Biologists think that endosymbiosis gave rise to mitochondria before plastids partly because
a. The products of photosynthesis could not be metabolized without mitochondrial enzymes.
b. All eukaryotes have mitochondria (or their remnants), whereas many eukaryotes do not have plastids.
c. Mitochondrial DNA is less similar to prokaryotic DNA than is plastid DNA.
d. Without mitochondrial CO₂ production, photosynthesis could not occur.

Endosymbiosis is a theory that explains the origin of eukaryotic cells from prokaryotic organisms. It suggests that mitochondria and plastids, such as chloroplasts, originated as free-living bacteria that were engulfed by a host cell. This symbiotic relationship eventually led to the bacteria becoming integral organelles within the eukaryotic cell, providing essential functions like energy production and photosynthesis.

Mitochondria are organelles responsible for producing energy through cellular respiration, while plastids, including chloroplasts, are involved in photosynthesis. The presence of mitochondria in all eukaryotic cells, as opposed to plastids, which are only found in plants and some protists, supports the idea that mitochondria were acquired earlier in evolutionary history. This distinction is crucial for understanding the sequence of endosymbiotic events.

Eukaryotic diversity refers to the wide range of organisms that possess eukaryotic cells, including animals, plants, fungi, and protists. The fact that all eukaryotes have mitochondria, while only some have plastids, suggests that the acquisition of mitochondria was a more fundamental and earlier event in eukaryotic evolution. This helps explain why biologists believe mitochondria appeared before plastids in the evolutionary timeline.