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Chapter 9 Phylum Apicomplexa: Malaria

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Title: Chapter 9 Phylum Apicomplexa: Malaria


1
Chapter 9 - Phylum Apicomplexa Malaria
  • Taxonomy
  • P. Apicomplexa
  • C. Coccidia
  • O. Haemosporida
  • G. Plasmodium

2
  • Overview
  • Malaria is one of the most prevalent and
    debilitating diseases afflicting humans
  • Worldwide prevalence is at approximately 489
    million cases, making malaria the most prevalent
    human parasitic disease, with an annual death
    toll of 2 million
  • There are more than 50 species of Plasmodium,
    but only 4 commonly cause malaria in humans - P.
    vivax, P. falciparum, P. malariae, and P. ovale

3
  • Life Cycle Overview
  • The life cycle of Plasmodium that infect humans
    includes 2 hosts
  • 1) the human host and 2) the insect vector, a
    female mosquito belonging to the genus Anopheles

Anopheles sp.
  • Like other apicomlexa, a significant feature of
    the life cycle is the alternation of sexual and
    asexual phases in the 2 hosts
  • The asexual cycles, termed merogony, occur in
    the human
  • The sexual cycle, termed gamogony occurs mainly
    in the mosquito
  • Subsequent to the sexual stage, another asexual
    phase of reproduction occurs in the mosquito,
    termed sporogony
  • The infective form in humans is the slender,
    elongated sporozoite

Plasmodium sp. sporozoites
4
  • Life Cycle (Detail)
  • During feeding, the mosquito secretes
    sporozoite-bearing saliva beneath the epidermis
    of the human victim, thus inoculating the
    sporozoites into the blood stream
  • About 24-48 hr later, sporozoites appear in the
    parenchymal cells in the liver, initiating the
    exoerythrocytic shizogonic cycle or
    pre-erthrythrocytic cycle

5
  • Exoerythrocytic Shizogonic Cycle
  • Inside the liver cell, the sporozoite develops
    into a trophozoite, feeding on host cytoplasm
    with its functional micropore
  • After 1-2 weeks, the nucleus of the trophozoite
    undergoes multiple fission, producing thousands
    of merozoites
  • These rupture from the host cell, enter the
    blood circulation, and invade RBCs, initiating
    the erythrocytic shizogonic cycle
  • Some sporozoites become dormant hypnozoites

6
  • Note
  • Studies of P. vivax show that the membrane
    receptor site for the engulfment phenomenon is
    determined by the type of antigen present on the
    surface of the RBC - e.g., merozoite penetration
    requires the presence of at least one of two
    Duffy antigens (Fya or Fy b )
  • People that lack the Duffy antigens (almost all
    West Africans and about 70 of American blacks)
    are resistent to vivax malaria
  • However, P. ovale and P. falciparum malarias
    are not influenced by Duffy antigens, thus
    accounting for their prevalence in West Africa

7
  • Erythrocytic Shizogonic Cycle
  • Electron microscopy has confirmed that
    merozoites interact with the RBC plasma membrane
    and actively invade the cell
  • During this process, rhoptries and micronemes
    are believed to secrete surface active molecules
    that cause the host RBC membrane to expand and
    invaginate to form a parasitophorous vacuole
    which envelops the parasite

Merozoite entering erythrocyte
Erythrocyctic trophozoite
8
  • Erythrocytic Shizogonic Cycle cont.
  • Once in the RBC, the merozoite assumes an early
    trophozoite shape consisting of a ring of
    cytoplasm and a dot-like nucleus - the signet
    ring stage
  • These early trophozoites feed on host
    hemoglobin, grow to the mature trophozoite stage,
    and then undergo multiple fission as schizonts,
    producing a characterisitc number of merozoites
    in each infected RBC

9
  • Erythrocytic Shizogonic Cycle cont.
  • Merozoites eventually rupture RBCs and each
    merozoite is capable of infecting a new RBC

Scanning electron micrograph of
Plasmodium-infected red blood cells
10
Erythrocytic Shizogonic Cycle cont.
One of 2 fates await these merozoites 1. Become
signet ring trophozoites and begin shizogony
anew 2. Differentiate into sexual stages,
becoming male microgametocytes or female
macrogametocytes
11
  • Life Cycle cont.
  • The sexual phase occurs in the female Anopheles
    mosquito and begins when the mosquito takes a
    blood meal that contains microgametocytes and
    macrogametocytes
  • Once the surrounding RBC material is lysed, the
    gametocytes are released into the lumen of the
    stomach
  • The microgametocytes undergo a maturation
    process known as exflagellation

12
  • Exflagellation
  • The nucleus undergoes 3 mitotic divisions,
    producing 6-8 nuclei that migrate to the
    periphery of the gametocyte
  • Accompanying the nuclear divisions are
    centriolar divisions, following which one portion
    joins each nuclear segment to become a basal
    body, providing the center from which the axoneme
    subsequently arises

