Golgi apparatus
Related Terms
Adult stem cell research adult stem cells, cell, cell membrane, cells, cellular, cellular division, chloroplast, cilia, cilium, cytoplasm, embryo, embryonic stem cell, embryonic stem cell research, embryonic stem cells, eukaryote, eukaryotic, flagella, flagellum, golgi apparatus, golgi complex, meiosis, mitochondria, mitosis, multicellular, nucleus, organelle, photosynthesis, plasma membrane, prokaryote, prokaryotic, ribosomes, stem cell, stem cell research, umbilical cord stem cell research, umbilical cord stem cells, unicellular, vesicle.
Background
Cell biology, also called cellular biology, is the study of cells, which are the basic units of all living organisms. Cells can only be seen with a microscope. Researchers study the structure and function of cells to learn about living organisms.
Cells make up all of the body's tissues and blood. There are about 200 different types of cells in the human that are specialized to perform specific functions. For instance, cells in the heart are specialized to make it pump blood, and cells in the pancreas are specialized to produce insulin.
Researchers estimate that there are about 10-100 trillion cells in the human body.
Some organisms are single-celled. Bacteria, for instance, are made up of just one cell.
Over the years, researchers have discovered that all cells store genetic information (DNA/RNA). This genetic information is used to produce proteins that regulate the functions and structures in all cells. All cells need energy to function. All cells are enclosed with a thin cellular membrane.
Researchers are particularly interested in studying stem cells. These cells are unspecialized cells that can potentially develop into different types of specialized cells. They are present in many body tissues (such as the brain and liver), umbilical cords, and embryos. Researchers are interested in studying these cells because they may help treat diseases that are currently incurable, such as Alzheimer's disease, Parkinson's disease, or multiple sclerosis (MS). Scientists hope that these cells may replace damaged cells that cause such diseases.
Author information
This information has been edited and peer-reviewed by contributors to the Natural Standard Research Collaboration (www.naturalstandard.com).
Bibliography
American Society for Cell Biology. .
Birch HM, Clayton J. Cell biology: close-up on cell biology. Nature. 2007 Apr 19;446(7138):937-40. .
Institute of Molecular and Cell Biology. .
Maini PK, Baker RE, Chuong CM. Developmental biology. The Turing model comes of molecular age. Science. 2006 Dec 1;314(5804):1397-8. .
Natural Standard: The Authority on Integrative Medicine. .
No authors listed. Abstracts from the Annual Meeting of the German Society for Cell Biology. March 14-17, 2007. Frankfurt, Germany. Eur J Cell Biol Suppl. 2007 Mar;57:7-64. .
Stem Cell Information. .
Basic structure
Cell membrane: The cell membrane, also called the plasma membrane, is the outer boundary of the cell. This structure surrounds the cell and helps control what substances enter or exit the cell. The membrane is made up of two flexible layers of fats and proteins.
Chloroplast: A chloroplast is a small, organ-like structure inside the cell. Chloroplasts are only found in plant cells. They help plants convert sunlight energy into energy that allows the plant to produce food (carbohydrates). This process is called photosynthesis.
Cilia: Cilia are short, hair-like structures on the outside of cells. They act like a propeller for some cells, allowing them to move. Cilia may also help some cells take in food. In humans, the cells that produce mucus in the nose and throat also have cilia. These cilia trap airborne irritants and carry them toward the esophagus where they are swallowed. This helps prevent infections from developing inside the lungs.
Cytoplasm: The cytoplasm is the jelly-like substance that surrounds the nucleus of the cell and contains the organelles. The organelles are small, organ-like structures inside the cell, including the mitochondria, ribosome, and golgi apparatus.
Flagella: A flagellum is a whip-like structure located on the outside of some cells, such as bacteria. Flagella help cells move and/or take in food.
Golgi apparatus: A golgi apparatus, also called golgi complex, is a small, organ-like structure inside of cells. All living organisms except viruses, bacteria, and blue-green algae have a golgi apparatus inside each of their cells. The golgi apparatus is involved in processing and exporting proteins from the cell. For instance, some of these proteins are secreted by the cells, while others are incorporated into the cell membrane.
Mitochondria: The mitochondria are rod-shaped organelles that are often called the powerhouse of the cell. Mitochondria convert nutrients into energy for the cell. All organisms except viruses, bacteria, and blue-green algae have mitochondria inside their cells.
Nucleus: The nucleus is a round, organ-like structure inside cells. It contains the cell's genetic makeup. This genetic material is needed in order for the cell to multiply because it provides the instructions for cellular division.
Ribosome: A ribosome is a small, organ-like structure inside cells. It contains ribonucleic acid (RNA), which translates the genetic information to produce proteins for the cell. Each protein has a specific structure and function in the cell.
Main types of cells
Eukaryote: If a cell has a membrane surrounding its nucleus and organelles, it is a eukaryote. All organisms except viruses, bacteria, and blue-green algae are considered eukaryotes. These cells are more complex than prokaryote cells. The organism's genetic information is contained inside the membrane-bound nucleus.
Prokaryote: If a cell does not have a membrane surrounding its nucleus and organelles, it is called a prokaryote. Single-celled organisms, including bacteria, viruses, and blue-green algae, are called prokaryotes.
