Jove
Visualize
Contact Us
JoVE
x logofacebook logolinkedin logoyoutube logo
ABOUT JoVE
OverviewLeadershipBlogJoVE Help Center
AUTHORS
Publishing ProcessEditorial BoardScope & PoliciesPeer ReviewFAQSubmit
LIBRARIANS
TestimonialsSubscriptionsAccessResourcesLibrary Advisory BoardFAQ
RESEARCH
JoVE JournalMethods CollectionsJoVE Encyclopedia of ExperimentsArchive
EDUCATION
JoVE CoreJoVE BusinessJoVE Science EducationJoVE Lab ManualFaculty Resource CenterFaculty Site
Terms & Conditions of Use
Privacy Policy
Policies

Related Concept Videos

The Anatomy of Chloroplasts01:08

The Anatomy of Chloroplasts

7.0K
Green algae and plants, including green stems and unripe fruit, harbor specialized organelles called chloroplasts to carry out photosynthesis. They coordinate both stages of photosynthesis — the light-dependent reactions and the light-independent reactions. The light-dependent reactions use sunlight to release oxygen and produce chemical energy in the form of ATP and NADPH, and the light-independent reactions capture CO2 and use ATP and NADPH to produce sugar.
Structure of...
7.0K
Diversity of Protists I01:15

Diversity of Protists I

2.3K
Excavata is a diverse group of protists that includes both chemoorganotrophic and phototrophic species, with some thriving in anaerobic environments. Among the key groups within Excavata are diplomonads and parabasalids, which are flagellated protists that lack mitochondria and chloroplasts. These microorganisms typically inhabit anoxic environments, such as the intestines of animals, where they exist either symbiotically or as parasites, relying on fermentation for energy production. Some...
2.3K
Diversity of Protists II01:27

Diversity of Protists II

2.3K
Alveolates are a group of organisms recognized by the presence of alveoli, which are cytoplasmic sacs located beneath the cell membrane. While their function remains uncertain, alveoli may help regulate water balance by controlling how much water enters and leaves the cell. In dinoflagellates, these structures may serve as armor plates. There are three major types of alveolates: ciliates, which move using cilia; dinoflagellates, which use flagella for movement; and apicomplexans, which are...
2.3K
Overview of Protists01:27

Overview of Protists

3.3K
Protists are diverse eukaryotic microorganisms that lack the specialized tissues of plants and animals and the chitinous cell walls of fungi. Their early divergence within Eukarya resulted in structural, functional, and ecological diversity. They are classified into supergroups such as Archaeplastida, Excavata, Amoebozoa, Rhizaria, Alveolata, and Stramenopiles, determined through genetic analysis and structural similarities.Structural and Functional AdaptationsProtists have various adaptations...
3.3K
Diversity of Protists III01:27

Diversity of Protists III

2.1K
Rhizaria are a diverse group of unicellular protists characterized by their threadlike cytoplasmic extensions known as pseudopodia. These structures aid in both locomotion and feeding, giving Rhizaria an amoeboid appearance. Their amoeboid morphology once led to taxonomic confusion, but molecular phylogenetics has clarified their evolutionary placement and emphasized their shared use of pseudopodia despite divergent lineages.This clade comprises diverse lineages such as Chlorarachniophyta,...
2.1K
Microbial Interactions: Parasitism01:22

Microbial Interactions: Parasitism

108
Parasitism is a form of microbial interaction in which parasitic microbes exploit a host organism for nutrients and shelter, often at the host's expense. Unlike mutualistic relationships, where both organisms benefit, parasitism benefits only the parasite and harms the host.Classification of ParasitesMicrobial parasites are broadly classified based on their location relative to the host.Ectoparasites remain on the host’s surface, such as the skin or outer tissues, drawing nutrients...
108

You might also read

Related Articles

Articles linked to this work by shared authors, journal, and citation graph.

Sort by
Same author

Hydrodynamic characterization of the SufBC and SufCD complexes and their interaction with fluorescent adenosine nucleotides.

Protein science : a publication of the Protein Society·2008
Same author

The kinetic mechanism of the SufC ATPase: the cleavage step is accelerated by SufB.

The Journal of biological chemistry·2006
Same author

Organelle-specific cochaperonins in apicomplexan parasites.

Molecular and biochemical parasitology·2005
Same author

The transcriptome: malariologists ride the wave.