13
  • Life Cycle cont.
  • The nucleus with the axoneme and a small amount
    of cytoplasm form a microgamete, which detaches
    from the mass and swims to the macrogametocyte
  • During this period the macrogametocytes have
    developed into macrogametes which become
    penetrated by the microgamete
  • The fusion of male and female pronuclei
    (syngamy) produces a diploid zygote that
    elongates into a motile wormlike ookinete

14
  • Life Cycle cont.
  • The ookinete penetrates the gut wall of the
    mosquito to the area between the epithelium and
    the basal lamina, where it develops into a
    rounded oocyst
  • Growth of the oocyst is, in part, due to the
    proliferation of haploid cells called
    sporoblasts, within the oocyst

15
  • Life Cycle cont.
  • Sporoblast nuclei undergo numerous divisions,
    producing thousands of sporozoites enclosed
    within the sporoblast membranes
  • As membranes rupture, sporozoites enter the
    cavity of the oocyst
  • The sporozoite-filled oocysts themselves
    rupture, releasing the sporozites in the hemocoel
  • The sporozoites are carried to the salivary
    gland ducts of the insect and are ready to be
    injected into the next victim when another blood
    meal is taken

16
Sporozoites isolated from the salivary glands of
a mosquito
Longitudinal section of mosquito intestine
showing numerous oocysts
17
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18
Plasmodium vivax (benign tertian malaria)
  • Less than 1 of the total RBC population is
    parasitized
  • Predilection for immature RBCs (reticulocytes)
  • Schuffners dots usually stains pink to red when
    subjected to stains
  • Hemozoin granules, by-products of hemoglobin
    degradation by the parasite, are prominent
  • The cytoplasm of the trophozoite stages is very
    irregular and displays an active ameboid movement

19
P. ovale (mild tertian malaria)
  • Less than 1 of the total RBC population is
    parasitized
  • Predilection for immature RBCs (reticulocytes)
  • Schuffners dots usually stains pink to red when
    subjected to stains
  • Hemozoin granules, by-products of hemoglobin
    degradation by the parasite, are prominent
  • The cytoplasm of the trophozoite stages is very
    irregular and displays an active ameboid movement

20
Plasmodium malariae (quartan malaria)
  • Parasitizes about 0.2 of older RBCs
  • Trophozoites accumulate pink staining Ziemanns
    dots
  • Hemozoin granules appear in the center or
    periphery of the shizont
  • Trophozoite often appear as a band across the
    cell
  • Mature trophozoites resemble macrogametocytes
  • Recrudescensces as long as 52 years after
    initial infection

21
Plasmodium falciparum (Malignant tertian malaria)
  • Only ring trophozoites and gametocytes seen in
    peripheral circulation later stages trapped in
    capillaries of muscle and visceral organs
  • Plasma membranes of infected RBCs undergo
    alteration causing them to adhere to the walls
    of capillaries
  • Infects RBCs of any age about 10 of the total
    RBCs
  • Multiple infections of single RBCs are common
  • Gametocytes are crescent shaped cells
  • Hemozoin as well as Maurers dots (precipitates
    in the cytoplasm of RBCs infected to P.
    falciparum), tend to aggregate around the nuclear
    region of gametocytes

22
  • Epidemiology
  • Endemicity of human malaria is usually
    determined by the geographic distribution of its
    anophelene mosquito areas where the vector is
    not present are free of the disease
  • Local environmental factors determine which
    particular species of mosquito transmits malaria
    in a given area local epidemiological surveys
    can be used to assay the prevalent vectors
  • Precipitin tests of ingested blood from infected
    mosquitoes reveal whether the vectors have
    zoophilic or anthrophilic feeding preferences
  • Water dependency for breeding varies greatly
  • The control of malaria depends on a variety of
    factors, such as availability of antimalarial
    drugs, use of screens on houses to keep out
    mosquitoes, proper use of insecticides,
    elimination of mosquito breeding sites, etc.

23
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24
  • Relapse of Infection
  • Victims of vivax or ovale malaria may suffer a
    relapse
  • Originally, the relapse was thought only to be
    due to populations of cryptozoites
    (pre-erythrocyte shizont) being maintained in the
    exoerythrocytic cycle
  • While one population progressed to the usual
    erythrocytic phase, underwent shizogony and
    released merozoites into the circulating blood
    stream causing malaria, the other population
    maintained an ongoing exoerythocytic cycle known
    as a para-erythrocytic cycle
  • Parasites in the hepatic stages of the cycle
    were thought to be protected from the host
    antibodies until activated by some physiological
    change within the host that allowed them to erupt
    from the hepatocytes, precipitating another bout
    of malaria
  • A more recent view also recognizes the existence
    of 2 different populations of sporozoites
  • Short prepatent sporozoites - upon entering the
    human host, undergo the usual exoerythrocytic and
    erythrocytic phases of development and cause
    malaria
  • Long prepatent sporozoites or hypnozoites -
    remain dormant in the hepatocytes for an
    indefinite period
  • Some kind of physiological fluctuation activates
    them into exoerythrocytic and erythrocytic cycles
    and a relapse occurs

