I believe that it is correct to say that RNA is not replicated, but reproduced. DNA, what I know currently, is the only one that replicates itself.
Plus, to my knowledge, you don't need to copy a RNA strand. It's only the tRNA that compliments mRNA.
Plasmids. These small, circular DNA molecules can replicate autonomously within bacterial cells and can carry genes that provide advantages such as antibiotic resistance or the ability to metabolize certain substances. Plasmids are commonly used in genetic engineering and biotechnology research.
The best example of this is Insulin produced in E.coli and this is carried out by recombinant DNA technology wherein the desired gene of interest in inserted into a vector system and then into host cell.
Viral genes encode proteins and enzymes that are necessary for the virus to infect host cells, replicate its genetic material, and produce new virus particles. These genes also help the virus evade the host immune response and manipulate host cell functions to favor virus replication.
Yes, viral genes can redirect the genetic and metabolic activities of a host cell by hijacking the host cell's machinery to replicate the virus. This can lead to changes in the host cell's gene expression and metabolism to favor viral replication and spread.
Organelles replicate through a process called binary fission, where they duplicate their components and divide into two separate organelles. This process is similar to how bacteria replicate. The cell's DNA contains instructions for organelle replication, ensuring that the new organelles have the necessary components for proper function.
if u are talking about genetic info yes but genes no
all of the offspring's genes come from one parent.
bacteriophages injected DNA into cells to replicate instead of protein
The Strand of genes is inserted into the cells DNA. This causes the cells to replicate the virus
The minimum number of genes needed by a living cell can vary depending on the organism. Some simple bacteria can survive with around 200-300 genes, while more complex organisms like humans have around 20,000-25,000 genes. Generally, these genes are necessary to provide the essential functions for the cell to survive and replicate.
Plasmids. These small, circular DNA molecules can replicate autonomously within bacterial cells and can carry genes that provide advantages such as antibiotic resistance or the ability to metabolize certain substances. Plasmids are commonly used in genetic engineering and biotechnology research.
An episome is a genetic element that can exist in both integrated and extrachromosomal forms within a cell. It can replicate independently of the cell's genome, making it capable of autonomous replication. Episomes are commonly found in bacteria and can carry genes that provide advantages, such as antibiotic resistance.
Yes it can. M. laboratorium bacterium is expected to be able to replicate itself with its man-made DNA, making it the most synthetic organism to date, although the molecular machinery and chemical environment that would allow it to replicate would not be synthetic.
Cells do not replicate "In DNA". Cells replicate their DNA during the process of cell division.
The BRCA genes are involved in initiating DNA repair and cell cycle check points, they as as regulators of other tumour supressors genes such as p53 and help the cell repair and damage which may lead to cancer occurring in the cell. In mutant versions of the BRCA genes they cannot perform their roles and damaged DNA may cause the cell to replicate uncontrollably as check point to prevent this has been removed. Genome stabiliy is affected and cancer can develop
The best example of this is Insulin produced in E.coli and this is carried out by recombinant DNA technology wherein the desired gene of interest in inserted into a vector system and then into host cell.
Tumor cells replicate continuously due to genetic mutations that disrupt normal cell cycle regulation. These mutations can activate oncogenes, which promote cell proliferation, and inhibit tumor suppressor genes, which normally prevent excessive cell growth. This uncontrolled replication is a hallmark of cancer.