Plasmodium knowlesi

Plasmodium knowlesi is a parasite that causes malaria in humans and other primates. It is found throughout Southeast Asia, and is the most common cause of human malaria in Malaysia. Like other Plasmodium species, P. knowlesi has a life cycle that requires infection of both a mosquito and a warm-blooded host. While the natural warm-blooded hosts of P. knowlesi are likely various Old World monkeys, humans can be infected by P. knowlesi if they are fed upon by infected mosquitoes. P. knowlesi is a eukaryote in the phylum Apicomplexa, genus Plasmodium, and subgenus Plasmodium. It is most closely related to the human parasite Plasmodium vivax as well as other Plasmodium species that infect non-human primates.
Humans infected with P. knowlesi can develop uncomplicated or severe malaria similar to that caused by Plasmodium falciparum. Diagnosis of P. knowlesi infection is challenging as P. knowlesi very closely resembles other species that infect humans. Treatment is similar to other types of malaria, with chloroquine or artemisinin combination therapy typically recommended. P. knowlesi malaria is an emerging disease previously thought to be rare in humans, but increasingly recognized as a major health burden in Southeast Asia.
P. knowlesi was first described as a distinct species and as a potential cause of human malaria in 1932. It was briefly used in the early 20th century to cause fever as a treatment for neurosyphilis. In the mid-20th century, P. knowlesi became popular as a tool for studying Plasmodium biology and was used for basic research, vaccine research, and drug development. P. knowlesi is still used as a laboratory model for malaria, as it readily infects the model primate the rhesus macaque, and can be grown in cell culture in human or macaque blood.

Life cycle

Like other Plasmodium parasites, P. knowlesi has a life cycle that requires it be passed back and forth between mammalian hosts and insect hosts. Primates are infected through the bite of an infected Anopheles mosquito which carries a parasite stage called the sporozoite in its salivary glands. Sporozoites follow the blood stream to the primate liver where they develop and replicate over five to six days before bursting, releasing thousands of daughter cells called merozoites into the blood. The merozoites in the blood attach to and invade the primate's red blood cells. Inside the red blood cell, the parasite progresses through several morphologically distinguishable stages, called the ring stage, the trophozoite, and the schizont. The schizont-infected red blood cells eventually burst, releasing up to 16 new merozoites into the blood stream that infect new red blood cells and continue the cycle. P. knowlesi completes this red blood cell cycle every 24 hours, making it uniquely rapid among primate-infecting Plasmodium species. Occasionally, parasites that invade red blood cells instead enter a sexual cycle, developing over approximately 48 hours into distinct sexual forms called microgametocytes or macrogametocytes. These gametocytes remain in the blood to be ingested by mosquitoes.
A mosquito ingests gametocytes when it takes a blood meal from an infected primate host. Once inside the mosquito gut, the gametocytes develop into gametes and then fuse to form a diploid zygote. The zygote matures into an ookinete, which migrates through the wall of the mosquito gut and develops into an oocyst. The oocyst then releases thousands of sporozoites, which migrate through the mosquito to the salivary glands. This entire process in the mosquito takes 12 to 15 days.

Cell biology

P. knowlesi largely resembles other Plasmodium species in its cell biology. Its genome consists of 23.5 megabases of DNA separated into 14 chromosomes. It contains approximately 5200 protein-coding genes, 80% of which have orthologs present in P. falciparum and P. vivax. The genome contains two large gene families that are unique to P. knowlesi: the SICAvar family, which is involved in displaying different antigens on the parasite surface to evade the immune system, and the Kir family, involved in adhering parasitized red blood cells to blood vessel walls.
As an apicomplexan, P. knowlesi has several distinctive structures at its apical end that are specialized for invading host cells. These include the large bulbous rhoptries, smaller micronemes, and dispersed dense granules, each of which secretes effectors to enter and modify the host cell. Like other apicomplexans, P. knowlesi also has two organelles of endosymbiotic origin: a single large mitochondrion and the apicoplast, both of which are involved in the parasite's metabolism.

