Plant cells need both chloroplasts and mitochondria because they perform both photosynthesis and cell respiration.

cytoplasm

Both plant and animal cells are eukaryotic, so they contain membrane-bound organelles like the nucleus and mitochondria. Plants and animals are very different on the outside as well as on the cellular level. Both animal and plant cells have. mitochondria, but only plant cells have chloroplasts.

Both animal and plant cells have mitochondria, but only plant cells have chloroplasts. Plants don’t get their sugar from eating food, so they need to make sugar from sunlight. This process (photosynthesis) takes place in the chloroplast.

​Mitochondria Mitochondria are membrane-bound cell organelles (mitochondrion, singular) that generate most of the chemical energy needed to power the cell’s biochemical reactions. Chemical energy produced by the mitochondria is stored in a small molecule called adenosine triphosphate (ATP).

Plants have both mitochondria and chloroplasts; they can produce their own glucose to fuel cellular respiration.

Chloroplasts are present in photosynthetic plants and is responsible for making the food of the plant. It is important to note that plants need both chloroplasts and mitochondria because without one organelle say the mitochondria the entire cell would be unable to carry out its life activities.

How do the chloroplast and mitochondria work together to keep plant cells alive? Chloroplasts convert sunlight into food during photosynthesis, then mitochondria makes energy out of the food in the form of ATP. where critical chemical reactions occur in the cell that allow for the release of energy from food.

Explanation: While plant cells have chloroplasts to photosynthesize, they also require ATP for cellular functions, and do use oxygen to break down some of the sugar they produce in order to generate that ATP. They need mitochondria for this.

Importantly, mitochondrial DNA is inherited from the mother, while the other type of DNA, nuclear DNA, is inherited from both parents. A cell can have some mitochondria with a mutation in their mtDNA and some that do not, a phenomenon known as heteroplasmy.

Our mitochondrial DNA accounts for a small portion of our total DNA. It contains just 37 of the 20,000 to 25,000 protein-coding genes in our body. But it is notably distinct from DNA in the nucleus. Unlike nuclear DNA, which comes from both parents, mitochondrial DNA comes only from the mother.

A mitochondrial DNA test (mtDNA test) traces a person’s matrilineal or mother-line ancestry using the DNA in his or her mitochondria. mtDNA is passed down by the mother unchanged, to all her children, both male and female. A mitochondrial DNA test, can therefore be taken by both men and women.

Mitochondrial DNA (mtDNA) is genetic material found in mitochondria. It is passed down from mothers to both sons and daughters, but sons cannot pass along their mothers’ mtDNA to their children. This is because mtDNA is transmitted through the female egg. You inherited your mtDNA exclusively from your mother.

There are three different mitochondrial genome types found in plants and fungi. The first type is a circular genome that has introns (type 2) and may range from 19 to 1000 kbp in length. The second genome type is a circular genome (about 20–1000 kbp) that also has a plasmid-like structure (1 kb) (type 3).

about 200,000 years

Inside the mitochondrion is a certain type of DNA. That’s different in a way from the DNA that’s in the nucleus. This DNA is small and circular. Mitochondrial DNA, unlike nuclear DNA, is inherited from the mother, while nuclear DNA is inherited from both parents.

Mitochondria, using oxygen available within the cell convert chemical energy from food in the cell to energy in a form usable to the host cell. NADH is then used by enzymes embedded in the mitochondrial inner membrane to generate adenosine triphosphate (ATP). In ATP the energy is stored in the form of chemical bonds.

Mitochondria are known as the powerhouses of the cell. The F1Fo-ATP synthase of the mitochondrial inner membrane produces the bulk of cellular ATP. The respiratory chain complexes pump protons across the inner membrane into the intermembrane space and thereby generate a proton-motive force that drives the ATP synthase.

You can think of the mitochondria as the energy factory or power plant of the cell. Mitochondria produce energy through the process of cellular respiration. The mitochondria take food molecules in the form of carbohydrates and combine them with oxygen to produce the ATP.