25
  • Recrudesence
  • Recurrence of malaria among victims infected by
    P. malariae many years after apparent cure
    fostered the idea that this species produced
    relapses like those produced by P. vivax and P.
    ovale
  • But, it has been shown that the periodic
    increase in numbers of parasites results from a
    residual population persisting at very low levels
    in the blood after inadequate or incomplete
    treatment of the initial infection
  • The situation may persist for as long as 53
    years before something triggers a parasite
    population explosion with accompanying disease
    manifestations -
  • This phenomenon is referred to as recrudesence

26
  • Symptomatology and Diagnosis
  • Pathology in human malaria (P. falciparum) is
    generally manifested in 2 basic forms host
    inflammatory reactions and anemia
  • Host inflammatory reactions are initiated by the
    periodic rupture of infected RBCs, which release
    malarial pigment such as hemozoin and parasite
    metabolic wastes
  • These ruptures are accompanied by fever
    paroxysms that are usually synchronous except
    during the primary attack (correlated with the
    merozoites rupturing from RBCs)
  • During cell rupturing, toxins are released which
    in turn cause macrophage cells to release tumor
    necrosis factor (TNF) its TNF that actually
    induces the fever
  • During the primary attack synchrony may not be
    evident, since the infection may arise from
    several populations of liver merozoites at
    different stages of development

27
  • Symptomatology and Diagnosis cont.
  • Macrophages, particularly those in the liver,
    bone marrow, and spleen, phagocytose released
    pigment
  • In extreme cases the amount of pigment is so
    great that it imparts a dark green, reddish brown
    hue to the visceral organs such as the liver,
    spleen and brain
  • With increased RBC destruction, accompanied by
    the bodys inability to recycle iron bound in the
    insoluable hemozoin, anemia develops
  • TNF toxicity may also induce splenic removal of
    unparasitized RBCs and inhibit bone marrow
    production of new RBCs
  • One pathological element unique to P. falciparum
    is vascular obstruction
  • Plasma membranes of RBCs infected with schizonts
    develop electron dense knobs by which they
    adhere to the endothelium of capillaries in
    visceral organs
  • As a consequence, the capillaries become
    obstructed, causing the affected organs to become
    anoxic
  • In terminal cases, blocked capillaries in the
    brain (cerebral malaria) cause it to become
    swollen and congested

Infected RBC showing surface knobs
28
  • Black Water Fever
  • A condition known as black water fever often
    accompanies falciprum malaria infections
  • It is characterized by massive lysis of RBCs
    and it produces abnormally high levels of
    hemoglobin in urine and blood
  • Fever, vomiting with blood, and jaundice also
    occur
  • There is between 20-50 mortality rate, usually
    due to renal failure probably due to renal
    anoxia
  • The exact cause of this condition is uncertain
  • It may be a reaction to quinine, or it may
    result from an autoimmune phenomenon in which
    hemolytic antibodies are produced in response to
    chemotherapy

29
  • Chemotherapy
  • Malaria control requires effective treatment of
    the disease in humans and continuous efforts to
    control mosquito populations
  • The first known antimalarial drug was quinine
  • The drug primarily destroys the schizogonic
    stages of malaria
  • The synthetic drug Atabrine dihydrochloride
    (circa 1936-36) proved useful against
    erythrocytic stages and in suppressing clinical
    stages
  • Since WWII several synthetic drugs have been
    used chloroquine, amodiaquin, and primaquine
  • Chloroquine is a weak base and it increases the
    pH of the food vacuole which in turn prevents the
    digestion of hemoglobin
  • Pyrimethamine used in combination with
    sulfadoxine have been effective in inhibiting the
    folic acid cycle of malarial parasites

30
  • Immunity
  • In addition to chemotherapy research,
    development of a protective vaccine against
    malaria is being pursued
  • Interestingly, the surface coat of the
    sporozoite acts as a renewable decoy to the
    vertebrate hosts immune system, stimulating the
    production of antibodies
  • When the sporozoite is attacked and its decoy
    coat sloughs off, a replacement coat is
    synthesized and its decoy effect continues
  • This system provides ideal protection for the
    sporozoite which only spends a brief amount of
    time in the blood before it penetrates a liver
    cell as is protected from circulating antibodies
  • In endemic areas, premunition is the basis for
    protective immunity as long as low-level
    infection persists however, with complete cure,
    the victim regains susceptibility
  • Also, while nursing infants in endemic areas are
    protected through antibodies in their mothers
    milk, they are at risk at the time of weaning
  • Also, P. falciparum can cross the placenta and
    cause infection on the fetus

31
  • Genetics and Malaria Infections
  • Several genetic conditions are known to affect
    the malarial organism
  • Susceptibility is conferred by the presence of
    Duffy antigens e.g., vivax merozoite
    penetration of RBCs requires 1 of 2 Duffy
    antigens
  • Genetic deficiency in G6PDH activity in RBCs
    (favism) creates and inhospitable environment for
    the parasites
  • Humans heterozygous for sickle cell anemia
    possess a selective advantage over individuals
    with normal hemoglobin in regions where P.
    falciparum is endemic
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