Kaposi's sarcoma-associated herpesvirus


Kaposi's sarcoma-associated herpesvirus is the ninth known human herpesvirus. It is also called Human herpesvirus 8, or HHV-8 in short. This virus causes Kaposi's sarcoma, a cancer commonly occurring in AIDS patients, as well as primary effusion lymphoma, HHV-8-associated multicentric Castleman's disease and KSHV inflammatory cytokine syndrome. It is one of seven currently known human cancer viruses, or oncoviruses. Even after many years since the discovery of KSHV/HHV8, there is no known cure for KSHV associated tumorigenesis.

History

In 1872, Moritz Kaposi described a blood vessel tumor that has since been eponymously named Kaposi's sarcoma. KS was at first thought to be an uncommon tumor of Jewish and Mediterranean populations until it was later determined to be extremely common throughout sub-Saharan African populations. This led to the first suggestions in the 1950s that this tumor might be caused by a virus. With the onset of the AIDS epidemic in the early 1980s, there was a sudden resurgence of KS affecting AIDS patients, with up to 50% of reported AIDS patients having this tumor—an extraordinary rate of cancer predisposition.
Careful analysis of epidemiologic data by Valerie Beral, Thomas Peterman and Harold Jaffe, led these investigators to propose that KS is caused by an unknown sexually transmitted virus that rarely causes tumors unless the host becomes immunosuppressed, as in AIDS.
Image:Kaposi sarcoma high mag.jpg|thumb|right|Micrograph of Kaposi sarcoma. H&E stain.
As early as 1984, scientists reported seeing herpesvirus-like structures in KS tumors examined under electron microscopy. Scientists had been searching for the agent causing KS, and over 20 agents were proposed as the possible cause, including cytomegalovirus and HIV itself. The pathogen was ultimately identified in 1994 by Yuan Chang and Patrick S. Moore, a wife and husband team at Columbia University, through the isolation of DNA fragments from a herpesvirus found in a KS tumor in an AIDS patient. Chang and Moore used representational difference analysis, or RDA, to find KSHV by comparing KS tumor tissue from an AIDS patient to his own unaffected tissue. The idea behind this experiment was that if a virus causes KS, the genomic DNA in the two samples should be precisely identical except for DNA belonging to the virus. In their initial RDA experiment, they isolated two small DNA fragments that represented less than 1% of the actual viral genome. These fragments were similar the known herpevirus sequences, indicating the presence of a new virus. Starting from these fragments, this research team was then able to sequence the entire genome of the virus less than two years later.
The discovery of this herpesvirus sparked considerable controversy and scientific in-fighting until sufficient data had been collected to show that indeed KSHV was the causative agent of Kaposi's sarcoma. The virus is now known to be a widespread infection of people living in sub-Saharan Africa; intermediate levels of infection occur in Mediterranean populations and low levels of infection occur in most Northern European and North American populations. The incidence rate is higher among gay and bisexual men.

