Two viral vaccines are expected to reduce the incidence of cancers. Which vaccines are these?

HPV 16/18 and hepatitis B vaccines

Measles virus and rubella virus vaccines

Adenovirus and mumps virus vaccines

Which statement is TRUE regarding the relationship between HPV vaccination and cervical cancer screening?

Screening recommendations are currently the same regardless of vaccination status

Vaccinated women require less frequent screening than unvaccinated women

HPV vaccination eliminates the need for cervical cancer screening

Screening should begin at a younger age in vaccinated women

An 80-year-old woman, a retirement home resident, has multiple bouts of pneumonia caused by Streptococcus pneumoniae. In an attempt to prevent such infections, polyvalent vaccines directed at multiple serotypes of the organism have been administered but have not elicited long-acting immunity. Which of the following is the probable explanation for this phenomenon?

Memory T lymphocytes respond poorly to polysaccharide antigens.

The bacterial capsule binds C3b, facilitating activation of the alternative complement pathway, inducing complement-mediated lysis, and preventing immunization.

The capsular polysaccharides of S. pneumoniae have limited hapten potential.

S. pneumoniae evades host immune response by forming capsular coatings composed of host proteins and recognized as "self" antigens.

New Vaccine Technologies for INI-CET: High-Yield Microbiology Lessons

Nucleic Acid Vaccines - Genetic Code Shots

Delivers genetic material (DNA or mRNA) encoding specific antigen(s) into host cells.
Host cells transcribe (DNA) and translate (mRNA/DNA) the genetic material to produce the antigen.
This in-situ antigen production mimics natural infection, eliciting robust cellular (T-cell) and humoral (B-cell) immunity.
Types:
- DNA Vaccines:
  - Plasmid DNA containing antigen gene.
  - Requires entry into nucleus for transcription.
  - Good stability; elicits strong Th1 responses.
- mRNA Vaccines:
  - In vitro transcribed mRNA encoding antigen.
  - Direct translation in cytoplasm; no nuclear entry needed.
  - Rapid development, potent immunogenicity (e.g., COVID-19 vaccines).
  - Often encapsulated in Lipid Nanoparticles (LNPs) for delivery & stability.

mRNA and DNA Vaccine Mechanisms

⭐ mRNA vaccines (e.g., Pfizer-BioNTech, Moderna for COVID-19) are known for their rapid development and ability to elicit strong neutralizing antibody responses and T-cell immunity. They bypass the need for nuclear entry, leading to faster antigen expression compared to DNA vaccines.

Advantages: Rapid development, scalability, safety (non-infectious, no integration risk for mRNA), induces broad immunity.
Challenges: Delivery systems (especially for DNA), stability (mRNA more labile than DNA), potential for anti-DNA antibodies (theoretical for DNA vaccines).

Viral Vector Vaccines - Trojan Horse Tactics

Harmless virus (vector) delivers pathogen's genetic material (DNA/RNA) into host cells. 📌 Viral Vans Deliver Genes.
Host cells produce pathogen antigens, triggering robust immune response (cellular & humoral).
- "Trojan Horse" delivery of antigen-coding genes.
Vector Types:
- Replicating: e.g., Measles, VSV. ↑Antigen, stronger immunity.
- Non-replicating: e.g., Adenovirus (Ad26, ChAdOx1), AAV. Safer; may need boosters.
Pros: Strong T & B-cell response; good stability.
Cons: Pre-existing vector immunity can ↓ efficacy; manufacturing complexity.
Examples:
- COVID-19: J&J (Ad26), AstraZeneca (ChAdOx1).
- Ebola: rVSV-ZEBOV.

⭐ Pre-existing adenovirus immunity can ↓ vector vaccine efficacy.

Subunit & Particle Vaccines - Protein Power-Ups

Uses purified antigens (proteins, polysaccharides) or Virus-Like Particles (VLPs). No whole organisms.
Pros: ↑ Safety (no infection risk), defined composition.
Cons: Often need adjuvants; immunity may be less broad/durable.
Examples:
- Protein Subunit: Hepatitis B (HBsAg), Acellular pertussis.
- Polysaccharide: Pneumococcal (PPSV23), Meningococcal. Conjugation (e.g., Hib, PCV13) vital for infant T-dependent response.
- Virus-Like Particles (VLPs): HPV, Hepatitis B. Self-assembling viral proteins; mimic virus, highly immunogenic, non-infectious.

⭐ HPV vaccine, a VLP type, shows high efficacy by mimicking viral structure, inducing robust protective immunity against specific oncogenic HPV types.

Emerging Vaccine Tech & Adjuvants - Frontier Technologies

Nanoparticle Vaccines: VLPs, liposomes. ↑ immunogenicity.
- Virus-Like Particles (VLPs): Non-infectious, mimic native pathogen structures (e.g., HPV, HBV).
- Outer Membrane Vesicles (OMVs): From Gram-negative bacteria, potent immunogens (e.g., MenB).
Reverse Vaccinology 2.0: Genomic/proteomic antigen discovery.
Structural Vaccinology: Structure-based rational antigen design.
Self-amplifying RNA (saRNA): Lower dose, prolonged antigen expression than mRNA.
Modern Adjuvants: Enhance magnitude & duration of immune response.
- TLR Agonists: CpG ODN (TLR9), MPLA (TLR4).
- Saponins: QS-21 (potent saponin from Quillaja saponaria).
- Emulsions: MF59, AS03 (oil-in-water).
- STING Agonists: Potent innate immune activation via STING.

⭐ AS04 adjuvant combines MPLA (TLR4 agonist) and alum, used in HPV (Cervarix) and HBV (Fendrix) vaccines.

High‑Yield Points - ⚡ Biggest Takeaways

mRNA vaccines (e.g., Pfizer, Moderna) use mRNA for antigen synthesis; rapid development, no infection risk.

Viral vector vaccines (e.g., Covishield) use a modified virus to deliver antigen genes.

DNA vaccines (e.g., ZyCoV-D) use plasmid DNA; stable, elicit cellular and humoral immunity.

Recombinant protein vaccines (e.g., Novavax) use purified antigens; fewer side effects.

Virus-Like Particles (VLPs) (e.g., HPV) are non-infectious, highly immunogenic structural mimics.

Modern adjuvants enhance immunogenicity and response duration.

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