BioEssays : news and reviews in molecular, cellular and developmental biology·2004
Same author

The use of DsRED in single- and dual-color fluorescence labeling of mitochondrial and plastid organelles in Plasmodium falciparum.

Molecular and biochemical parasitology·2004
Same author

Spotlight: re-evaluating replicating organelles.

Protist·2003
Same journal

Animal empathy reconsidered: a multidimensional profile account.

Biological reviews of the Cambridge Philosophical Society·2026
Same journal

Dynamic molecular networks unveil the mechanism behind hypoxia-induced tumour cell dormancy.

Biological reviews of the Cambridge Philosophical Society·2026
Same journal

Kin discrimination in plants: overview and implications for population and community ecology.

Biological reviews of the Cambridge Philosophical Society·2026
Same journal

Review of the fauna associated with wild and farmed mussels and oysters in the Mediterranean.

Biological reviews of the Cambridge Philosophical Society·2026
Same journal

What drives animal responses to high severity fire? The role of functional traits.

Biological reviews of the Cambridge Philosophical Society·2026
Same journal

Partners or passengers? Revisiting the association between diatoms and aquatic animals.

Biological reviews of the Cambridge Philosophical Society·2026
See all related articles

Related Experiment Video

Updated: May 2, 2026

Layers of Symbiosis - Visualizing the Termite Hindgut Microbial Community
11:28

Layers of Symbiosis - Visualizing the Termite Hindgut Microbial Community

Published on: May 28, 2007

36.4K

Parasite plastids: approaching the endgame.

R J M Iain Wilson1

  • 1National Institute for Medical Research, Mill Hill, London, NW7 1AA, UK. rwilson@nimr.mrc.ac.uk

Biological Reviews of the Cambridge Philosophical Society
|February 25, 2005
PubMed
Summary
This summary is machine-generated.

Targeting the malaria parasite

More Related Videos

Leveraging Micro-CT Scanning to Analyze Parasitic Plant-Host Interactions
06:23

Leveraging Micro-CT Scanning to Analyze Parasitic Plant-Host Interactions

Published on: January 12, 2022

2.0K
Author Spotlight: Identifying Compensatory Pathways in Malaria Parasites Containing Hypomorphic Allele of Essential Protein Kinases
09:13

Author Spotlight: Identifying Compensatory Pathways in Malaria Parasites Containing Hypomorphic Allele of Essential Protein Kinases

Published on: November 22, 2024

1.4K

Related Experiment Videos

Last Updated: May 2, 2026

Layers of Symbiosis - Visualizing the Termite Hindgut Microbial Community
11:28

Layers of Symbiosis - Visualizing the Termite Hindgut Microbial Community

Published on: May 28, 2007

36.4K
Leveraging Micro-CT Scanning to Analyze Parasitic Plant-Host Interactions
06:23

Leveraging Micro-CT Scanning to Analyze Parasitic Plant-Host Interactions

Published on: January 12, 2022

2.0K
Author Spotlight: Identifying Compensatory Pathways in Malaria Parasites Containing Hypomorphic Allele of Essential Protein Kinases
09:13

Author Spotlight: Identifying Compensatory Pathways in Malaria Parasites Containing Hypomorphic Allele of Essential Protein Kinases

Published on: November 22, 2024

1.4K

Area of Science:

  • Parasitology
  • Molecular Biology
  • Drug Discovery

Background:

  • The malaria parasite Plasmodium spp. possesses a non-photosynthetic plastid organelle.
  • Genomic and transcriptional data are being analyzed to understand plastid functions.
  • Established antimicrobial strategies are being explored for new antimalarial drug development.

Purpose of the Study:

  • To review current research on the Plasmodium plastid.
  • To highlight the need for clinical applications of plastid-targeted research.
  • To emphasize intensified efforts in discovering novel plastid inhibitors.

Main Methods:

  • Analysis of genomic and transcriptional data.
  • Elucidation of metabolic and housekeeping functions.
  • Structural investigations of plastid-associated enzymes.

Main Results:

  • Several plastid functions based on bacterial biochemistry have been identified.
  • Potential drug targets within the plastid have been identified.
  • Research is progressing towards understanding the plastid's role in parasite survival.

Conclusions:

  • Understanding the Plasmodium plastid is crucial for developing new antimalarials.
  • Drug resistance necessitates intensified research into novel therapeutic targets like the plastid.
  • A focus on clinical outcomes is essential for translating research into effective treatments.