Virology

KSHV is a herpesvirus, and is a large double-stranded DNA virus with a protein covering that packages its nucleic acids, called the capsid, which is then surrounded by an amorphous protein layer called the tegument, and finally enclosed in a lipid envelope derived in part from the cell membrane. KSHV has a genome which is approximately 165,000 nucleic acid bases in length. The viral genome consists of a ~145 kilobase-long unique region, encoding all of expressed viral genes, which is flanked by ~20-30 kilobases of terminal repeat sequences.
Each terminal repeat unit is 801 bp in length, has 85% G+C content and is oriented in a repetitive head-to-tail fashion. KSHV is a rhadinovirus, a Herpes genus remarkable since it has stolen numerous genes from host cells including, in the case of KSHV, genes that encode for complement-binding protein, IL-6, BCL-2, cyclin-D, a G protein-coupled receptor, interferon regulatory factor and Flice inhibitory protein, as well as DNA synthesis proteins including dihydrofolate reductase, thymidine kinase, thymidylate synthetase, DNA polymerase and many others. While no other human tumor virus possesses these same genes, other tumor viruses target the same cellular pathways illustrating that at a basic level, all tumor viruses appear to attack the same cellular control pathways, so-called tumor suppressor pathways.
Crucial for the entry of KSHV into cells
are the EPH receptor A2,
Hrs,
TSG101,
and a few integrins.
After infection, the virus enters into lymphocytes via macropinosomes.
Once the virus newly infects a cell, the lipid membrane is shed and the virion travels to the nucleus. The viral genome is released where it circularizes into an episome through a poorly understood process that appears to involve homologous recombination of the terminal repeats. The viral episome is chromatinized upon entry into the host cell nucleus.
After entry, the virus typically remains in a latent state. Only a subset of genes that are encoded in the KSHV latency associated region are expressed during latency, including latency-associated nuclear antigen, vFLIP, vCyclin and 12 microRNAs. Latency is the hallmark of all KSHV-associated etiologies known to date including all KSHV-associated oncogenesis. It has been shown that both protein coding genes such as LANA and noncoding genes encoded in KLAR are important for KSHV associated tumorigenesis. To study the functions of microRNAs, a detailed protocol of bacmid mutagenesis and a complete set of cell-lines carrying microRNA deletion mutants have been established and are available as a resource to researchers.
Additionally, it has been shown that vFLIP and vCyclin interfere with the TGF-β signaling pathway indirectly by inducing the oncogenic host mir17-92 cluster. These observations represents a novel mechanism that may be important for KSHV tumorigenesis and angiogenesis, a hallmark of KS.
During latency, LANA is the only viral protein that is required for viral replication, which is carried out by the host replication machinery. LANA tethers the viral DNA to cellular chromosomes, inhibits p53 and retinoblastoma protein and suppresses viral genes needed for full virus production and assembly. Why only a subset of virus genes expressed during latency is not fully understood. But it has been shown that the latency associated gene expression can be explained in part by a characteristic epigenetic state that KSHV episome acquires during latency. LANA plays an important role during latency, regulating both host and virus transcripts and binding to multiple active promoters; it also associates with the host protein hSET1 that creates H3K4me3 marks in chromatin.
Various signals such as inflammation may provoke the virus to enter into lytic replication. The primary viral protein responsible for the switch between latent and lytic replication is known as the ORF50 Replication Transactivation Activator. When cell signaling conditions activate the generation of RTA, it in turn activates synthesis of a stereotypic cascade of secondary and tertiary viral proteins that ultimately make components of the virus capsid and also the DNA synthesis enzymes required to replicate the virus genome.
During lytic replication, it is believed that the virus genome is replicated as a continuous linear molecule off of an episome. As each unit genome is replicated, it is cut within the terminal repeat region, and then packaged into a virus particle. The virus then becomes enveloped with a lipid membrane as it transits the nucleus and the cytoplasm to exit the cell. Thus, whereas KSHV genome is circular in the nucleus of latently infected cells, it is packaged into infectious viruses as a linear molecule. When the virus enters into lytic replication, thousands of virus particles can be made from a single cell, which usually results in death of the infected cell.

COVID-19 and KSHV

It was discovered in 2020 that infection with the SARS-CoV-2 virus, the virus which causes COVID-19, may induce the lytic reactivation of KSHV in the human body, causing the herpes virus to cease latency and begin the formation of cancerous cells. Further, it was discovered that some medications used to treat infection with SARS-CoV-2, namely Nafamostat and Azithromycin, ended up promoting the production of mature virions, "... potentially inducing KSHV lytic reactivation."

Pathophysiology

The mechanisms by which the virus is contracted are not well understood. Healthy individuals can be infected with the virus and show no signs or symptoms, due to the immune system's ability to keep the infection in check. Infection is of particular concern to the immunocompromised. Cancer patients receiving chemotherapy, AIDS patients, and organ transplant patients are all at a high risk of showing signs of infection..
Recent advances in sequencing technologies have uncovered that virus is chromatinized during latency. It has also been shown that virus encoded microRNA manipulates and interacts not only with host mRNA but also deregulate host long non-coding RNA. More recently, circularRNAs are recently discovered in both EBV and KSHV
Infection with this virus is thought to be lifelong, but a healthy immune system will keep the virus in check. Many people infected with KSHV will never show any symptoms. Kaposi's sarcoma occurs when someone who has been infected with KSHV becomes immunocompromised due to AIDS, medical treatment, or, very rarely, aging.
KSHV is a known causative agent of four diseases: