Because your mom said so while she was trippin balls to her 4th period class. then she let basedgod F*ck her B*tch
They are similar because they use the same bonding techniques. However are different because eukaryotic cells have a nucleus creating a much more complex system, therefore they have more DNA than prokaryotic cells.
The regulation of gene expression allows prokaryotic cells, such as bacteria, to better respond to stimuli and to conserve energy and materials
One way that protein synthesis differs between prokaryotes and eukaryotes is that gene groups that produce proteins are organized into operons in prokaryotes, but they are not organized into operons in eukaryotes. Also, protein synthesis in eukaryotes involves more protein and is a more intricate process than in prokaryotes.
Gene regulation can occur in eukaryotic cells before, during, and after transcription.
Yes, both Mendelian and non-Mendelian laws are applicable to prokaryotes. Mendelian laws, such as the law of segregation and the law of independent assortment, describe the inheritance patterns of genes in prokaryotes similarly to how they do in eukaryotes. Non-Mendelian laws, such as incomplete dominance or co-dominance, can also be observed in prokaryotes. However, it is important to note that prokaryotes have different mechanisms of gene transfer, such as horizontal gene transfer, which can give rise to non-Mendelian inheritance patterns.
They are similar because they use the same bonding techniques. However are different because eukaryotic cells have a nucleus creating a much more complex system, therefore they have more DNA than prokaryotic cells.
everything
The regulation of gene expression allows prokaryotic cells, such as bacteria, to better respond to stimuli and to conserve energy and materials
One way that protein synthesis differs between prokaryotes and eukaryotes is that gene groups that produce proteins are organized into operons in prokaryotes, but they are not organized into operons in eukaryotes. Also, protein synthesis in eukaryotes involves more protein and is a more intricate process than in prokaryotes.
Gene regulation can occur in eukaryotic cells before, during, and after transcription.
Prokaryotes have been around for 2 billion more years than eukaryotes so have a much wider diversity. Some prokaryotes can live in extreme environments, so there is a lot to learn from them. Plus the wide range of prokaryotes have not been cataloged while the majority of eukaryotic species have likely been discovered.
Like prokaryotes, eukaryotes must regulate gene expression. This is accomplished primarily by controlling when RNA polymerase binds to the beginning of a gene. This binding cannot take place in eukaryotes without the aid of transcription factor.
Yes, eukaryotes have a membrane-bound nucleus that houses their DNA. This nucleus separates the genetic material from the rest of the cell's activities, allowing for more complex regulation of gene expression.
1. Their genomes are smaller and simpler 2. Gene regulation in prokaryotes is well understood 3. They have short generation times and is therefore easier to analyze the genome of subsequent generations 4. They are easy to culture and monitor
Eukaryotic exons may be spliced in alternative patterns
Histones function in the packaging of DNA as well as in regulation of gene expression in eukaryotic (and some bacterial) cells. Histone proteins are among the most highly conserved proteins in eukaryotes, emphasizing their requirement for the survival of more complex life forms. Cells deficient in histones likely would not survive as the complex genomes of eukaryotes would not have the necessary levels of regulation as well as the DNA would not be efficiently packed and would be fragile and highly susceptible to damage.
Histones function in the packaging of DNA as well as in regulation of gene expression in eukaryotic (and some bacterial) cells. Histone proteins are among the most highly conserved proteins in eukaryotes, emphasizing their requirement for the survival of more complex life forms. Cells deficient in histones likely would not survive as the complex genomes of eukaryotes would not have the necessary levels of regulation as well as the DNA would not be efficiently packed and would be fragile and highly susceptible to damage.