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Usage Examples
Filter by Meaning Bacterial infections are caused by prokaryotic organisms.
Prokaryotic horizontal gene transfer is a significant contributor to the genetic diversity of microbial communities.
The prokaryotic genome is circular and smaller in size than the eukaryotic genome.
Prokaryotic metabolism can be aerobic or anaerobic depending on the type of organism.
The thickness of the prokaryotic cell wall can vary between different species.
Prokaryotic organisms play an important role in nutrient cycling in ecosystems.
The exchange of antibiotic resistance genes through prokaryotic horizontal transfer is a growing public health concern.
In prokaryotic transcription, the RNA polymerase can begin transcription before the transcriptional unit is fully unwound.
The cell walls of prokaryotic cells are often composed of peptidoglycan, a unique macromolecule not found in eukaryotic cells.
Prokaryotic organisms are often classified based on their shape, such as cocci, bacilli, or spirilla.
The activity of prokaryotic microbes is essential for maintaining the health of soil ecosystems, which in turn supports the growth of crops and other plants.
Transduction is another mechanism of prokaryotic horizontal gene transfer that involves the transfer of DNA by a bacteriophage.
Prokaryotic organisms play an important role in the nitrogen cycle.
The prokaryotic community in soil affects the cycling of carbon and other nutrients.
Prokaryotic microbes are involved in the production of methane, a potent greenhouse gas, in wetland ecosystems.
Prokaryotic nitrogen fixation is a key process for maintaining soil fertility.
Prokaryotic cells typically have a single, circular chromosome.
Prokaryotic cells have a cell wall made of peptidoglycan.
Prokaryotic cells have a simpler transcription and translation process than eukaryotic cells.
Prokaryotic organisms lack membrane-bound organelles, such as mitochondria and chloroplasts.
Most bacteria are prokaryotic and have a single circular chromosome.
Prokaryotic horizontal gene transfer has been observed between distantly related bacterial species.
The ribosomes of prokaryotic cells are smaller than those of eukaryotic cells.
The prokaryotic mRNA has a shorter half-life compared to eukaryotic mRNA.
Archaea are known for their prokaryotic cell structure.
Prokaryotic organisms are capable of a wide range of metabolic processes, including photosynthesis, fermentation, and respiration.
Prokaryotic cells reproduce through binary fission, a simple form of asexual reproduction.
Prokaryotic microorganisms play a role in the breakdown of pollutants in the environment, helping to clean up contaminated sites.
The cell wall of prokaryotic organisms is composed of peptidoglycan.
The prokaryotic metabolic pathway involves glycolysis, the TCA cycle, and electron transport chain.
The 70S ribosome is the primary ribosome found in prokaryotic cells.
The genetic material in prokaryotic cells is not contained within a membrane-bound nucleus.
The initiation of prokaryotic translation involves recognition of a Shine-Dalgarno sequence.
The sigma factor is a key component of prokaryotic transcription initiation.
Prokaryotic cells have a simple cell wall that provides shape and protection to the cell.
The cell wall of prokaryotic organisms can help to maintain osmotic balance.
Some prokaryotic organisms have specialized structures called endospores within their cell walls.
The cell walls of prokaryotic cells are made of peptidoglycan.
The cytoplasm of a prokaryotic cell contains ribosomes for protein synthesis.
The Shine-Dalgarno sequence is important for efficient translation initiation in prokaryotic cells.
Understanding prokaryotic metabolism is crucial for the development of new antimicrobial therapies.
Prokaryotic cells are the simplest and most primitive forms of life on Earth.
The regulation of prokaryotic metabolism is an active area of research.
The genome of prokaryotic organisms can vary greatly in size, from a few hundred kilobases to over 10 megabases.
The mechanisms of prokaryotic horizontal gene transfer are diverse and complex, and involve a range of genetic elements and molecular machinery.
The study of prokaryotic metabolism has led to the discovery of novel enzymes and metabolic pathways.
Prokaryotic organisms are found in almost every environment on Earth, from soil to water to the human body.
Prokaryotic organisms can be used in biotechnology to produce useful compounds such as antibiotics.
The prokaryotic flagellum is composed of different proteins than the eukaryotic flagellum.
Prokaryotic cells are often much smaller than eukaryotic cells.
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