Cellular reproduction
General: Cell division occurs when the parent cell divides into two cells, called daughter cells. When a single-celled organism, such as the Amoeba, divides, it forms an entirely new organism. Cell division allows multi-cellular organisms, such as humans, to continually repair and renew of cells. For instance, when the skin is scraped, cells divide to form new skin cells. As a result, the wound heals. There are two types of cellular reproduction:
meiosis and mitosis.
Meiosis: Meiosis, also called sexual reproduction, leads to the production of sperm or egg cells. Meiosis is a two-part cell division process in organisms, including humans, which sexually reproduce. Meiosis produces gametes (sperm or eggs cells) that contain half the number of chromosomes as the parent cell. Chromosomes contain all of the genetic information of an organism.
The parent cell contains 46 chromosomes. During the first phase of meiosis, the parent cell divides into two cells. Each of these new cells contains 23 chromosomes. During the second phase, each of these two cells produces a clone cell that also contains 23 chromosomes. A total of four gametes are now present.
Mitosis: Mitosis, also called asexual reproduction, occurs when one cell divides and creates an identical cell. There are five main phases of mitosis:
interphase, prophase, metaphase, anaphase, and telophase.
During interphase, the cell prepares for division by enlarging and making a copy of its genetic material. During prophase, the genetic material condenses into structures called chromosomes. The membrane that contains the nucleus breaks down and tiny fibers called spindles form at opposite ends of the cell and meet at the equator. During metaphase, the chromosomes move so that they are aligned in the middle of the cell. During anaphase, the paired chromosomes (called chromatids) move to opposite ends of the cell. During telophase, the cell begins to split in half. Two new nuclei emerge at either end of the cell, and one-half of the chromosomes line up near each nucleus. The two cells then split apart completely, forming two new cells that are identical.
Stem cells
General: Stem cells are unspecialized cells that can potentially develop into different types of specialized cells. Researchers are interested in studying these cells because they may help treat diseases that are currently incurable, such as, Alzheimer's disease, Parkinson's disease, or multiple sclerosis (MS).
Adult stem cells (somatic stem cell): Adult stem cells are present in many human body tissues and organs. These cells allow the person to repair damaged cells or produce new cells in a tissue or organ. Researchers have discovered stem cells in more tissues and organs than they once thought possible. Stem cells have been identified in the brain, bone marrow, bloodstream, blood vessels, skeletal muscle, skin, and liver.
Today, adult stem cells are commonly used in patients who need bone marrow transplants. Researchers have been transplanting blood-forming stem cells from the bone marrow for more than 30 years.
Scientists have been studying these cells in laboratories to determine whether adult stem cells can be manipulated to produce specific types of cells. If scientists can find ways to make the adult stem cells produce specialized cells, they may be able to treat diseases. For instance, these specialized cells might be able to replace insulin-producing cells in patients with diabetes or dopamine-producing cells in patients with Parkinson's disease.
One potential advantage of adult stem cells is that they could be taken out of the patient and grown on a petri dish under specific conditions to make specialized cells. Then, the cells could be reintroduced into the same patient. Since the cells originally came from the same patient, there is no chance of rejection.
Unlike embryonic stem cell research, adult stem cell research is widely accepted. This is because the process does not require the destruction of an embryo.
Embryonic stem cells: Embryonic stem cells are present in organisms during the very early stages of development. In an embryo that is three to five days old, these stem cells produce specialized cells that make up the heart, liver, lungs, and other tissues.
Scientists are capable of removing stem cells from a human embryo for research. They are removed from eggs that have been fertilized in a laboratory and then donated for research purposes. Scientists want to learn more about the functions of these cells and how they are different from specialized cells. Researchers have suggested that these cells may be an effective cure for diseases, such as multiple sclerosis (MS). These cells may be able to replace the dead or defective cells that cause such diseases.
Embryonic stem cell research is controversial. Some individuals believe it is unethical to isolate stem cells from an embryo because embryos have the potential to develop into human beings.
In 2001, President George W. Bush approved federal funding for research of more than 60 pre-existing stem cell lines that have already been isolated from embryos. The embryos from which the existing stem cell lines were created had already been destroyed.
Federal funds are not available to isolate stem cells from additional embryos that have been fertilized in a laboratory and then donated for research purposes. Because the government does not currently support using embryos for research, it may only be conducted with private funds.
Umbilical cord stem cells: The umbilical cord, which carries blood, oxygen, and nutrients from the placenta to the baby during pregnancy, also contains stem cells. These cells can be removed from the placenta after the baby is born, and the umbilical cord is not longer needed.
Researchers are studying umbilical cord stem cells as possible treatments for diseases. One potential benefit of these cells is that they are less likely to cause transplant rejection than donated bone marrow or blood stem cells. Transplant rejection occurs when the transplant recipient recognizes the donated cells as foreign invaders and attacks them. Transplant rejection is less likely to occur because umbilical cord stem cells have not developed the features that the recipient's immune system can recognize and attack.
In addition, patients who receive umbilical cord blood have a decreased risk of developing graft-versus host disease (GVHD). This disease occurs when the donated cells attack the recipient's cells because they are identified as foreign. GVHD is less likely to occur because the umbilical cord blood does not contain well-developed immune cells needed to launch an attack.