Humans are the intermediate hosts in which asexual reproduction occurs, and female
anopheline mosquitoes are the definitive hosts harbouring the sexual reproduction stage.
In humans Infection in humans begins with the bite of an infected female
Anopheles mosquito. Out of about 460 species of
Anopheles mosquito, more than 70 species transmit falciparum malaria.
Anopheles gambiae is one of the best known and most prevalent
vectors, particularly in Africa. The infective stage called the
sporozoite is released from the
salivary glands through the
proboscis of the mosquito to enter through the skin during feeding. The mosquito saliva contains antihemostatic and anti-inflammatory enzymes that disrupt
blood clotting and inhibit the
pain reaction. Typically, each infected bite contains 20–200 sporozoites. A proportion of sporozoites invade liver cells (
hepatocytes). The sporozoites move in the bloodstream by
gliding, which is driven by a motor made up of the proteins
actin and
myosin beneath their
plasma membrane.
Liver stage or exo-erythrocytic schizogony Entering the hepatocytes, the parasite loses its
apical complex and surface coat and transforms into a
trophozoite. Within the
parasitophorous vacuole of the hepatocyte, it undergoes 13–14 rounds of
mitosis which produce a
syncytial cell (
coenocyte) called a
schizont. This process is called
schizogony. A schizont contains tens of thousands of nuclei. From the surface of the schizont, tens of thousands of
haploid (1n) daughter cells called
merozoites emerge. The liver stage can produce up to 90,000 merozoites, which are eventually released into the bloodstream in parasite-filled
vesicles called
merosomes.
Blood stage or erythrocytic schizogony Merozoites use the
apicomplexan invasion organelles (
apical complex, pellicle, and surface coat) to recognize and enter the host erythrocyte (
red blood cell). The merozoites first bind to the erythrocyte in a random orientation. It then reorients such that the apical complex is in proximity to the erythrocyte
membrane. The parasite forms a
parasitophorous vacuole, to allow for its development inside the
erythrocyte. This infection cycle occurs in a highly synchronous fashion, with roughly all of the parasites throughout the blood in the same stage of development. This precise clocking mechanism is dependent on the human host's own
circadian rhythm. Within the erythrocyte, the parasite metabolism depends on the digestion of
haemoglobin. The clinical symptoms of malaria such as
fever,
anemia, and neurological disorder are produced during the blood stage.
Trophozoite After invading the erythrocyte, the parasite loses its specific invasion organelles (apical complex and surface coat) and de-differentiates into a round
trophozoite located within a parasitophorous vacuole. The trophozoite feeds on the haemoglobin of the erythrocyte, digesting its proteins and converting (by
biocrystallization) the remaining
heme into insoluble and chemically inert β-
hematin crystals called
haemozoin. The young trophozoite (or "ring" stage, because of its morphology on stained blood films) grows substantially before undergoing multiplication.
Schizont At the schizont stage, the parasite replicates its DNA multiple times and multiple
mitotic divisions occur asynchronously. Cell division and multiplication in the erythrocyte is called erythrocytic
schizogony. Each schizont forms 16-18
merozoites.
Gametocyte Some merozoites differentiate into sexual forms, male and female
gametocytes. These gametocytes take roughly 7–15 days to reach full maturity, through the process called gametocytogenesis. These are then taken up by a female
Anopheles mosquito during a blood meal.
Incubation period The time of appearance of the symptoms from infection (called
incubation period) is shortest for
P. falciparum among
Plasmodium species. An average incubation period is 11 days, Pregnancy and co-infection with
HIV are important conditions for delayed symptoms. Parasites can be detected from blood samples by the 10th day after infection (pre-patent period). The flagellated microgamete fertilizes the female
macrogamete to produce a
diploid cell called a
zygote. The zygote then develops into an
ookinete. The ookinete is a
motile cell, capable of invading other organs of the mosquito. It traverses the
peritrophic membrane of the mosquito midgut and crosses the midgut
epithelium. Once through the epithelium, the ookinete enters the
basal lamina and settles into an immotile
oocyst. For several days, the oocyst undergoes 10 to 11 rounds of cell division to create a
syncytial cell (
sporoblast) containing thousands of nuclei.
Meiosis takes place inside the sporoblast to produce over 3,000 haploid daughter cells called
sporozoites on the surface of the mother cell. Immature sporozoites break through the oocyst wall into the
haemolymph. They migrate to the mosquito salivary glands where they undergo further development and become infective to humans. Researchers have recently discovered that mosquitoes are very selective about their sugar meal sources. For example
Anopheles mosquitoes prefer some plants over others, specifically those containing compounds that hinder the development and survival of malaria parasites inside the mosquito. This discovery offers an opportunity to look into what could be playing a role in these behavior changes in mosquitoes and also find out what they ingest when they foraged on the selected plants. In other studies, it has been shown that sources of sugars and some
secondary metabolites e.g.
ricinine, have contrasting effects on mosquito capacity to transmit the parasites malaria.
Meiosis Plasmodium falciparum is
haploid (one set of chromosomes) during its reproductive stages in human blood and liver. When a mosquito takes a blood meal from a
plasmodium infected human host, this meal may include haploid micro
gametes and macro
gametes. Such gametes can fuse within the mosquito to form a diploid (2N) plasmodium
zygote, the only diploid stage in the life cycle of these parasites. The zygote can undergo another round of
chromosome replication to form an ookinete (4N) (see Figure: Life cycle of plasmodium). The ookinete that differentiates from the zygote is a highly mobile stage that invades the mosquito midgut. The ookinetes can undergo
meiosis involving two meiotic divisions leading to the release of haploid sporozoites (see Figure). The sporozoite is an elongated crescent-shaped invasive stage. These sporozoites may migrate to the mosquito's salivary glands and can enter a human host when the mosquito takes a blood meal. The sporozoite then can move to the human host liver and infect
hepatocytes. The profile of genes encoded by plasmodium that are employed in meiosis has some overlap with the profile of genes employed in meiosis in other more well-studied organisms, but is more divergent and is lacking some components of the meiotic process found in other organisms. During plasmodium meiosis,
recombination occurs between
homologous chromosomes as in other organisms. ==Interaction with human immune system==