
into intradermal for inducing potent and durable adaptive immunity.
IFN-γ
+
CD4/8
+
and IL-2
+
CD4/8
+
T cells
or virus specific IgG are significantly increased after vaccination. Moreover,
in vivo
results show the SMN patches can be stored at room
temperature for at least 30 days without decreases in immune responses. These features
of nanovaccines-laden SMN patch are important for developing advanced COVID-19 vaccines
with global accessibility.
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