Why are you different from your parents? Everything living be it plant, animal, bacteria or even a virus, has different DNA. Your DNA has different sections for traits called Genes, and those are your body's "instructions" to grow. Different species have different Genes that are usually either incompatible to another's body or it will be good for the body, usually the first. DNA is different from one organism to another by different sets of nitrogen bases that's different sequences are translated into different Genes, which create diversity among seperate organisms.
The nitrogenous base can differ from one nucleotide to another. It can be adenine, guanine, cytosine, or thymine (in DNA) or uracil (in RNA). The sugar and phosphate components remain the same in all nucleotides.
Each chromosome is originally made of one DNA molecule.
Transcription is the process of synthesizing a complementary RNA strand from a DNA template, while replication is the process of making an exact copy of the DNA molecule. Transcription produces RNA, whereas replication produces DNA. Transcription occurs at specific genes, while replication occurs throughout the entire genome.
After DNA replication, each new molecule has one strand of the original DNA molecule and the other strand is composed of new nucleic acids. This is due to the semi-conservative replication of DNA.
DNA actually has 3 forms. A-DNA, B-DNA, and Z-DNA. B-DNA is the kind you are most familiar with and present in most organisms. A-DNA can be found in dehydrated samples while Z-DNA is rare and mostly synthesized in the lab.
A molecule that consists of a piece of DNA from one organism combined with the DNA from a member of another species is known as a recombinant DNA molecule. This molecule is typically created using techniques like genetic engineering to insert specific genes from one organism into another.
The nitrogenous base can differ from one nucleotide to another. It can be adenine, guanine, cytosine, or thymine (in DNA) or uracil (in RNA). The sugar and phosphate components remain the same in all nucleotides.
Each chromosome is originally made of one DNA molecule.
one is a ribosome and one is a dna
The sequence of nucleotide bases, which are adenine (A), thymine (T), cytosine (C), and guanine (G), determines the unique genetic information in each DNA molecule. Variations in this sequence result in different genes and ultimately lead to the diversity observed in living organisms. Additionally, differences in the length or structure of a DNA molecule can also distinguish one from another.
DNA molecules contain genetic information in a double-stranded helical structure, while daughter DNA molecules are formed during DNA replication and consist of two identical copies of the original DNA molecule. Daughter DNA molecules are produced through a semi-conservative process where one strand of the original DNA molecule is conserved in each daughter molecule.
Transcription is the process by which DNA is copied into RNA. It involves the synthesis of an RNA molecule that is complementary to one strand of DNA. This RNA molecule carries the genetic information from the DNA in a form that can be used for protein synthesis.
Transcription is the process of synthesizing a complementary RNA strand from a DNA template, while replication is the process of making an exact copy of the DNA molecule. Transcription produces RNA, whereas replication produces DNA. Transcription occurs at specific genes, while replication occurs throughout the entire genome.
There is one double helix DNA molecule per chromosome.
After DNA replication, each new molecule has one strand of the original DNA molecule and the other strand is composed of new nucleic acids. This is due to the semi-conservative replication of DNA.
DNA actually has 3 forms. A-DNA, B-DNA, and Z-DNA. B-DNA is the kind you are most familiar with and present in most organisms. A-DNA can be found in dehydrated samples while Z-DNA is rare and mostly synthesized in the lab.
Each DNA molecule formed is half new, with one strand coming from the original DNA molecule and the other newly synthesized during replication. This process ensures that each new DNA molecule contains one original strand to serve as a template for accurate replication.