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Cofactors and Coenzymes01:24

Cofactors and Coenzymes

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Enzymes are proteins made of amino acids. The functional group of each constituent amino acid catalyzes a wide variety of chemical reactions via ionic interactions or acid-base reactions. However, amino acids cannot catalyze oxidation-reduction and group transfer reactions and need to be aided by non-protein components called cofactors. Cofactors are also referred to as the chemical teeth of an enzyme.
Cofactors can be metallic ions or organic molecules called coenzymes. These types of helper...
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Compounds Essential to Human Function01:25

Compounds Essential to Human Function

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The human body is composed of cells that are fundamentally made up of several different molecules. These molecules are essential to carry out all physiological processes in the body and are broadly classified into organic and inorganic based on their chemical structures.
Inorganic Compounds Essential to Human Functioning
Inorganic compounds essential to human functioning include water, salts, acids, and bases. These compounds are inorganic, i.e., they do not have a carbon-hydrogen bond. Water...
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Animal Mitochondrial Genetics02:59

Animal Mitochondrial Genetics

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Among all the organelles in an animal cell, only mitochondria have their own independent genomes. Animal mitochondrial DNA is a double-stranded, closed-circular molecule with around 20,000 base pairs. Mitochondrial DNA is unique in that one of its two strands, the heavy, or H, -strand is guanine rich, whereas the complementary strand is cytosine rich and called the light, or L, -strand. Compared to nuclear DNA, mitochondrial DNA has a very low percentage of non-coding regions and is marked by...
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Pleiotropy01:33

Pleiotropy

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Pleiotropy is the phenomenon in which a single gene impacts multiple, seemingly unrelated phenotypic traits. For example, defects in the SOX10 gene cause Waardenburg Syndrome Type 4, or WS4, which can cause defects in pigmentation, hearing impairments, and an absence of intestinal contractions necessary for elimination. This diversity of phenotypes results from the expression pattern of SOX10 in early embryonic and fetal development. SOX10 is found in neural crest cells that form melanocytes,...
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Proteins: Dietary Sources and Requirements01:28

Proteins: Dietary Sources and Requirements

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Consuming animal-based products offers high-quality proteins that contain optimal levels and combinations of essential amino acids, crucial for tissue repair and growth. Foods like eggs, milk, fish, and most meats are a source of complete proteins. Legumes and cereals are abundant in proteins; however, they typically lack a full range of essential amino acids. As a result, they are considered incomplete protein sources. Some plant sources like soybeans, quinoa, and amaranth do contain complete...
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Mitochondrial Precursor Proteins01:39

Mitochondrial Precursor Proteins

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Mitochondrial precursors are partially unfolded or loosely folded polypeptide chains. Newly synthesized precursors are inhibited from spontaneously folding into their native conformation by the cytosolic chaperones, heat shock proteins 70 (Hsp70), and mitochondrial import stimulation factors (MSFs). Precursors bound to MSFs are guided to the TOM70-TOM37 receptors, while precursors bound to Hsp70  chaperones are targetted to TOM20-TOM22 receptor complexes.
Most of the mitochondrial...
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Related Experiment Video

Updated: Sep 10, 2025

Assessment of Open Probability of the Mitochondrial Permeability Transition Pore in the Setting of Coenzyme Q Excess
07:35

Assessment of Open Probability of the Mitochondrial Permeability Transition Pore in the Setting of Coenzyme Q Excess

Published on: June 1, 2022

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Evolutionary clues unlock CoQ10 biofortification.

Florian Hänsel1, Goetz Hensel2

  • 1Heinrich Heine University Düsseldorf, Faculty of Mathematics and Natural Sciences, Synthetic Microbiology, Düsseldorf, Germany; Cluster of Excellence on Plant Sciences (CEPLAS), Heinrich Heine University Düsseldorf, Germany.

Trends in Plant Science
|August 27, 2025
PubMed
Summary

Coenzyme Q (CoQ) is essential for health but hard to supplement from plants due to structural differences. This study identified evolutionary targets for engineering crops to improve CoQ levels and nutritional value.

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Quantification of Coenzyme A in Cells and Tissues
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Related Experiment Videos

Last Updated: Sep 10, 2025

Assessment of Open Probability of the Mitochondrial Permeability Transition Pore in the Setting of Coenzyme Q Excess
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Quantification of Coenzyme A in Cells and Tissues
08:51

Quantification of Coenzyme A in Cells and Tissues

Published on: September 27, 2019

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Area of Science:

  • Plant biology
  • Nutritional science
  • Evolutionary biology

Background:

  • Coenzyme Q (CoQ) is crucial for human health, acting as a vital antioxidant and electron carrier in cellular respiration.
  • Dietary intake is a significant source of CoQ, yet structural variations in plants limit effective supplementation.
  • Enhancing CoQ levels in crops presents a promising strategy for biofortification and improving public health.

Purpose of the Study:

  • To investigate the evolutionary diversification of Coenzyme Q biosynthesis pathways across diverse plant lineages.
  • To identify specific genetic targets within these pathways that can be engineered to increase CoQ content in crops.
  • To provide a framework for utilizing evolutionary insights to guide crop biofortification strategies.

Main Methods:

  • Phylogenetic analysis of CoQ biosynthesis genes across a wide range of plant species.
  • Comparative genomics to identify conserved and divergent regions associated with CoQ production.
  • Bioinformatic tools to predict the functional impact of identified genetic variations on CoQ levels.

Main Results:

  • Xu et al. successfully traced the evolutionary history of Coenzyme Q diversification in plants.
  • Distinct evolutionary signatures and potential engineering targets were identified across different plant groups.
  • The study provides a detailed map of CoQ pathway evolution, highlighting key diversification events.

Conclusions:

  • Evolutionary signatures offer a powerful tool for understanding and manipulating metabolic pathways in plants.
  • Targeted genetic engineering based on evolutionary insights can enhance CoQ levels in crops.
  • This research paves the way for developing biofortified crops to improve CoQ nutrition.