Evolution and taxonomy

Despite its morphological similarity to P. malariae, P. knowlesi is most closely related to P. vivax as well as other Plasmodium species that infect non-human primates. The last common ancestor of all modern P. knowlesi strains lived an estimated 98,000 to 478,000 years ago. Among human parasites, P. knowlesi is most closely related to P. vivax, from which it diverged between 18 million and 34 million years ago. A phylogenetic tree comparing the Plasmodium species that infect humans is shown below:
The population of P. knowlesi parasites is more genetically diverse than that of P. falciparum or P. vivax. Within P. knowlesi there are three genetically distinct subpopulations. Two are present in the same areas of Malaysian Borneo and may infect different mosquitoes. The third has been found only in laboratory isolates originating from other parts of Southeast Asia. Populations of P. knowlesi isolated from macaques are genetically indistinguishable from those isolated from human infections, suggesting the same parasite populations can infect humans and macaques interchangeably.
Three subspecies of P. knowlesi have been described based on differences in their appearance in stained blood films: P. knowlesi edesoni, P. knowlesi sintoni, and P. knowlesi arimai, which were isolated from Malaysia, Java, and Taiwan respectively. The relationship between these described subspecies and the populations described in the modern literature is not clear.

Distribution

Plasmodium knowlesi is found throughout Southeast Asia, where it primarily infects the long-tailed macaque, pig-tailed macaque, and Sumatran surili as well as the mosquito vectors Anopheles hackeri in peninsular Malaysia and Anopheles latens in Sarawak. Long-tailed macaques in the wild can be infected with P. knowlesi without any apparent disease, even when they are simultaneously infected with various other Plasmodium species. P. knowlesi is rarely found outside of Southeast Asia, likely because the mosquitoes it infects are restricted to that region.

Role in human disease

P. knowlesi can cause both uncomplicated and severe malaria in humans. Those infected nearly always experience fever and chills. People with uncomplicated P. knowlesi malaria often also experience headaches, joint pain, malaise, and loss of appetite. Less commonly, people report coughing, abdominal pain, diarrhea, nausea, and vomiting. Laboratory tests of infected people nearly always show a low platelet count, although this rarely leads to bleeding problems. Unlike other human malarias, P. knowlesi malaria tends to have fevers that spike every 24 hours, and is therefore often called daily or "quotidian" malaria. Uncomplicated P. knowlesi malaria can be treated with antimalarial drugs such as artemisinin combination therapy or chloroquine ACT is the preferred treatment as the drug is associated with a faster parasite clearance time.
At least 10% of people infected with P. knowlesi develop severe malaria. Severe P. knowlesi malaria resembles severe malaria caused by P. falciparum. Those with severe disease may experience shortness of breath, abdominal pain, and vomiting. As disease progresses, parasites replicate to very high levels in the blood likely causing acute kidney injury, jaundice, shock, and respiratory distress. Metabolic acidosis is uncommon, but can occur in particularly severe cases. Unlike P. falciparum malaria, severe P. knowlesi malaria rarely causes coma or severe anemia. Approximately 1-2% of cases are fatal.

Diagnosis

Malaria is traditionally diagnosed by examining Giemsa-stained blood films under a microscope; however, differentiating P. knowlesi from other Plasmodium species in this way is challenging due to their similar appearance. P. knowlesi ring-stage parasites stained with Giemsa resemble P. falciparum ring stages, appearing as a circle with one or two dark dots of chromatin. Older trophozoites appear more dispersed, forming a rectangular-shape spread across the host cell called a "band-form" that resembles the similar stage in P. malariae. During this stage, dots sometimes appear across the host red blood cell, called "Sinton and Mulligans' stippling". Schizonts appear, similarly to other Plasmodium species, as clusters of purple merozoites surrounding a central dark-colored pigment.
Due to the morphological similarity among Plasmodium species, misdiagnosis of P. knowlesi infection as P. falciparum, P. malariae, or P. vivax is common. While some rapid diagnostic tests can detect P. knowlesi, they tend to have poor sensitivity and specificity and are therefore not always reliable. Detection of nucleic acid by PCR or real-time PCR is the most reliable method for detecting P. knowlesi, and differentiating it from other Plasmodium species infection. However, due to the relatively slow and expensive nature of PCR, this is not available in many endemic areas. Loop-mediated isothermal amplification methods of P. knowlesi detection have also been developed, but are not yet widely used.